Title of Invention

A METHOD FOR PRODUCING AN AROMATIC CARBONATE

Abstract Title: A method for producing an aromatic carbonate. Production of an aromatic carbonic ester through an ester exchange reaction between a starting material and a reactant while distilling by-product alcohols and/or by-product dialkyl carbonates off the reaction system, wherein use is made of a specified catalyst.
Full Text DESCRIPTION
PROCESS FOR PRODUCING; AROMATIC CARBONATE
TECHNICAL FIELD
The present invention relates to a method for
producing an aromatic carbonate. More specifically,
the present invention relates to a method capable of
producing a high purity aromatic carbonate in a stable
manner for a long period, which comprises allowing to
react a starting material selected from the group
consisting of a dialkyl carbonate, an alkylaryl
carbonate and a mixture thereof and a reactant selected
from the group consisting of an aromatic monohydroxy
compound, an alkylaryl carbonate and a mixture thereof
in the presence of a metal-containing catalyst which
has a molecular weight of 450 or more and which is in
the form of liquid or dissolved in a liquid phase in
the reaction system, with distilling off by-product
alcohol and/or by-product dialkyl carbonate to the
outside of the reaction system.
BACKGROUND ART
Aromatic carbonate is useful as a raw
material for producing aromatic polycarbonate which is
recently becoming more and more important as an
engineering plastic, without using poisonous phosgene,
or as a raw material for producing isocyanate without
using poisonous phosgene. Referring to the method of

producing an aromatic carbonate, a method is known,
which comprises subjecting dialkyl carbonate, alkylaryl
carbonate or a mixture thereof which is a starting
material and an aromatic monohydroxy compound, an
alkylaryl carbonate or a mixture thereof which is a
reactant to an transesterification to produce a
corresponding aromatic carbonate or an aromatic
carbonate mixture.
However, all such transesterification are an
equilibrium reaction, and due to the reactant-favored
equilibrium and its low reaction rate, industrial
production of aromatic carbonate by this method has
been very difficult. Several approaches have been
proposed in order to make this method improvements, and
most of them relate to catalysts for increasing the
reaction rate and a number of metal-containing
catalysts are known. In a method for producing
alkylaryl carbonate, diaryl carbonate or a mixture
thereof by a reaction between dialkyl carbonate and an
aromatic hydroxy compound, the following catalysts are
proposed as such catalysts: Lewis acid such as
transition metal halide or a compound which produces
Lewis acid (Patent Document 1, Patent Document 2,
Patent Document 3 (which is corresponding to Patent
Documents 4 to 6)), tin compounds such as organic tin
alkoxide and organic tin oxide (Patent Document 7
(which is corresponding to Patent Document 8)), Patent
Document 9, Patent Document 10 (which is corresponding

to Patent Document 11), Patent Document 12 (which is
corresponding to Patent Document 13), Patent Document
14, and Patent Document 15), salts and alkoxides of
alkali metal or alkaline earth metal (Patent Document
16), lead compounds (Patent Document 16), complexes of
metal such as copper, iron or zirconium (Patent
Document 17), titanates (Patent Document 18 which is
corresponding to Patent Document 19), a mixture of
Lewis acid and protonic acid (Patent Document 20 which
is corresponding to Patent Document 21), a compound of
Sc, Mo, Mn, Bi, Te (Patent Document 22) and ferric
acetate (Patent Document 23).
In addition, in a method of producing diaryl
carbonate by disproportionation of diaryl carbonate and
diaryl carbonate by an transesterification between the
same kind of molecules of alkylaryl carbonate, the
following catalysts are proposed as such catalysts:
Lewis acid and a transition metal compound which can
produce Lewis acid (Patent Document 24 which is
corresponding to Patent Documents 25 and 26), a
polymeric tin compound (Patent Document 27 which is
corresponding to Patent Document 28), a compound
represented by the formula R-X(=O)OH (in which X is
selected form Sn and Ti and R is selected from
monovalent hydrocarbon groups) (Patent Document 29
which is corresponding to Patent Document 30), a
mixture of Lewis acid and protonic acid (Patent
Document 31 which is corresponding to Patent Document

32), a lead catalyst (Patent Document 33), a titanium
or zirconium compound (Patent Document 34), a tin
compound (Patent Document 35) and a compound of Sc, Mo,
Mn, Bi, Te (Patent Document 36).
On the other hand, it is also attempted to
improve the yield of aromatic carbonate by shifting the
equilibrium to the product side as much as possible by
designing a suitable reaction system. For example, a
method in which by-product methanol is distilled off
together with an azeotropic agent by azeotropic
distillation in a reaction between dimethyl carbonate
and phenol (Patent Document 37 and corresponding Patent
Documents 38 and 39, Patent Document 40) and a method
in which by-product methanol is removed by adsorption
using molecular sieve (Patent Document 41 which is
corresponding to Patent Document 42) are proposed.
Further, a method in which alcohol produced
by the above-mentioned reaction is distilled off from a
reaction mixture using an apparatus having a
distillation column on the upper part of a reactor is
also known (Examples of Patent Document 43 which is
corresponding to Patent Document 44, Examples of Patent
Document 45, Examples of Patent Document 46 and
corresponding Patent Document 47, Examples of Patent
Document 48 which is corresponding Patent Document 49,
Examples of Patent Document 50 which is corresponding
Patent Document 51), Examples of Patent Documents 52,
53 and 54).

More preferable methods include a method in
which dialkyl carbonate and an aromatic hydroxy
compound are continuously supplied to a multi-stage
distillation column and continuously reacted in the
column while continuously removing produced low boiling
point components including alcohol by distillation and
extracting generated products containing alkylaryl
carbonate from the bottom of the column (Patent
Document 55), and a method in which alkylaryl carbonate
is continuously supplied to a multi-stage distillation
column and continuously reacted in the column while
removing produced low boiling point components
including dialkyl carbonate by distillation and
extracting generated products containing diaryl
carbonate from the bottom of the column (Patent
Document 56). These methods are the first disclosures
of efficient and continuous production of aromatic
carbonate. Similar continuous production methods have
been thereafter filed, such as a method in which
materials are brought into contact in a column type
reactor to perform transesterification (Patent
Documents 57, 58 and 59), a method in which a plurality
of reaction vessels are connected in series (Patent
Documents 60 and 61), a method in which a bubble column
reactor is used (Patent Document 62) and a method in
which a vertical reaction vessel is used (Patent
Document 63).
Regarding industrial production of aromatic

carbonate by these methods, methods for stable and
long-term operation have also been proposed. Patent
Document 64 discloses a method in which aliphatic
alcohol is removed from a distillation column connected
to a reactor so that the concentration of the aliphatic
alcohol in the reactor is 2% by weight or less upon
production of aromatic carbonate from dialkyl carbonate
and an aromatic hydroxy compound, and it is described
that stable continuous operation was achieved. The
method of the publication is directed to avoid problems
of precipitation of catalyst in the distillation
column. Further, Patent Document 65 discloses a method
which enables long-term stable operation by suppressing
precipitation of catalyst by controlling the weight
ratio of an aromatic polyhydroxy compound and/or a
residue thereof to 2 or less relative to the metal
component of the catalyst in a liquid matter in the
system containing the catalyst.
On the other hand, the catalyst used in this
reaction system is usually dissolved in a reaction
mixture under reaction conditions, and has a higher
boiling point than aromatic carbonate. Therefore, to
obtain high purity aromatic carbonate from the reaction
mixture, low boiling point components are first removed
from the mixture and then diaryl carbonate of the high
boiling point components is separated from the catalyst
so as to purify the diaryl carbonate. It is known that
the catalyst may be recovered and reused as a high

boiling point component in that case, and deactivated
components may be removed. Examples of such method of
separating catalyst are described in Patent Document
66.
Titanium compounds are known to be an
excellent catalyst (e.g., Patent Documents 67 and 68).
However, when titanium based catalysts, for example,
titanium phenoxide: Ti(OPh)4 or titanium alkoxide:
Ti(OR)4, is used, there is a problem that diaryl
carbonate which is the final product is colored with
dark red as described in Patent Document 69. This is
because, since titanium butoxide: Ti(OBu)4 typically
used has a boiling point of 206°C at 1.3 KPa and
titanium phenoxide typically used has a boiling point
of about 250°C at about 27 Pa (No patent Document 1),
they are also distilled off in a proportion
corresponding to their vapor pressure upon separation
of diaryl carbonate by distillation and therefore not
sufficiently separated from the product. Further, as
described in Patent Document 70, degradation of
catalyst and deterioration of diaryl carbonate due to
high temperature in separation of titanium phenoxide
have been reported. Also, Patent Document 71 describes
a problem that when Ti(OPh)4 is used and a mixture of
starting materials and a catalyst is supplied to a
continuous multi-stage distillation column to continue
the reaction, the distillation column may be clogged.
Thus, the well-known titanium based catalysts have

problems that due to their high vapor pressure under
reaction conditions, separation of produced diaryl
carbonate is difficult, and the fraction at high
temperature for a long period causes degradation of
catalyst, clogging of the distillation column and
deterioration of diaryl carbonate.
[Patent Document 1] JP-A-51-105032
[Patent Document 2] JP-A-56-123948
[Patent Document 3] JP-A-56-123949
[Patent Document 4] DE 2528412
[Patent Document 5] GB Patent No. 1499530
[Patent Document 6] U.S. Patent No. 4,182,726
[Patent Document 7] JP-A-54-48733
[Patent Document 8] DE 2736062
[Patent Document 9] JP-A-54-63023.
[Patent Document 10] JP-A-60-169444
[Patent Document 11] U.S. Patent No. 4,554,110
[Patent Document 12] JP-A-60-169445
[Patent Document 13] U.S. Patent No. 4,552,704
[Patent Document 14] JP-A-62-277345
[Patent Document 15] JP-A-1-265063
[Patent Document 16] JP-A-57-176932
[Patent Document 17] JP-A-57-183745
[Patent Document 18] JP-A-58-185536
[Patent Document 19] U.S. Patent No. 4,410,464
[Patent Document 20] JP-A-60-173016
[Patent Document 21] U.S. Patent No. 4,609,501
[Patent Document 22] JP-A-1-265064

[Patent Document 23] JP-A-61-172852
[Patent Document 24] JP-A-51-75044
[Patent Document 25] DE 2552907
[Patent Document 26] U.S. Patent No. 4,045,464
[Patent Document 27] JP-A-60-169444
[Patent Document 28] U.S. Patent No. 4,554,110
[Patent Document 29] JP-A-60-169445
[Patent Document 30] U.S. Patent No. 4,552,704
[Patent Document 31] JP-A-60-173016
[Patent Document 32] U.S. Patent No. 4,609,501
[Patent Document 33] JP-A-1-93560
[Patent Document 34] Japanese Patent No. 2540590
[Patent Document 35] JP-A-1-265063
[Patent Document 36] JP-A-1-265064
[Patent Document 37] JP-A-54-48732
[Patent Document 38] DE 736063
[Patent Document 39] U.S. Patent No. 4,252,737
[Patent Document 40] JP-A-61-291545
[Patent Document 41] JP-A-58-185536
[Patent Document 42] U.S. Patent No. 410464
[Patent Document 43] JP-A-56-123948
[Patent Document 44] U.S. Patent No. 4,182,726
[Patent Document 45] JP-A-56-25138
[Patent Document 46] JP-A-60-169444
[Patent Document 47] U.S. Patent No. 4,554,110
[Patent Document 48] JP-A-60-169445
[Patent Document 49] U.S. Patent No. 4,552,704
[Patent Document 50] JP-A-60-173016

[Patent Document 51] U.S. Patent No. 4,609,501
[Patent Document 52] Examples of JP-A-61-172852
[Patent Document 53] Examples of JP-A-61-291545
[Patent Document 54] JP-A-62-277345
[Patent Document 55] JP-A-3-291257
[Patent Document 56] JP-A-4-9358
[Patent Document 57] JP-A-6-41022
[Patent Document 58] JP-A-6-157424
[Patent Document 59] JP-A-6-184058
[Patent Document 60] JP-A-6-234707
[Patent Document 61] JP-A-6-263694
[Patent Document 62] JP-A-6-298700
[Patent Document 63] JP-A-6-345697
[Patent Document 64] JP-A-6-157410
[Patent Document 65] National Publication of
International Patent Application No. 9-11049
[Patent Document 66] JP-A-9-169704
[Patent Document 67] DE Patent No. 2,528,412
[Patent Document 68] DE Patent No. 2,552,907
[Patent Document 69] EP Patent No. 879
[Patent Document 70] JP-A-9-169704
[Patent Document 71] JP-A-2004-307400
[Non-patent Document 1] J. Inorg. Nucl. Chem.
Vol. 28, 2410 (1966)
DISCLOSURE OF THE INVENTION
PROBLEMS TO BE SOLVED BY THE INVENTION
An object of the present invention is to

provide a method of producing high purity diaryl
carbonate in which a catalyst can be easily separated
without the above-described problems, when producing an
aromatic carbonate by allowing to react a starting
material selected from the group consisting of a
dialkyl carbonate, an alkylaryl carbonate and a mixture
thereof and a reactant selected from the group
consisting of an aromatic monohydroxy compound, an
alkylaryl carbonate and a mixture thereof in the
presence of a metal-containing catalyst, with
distilling off by-product alcohol and/or by-product
dialkyl carbonate to the outside of the reaction
system.
MEANS FOR SOLVING THE PLOBLEMS
As a result of intensive studies conducted by
the present inventors to solve the aforementioned
problems, the inventors have found that the object can
be achieved by using a specific metal-containing
catalyst as a catalyst when producing an aromatic
carbonate by allowing to react a starting material
selected from the group consisting of a dialkyl
carbonate, an alkylaryl carbonate and a mixture thereof
with a reactant selected from the group consisting of
an aromatic monohydroxy compound, an alkylaryl
carbonate and a mixture thereof in the presence of a
metal-containing catalyst, with distilling off by-
product alcohol and/or by-product dialkyl carbonate to

the outside of the reaction system, and the present
invention has been completed. Surprisingly, the
present invention can solve the problem of conventional
method that clogging and blocking of distillation
column frequently occur when reactants and a catalyst
are supplied to the middle plate of/the distillation
column, and the present invention also makes it easier
to separate produced diaryl carbonate from other
components and thus can produce high purity diaryl
carbonate in which the amount mixed of a metal compound
derived from a catalyst is extremely small.
Accordingly, the present invention is as
follows.
[1] A method for producing an aromatic
carbonate, which comprises allowing to react a starting
material selected from the group consisting of a
dialkyl carbonate represented by the following formula
(1) an alkylaryl carbonate represented by the
following formula (2) and a mixture thereof with a
reactant selected from the group consisting of an
aromatic monohydroxy compound represented by the
following formula (3), an alkylaryl carbonate
represented by the following formula (4) and a mixture
thereof in the presence of a metal-containing catalyst,
with distilling off by-product alcohols and/or by-
product dialkyl carbonates to the outside of the
reaction system, thereby producing an aromatic
carbonate represented by the following formula (5)

and/or the following formula (6) corresponding to the starting material
and the reactant, wherein the metal-containing catalyst is an organic
polytitanoxane composition of a molecular weight of 480 or more which
comprises at least two titanium atoms and is dissolved in a liquid phase in
the reaction system or present in the form of liquid during the reaction,

(wherein R1, R2 and R3 in the formulas (1) to (4) independently
represent an alkyl group having 1 to 10 carbon atoms, an alicyclic
group having 3 to 20 carbon atoms or an aralkyl group having
6 to 10 carbon atoms,

and Ar1, Ar2 and Ar3 independently represent an aromatic group having 5
to 30 carbon atoms), and

(wherein R and Ar in he formulas (5) and (6) are each selected from R1, R2,
R3, Ar1, Ar2 and Ar3 of the corresponding starting material and reactant).
2. The method according to [1], wherein the organic
polytitanoxane composition contains at least one alkoxy group and/or
aryloxy group as an organic group.
3. The method according to [1], wherein the organic polytitanoxane
composition is obtained by a polycondensation reaction of at least one raw
material selected from the group consisting of tetraalkoxytitanium,
tetrahalotitanium (TiX4: X being selected from Cl and Br) and titanium
hydroxide.
4. The method according to [3], wherein the organic polytitanoxane
composition is obtained by sequentially or simultaneously performing the
two steps of:

1) preparing a partially hydrolyzed product by partially
hydrolyzing tetraalkoxytitanium and
2) distilling off a generated low boiling point component including
alcohol from the partially hydrolyzed product and subjecting the product to
polycondensation.

5. The method according to [3], wherein the organic polytitanoxane
composition is obtained by subjecting tetraalkoxytitanium to heating,
deetherification and polycondensation.
6. The method according to [3], wherein the organic polytitanoxane
composition is obtained by sequentially or simultaneously performing the three
steps of:

1) preparing a partially hydrolyzed product by partially
hydrolyzing tetrahalotitanium,
2) distilling off a low boiling point component from the partially
hydrolyzed product and subjecting the product to polycondensation and
3) reacting the resultant with alcohol, removing HX therefrom and
alkoxylating the same.
7. The method according to any, one of [1] to [6], wherein the
polytitanoxane composition is used as is or after alkoxy group exchange by
reacting

the composition with a composition containing at least one member selected
from alcohol, an aromatic hydroxy compound and carbonic acid ester.
8. The method according to any one of [1] to [7], wherein the titanium
containing compound contains at least two Ti atoms in one molecule.
9. The method according to [8], wherein the titanium containing
compound contains 2 to 6 Ti atoms in one molecule.
10. The method according to [8], wherein the titanium containing
compound contains at least one Ti-O-Ti bond in a molecule.
11. The method according to [1], wherein the metal-containing catalyst
has a vapor pressure at 230° of 10 Pa or lower.
12. The method according to any one of [1] to [11], wherein the metal-
containing catalyst is used in a proportion of 0.0001 to 30% by weight based on
the total weight of the starting material and the reactant.
13. The method according to any one of [1] to [12, wherein the aromatic
hydroxy compound is phenol.
14. Diphenyl carbonate produced by the method according to [13]
containing 1 ppm or less of a metal component derived from the metal-
containing catalyst.

15. Polycarbonate comprising the dephenyl carbonate by the method
according to [13] containing 1 ppm or less of a metal component derived from
the metal-containing catalyst.
Although titanium-based catalysts have excellent catalytic action
including a good reaction rate and selectivity as described above, it was
difficult to separate such titanium catalyst or a titanium containing
compound
derived from the titanium catalyst from produced diaryl carbonate in the
reaction mixture after the reaction and to obtain diaryl carbonate whose
titanium content is small. A novel finding that use of a specific titanium
catalyst facilitates separation has made it possible for the first time to
obtain diaryl carbonate whose titanium content is small without difficulty.
According to the present invention, diaryl carbonate whose
titanium content is small can be easily produced without causing problems such
as coloring due to titanium.
In the following, the present invention is described in
detail. The dialkyl carbonate used in the present invention is
represented by the formula (1):


wherein R1 represents an alkyl group having 1 to 10
carbon atoms, an alicyclic group having 3 to 10 carbon
atoms or an aralkyl group having 6 to 10 carbon atoms.
Examples of dialkyl carbonates containing
such R1 include dimethyl carbonate, diethyl carbonate,
dipropyl carbonate (and isomers thereof), dibutenyl
carbonate (and isomers thereof), dibutyl carbonate (and
isomers thereof), dipentyl carbonate (and isomers
thereof), dihexyl carbonate (and isomers thereof),
diheptyl carbonate (and isomers thereof), dioctyl
carbonate (and isomers thereof), dinonyl carbonate (and
isomers thereof), didecyl carbonate (and isomers
thereof), dicyclopentyl carbonate, dicyclohexyl
carbonate, dicycloheptyl carbonate, dibenzyl carbonate,
diphenetyl carbonate (and isomers thereof),
di(phenylpropyl) carbonate (and isomers thereof),
di(phenylbutyl) carbonate (and isomers thereof),
di(chlorobenzyl) carbonate (and isomers thereof),
di(methoxybenzyl) carbonate (and isomers thereof),
di(methoxymethyl) carbonate, di(methoxyethyl) carbonate
(and isomers thereof), di(chloroethyl) carbonate (and
isomers thereof) and di(cyanoethyl) carbonate (and

isomers thereof). Of these dialkyl carbonates, those
in which R1 contains an alkyl group having 1 to 6 carbon
atoms are preferably used in the present invention. R1
is more preferably an n-butyl group, an isobutyl group
and an alkyl group having 5 or 6 carbon atoms, and
dialkyl carbonate containing a linear or branched alkyl
group in which the carbon atom at the a position of
oxygen is secondary carbon (-CH2-) is preferred.
Particularly preferred are dibutyl carbonate and bis
(2-ethylbutyl) carbonate.
The alkylaryl carbonate used as a starting
material in the present invention is represented by the
formula (2):

wherein R2 may be the same as or different from R1 and
represents an alkyl group having 1 to 10 carbon atoms,
an alicyclic group having 3 to 10 carbon atoms or an
aralkyl group having 6 to 10 carbon atoms, and Ar2
represents an aromatic group having 5 to 30 carbon
atoms.
Examples of such R2 are groups listed above as
R1. Examples of Ar2 include phenyl, tolyl (and isomers
thereof), xylyl (and isomers thereof), alkylphenyls
groups such as trimethylphenyl (and isomers thereof),

tetramethylphenyl (and isomers thereof), ethylphenyl
(and isomers thereof), propylphenyl (and isomers
thereof), butylphenyl (and isomers thereof),
diethylphenyl (and isomers thereof), methylethylphenyl
(and isomers thereof), pentylphenyl (and isomers
thereof), hexylphenyl (and isomers thereof) and
cyclohexylphenyl (and isomers thereof); alkoxyphenyl
groups such as methoxyphenyl (and isomers thereof),
ethoxyphenyl (and isomers thereof) and buthoxyphenyl
(and isomers thereof); halogenated phenyl groups such
as fluorophenyl (and isomers thereof), chlorophenyl
(and isomers thereof) , bromophenyl (and isomers
thereof), chloro(methyl)phenyl (and isomers thereof)
and dichlorophenyl (and isomers thereof); substituted
phenyl groups represented by the following formula (7):

(wherein A represents a bond, a divalent group such as
-O-, -S-, -CO- or - SO2-, an alkylene group or a
substituted alkylene group represented by the following
(8) or a cycloalkylene group represented by the
following (9), and an aromatic ring may be substituted
by a lower alkyl group, a lower alkoxy group, an ester
group, a hydroxy group, a nitro group, a halogen or a
cyano group),


wherein R4, R5, R6 and R7 are each independently a
hydrogen atom, a lower alkyl group, a cycloalkyl group,
an aryl group or an aralkyl group, which may be
optionally substituted by a halogen atom or an alkoxy
group, and

(wherein k is an integer of 3 to 11 and a hydrogen atom
may be substituted by a lower alkyl group, an aryl
group or a halogen atom);
naphthyl (and isomers thereof), substituted naphthyl
groups such as methylnaphthyl (and isomers thereof),
dimethylnaphthyl (and isomers thereof), chloronaphthyl
(and isomers thereof), methoxynaphthyl (and isomers
thereof) and cyanonaphthyl (and isomers thereof); and
substituted or unsubstituted heteroaromatic groups such
as pyridine (and isomers thereof), cumaryl (and isomers
thereof), quinolyl (and isomers thereof), methylpyridyl
(and isomers thereof), chloropyridyl (and isomers

thereof), methylcumaryl (and isomers thereof) and
methylquinolyl (and isomers thereof).
Examples of alkylaryl carbonates containing
such R2 and Ar2 include methyl phenyl carbonate, ethyl
phenyl carbonate, propyl phenyl carbonate (and isomers
thereof), allyl phenyl carbonate, butyl phenyl
carbonate (and isomers thereof), pentyl phenyl
carbonate (and isomers thereof), hexyl phenyl carbonate
(and isomers thereof), heptyl phenyl carbonate (and
isomers thereof), octyl tolyl carbonate (and isomers
thereof), nonyl (ethylphenyl) carbonate (and isomers
thereof), decyl (butylphenyl) carbonate (and isomers
thereof), methyl tolyl carbonate (and isomers thereof),
ethyl tolyl carbonate (and isomers thereof), propyl
tolyl carbonate (and isomers thereof), butyl tolyl
carbonate (and isomers thereof), allyl tolyl carbonate
(and isomers thereof), methyl xylyl carbonate (and
isomers thereof), methyl (trimethylphenyl) carbonate
(and isomers thereof), methyl (chlorophenyl) carbonate
(and isomers thereof), methyl (nitrophenyl) carbonate
(and isomers thereof), methyl (methoxyphenyl) carbonate
(and isomers thereof), methyl cumyl carbonate (and
isomers thereof), methyl (naphthyl) carbonate (and
isomers thereof), methyl (pyridyl) carbonate (and
isomers thereof), ethyl cumyl carbonate (and isomers
thereof), methyl (benzoyl phenyl) carbonate (and
isomers thereof), ethyl xylyl carbonate (and isomers
thereof) and benzyl xylyl carbonate.

Of these alkylaryl carbonates, those in which
R2 is an alkyl group having 1 to 6 carbon atoms, and
more preferably R1 is n-butyl, isobutyl or an alkyl
group having 5 to 6 carbon atoms and Ar2 is an aromatic
group having 6 to 10 carbon atoms are more preferably
used. Particularly preferred are butyl phenyl
carbonate and (2-ethylbutyl) phenyl carbonate. The
starting material used in the present invention is
selected from the group consisting of a dialkyl
carbonate represented by the above-described formula
(1), an alkylaryl carbonate represented by the formula
(2) and a mixture thereof.
The aromatic monohydroxy compound used as a
reactant in the present invention is represented by the
following formula (3), and any compound may be used as
long as a hydroxyl group is directly bonded to the
aromatic group.

In the formula, Ar1 may be the same as or
different from Ar2 and represents an aromatic group
having 5 to 30 carbon atoms. Examples of such Ar1 are
those listed above as Ar2.
Examples of aromatic monohydroxy compounds
having such Ar1 include phenol, alkylphenols such as
cresol (and isomers thereof), xylenol (and isomers

thereof), trimethylphenol (and isomers thereof),
tetramethylphenol (and isomers thereof), ethylphenol
(and isomers thereof), propylphenol (and isomers
thereof), butylphenol (and isomers thereof),
diethylphenol (and isomers thereof), methylethylphenol
(and isomers thereof), methylpropylphenol (and isomers
thereof) , dipropylphenol (and isomers thereof),
methylbutylphenol (and isomers thereof), pentylphenol
(and isomers thereof), hexylphenol (and isomers
thereof) and cyclohexylphenol (and isomers thereof);
alkoxyphenols such as methoxyphenol (and isomers
thereof) and ethoxyphenol (and isomers thereof);
substituted phenols represented by the formula (10):

(wherein A is a group as defined above);
naphthol (and isomers thereof) and substituted
naphthols; and monohydroxy heteroaromatic compounds
such as hydroxypyridine (and isomers thereof),
hydroxycoumarin (and isomers thereof) and
hydroxyquinoline (and isomers thereof). Of these
aromatic mono hydroxy compounds, aromatic mono hydroxy
compounds whose Ar1 is an aromatic group having 6 to 10
carbon atoms are preferred in the present invention,

and phenol is particularly preferred.
The alkylaryl carbonate used as a reactant in
the present invention is represented by the following
formula (4).

In the formula, R3 may be the same as or
different from R1 and R2, and represents an alkyl group
having 1 to 10 carbon atoms, an alicyclic group having
3 to 10 carbon atoms or an aralkyl group having 6 to 10
carbon atoms, and Ar3 may be the same as or different
from Ar1 and Ar2, and represents an aromatic group
having 5 to 30 carbon atoms. Examples of such R3 are
groups listed above as R1, and examples of Ar3 are those
listed above as Ar2.
Examples of alkylaryl carbonates containing
such R3 and Ar3 are those listed above as in the formula
(2). Of these alkylaryl carbonates, those whose R3 has
an alkyl group having 1 to 6 carbon atoms and Ar3 is an
aromatic group having 6 to 10 carbon atoms are
preferably used. R3 is more preferably an n-butyl
group, an isobutyl group or a linear or branched alkyl
group having 5 to 6 carbon atoms in which the carbon
atom at the a position of oxygen is secondary carbon (-
CH2-). Particularly preferred are butyl phenyl

carbonate and (2-ethylbutyl) phenyl carbonate.
The reactant of the present invention is
selected from the group consisting of an aromatic
monohydroxy compound represented by the formula (3), an
alkylaryl carbonate represented by the formula (4) and
a mixture thereof. The method of the present invention
for producing an aromatic carbonate or an aromatic
carbonate mixture, which comprises allowing to react a
starting material and a reactant in the presence of a
metal-containing catalyst typically involves the
reactions of the formulas (E1), (E2), (E3) and (E4).

(In the formulas, R1, R2, R3, Ar1, Ar2 and Ar3
are as defined above; in the reaction formula (E4), Ar
independently represents Ar2 or Ar3 and R independently
represents R2 or R3; when R2=R3 and Ar2=Ar3 in the
reaction formula (E4), the reaction is an
transesterification between the same kind of molecules,

which may also be generally referred to as a
disproportionation reaction.)
When carrying out reactions of the formulas
(E1), (E2), (E3) and (E4) according to the method of
the present invention, one or at least two dialkyl
carbonates and alkylaryl carbonates may be used as
starting materials. Further, one or at least two
aromatic monohydroxy compounds and alkylaryl carbonates
may be used as reactants.
A case in which R2=R3=R and Ar2=Ar3=Ar in the
transesterification represented by the reaction formula
(E4) is preferred because diaryl carbonate and dialkyl
carbonate are obtained by an transesterification of the
same kind of molecules of one alkylaryl carbonate.
Further, when R1=R2=R3=R and Ar1=Ar2=Ar3=Ar in the
reaction formulas (E1) and (E4), diaryl carbonate is
obtained from dialkyl carbonate and an aromatic
monohydroxy compound through alkylaryl carbonate as
described in the following reaction formulas (E5) and
(E6) by combining the reaction represented by the
reaction formula (E1) and the reaction represented by
the reaction formula (E4), and this is a particularly
preferred embodiment of the present invention.


When dialkyl carbonate produced as a by-
product in the reaction represented by the reaction
formula (E6) is reused as a raw material of the
reaction represented by the reaction formula (E5), 1
mole of diaryl carbonate and 2 moles of aliphatic
alcohol are produced from 1 mole of dialkyl carbonate
and 2 moles of an aromatic monohydroxy compound. In
the above-described reaction formula (E5), when R is
selected from n-butyl, iso-butyl and an alkyl group
having 5 to 6 carbon atoms and Ar=C6H5, by-product
alcohol has the lowest boiling point in the reaction
system and forms no azeotrope with dialkyl carbonate
which is a reactant. This case is particularly
advantageous because the reaction proceeds efficiently
and easily produces diphenyl carbonate which is an
important raw material of polycarbonate and isocyanate.
The metal-containing catalyst used in the
present invention means a specific metal-containing
catalyst which facilitates the aforementioned reactions
of the reaction formulas (E1) to (E4), has a molecular
weight of 450 or more, more preferably a molecular
weight of 480 or more, and is in the form of liquid
(under the above-described reaction conditions) or

dissolved in the liquid phase of the reaction system.
The metal-containing catalyst is preferably a titanium
containing compound containing titanium. Examples of
preferred titanium containing compounds in the form of
liquid under the above-described reaction conditions or
dissolved in the liquid phase of the reaction system
include organopolytitanoxane composition such as
polyorthotitanate and condensed orthotitanate. It is
preferred that the organic polytitanoxane has at least
one alkoxy group and/or aryloxy group as an organic
group.
When the metal-containing catalyst is a
metal-containing catalyst containing titanium and/or a
metal-containing catalyst having a vapor pressure at
230°C of 10 Pa or lower and containing titanium, the
catalyst preferably contains at least two Ti atoms in
one molecule, more preferably 2 to 6 Ti atoms in one
molecule. When the metal-containing catalyst contains
2 or more Ti atoms in one molecule, the compound
contains at least one Ti-O-Ti bond in one molecule.
When the metal-containing catalyst contains Sn, it
contains at least 3 Sn atoms.
Examples of such compounds include metal-
containing catalysts represented by the following
formulas (11), (12) and (13), titanate oligomers
containing at least one titanoxane structure (Ti-O-Ti
bond) (e.g., titanium compounds represented by the
following formula (14)) in one molecule and tin

compounds represented by the following formula (15).
Since the above-described metal-containing catalysts
are easily associated, they may be in the form of a
monomer, in an associated form, or an adduct or an
associated form with alcohol or an aromatic hydroxy
compound. These catalytic components may be a product
of a reaction with an organic compound present in the
reaction system, e.g., aliphatic alcohols, an aromatic
monohydroxy compounds, alkylaryl carbonates, diaryl
carbonates or dialkyl carbonates, or may be heated in
the form of a raw material or a product prior to the
reaction. The titanium compound represented by the
formula (11) and/or the formula (14) (e.g., when R44 to
R61 in the formula (14) are aromatic groups (e.g.,
phenyl group)) tends to form an adduct particularly
with an aromatic hydroxy compound. The structure of
the adduct is unknown by the present analytical
methods, but the structure represented by the following
formula has a molecular weight of 450 or more, more
preferably a molecular weight of 480 or more, excluding
the molecular weight of the molecules involved in the
formation of an adduct. Such molecules involved in the
formation of an adduct may be identified by a method
such as NMR, or the aromatic hydroxy compound involved
in the formation of an adduct may be removed by a known
method (e.g., recrystallization using solvent described
in J. Indian. Chem. Soc, Vol. 38, No. 3, 147-152
(1961)).


In the formula (11), R8, R9, R10, R11, R12, R13,
R14, R15, R16, R17, R18, R19, R20, R21, R22, R23, R24, R25, R26
and R27 independently represent a hydrogen atom, an
alkyl group, an aralkyl group or an aryl group, X1 and
X2 represent an alkyl group, an aralkyl group or an aryl
group; R8, R9, R10, R11, R12, R13, R14, R15, R16, R17, R18,
R19, R20, R21, R22, R23, R24, R25, R26 and R27 are not
simultaneously a hydrogen atom, and at least four of
them are an alkyl group, an aralkyl group or an aryl
group; R28, R29, R30, R31, R32, R33, R34 and R35 may be
covalently bonded within the range that the molecular
weight is 450 or more, and more preferably 480 or more)
(In the formula (12), R28, R29, R30, R31, R32,
R33, R34 and R35 independently represent a hydrogen atom,
an alkyl group, an aralkyl group or an aryl group; X1
and X2 represent an alkyl group, an aralkyl group and an
aryl group; at least two of R28, R29, R30, R31, R32, R33,

R34, R35, X1 and X2 are an aralkyl group or an aryl
group.)

(In the formula (13), R36, R37, R38, R39, R40,
R41, R42 and R43 independently represent a hydrogen atom,
an alkyl group, an aralkyl group or an aryl group, at
least two of them are an aralkyl group or an aryl
group, and these R36 to R43 may be bonded with each
other.)

(In the formula (14), R44, R45, R46, R47, R48,
R49, R50, R51, R52, R53, R54, R55, R56, R57, R58, R59, R60 and

R61 independently represent a hydrogen atom, an alkyl
group, an aralkyl group, an aryl group or an acyl
group, a, b, c, d, e and f independently represent an
integer of 0 to 4, and R44, R45, R46, R47, R48, R49, R50,
R51, R52, R53, R54, R55, R56, R57, R58, R59, R60 and R61 in the
formula (14) each may be covalently bonded.)

(In the formula (15), R62 is an alkyl group,
an aralkyl group or an aryl group having 4 or more
carbon atoms, R63, R64, R65, R66 and R67 independently
represent a hydrogen atom, an alkyl group, an aralkyl
group, an aryl group or an acyl group, g represents an
integer of 1 or more, and R63, R64, R65, R66 and R67 in the
formula (15) each may be covalently bonded.)
Examples of alkyl groups represented by R8 to
R61 include linear or cyclic alkyl groups having 1 to 10
carbon atoms, such as a methyl group, an ethyl group, a
propyl group (and isomers thereof), a butyl group (and
isomers thereof), a pentyl group (and isomers thereof),
a hexyl group (and isomers thereof), a heptyl group
(and isomers thereof), an octyl group (and isomers
thereof), a nonyl group (and isomers thereof), a decyl

group (and isomers thereof), a cyclobutyl group, a
cyclopentyl group (and isomers thereof) and a
cyclohexyl group (and isomers thereof). Those
containing an ether bond are also useful, and examples
thereof include a methoxyethyl group (and isomers
thereof), an ethoxyethyl group (and isomers thereof), a
methoxypropyl group (and isomers thereof), an
ethoxypropyl group (and isomers thereof), a
methoxybutyl group (and isomers thereof) and an
ethoxybutyl group (and isomers thereof).
Examples of aralkyl groups represented by R8
to R61 include aralkyl groups having 7 to 12 carbon
atoms which may have a substituent, such as a benzyl
group and a phenylethyl group.
Examples of aryl groups represented by R8 to
R61 include phenyl or alkylphenyl groups such as phenyl,
tolyl (and isomers thereof), xylyl (and isomers
thereof), trimethylphenyl (and isomers thereof),
tetramethylphenyl (and isomers thereof), ethylphenyl
(and isomers thereof), propylphenyl (and isomers
thereof), butylphenyl (and isomers thereof),
diethylphenyl (and isomers thereof), methylethylphenyl
(and isomers thereof), pentylphenyl (and isomers
thereof), hexylphenyl (and isomers thereof) and
cyclohexylphenyl (and isomers thereof); alkoxyphenyl
groups such as methoxyphenyl (and isomers thereof),
ethoxyphenyl (and isomers thereof) and butoxyphenyl
(and isomers thereof); halogenated phenyl groups such

as fluorophenyl (and isomers thereof), chlorophenyl
(and isomers thereof), bromophenyl (and isomers
thereof), chloro(methyl)phenyl (and isomers thereof)
and dichlorophenyl (and isomers thereof); substituted
phenyl groups represented by the following formula
(16):

(wherein B represents a bond, a divalent group such as
-O-, -S-, -CO- and - SO2-, an alkylene group or a
substituted alkylene group represented by the following
(17) or a cycloalkylene group represented by the
following (18), and an aromatic ring may be substituted
by a lower alkyl group, a lower alkoxy group, an ester
group, a hydroxy group, a nitro group, a halogen or a
cyano group),

(wherein R68, R69, R70 and R71 are each independently a
hydrogen atom, a lower alkyl group, a cycloalkyl group,
an aryl group or an aralkyl group, which may be

optionally substituted by a halogen atom or an alkoxy
group), and

(wherein m is an integer of 3 to 11 and a hydrogen atom
may be substituted by a lower alkyl group, an aryl
group or a halogen atom);
naphthyl (and isomers thereof), substituted naphthyl
groups such as methylnaphthyl (and isomers thereof),
dimethylnaphthyl (and isomers thereof), chloronaphthyl
(and isomers thereof), methoxynaphthyl (and isomers
thereof) and cyanonaphthyl (and isomers thereof); and
substituted or unsubstituted heteroaromatic groups such
as pyridine (and isomers thereof), cumaryl (and isomers
thereof), quinolyl (and isomers thereof), methylpyridyl
(and isomers thereof), chloropyridyl (and isomers
thereof), methylcumaryl (and isomers thereof) and
methylquinolyl (and isomers thereof).
The aryl group represented by R8 to R61 may
also be a hydroxy substituted aryl group which is
represented by the following formula (19):

(wherein Ar4 represent an aromatic group having a

valence of n, n is an integer of 2 or more, and each -
OH group may be bonded to any position of Ar4) .
The residue of the aromatic polyhydroxy
compound is represented by the following formula (20)
and is chemically bonded to at least one member
selected from the group consisting of metal of metal-
containing catalyst, an alkoxycarbonyl group derived
from dialkyl carbonate or alkylaryl carbonate, an
aryloxycarbonyl group derived from alkylaryl carbonate
or diaryl carbonate and a carbonyl group derived from
dialkyl carbonate, alkylaryl carbonate or diaryl
carbonate,

(wherein Ar4 and n are as described above, p is an
integer of 1 to m, and an -OH group and an -O- group
may be bonded to any position of the aromatic ring of
Ar4) .
Examples of Ar4 in the formula (19) and (20)
include aromatic groups represented by the following
formulas (21), (22), (23), (24) and (25):


(wherein Q1 is a single bond, a divalent alkylene group
having 1 to 30 carbon atoms or a divalent group
selected from -O-, -CO-, -S-, - SO2-, -SO- and -COO-);

(wherein Q1 is as defined above and each Q1 may be the
same or different); and

(wherein Q2 represents a tri-valent group such as a tri-
valent alkanetriyl group having 1 to 30 carbon atoms or
a tri-valent aromatic group; at least one hydrogen atom
on an aromatic ring may be substituted by another
substituent such as a halogen atom, an alkoxy group
having 1 to 30 carbon
atoms, a phenyl group, a phenoxy
group, a vinyl group, a cyano group, an ester group, an
amide group or a nitro group).


Examples of such hydroxy substituted aryl
groups include hydroxyphenyl (and isomers thereof),
dihydroxyphenyl (and isomers thereof), trihydroxyphenyl
(and isomers thereof), hydroxytolyl (and isomers
thereof), hydroxyxylyl (and isomers thereof), [1-
(hydroxyphenyl)-1-methyl-ethyl]-phenyl (and isomers
thereof), [4-(hydroxybenzyl)]-phenyl (and isomers
thereof), (hydroxy-phenoxy)-phenyl (and isomers
thereof), hydroxybenzoyl-phenyl (and isomers thereof),
hydroxybiphenyl (and isomers thereof), 2-
(hydroxyphenyl)-hydroxypropyl-phenyl, tri-
hydroxyphenyl) -phenyl (and isomers thereof),
hydroxynaphthyl (and isomers thereof) and
trihydroxynaphthyl (and isomers thereof).
Examples of acyl groups include acyl groups
represented by the following formula (26):

(wherein Ar5 represents an aromatic group).
Examples of aromatic group represented by Ar5
include phenyl or alkylphenyl groups such as phenyl,
tolyl (and isomers thereof), xylyl (and isomers
thereof), trimethylphenyl (and isomers thereof),
tetramethylphenyl (and isomers thereof), ethylphenyl
(and isomers thereof), propylphenyl (and isomers
thereof), butylphenyl (and isomers thereof),

diethylphenyl (and isomers thereof), methylethylphenyl
(and isomers thereof), pentylphenyl (and isomers
thereof), hexylphenyl (and isomers thereof) and
cyclohexyl phenyl (and isomers thereof); alkoxyphenyl
groups such as methoxyphenyl (and isomers thereof),
ethoxyphenyl (and isomers thereof) and butoxyphenyl
(and isomers thereof); halogenated phenyl groups such
as fluorophenyl (and isomers thereof), chlorophenyl
(and isomers thereof), bromophenyl (and isomers
thereof), chloro(methyl)phenyl (and isomers thereof)
and dichlorophenyl (and isomers thereof) and
substituted phenyl groups represented by the
aforementioned formulas (16), (19) and (20).
Examples of such acyl groups include a
benzoyl group, a phthaloyl group, a terephthaloyl group
and a salicyl group.
The same kinds of groups as those selected
from R1, R2, R3, Ar1, Ar2 and Ar3 of the starting
material and/or the reactant are preferred as the
groups of R44 ~ R61 because kinds of products can be
reduced. In case of the compound represented by
formula (11), they are R8 ~ R27 when the molecular
weight of the compound is 450 or more, and more
preferably 4 80 or more. In case of the compound
represented by formula (14), the groups of R44 ~ R61 are
selected so that the molecular weight of the compound
is 450 or more, and more preferably 480 or more.
Examples of alkyl groups represented by R62 in

the formula (15) include a linear or cyclic alkyl group
having 4 to 10 carbon atoms such as a butyl group (and
isomers thereof), a penthyl group (and isomers
thereof), a hexyl group (and isomers thereof), a heptyl
group (and isomers thereof), an octyl group (and
isomers thereof), a nonyl group (and isomers thereof),
a decyl group (and isomers thereof), a cyclobutyl
group, a cyclopentyl group (and isomers thereof) and a
cyclohexyl group (and isomers thereof). Those
containing an ether bond are also useful, and examples
thereof include a methoxyethyl group (and isomers
thereof), an ethoxyethyl group (and isomers thereof), a
methoxypropyl group (and isomers thereof), an
ethoxypropyl group (and isomers thereof), a
methoxybutyl group (and isomers thereof) and an
ethoxybutyl group (and isomers thereof).
Examples of aralkyl groups represented by R62
include aralkyl groups having 7 to 12 carbon atoms
which may have a substituent, such as a benzyl group
and a phenylethyl group.
Examples of aryl groups represented by R62
include phenyl or alkylphenyl groups such as phenyl,
tolyl (and isomers thereof), xylyl (and isomers
thereof), trimethylphenyl (and isomers thereof),
tetramethylphenyl (and isomers thereof), ethylphenyl
(and isomers thereof), propylphenyl (and isomers
thereof), butylphenyl (and isomers thereof),
diethylphenyl (and isomers thereof), methylethylphenyl

(and isomers thereof), pentylphenyl (and isomers
thereof), hexylphenyl (and isomers thereof) and
cyclohexylphenyl (and isomers thereof); alkoxyphenyl
groups such as methoxyphenyl (and isomers thereof),
ethoxyphenyl (and isomers thereof) and butoxyphenyl
(and isomers thereof); halogenated phenyl groups such
as fluorophenyl (and isomers thereof), chlorophenyl
(and isomers thereof), bromophenyl (and isomers
thereof), chloro(methyl)phenyl (and isomers thereof)
and dichlorophenyl (and isomers thereof).
Examples of R63 to R67 in the formula (15)
include alkyl groups, aralkyl groups and aryl groups
listed above as examples of R8 to R61.
The same kinds of groups as those selected
from R1, R2, R3, Ar1, Ar2 and Ar3 of the starting
material and/or the reactant are preferred because
kinds of products can be reduced.
Examples of compounds represented by the
formula (11) include titanium methylphenoxide:
Ti(OPhMe)4 and titanium dimethylphenoxide:
Ti(OPh(Me)2)4.
The compound represented by the formula (12)
has a valence of Ti of 4, and the compound may contain
alcohol or aromatic alcohol as a ligand in the form of
alcoholate or phenolate. Examples of compounds of the
formula (12) include compounds of the following formula
(27) .


Examples of compounds represented by the
formula (13) include titanium-disalicylate, titanium-
bis(2-methyl salicylate) and titanium-bis(3-methyl
salicylate).
Of the titanium containing compounds, an
organic polytitanoxane composition produced by a known
method may be used. Such known methods include a
method in which titanium alkoxide is partially
hydrolyzed and subjected to polycondensation while
removing alcohol (e.g., Journal of Polymer Science,
vol. VII, No. 6, 591-602). Examples of such
polytitanoxane compositions also include ladder
polytitanoxane obtained by the method described in JP-
A-1-129031 and cyclic titanoxane obtained by the method
described in JP-A-1-31793, JP-A-1-52786 and JP-A-64-
52786.

Further, a copolymer with another metal
alkoxide obtained by the method described in JP-B-5-
31900 may be also used. Polytitanoxane or
copolytitanoxane having 2 or more, preferably 2 to 6,
more preferably 4 to 6 Ti atoms in a molecule is
preferably used. These polytitanoxane and
copolytitanoxane may contain at least one Ti-O-Ti bond
in a molecule. Although analysis of Ti-O-Ti bonds is
extremely difficult, researchers in this field now
consider that a Ti-O-Ti bond is formed when titanium
alkoxide described above is partially hydrolyzed and
subjected to polycondensation with removing alcohol,
and the present invention also follows this argument.
Specifically, as shown in the following formula (28),
one Ti-O-Ti bond is formed by partially hydrolyzing
titanium(tetraalkoxide) by adding one molecule of water
per two molecules of titanium(tetraalkoxide) and then
removing two molecules of alcohol.
Further, in the case of a oligomerization
reaction, polytitanoxane having a few Ti-O-Ti bonds in
a molecule can be obtained by adding water in an amount
suitable for the oligomerization degree and removing
produced alcohol. In order to obtain a titanium
compound containing 2 to 6 Ti atoms in a molecule,
tetraalkoxytitanium is partially hydrolyzed by water of
not more than 0.1 to 2-fold mole in a molar ratio
relative to Ti atoms, preferably by water of not more
than 0.3 to 1.5-fold mole, more preferably by water of

not more than 0.5 to 1.2-fold mole in order to avoid
generation of solid components caused by excessive
partial hydrolysis; and then can be obtained by the
polycondensation which removes low boiling point
components. The amount of water used for partial
hydrolysis described above is based on the total amount
of tetraalkoxytitanium used for producing an organic
polytitanoxane composition. All of water necessary for
partial hydrolysis may be used for partial hydrolysis
of part of the tetraalkoxytitanium used for production,
and then the rest of the tetraalkoxytitanium is added
thereto to perform a reaction. In this case, an
organic polytitanoxane composition containing many
branched structures can be obtained. Solid components
generated during partial hydrolysis may be removed by
filtration. Referring to the partial hydrolysis,
tetraalkoxytitanium is dissolved in an alcohol solvent
and the solution is cooled to 80°C or lower, preferably
5°C or lower, then alcohol containing a desired amount
of water is added thereto dropwise over 1 to 5 hours
under stirring, the solution temperature is adjusted to
30°C to 150°C, and the low boiling point components are
removed by distillation. The reaction may be
terminated when alcohol is no longer extracted. A
known reactor may be used, and preferred is a stirring
vessel in which cooling and heating can be performed.
Thus, in the method of producing organic polytitanoxane
of the present invention, organic polytitanoxane can be

obtained by sequentially or simultaneously performing
the two steps of: 1) preparing a partially hydrolyzed
product by partially hydrolyzing tetraalkoxytitanium
and 2) removing the generated low boiling point
component including alcohol from the partially
hydrolyzed product and subjecting the product to
polycondensation.
Alternatively, an organic polytitanoxane
composition may be obtained by partially hydrolyzing
tetrahalotitanium (TiX4: X=Cl, Br), removing -HX
therefrom and subjecting the resultant to a
polycondensation reaction, or by removing -HX from
titanium hydroxide and tetrahalotitanium and subjecting
the resultant to a polycondensation reaction. Also
preferred is an organic polytitanoxane composition
obtained by sequentially or simultaneously performing
the three steps of: 1) preparing a partially hydrolyzed
product by partially hydrolyzing tetrahalotitanium, 2)
removing a low boiling point component from the
partially hydrolyzed product and subjecting the product
to polycondensation and 3) reacting the resultant with
alcohol, removing HX therefrom and alkoxylating the
same.
It is also possible to dealcoholize titanium
hydroxide and tetraalkoxytitanium and subject the
resultant to polycondensation.
Another well-known method for producing an
organic titanoxane composition comprises subjecting

tetraalkoxytitanium to heating, deetherification and
polycondensation. Preferably used is an organic
polytitanoxane composition obtained after removing 0.1
to 2-fold mole, preferably 0.3 to 1.5-fold mole, more
preferably 0.5 to 1.2-fold mole of ether based on
titanium atoms contained in tetraalkoxytitanium at a
deetherification temperature of 100°C to 300°C,
preferably 150°C to 250°C over 1 to 300 hours.
These known organic polytitanoxanes obtained
by a polycondensation reaction of at least one raw
material selected from tetraalkoxytitanium,
tetrahalotitanium (TiX4: X being selected from Cl and
Br) and titanium hydroxide can be used in the present
invention.
The above-described organic polytitanoxane
and metal-containing catalyst may be used as is, or
after exchange of organic groups before use. For
example, they may be used after exchange of alkoxy
groups by reacting with a composition containing at
least one component selected from alcohol, an aromatic
hydroxy compound and carbonic acid ester. In other
words, they may be used after mixing or reacting with a
starting material, a reactant or a by-product of an
transesterification or a disproportionation reaction in
the present invention.
When a conventional organic titanate is used,
more specifically when dimethyl carbonate is used as a
starting material, phenol is used as a reactant and

phenyl titanate [Ph(OPh)4] (phenol adduct also usable)
is used as organic titanate to produce an aromatic
carbonate, specifically, methyl phenyl carbonate,
methyl titanate [Ti(OMe)4] may be generated in the
distillation column in the equilibrium reaction due to
alkoxy exchange. Since methyl titanate is hardly
soluble in the reaction mixture and is subliming, it
may adhere to the wall of the distillation column to
cause clogging. Surprisingly, however, it has been
found that the organic polytitanoxane composition
(titanate oligomer, etc.) used in the present invention
hardly causes such poor solubility or adhesion to walls
due to sublimation.
Whether a Ti-O-Ti bond is present or not may
be simply confirmed by elemental analysis of the
catalyst and NMR. When the structure of an organic
group bonded or coordinated to Ti is known, the amount
of bridging oxygen derived from Ti-O-Ti can be
determined by subtracting the amount of oxygen atoms
derived from the organic group from the elemental
analysis value. The number of bridging oxygen involved
in Ti-O-Ti bonds and the number of the bonds may be
determined from the ratio of the amount of Ti atoms to
the amount of bridging oxygen. In addition, the
valence of Ti and the number of oxygen atoms involved
in Ti-O-Ti may be determined by known X-ray
crystallographic analysis (e.g., JP-A-2004-256719),
assuming that a Ti-O bond is present when the atomic

distance between Ti and 0 is smaller than the sum (2.87
A) of the ionic radii of Ti atom and oxygen atom.

In addition, such polytitanoxane or
copolytitanoxane obtained by a known method may be
alkoxy-substituted by reacting with alcohol or an
aromatic hydroxy compound by a known method (e.g., J.
inorg. nucl. Chem., Vol. 28, 2410 (1966), J. Indian
Chem. Soc, Vol. 38, No. 3, pl47-152 (1961)). These
catalytic components may be a product of a reaction
with an organic compound present in the reaction
system, e.g., aliphatic alcohols, aromatic monohydroxy
compounds, alkylaryl carbonates, diaryl carbonates or
dialkyl carbonates or may be heated prior to the
reaction in the form of a raw material or a product, or
low boiling point components may be removed therefrom
upon heating. The catalyst may be an adduct or an
associated form with alcohol or an aromatic hydroxy
compound present in the reaction system.
The structure of polytitanoxane obtained by
the above-mentioned method is shown in the above-
described formula (14).
Examples of such titanium compounds include

1) linear polytitanate represented by the following
formula (29) and cyclic polytitanate represented by the
following formula (30).

(In the formula (29), R72 represents an alkyl
group having 1 to 10 carbon atoms, an aralkyl, aryl or
acyl group, R72 may be the same or different from each
other or may be bonded with each other, and h is an
integer of 1 to 5).

(In the formula (30), R73 represents an alkyl
group having 1 to 10 carbon atoms, an aralkyl, aryl or
acyl group, R73 may be the same or different from each
other or may be bonded with each other, and i is an
integer of 1 to 4, j is an integer of 0 to 4, and
i+j=4.)

When R72 in the formula (29) and R73 in the
formula (30) have a small number of carbon atoms, the
catalyst itself may not be in the form of liquid, or
may not be in the form of liquid in the reaction system
because it has extremely low solubility in the liquid
phase of the reaction system. Thus, preferred examples
of R72 and R73 are an alkyl group having 3 to 10 carbon
atoms such as a propyl group (and isomers thereof), a
butyl group (and isomers thereof), a pentyl group (and
isomers thereof), a hexyl group (and isomers thereof),
a heptyl group (and isomers thereof), an octyl group
(and isomers thereof), a nonyl group (and isomers
thereof), a decyl group (and isomers thereof), a
cyclobutyl group, a cyclopentyl group (and isomers
thereof) and a cyclohexyl group (and isomers thereof).
Those containing an ether bond are also useful, and
examples thereof include alkyl groups such as a
methoxyethyl group (and isomers thereof), an
ethoxyethyl group (and isomers thereof), a
methoxypropyl group (and isomers thereof), an
ethoxypropyl group (and isomers thereof), a
methoxybutyl group (and isomers thereof) and an
ethoxybutyl group (and isomers thereof). Preferred
examples thereof also include aralkyl groups having 7
to 12 carbon atoms which may have a substituent, such
as a benzyl group and a phenylethyl group. Preferred
examples thereof also include aryl groups, e.g. phenyl
or alkylphenyl groups such as phenyl, tolyl (and

isomers thereof), xylyl (and isomers thereof),
trimethylphenyl (and isomers thereof),
tetramethylphenyl (and isomers thereof), ethylphenyl
(and isomers thereof), propylphenyl (and isomers
thereof), butylphenyl (and isomers thereof) ,
diethylphenyl (and isomers thereof), methylethylphenyl
(and isomers thereof), pentylphenyl (and isomers
thereof), hexylphenyl (and isomers thereof) and
cyclohexylphenyl (and isomers thereof); alkoxyphenyl
groups such as methoxyphenyl (and isomers thereof),
ethoxyphenyl (and isomers thereof) and butoxyphenyl
(and isomers thereof); halogenated phenyl groups such
as fluorophenyl (and isomers thereof), chlorophenyl
(and isomers thereof), bromophenyl (and isomers
thereof), chloro(methyl)phenyl (and isomers thereof)
and dichlorophenyl (and isomers thereof).
Examples of such compounds include compounds
whose structural formula is as described below, e.g.,
butoxy titanate dimer, phenoxy titanate oligomers such
as phenoxy titanate dimer, phenoxy titanate trimer and
phenoxy titanate tetramer (and isomers thereof),
phenoxy salicyl titanate oligomers such as phenoxy-
salicyl-titanate dimer and phenoxy-salicyl-titanate
trimer, titanate dimer (derived from phenol and
bisphenol A) and titanate trimer (derived from phenol
and bisphenol A). Compounds containing 2 to 6 Ti atoms
in a molecule are preferred in terms of their
solubility. Titanate oligomers have molecular weight

distribution, and they may contain a component which
does not satisfy the molecular weight of 450 or more
defined in the present invention, or contain a
component whose vapor pressure at 230°C is 10 Pa or
higher. Such titanate oligomers may be used as is, but
they may be used after removing low boiling point
components or low molecular weight components by
distillation.



These catalytic components may be a product
of a reaction with an organic compound present in the
reaction system, e.g., aliphatic alcohol, an aromatic

monohydroxy compound, alkylaryl carbonate, diaryl
carbonate or dialkyl carbonate or may be heated prior
to the reaction in the form of a raw material or a
product, or low boiling point components may be removed
therefrom upon heating.
Examples of compounds represented by the
formula (15) include monoalkyltin (IV) alkoxide oxide.
Among the scientists of the research field concerned,
it is a common knowledge that no Sn=O double bond is
generally present and monoalkyltin (IV) alkoxide oxide
is usually present in the form of an oligomer of bonded
molecules. Examples of such compounds include butyltin
(IV) butyloxide oxide, butyltin (IV) (2-
ethylbutyloxide) oxide, butyltin (IV)(3-
methoxypropyloxide) oxide, butyltin (IV) (2-
methoxyethoxide) oxide, butyltin (IV) (2-
ethoxyethoxide) oxide, butyltin (IV) phenoxide oxide,
octyltin (IV) butyloxide oxide, octyltin (IV) (2-
ethylbutyloxide) oxide, octyltin (IV) (3-
methoxypropyloxide) oxide, octyltin (IV) (2-
methoxyethoxide) oxide, octyltin (IV) (2-
ethoxyethoxide) oxide and octyltin (IV) phenoxide
oxide.
The types of the reaction vessel used in the
present invention are not particular limited, and any
conventional reaction vessel such as a stirring vessel,
a multi-stage stirring vessel, a multi-stage
distillation column or a combination of these may be

used. These reaction vessels may be used for either a
batchwise reaction or a continuous reaction. In order
to efficiently shift the equilibrium of the reaction in
the direction of the product system, a process using a
multi-stage distillation column is preferred, and a
continuous process using a multi-stage distillation
column is more preferred. Multi-stage distillation
columns have two or more theoretical distillation
stages, and any type may be used as long as it is
capable of performing continuous distillation.
As such a multi-stage distillation column,
any generally used multi-stage distillation column may
be used, and examples thereof include plate type
columns using a tray such as a bubble-cap tray, a sieve
tray, a valve tray or a counterflow tray, and packed
type columns packed with any of various packings such
as a Raschig ring, a Lessing ring, a Pall ring, a Berl
saddle, an Interlox saddle, a Dixon packing, a McMahon
packing, a Heli pack, a Sulzer packing and Mellapak.
Further, a plate-packed column combined type having
both a plate column section and a packed column section
with packings may also be preferably used. When a
continuous process using a multi-stage distillation
column is applied to the production of aromatic
carbonates, starting materials and reactants are
supplied to a continuous multi-stage distillation
column and these materials are allowed to react with
each other in the presence of a metal-containing

catalyst in a liquid phase or in a gas-liquid phase in
the distillation column while simultaneously extracting
the produced high boiling point reaction mixture
containing aromatic carbonate or an aromatic carbonate
mixture in a liquid form from the bottom of the column,
while continuously distilling off the produced low
boiling point reaction mixture containing a by-product
in the form of gas from the upper part of the
distillation column by distillation.
The catalyst in the present invention is used
in a proportion of usually 0.0001 to 30% by weight,
preferably 0.001 to 10% by weight, more preferably 0.01
to 5% by weight based on the total weight of the raw
materials, although the proportion depends on the kind
of the catalyst used, the kind and the amount of raw
materials and reaction conditions such as reaction
temperature and reaction pressure. The reaction time
(residence time in a continuous process) in the present
invention is not particular limited, and is usually
0.001 to 50 hours, preferably 0.01 to 10 hours, more
preferably 0.05 to 5 hours.
The reaction is performed at a reaction
temperature of usually 50 to 350°C, preferably 100 to
280°C depending on the kind of raw material compounds
used. The reaction is performed under reduced
pressure, atmospheric pressure or increased pressure,
usually at 0.1 to 2.0xl07 Pa depending on the kind of
the raw material compounds used and the reaction

temperature. In the present invention, it is not
always necessary to use a reaction solvent, but an
appropriate inert solvent such as ether, aliphatic
hydrocarbon, aromatic hydrocarbon or halogenated
aromatic hydrocarbon may be used as a reaction solvent
in order to facilitate the reaction procedure.
The present invention has a feature that
liquid containing high boiling point materials and a
metal-containing catalyst is removed from the reaction
system and produced aromatic carbonate is transported
in the form of gas, and the liquid containing the
metal-containing catalyst is recycled in the system.
In this process, part of the liquid
containing a metal-containing catalyst may be blown
down and a fresh catalyst may be added to the liquid.
Also, the liquid may be reacted with an active
substance to produce a reaction mixture of a substance
derived from a high boiling point material and a
substance derived from a metal-containing catalyst, and
the mixture is separated into a component composed
mainly of a substance derived from a high boiling point
material and a component composed mainly of a substance
derived from a metal-containing catalyst, and the
substance derived from a metal-containing catalyst may
be recycled in the system.
The term "reaction system" refers to the
space inside the reactor, piping and equipment
surrounding the reactor, equipment and piping for the

catalyst recovery system. The "liquid containing a
high boiling point material and a metal-containing
catalyst" in the present invention refers to liquid
containing a catalyst and a high boiling point material
supplied to the reactor, a reaction mixture containing
a catalyst and a high boiling point material present in
the reactor, a reaction mixture containing a catalyst
and a high boiling point material discharged from the
reactor and a concentrated liquid having increased
concentration of a catalyst and a high boiling point
material by evaporation of part of the reaction
mixture. The catalyst may be completely dissolved in
the liquid or present in the form of slurry. In the
case of slurry, undissolved portions in the slurry are
also included in the "liquid containing a high boiling
point material and a metal-containing catalyst".
The "high boiling point material" in the
present invention is an organic substance whose boiling
point is the same as or higher than that of aromatic
carbonate produced in the present invention. Examples
thereof include aromatic polyhydroxy compounds and
residues thereof, aromatic carboxyl compounds and
residues thereof and xanthones. Another example of
such high boiling point material is a high molecular
weight by-product produced by an additional reaction of
the above-described aromatic polyhydroxy compounds and
residues thereof, aromatic carboxyl compounds and
residues thereof and xanthones.

The aromatic polyhydroxy compound is
represented by the following formula (31):

(wherein Ar6 is an aromatic group having a valence of q,
q is an integer of 2 or more, and each -OH group may be
bonded to any position of Ar6 group).
The residue of the aromatic polyhydroxy
compound is represented by the following formula (32)
and is chemically bonded to at least one member
selected from the group consisting of metal of a metal-
containing catalyst, an alkoxycarbonyl group derived
from dialkyl carbonate or alkylaryl carbonate, an
aryloxycarbonyl group derived from alkylaryl carbonate
or diaryl carbonate and a carbonyl group derived from
dialkyl carbonate, alkylaryl carbonate or diaryl
carbonate

(wherein Ar6 and q are as defined above, v is an integer
of 1 to m, and an -OH group and an -O- group may be
bonded to any position of the aromatic ring of Ar6
group).
Examples of Ar6 in the formulas (23) and (24)
include aromatic groups represented by the following
formulas (33), (34), (35), (36) and (37):


(wherein Y1 is a single bond, a divalent alkylene group
having 1 to 30 carbon atoms or a divalent group
selected from -O-, -CO-, -S-, - SO2-, -SO- and -COO-);

(wherein Y1 is as defined above and each Y1 may be the
same or different); and

(wherein Z represents a trivalent group such as a
trivalent alkanetriyl group having 1 to 30 carbon atoms
and a trivalent aromatic group; at least one hydrogen
atom on an aromatic ring may be substituted by another

substituent such as a halogen atom, an alkoxy group
having 1 to 30 carbon atoms, a phenyl group, a phenoxy
group, a vinyl group, a cyano group, an ester group, an
amide group or a nitro group).

Specific examples of aromatic polyhydroxy
compounds described above include hydroquinone,
resorcin, catechol, trihydroxybenzene (and isomers
thereof), bis-(hydroxyphenyl)-propane (and isomers
thereof), bis-(hydroxyphenyl)-methane (and isomers
thereof), bis-(hydroxyphenyl)-ether (and isomers
thereof), bis-(hydroxyphenyl)-ketone (and isomers
thereof), bis-(hydroxyphenyl)-sulfone (and isomers
thereof), bis-(hydroxyphenyl)-sulfide (and isomers
thereof), dihydroxydiphenyl (and isomers thereof), bis-
(dihydroxyphenyl) methane (and isomers thereof), 2-
(hydroxyphenyl)-hydroxypropyl-phenol, dihydroxy-
(hydroxyphenyldiphenyl) (and isomers thereof), tri-
(hydroxyphenyl) ethane (and isomers thereof), tri-
(hydroxyphenyl)-benzene (and isomers thereof),
dihydroxynaphthalene (and isomers thereof) and
trihydroxynaphthalene (and isomers thereof).
Of these aromatic polyhydroxy compounds and
residues thereof, compounds that are often found in the
process for producing the aromatic carbonate of the
present invention need a careful attention. Examples

of aromatic polyhydroxy compounds often found in the
production process include the following (A), (B) and
(C) .
(A) oxidation product of aromatic monohydroxy compound
which is a reactant
(B) product produced by Fries rearrangement of diaryl
carbonate obtained by the present reaction and
oxidation product thereof
(C) aromatic dihydroxy compound derived from phenol
which is a reactant, represented by the following
formula (38) and oxidation product thereof:

(wherein Y1 is as defined above).
Examples of oxidation products (A) of an
aromatic monohydroxy compound include compounds
represented by the following formulas (39) and (40):

Examples of products (B) produced by Fries

rearrangement of diaryl carbonate include compounds
represented by the following formulas (41), (42) and
(43).

Examples of oxidation products of the
compound represented by the formula (41) include
compounds represented by the formulas (44) and (45).
Examples of oxidation products of the compounds
represented by the formulas (42) and (43) include
compounds represented by the formulas (46) and (47).



Examples of aromatic dihydroxy compounds (C)
represented by the formula (38) include compounds
represented by the formula (48).

Examples of oxidation products of the
compound represented by the formula (48) include

compounds represented by the formulas (49) and (50).

(wherein Y1 is as defined above).
An aromatic polyhydroxy compound of type (A)
is present in the production process because it is
produced by oxidation of an aromatic monohydroxy
compound due to mixing of a trace amount of oxygen to
the system when producing aromatic carbonate, or
because it is incorporated into the reaction system as
impurities contained in the raw material aromatic
monohydroxy compound. Typical examples of aromatic
polyhydroxy compound (A) include dihydroxybenzene (and
isomers thereof) and dihydroxydiphenyl (and isomers
thereof).
A product produced by Fries rearrangement of
diaryl carbonate of type (B) tends to be produced by a
side reaction upon producing diaryl carbonate.
Examples of polyhydroxy compounds (B) include 2,2'-

dihydroxybenzophenone, 2,4'-dihydroxybenzophenone and
4 , 4'-dihydroxybenzophenone.
An aromatic dihydroxy compound of type (C) is
a compound generally used as a monomer for producing
aromatic polycarbonate. Aromatic polycarbonate can be
produced by an transesterification of such aromatic
dihydroxy compound and diaryl carbonate, and in the
transesterification, an aromatic monohydroxy compound
is produced as a by-product. The aromatic dihydroxy
compound of type (C) is easily mixed to the production
process when the by-product aromatic monohydroxy
compound is to be used as a reactant in the present
invention. Typical examples of such polyhydroxy
compounds include 2,2-bis-(4-hydroxyphenyl)-propane.
The aromatic polyhydroxy compounds in the
present invention also include an aromatic polyhydroxy
compound described below, which is generally coexistent
with 2,2-bis-(4-hydroxyphenyl)-propane:



The aromatic carboxyl compound categorized as
a high boiling point material in the present invention
is represented by the formula (51):

(wherein Ar7 is an aromatic group having a valence of r,
r is an integer of 1 or more, s is an integer of 0 to
r-1, and each -OH group and -(COOH) group may be bonded
to any position of Ar7 group).
The residue of the aromatic carboxyl compound
is represented by the formula (52) and is chemically
bonded to at least one member selected from the group
consisting of metal of a metal-containing catalyst, an
alkoxycarbonyl group derived from dialkyl carbonate or
alkylaryl carbonate, an aryloxycarbonyl group derived
from alkylaryl carbonate or diaryl carbonate and a

carbonyl group derived from dialkyl carbonate,
alkylaryl carbonate or diaryl carbonate.

(wherein Ar7, r and s are as defined above, t is an
integer of 0 to s, u is an integer of 0 to r-s, and -OH
group, -(COOH) group, -O- group and -(COO)- group may
be bonded to any position of Ar7).
The particular example of such aromatic
carboxyl compounds and its residues include: aromatic
carbonic acids such as benzoic acid, terephthalic acid,
isophthalic acid, phthalic acid or the like; aromatic
carbonates, such as methyl benzoate, phenyl benzoate,
dimethyl terephtharate or the like; hydroxyl aromatic
carbonic acids such as salicylic acid, p-hydroxybenzoic
acid, m-hydroxybenzoic acid, dihydroxybenzoic acid
(isomers thereof), carboxy diphenol (isomers thereof),
2-(4-hydroxyphenyl)- 2-(3'-carboxy-4'-
hydroxyphenyl)propane or the like; aryloxycarbonyl-
(hydroxyl)-arenes such as phenyl salicylate, phenyl p-
hydroxybenzoate, tolyl salicylate, tolyl p-
hydroxybenzoate, phenyl dihydroxybenzoate (isomers

thereof), tolyl dihydroxybenzoate (isomers thereof),
phenoxycarbonyl diphenol (isomers thereof), 2-(4-
hydroxyphenyl)- 2-(3'-phenoxycarbonyl-4' -
hydroxyphenyl)propane or the like; alkoxycarbonyl-
(hydroxyl)-arenes such as methyl salicylate, methyl p-
hydroxybenzoate, ethyl salicylate, ethyl p-
hydroxybenzoate, methyl dihydroxybenzoate (isomers
thereof), methoxycarbonyl diphenol (isomers thereof),
2-(4-hydroxyphenyl)-2-(3'-methoxycarbonyl-4'-
hydroxyphenyl)propane or the like; aryloxycarbonyl-
(alkoxy)-arenes such as phenyl methoxybenzoate (isomers
thereof), tolyl methoxybenzoate (isomers thereof),
phenyl ethoxybenzoate (isomers thereof), tolyl
ethoxybenzoate (isomers thereof), phenyl hydroxyl-
methoxybenzoate (isomers thereof), hydroxyl-methoxy-
(phenoxycarbonyl)-diphenyl (isomers thereof), 2-(4-
methoxyphenyl)-2-(3'-phenoxycarbonyl-4'-
hydroxyphenyl)propane, 2-(4-hydroxyphenyl)-2-(3'-
phenoxycarbonyl-4'-methoxyphenyl)propane or the like;
aryloxycarbonyl-(aryloxy)-arenes such as phenyl
phenoxybenzoate (isomers thereof), tolyl
phenoxybenzoate (isomers thereof), tolyl
tolyloxybenzoate (isomers thereof), phenyl hydroxyl-
phenoxy-benzoate (isomers thereof), hydroxyl-phenoxy-
(phenoxycarbonyl)-diphenyl (isomers thereof), 2-(4-
phenoxyphenyl)-2-(3'-phenoxycarbonyl-4'-
hydroxyphenyl)propane, 2-(4-hydroxyphenyl)-2-(3' -
phenoxycarbonyl-4'-phenoxyphenyl)propane or the like;

alkoxycarbonyl-(alkoxy)-arenes such as methyl
methoxybenzoate (isomers thereof), ethyl
methoxybenzoate (isomers thereof), methyl
ethoxybenzoate (isomers thereof), ethyl ethoxybenzoate
(isomers thereof), methyl hydroxyl-methoxybenzoate
(isomers thereof), hydroxyl-methoxy-(methoxycarbonyl)-
diphenyl (isomers thereof), 2-(4-methoxyphenyl)-2-(3'-
methoxycarbonyl-4'-hydroxyphenyl)propane, 2-(4-
hydroxyphenyl)-2-(3'-methoxycarbonyl-4'-
methoxyphenyl)propane or the like; alkoxycarbonyl-
(aryloxy)-arenes such as methyl phenoxybenzoate
(isomers thereof), ethyl phenoxybenzoate (isomers
thereof), methyl tolyloxybenzoate (isomers thereof),
ethyl tolyloxybenzoate (isomers thereof), phenyl
hydroxyl-methoxy-benzoate (isomers thereof), hydroxyl-
methoxy- (phenoxycarbonyl) -diphenyl (isomers thereof),
2-(4-methoxyphenyl)-2-(3'-phenoxycarbonyl-4'-
hydroxyphenyl)propane, 2-(4-hydroxyphenyl)-2-(3-
phenoxycarbonyl-4'-methoxyphenyl)propane or the like;
aryloxycarbonyl-(aryloxycarbonyloxy)-arenes such as
phenyl phenoxycarbonyloxybenzoate (isomers thereof),
tolyl phenoxycarbonyloxybenzoate (isomers thereof),
tolyl tolyloxycarbonyloxybenzoate (isomers thereof),
phenyl hydroxyl-phenoxycarbonyloxy-benzoate (isomers
thereof), hydroxyl-phenoxycarbonyloxy-
(phenoxycarbonyl)-diphenyl (isomers thereof), 2-[4-
(phenoxycarbonyloxy)phenyl-2-(3'-phenoxycarbonyl-4'-
hydroxyphenyl)propane, 2-(4-hydroxyphenyl)-2-[3'-

phenoxycarbonyl-4'-(phenoxycarbonyloxy)phenyl]propane
or the like; aryloxycarbonyl-(alkoxycarbonyloxy)-arenes
such as phenyl methoxycarbonyloxybenzoate (isomers
thereof) , tolyl methoxycarbonyloxybenzoate (isomers
thereof), phenyl ethoxycarbonyloxybenzoate (isomers
thereof), tolyl ethoxycarbonyloxybenzoate (isomers
thereof), phenyl hydroxyl-methoxycarbonyloxy-benzoate
(isomers thereof), hydroxyl-methoxycarbonyloxy-
(phenoxycarbonyl)-diphenyl (isomers thereof), 2-[4-
(methoxycarbonyloxy)phenyl]-2-(3'-phenoxycarbonyl-4'-
hydroxyphenyl)propane, 2-(4-hydroxyphenyl)-2-[3'-
phenoxycarbonyl-4'-(methoxyccarbonyloxy)phenyl]propane
or the like; alkoxycarbonyl-(aryloxycarbonyloxy)-arenes
such as methyl phenoxycarbonyloxybenzoate (isomers
thereof), ethyl phenoxycarbonyloxybenzoate (isomers
thereof), methyl tolyloxycarbonyloxybenzoate (isomers
thereof), ethyl tolyloxycarbonyloxybenzoate (isomers
thereof), methyl hydroxyl-phenoxylcarbonyloxybenzoate
(isomers thereof), hydroxyl-phenoxycarbonyloxy-
(methoxycarbonyl)-diphenyl (isomers thereof), 2-[4-
(phenoxycarbonyloxy)phenyl]-2-(3'-methoxycarbonyl-4'-
hydroxyphenyl)propane, 2-(4-hydorxyphenyl)-2-[3'-
methoxycarbonyl-4'(phenoxycarbonyloxy)phenyl]propane or
the like; alkoxycarbonyl-(alkoxycarbonyloxy)-arenes
such as methyl methoxycarbonyloxybenzoate (isomers
thereof), ethyl methoxycarbonyloxybenzoate (isomers
thereof), methyl ethoxycarbonyloxybenzoate (isomers
thereof), ethyl ethoxycarbonyloxybenzoate (isomers

thereof), methyl hydroxyl-methoxycarbonyloxy-benzoate
(isomers thereof), hydroxyl-methoxycarbonyloxy-
(methoxycarbonyl)-diphenyl (isomers thereof), 2-[4-
(methoxycarbonyloxy)phenyl]-2-(3'-methoxyarbonyl-4'-
hydroxyphenyl)propane, 2-(4-hydroxyphenyl)-2-[3'-
methoxycarbonyl-4'-(methoxycarbonyloxy)phenyl]propane
or the like.
Among these aromatic carboxyl compounds and
the residues thereof, the special attentions should be
paid those tend to exist in the production process of
aromatic carbonates of the present invention. Aromatic
carboxyl compounds that tend to exist may include (D)
and (E) described below.
(D) includes products of Fries rearrangement
of aromatic carbonates which are obtained by the
transesterification of the present invention, and
hydrolysis products thereof. (E) includes products of
Fries rearrangement of the transesterification products
of the aromatic polyvalent hydroxyl compounds and
hydrolysis products thereof.
As described earlier, in the production
method of aromatic carbonates of the present invention,
the reactions to obtain butyl phenyl carbonate and
diphenyl carbonate from dibutylcarbonate and phenol are
particularly important, and therefore, aromatic
carboxyl compounds and residues thereof of (D) and (E)
described above are shown below as examples.
Example of (D) may include: salicylic acid;

p-hydoxybenzoic acid; phenyl salicylate; phenyl p-
hydroxybenzoate, butyl salicylate; butyl p-
hydroxybenzoate; phenyl butoxybenzoate (isomers
thereof); phenyl phenoxybenzoate (isomers thereof);
phenyl phenoxycarbonyloxybenzoate (isomers thereof);
butyl phenoxycarbonyloxybenzoate (isomers thereof);
butyl butoxycarbonyloxybenzoate (isomers thereof) or
the like.
Example of (E) may include
: dihydroxybenzoic acid (isomers thereof); phenyl
dihydroxybenzoate (isomers thereof); phenoxycarbonyl
diphenol (isomers thereof); 2-(4—hydroxyphenyl)-2-(3'-
phenoxycarbonyl-4'-hydroxyphenyl)propane or the like.
Xanthones that are included in the high
boiling point materials of the present invention
include xanthone and the xanthone having at least one
substituent on the aromatic ring selected from
following various substituent group consisting of:
alkyl groups such as a methyl group, ethyl group,
propyl group, isopropyl group, butyl group, and
isobutyl group; hydroxyl group; alkoxy groups such as a
methoxy group, ethoxy group, propoxy group, isopropoxy
group, and butoxy group; aryloxy groups such as a
phenoxy group, tolyloxy group; alkoxycarbonyloxy groups
such as a methoxycarbonyloxy group, ethoxycarbonyloxy
group, propoxycarbonyloxy group, and buthoxycarbonyloxy
group; aryloxycarbonyloxy groups such as a
phenoxycarbonyloxy group, tolyroxycarbonyloxy group; a

carboxyl group; alkoxycarbonyl groups such as a
methoxycarbonyl group and ethoxycarbonyl group;
aryloxycarbonyl groups such as a phenoxycarbonyl group
and tolyloxycarbonyl group; and arylcarbonyloxy groups
such as a benzoiloxy group and tolylcarbonyloxy group.
An active substance in the present invention
is a substance that reacts with a high boiling point
material and/or a metal-containing catalyst, and any
substance may be used as long as a separable reaction
mixture is produced as the result of the reaction. For
example, the active substance includes an oxidizing
agent, a reducing agent, a precipitating agent, an
adsorption agent, a reactive solvent or the like. In
particular, the oxidizing agent, precipitating agent,
reactive solvent or the like are preferably used.
These active substances may be used singly, or in
combination of 2 kinds and further simultaneously or
sequentially.
The product derived from the high boiling
point substance in the present invention is the
reaction products and/or un-reacted high boiling point
substances that results from the reaction between the
high boiling point substance and the active substance.
Also the product derived from the metal-
containing catalyst is the reaction products and/or un-
reacted metal-containing catalyst that results from the
reaction between the metal-containing catalyst and the
active substance.

The separation of the reaction mixture
containing the product derived from the high boiling
point substance and the product derived from the metal-
containing catalyst may be carried out by any
separation method as long as the method is able to
separate this reaction mixture into two components, one
that mainly contains the product derived from the high
boiling point substance and the other that mainly
contains the product derived from the metal-containing
catalyst. For example, gas-condensation phase
separation methods such as gas-liquid separation, gas-
solid separation, gas-solid liquid phase separation or
the like method; solid-liquid separation methods such
as sedimentation, centrifugation, filtration or the
like method; distillation method; extraction method;
adsorption method; or the like may be used, and
preferably, separation methods such as sedimentation,
distillation, and adsorption are used. Further, these
separation methods may be used singly, or in
combination of the two or more methods simultaneously
or sequentially.
The combination of this active substance and
the separation method is not limited in particular, but
the preferred methods for carrying out the present
invention includes as follows.
(I) The gas-condensation phase separation
method, wherein the active substance is an oxidizing
agent, the reaction is an oxidizing reaction, the

product derived from the high boiling point material
are low boiling point oxidized products, and the
product derived from the metal-containing catalyst is
metalic oxide.
(II) The solid-liquid separation method,
wherein the active substance is a precipitating agent,
the reaction is the precipitating reaction, and the
product derived from the metal-containing catalyst is
the metal containing solid substance which presents in
the reaction mixture.
(III) The distillation separation method,
wherein the active substance is a reactive solvent, the
reaction is the solvolysis, and the product derived
from high boiling point material is one of the
solvolysis with low boiling point.
On using the aforementioned method of (I),
the oxidizing agent to be used is the one that oxidizes
high boiling point material producing low boiling point
oxidation products as the derivatives of the high
boiling point material, and that oxidizes the metal-
containing catalyst producing metalic oxide as the
product derived from the metal-containing catalyst.
Examples of those oxidizing agents include: air,
molecular oxygen, ozone, hydrogen peroxide, silver
oxide; organic peroxides such as peracetic acid,
perbenzoic acid, benzoyl peroxide, tert-
butylhydroperoxide, cumyl hydroperoxide or the like;
oxo-acids such as nitrous acid, nitric acid, chloric

acid, and hypochlorous acid' and salts thereof or the
like. Air, molecular oxygen, ozone, hydrogen peroxide,
nitrous acid, and nitric acid are preferably used, and
more preferably air and molecular oxygen are used.
The reaction between the liquid and an
oxidizing agent is carried out in a phase selected from
the group consists of liquid phase, gas-liquid mixed
phase and gas-liquid solid mixed phase, although the
reaction depends on the kind of the oxidizing agent and
the reaction conditions. The reaction temperature,
although it may be varied depending on the kind of
oxidizing agent used, is normally -30-2000°C, preferably
0-1200°C and more preferably 0-900°C. The reaction
time, although it may be varied depending on the kind
of the oxidizing agent and the reaction time, is
normally 0.001-100 hours, preferably 0.1-20 hours. The
reaction pressure is normally carried out under 10-107
Pa, and preferably 102-3 x 106 Pa. This reaction may be
carried out in a batch reaction or in continuous
reaction.
In the method of the aforementioned (I), the
separation of the reaction mixture is carried out by
gas-condensation phase separation. The condensation
phase means liquid phase, solid phase or mixed phase of
solid and liquid. If the reaction mixture of the
aforementioned oxidizing reaction is in liquid phase at
the end of the oxidizing reaction, gas liquid mixed
phase or gas liquid solid mixed phase, the condensed

phase components consisting of mainly metal oxide may
be obtained: by carrying out phase separation of the
reaction mixture into the gas phase components
consisting of mainly low boiling point products of
oxidization and the condensation phase containing metal
oxides; and by distilling or evaporating low boiling
point oxidation products from the obtained condensation
phase components.
If the metal-containing catalyst in the
liquid is oxidized to metal oxide forming solid phase
during the progression of the aforementioned oxidation
reaction, the solid liquid mixture may be obtained
while the reaction is in progress.
Further, the oxidation reaction mixture may
be converted into solid phase only by evaporating the
low boiling point oxidation product, which is produced
by the oxidation of the high boiling point material,
together with the volatile components in the liquid.
This is the preferred method because, simultaneously
with the oxidizing reaction, the solid phase which
mainly consists of metal oxide is separated from the
gas phase containing the low boiling point oxidation
product.
The low boiling point oxidation product is a
compound that is produced by the oxidation of a high
boiling point material by the oxidizing agent, having a
lower boiling point than that of the high boiling point
material. The examples of the low boiling point

oxidation product include carbon dioxide, water, carbon
monoxide, organic compounds containing oxygen,
unsaturated organic compounds, the high boiling point
materials with reduced carbons or the like, although
they may be varied depending on the kind of the
oxidizing agent and high boiling point material used.
The metal oxide is the oxide of the metal in
the metal-containing catalyst, and includes TiO, Ti2O3,
TiO2 or the like. When a metal-containing catalyst
having a plurality of metals is used, a mixture of the
corresponding metal oxides and/or the complex metal
oxide is obtained.
In case the method of aforementioned (II) is
used, this metal containing substance may be any metal
containing substance as long as it exists as the solid
in this reaction mixture and contains this metal. For
example, it includes: a metal hydroxide; a metal
chalcogenide such as metal oxide, a metal sulfide or
the like; an inorganic acid salt such as metal
carbonate, metal sulfate or the like; metal organic
acid salt; metal complex; metal double salt or the
like. Metal carbonates, metal hydroxides, metal
oxides, metal sulfides and metal sulfates are
preferable because their solubility in this reaction
mixture is low. The reactive substance, starting
material or the like may coordinate with these metal-
containing substances.
Any precipitating agent may be used that

reacts with the metal-containing catalyst producing the
metal containing substance described above. For
example, to precipitate these metal hydroxides,
inorganic hydroxides such as alkali metal hydroxides,
alkali earth metal hydroxide or the like, and water are
used. In order to precipitate these metal oxides,
inorganic oxides such as alkali metal oxides, alkali
earth metal oxides or the like, and oxidizers such as
hydrogen peroxide or the like are used. In order to
precipitate these metal sulfides, inorganic sulfides
such as alkali metal sulfide, alkali earth sulfide or
the like, and hydrogen sulfide are used. In order to
precipitate these metal carbonate, inorganic carbonate
salts such as alkali metal carbonates, alkali earth
metal carbonates or the like, and carbonic acid, carbon
dioxide and water are used. In order to precipitate
these metal sulfate, inorganic sulfate salts such as
alkali metal sulfate, alkali earth metal salt or the
like, sulfuric acid, sulfur trioxide and water are
used.
The reaction between the metal-containing
catalyst and the precipitating agent, although it may
be varied depending on the kinds of the catalyst and
the precipitating agent, and the reaction condition
used, is normally carried out in the one phase
condition selected from the group consisting of liquid
phase, gas liquid mixed phase, gas liquid solid mixed
phase and solid liquid mixed phase. The reaction

temperature, although it may be varied depending on the
kind of the precipitating agent used, is normally -70-
600°C, preferably-30-400°C, more preferably -10-250°C.
The reaction time, although it may be varied
depending on the kind of the precipitating agent and
the reaction temperature, is normally 0.001-100 hour,
preferably 0.1-20 hours. The reaction is usually
carried out under the pressure of 10-107 Pa. This
reaction may be carried out as the batch or continuous
reaction.
In the precipitating reaction, it is the
preferable method to add a substance forming crystal
nuclei. Further, although the metal containing
substance exists as solid on separating this reaction
mixture, it does not necessarily need to exist as solid
while the precipitating reaction is proceeding, and it
may be solidified through the operations such as
cooling or the like after this reaction. In the case
of the aforementioned (II) , the separation of the
reaction mixture is the solid-liquid separation, and
the mixture is separated to a solid phase mainly
consisting of the metal containing substance and a
liquid phase mainly consisting of the product derived
from the high boiling point material. For this solid
liquid separation, normally sedimentation,
centrifugation, filtration or the like separation
method are used.
Further in carrying out the method of (II),

the high boiling point material containing in the
liquid may react or may not react in the precipitating
reaction.
In case the method of the aforementioned
(III) is used, the reactive solvent to be used may be
any reactive solvent as long as it reacts with the high
boiling point material and produces compounds with the
boiling point lower than that of the high boiling point
material. For example, water; lower alcohols such as
methanol, ethanol, propanol (isomers thereof), butanol
(isomers thereof), or the like; lower carboxylic acids
such as formic acid, acetic acid, propionic acid or the
like; carbonates such as dimethyl carbonate, diethyl
carbonate, dibutyl carbonate or the like may be used.
Water, methanol, ethanol, acetic acid, methyl acetate,
ethyl acetate, dimethyl carbonate, diethyl carbonate,
dibutyl carbonate or the like are preferably used and
more preferably, water is used.
The solvolysis in the present invention means
the reaction between the reactive solvent and the high
boiling point material, and the solvolysis products may
undergo further reactions such as the decarboxylation
reaction that is different from the solvolysis
reaction. This low boiling point product of the
solvolysis may be a product with a lower boiling point
than the high boiling point material and its variety or
structure may be varied depending upon the reactive
solvent and the kind of the high boiling point

material. The solvolysis products with low boiling
point are explained particularly in following (i)-
(iii), when the high boiling point material is phenyl
salicylate that is one of aromatic carboxyl compounds.
(i) In the case where the reactive solvent is
water: phenol and salicylic acid are produced by
hydrolysis and this salicylic acid further undergoes
decarboxylation reaction producing phenol and carbon
dioxide.
(ii) In the case where the reactive solvent
is alcohol: alkyl salicylate and phenol are produced by
alcoholysis.
(iii) In the case where the reactive solvent
is calboxylic acid: salicylic acid and phenyl
carboxylate ester are produced by the
transesterification and this salicylic acid further
undergoes decarboxylation reaction converted into
phenol and carbon dioxide.
Above explanation is based on the example of
phenyl salicylate that is relatively simple structured
aromatic carboxylic compound but similar reactions
involving more complexed aromatic carboxylic compounds
may also generate corresponding solvolysis products
such as aromatic monohydroxy compound, ester of lower
carboxylic acid and aromatic mono hydroxyl compound,
ester of aromatic carboxyl compound and a lower
alcohol, carbon dioxide or the like. In particular,
aromatic monohydroxy compounds are preferable as

solvolysis products because they are the reactive
substances of the present invention and can be reused.
Since the liquid contains the metal-
containing catalyst which normally functions as a
catalyst for the solvolysis reaction, it is not
necessary to use a catalyst for the solvolysis reaction
in particular. However, the catalyst may be used for
the purpose of improving the rate of reaction or the
like.
The reaction between the high boiling point
material and the reactive solvent is normally carried
out, although it may be varied depending on the
reaction condition, in one phase condition either
liquid phase or solid liquid mixture phase.
The reaction temperature, although it may be
varied depending on the kind of the reactive solvent
used, is normally -30 to 400°C, preferably -10 to 300°C,
more preferably -0 to 250°C.
The reaction time, although it may be varied
depending on the kind of the reactive solvent and the
reaction temperature, normally 0.001-100 hour,
preferably 0.1-20 hours. The reaction is usually
carried out under the pressure of 10-107 Pa. This
reaction may be carried out as the batch or continuous
reaction.
The metal-containing catalyst may or may not
catalyze the solvolysis reaction. In case of reacting
water or alcohols as the reactive solvent to the liquid

containing an aromatic carboxylic compound as the high
boiling point material, carbon dioxide is generated as
one of the derivations from the high boiling point
material due to the decarboxylation. Thus this carbon
dioxide acts as the precipitating agent and reacts with
the metal-containing catalyst, and metal containing
substances such as metal carbonate or the like may be
obtained in soluble and/or solidified states.
In the method of the aforementioned (III),
the reaction mixture is separated by distillation, and
the low boiling points solvolysis products that are the
products derived from the high boiling point material
are mainly obtained as distillates. The metal-
containing catalyst remains in the residual liquid in
the distillation still. This distillation separation
is carried out at the temperature normally 10-300°C,
preferably 50-250°C, represented as the temperature of
the liquid in the distillation still. The reaction is
usually carried out under the pressure of 0.1-1.0 x 106
Pa, preferably 1.0-1.0 x 105 Pa. The distillation may
be carried out batch-wise or continuously.
When the products derived from the metal-
containing catalyst, which are obtained by separating
the reaction mixture of the liquid from the active
substance, are to be recycled in the system, the
composition containing the products derived from the
metal-containing catalyst, which are obtained by
separation of the reaction mixture, in liquid, solid or

liquid solid mixed phase may be recycled into the
system as they are, or if this composition contains
other components than the products derived from the
metal-containing catalyst, a part or the whole
components may be separated and then recycled in the
system. Further, the reaction solution or slurry,
which is obtained by reacting the products derived from
the metal-containing catalyst to the starting material
or to the reactive substance, may be recycled. This
method is the preferred method when the products
derived from the metal-containing catalyst are in a
solid or a solid liquid mixed phase.
Concerning the high boiling point liquid
materials to be removed from the system, those
concentrations which may be varied depending on the
kind of materials, are not preferred to be kept
extremely low because the volume of the liquid, which
is subjected to the removal, becomes too large. Also,
if the concentration of the high boiling point material
is too high, handling becomes difficult due to the
increase of the boiling point and the viscosity.
Therefore, the concentration of the high boiling point
material in the liquid, which is subjected to the
removal, is normally 0.01-99% by weight, preferably
0.1-95% by weight and more preferably 1-90% by weight.
Further, when the high boiling point material
is an aromatic polyvalent hydroxyl compound, the weight
ratio of aromatic polyvalent hydroxyl compound to the

metal of the catalyst in the liquid is normally kept at
2 or below to prevent deposition and attachment of the
catalyst in the reactor and the lines.
By using the metal-containing catalyst of the
present invention, factors that rendered the production
unstable in the past such as clogging of the
distillation column, deposition of the catalyst
component to the wall are surprisingly improved.
Further, the preferred example of the present
invention includes the usage of diaryl carbonate,
purified by the method of the present invention, in
aromatic polycarbonate production by the
transesterification method. Polycarbonate which is
produced by the transesterification method, depending
on the polymerization method, tends to show red
coloring due to the metal content in the catalyst for
diphenyl carbonate which is used as the material,
especially when the Ti content is greater than 1 ppm.
However, the aromatic carbonate, particularly important
diphenyl carbonate, which is produced by the method of
the present invention contains Ti at 1 ppm or below.
Polycarbonate is easily produced by the
transesterification polymerization with bisphenol A.
Thus polycarbonate produce in the present invention is
high quality because it contains less Ti which causes
coloring of polycarbonate.
Further, in producing aromatic polycarbonate
by the transesterification method, the polymerization

at high rate may be achieved using the diaryl carbonate
produced by the method of the present invention. Still
further, aromatic polycarbonate produced by the
transesterification method, which is obtained using
aromatic dihydroxy compound and diaryl carbonate
produced by the method of the present invention, has no
coloring and is high quality.
EFFECT OF THE INVENTION
According to the present invention, high
purity diaryl carbonate that is easily separated from a
catalyst is produced, wherein a starting material
selected from the group consisting of a dialkyl
carbonate, an alkylaryl carbonate and a mixture thereof
and a reactive substance selected from the group
consisting of an aromatic monohydroxy compound, an
alkylaryl carbonate and a mixture thereof are reacted
in the presence of a metal-containing catalyst to
produce aromatic carbonates while by-products alcohols
and/or dialkyl carbonates are distilled out of the
system.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is a process flow chart related to the
production of aromatic carbonate in the present
invention; and
Fig. 2 is a process flow chart related to the
purification of diaryl carbonate in the present

invention.
Fig. 3 is a process flow chart related to the
structure of aromatic carbonic acid ester.
Fig. 4 is a process flow chart related to the
structure of aromatic carbonic acid ester.
DESCRIPTION OF SYMBOLS
1, 4, 7, 10, 13, 16, 19, 22, 25, 28, 31, 34, 37, 40,
43, 46, 54, 57, 58, 60: line
50, 56: inlet line
2, 14, 26, 38, 51: preheater
3, 15, 27, 39, 49: continuous multi-stage distillation
column

5, 17, 29, 41: cooler
55: condenser
6, 18, 30, 42: gas liquid separator
11, 23, 35, 47, 59: reboiler

8, 12, 20, 24, 33, 36, 44, 48: storage tank
9, 21, 32, 45: pressure control valve
52: top of the column
53: bottom of the column
BEST MODE FOR CARRYING OUT THE INVENTION
Next, the present invention will be
explained in particular by the examples, but the
present invention is not limited by these examples.
Further, the measurements for the concentration of the
catalyst and the concentration of the metal derived

from the metal-containing catalyst in aromatic
carbonate were carried out using an ICP/AES
(Inductively Coupled Plasma/Atomic Emission
Spectroscopy: Detection limit of 0.1 ppm). The
concentrations of the organic components in the liquid
were measured by Gas Chromatography.
(1) Conditions for gas chromatographic analysis.
Column: DB-1 (J & W Scientific)
Liquid phase: 100% dimethylpolysiloxane
Length: 30 m
Internal diameter: 0.25 mm
Film thickness: 1 µm.
Column temperature: 50°C (increased by
10°C/min) 300°C
Injection temperature: 300°C
Detector temperature: 300°C
Detection method: FID
(2) Quantitative analysis
The analysis sample solutions are
quantitatively analyzed based on the standard curves
prepared by carrying out the analyses on the
calibration samples of each standard substance.
(3) Confirmation of Ti-O-Ti bond.
The presence of Ti-O-Ti bond is estimated by
identifying Ti substituent (or ligand) from the result
of 1H-NMR, and subtracting the oxygen value derived from
this substituent (or ligand) from the result of the
element analysis (C, H, O, Ti) and by assuming this

oxygen value as the cross linkage oxygen derived from
Ti-O-Ti.
(4) Conditions for NMR analysis
Device: JNM-A4 00 FT-NMR system made by JEOL
Ltd.
(Preparation of samples for 1H-NMR, 13C-NMR analysis)
The metal-containing catalyst was weighed in the range
of 0.1 g-1 g and mixed homogeneously with deuterated
chloroform (Aldrich Co. 99.8%) or carbon tetrachloride
that weighed in the range of 0.05 g-0.7 g to prepare
samples for the NMR analysis. TMS (tetramethyl silane)
was used as the internal standard.
Examples
The present invention will be described based
on the examples.
Example 1
[Production of aromatic carbonic acid ester]
Aromatic carbonate was produced using a
device shown in Fig. 1. The reaction was carried out
by supplying continuously at a rate of about 109 g/Hr,
through a preheater 2 and a line 1, a mixed solution
consisting of dibutyl carbonate, phenol and, as the
catalyst, phenyl titanate dimer-2PhOH adduct [(PhO)3-Ti-
0-Ti-(OPh)3-2PhOH] (result of element analysis: C=67.2,
H=4.93, 0=16.77, Ti=11.1; result of 1H-NMR analysis:
PhOH and PhO groups exist at the ratio of 2:6. In one
molecule, two Ti atoms and one oxygen atom that is not
derived from PhOH and PhO groups exist, that is, one

Ti-O-Ti bond exists; molecular weight without the
adduct PhOH: 670; vapor pressure: 1 Pa or below at
230°C) (the mixed solution in which that the ratio by
weight of dibutyl carbonate to phenol was adjusted to
about 65/35, and Ti as atoms was adjusted to about
10,000 ppm of the whole liquid) from the middle stage
of a continuous multi-stage distillation column 3,
which was composed of a condensation part, which was 2
inch in the internal diameter, 0.5 m in the column
length and filled with 10 stages of sieve trays, and a
recovery part which was 2 inch in the internal
diameter, 1 m in the column length and filled with
Dixon packing (6 mm(|>) . The condensation part was
disposed in the lower part of the stage where the
mixture was supplied continuously, and the recovery
part was disposed in the upper part. The heat required
for the reaction and distillation was supplied by
circulating the liquid in the lower part of the column
through a line 10 and a reboiler 11, and the
temperature at the bottom of the multi-stage
distillation column was controlled to be about 230°C.
The reaction liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 3 through a line 10 to a storage tank 12 at 90
g/Hr. The catalyst was dissolved in the reaction
liquid.
After the low boiling point liquid mixture
containing 1-butanol as a by-product was removed from

the top of the column through a line 4, and then it was
liquefied by a cooler 5, and a part of it was removed
continuously to a storage tank 8 at 19 g/Hr and the
rest was refluxed to the distillation column (reflux
ratio=1.9).
The liquid removed to the storage tank 12 was
composed of about 23% by weight of phenol, about 56% by
weight dibutyl carbonate, about 12% by weight of butyl
phenyl carbonate, about 0.2% by weight of diphenyl
carbonate, about 0.3% by weight of 1-butanol and the
catalyst. The liquid removed to the storage tank 8 was
composed of about 99% by weight of 1-butanol, about
0.5% by weight of phenol, and about 0.2% by weight of
dibutyl carbonate.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve
trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ) , and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this

distillation column 15, and the recovery part was
disposed in the upper part.
The reaction was carried out by supplying
continuously through a line 13 the reaction liquid,
which was removed from the bottom of the continuous
multi-stage distillation column 3 through the line 10
to the storage tank 12, to the continuous multi-stage
distillation column 15 at 100 g/Hr after preheating
with a preheater 14. The heat required for the
reaction and distillation was supplied by circulating
the liquid in the lower part of the column through a
line 22 and a reboiler 24, and the temperature at the
bottom of the multi-stage distillation column is
controlled to be about 220°C.
The reaction liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4).
The liquid removed to the storage tank 24 was
composed of about 5% by weight of dibutyl carbonate,
about 74% by weight of butyl phenyl carbonate, about
10% by weight of diphenyl carbonate, and the catalyst.

The liquid removed to the storage tank 20 was composed
of about 0.3% by weight of 1-butanol, about 18% by-
weight of phenol, and about 81% by weight of dibutyl
carbonate. No deposit or the like were found in the
distillation column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 192
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mm internal diameter of 2 inch and a length of 1 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 34 and a
reboiler 35, and the temperature at the bottom of the
multi-stage distillation column is controlled to be
about 210°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 27 through the line 34 to the
storage tank 36 at about 90 g/Hr. After removing from
the top of the column through the line 28, the
distillate was liquefied by a cooler 29 and was removed
continuously to a storage tank 33 at about 102 g/Hr.
The liquid removed to the storage tank 33 is composed

of dibutyl carbonate: about 0.6% by weight, butyl
phenyl carbonate: about 73% by weight, diphenyl
carbonate: about 26% by weight.
The distillation separation was carried out
by continuously feeding the liquid, which was
continuously removed to the storage tank 33, through a
line 37 passing a preheater 38 at about 101 g/Hr to the
middle stage of a continuous multi-stage distillation
column 39, which was a column filled with Dixon packing
(6 mm(j)) with an internal diameter of 2 inch and a length
of 2 m. The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 4 6 and a
reboiler 47, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 200°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 39 through the line 46 to a storage
tank 48 at about 19 g/Hr.
After removing from the top of the column
through a line 40, the distillate was liquefied by a
cooler 41 and was removed continuously to a storage
tank 4 4 at about 82 g/Hr. The liquid removed to the
storage tank 44 is composed of dibutyl carbonate: about
0.7% by weight, butyl phenyl carbonate: about 90% by
weight, diphenyl carbonate: about 9% by weight.
White liquid that was solidified at ambient
temperature was continuously removed to a storage tank

48 and contained diphenyl carbonate: about 100% by
weight, and butyl phenyl carbonate was below the
detection limit. The analysis of the liquid indicated
that Ti was below the detection limit. Inspection of
the distillation column revealed not deposit or the
like.
Comparative Example 1
[Production of aromatic carbonate]
Aromatic carbonate was produced in the device
shown in Fig. 1. The reaction was carried out by
supplying continuously at a rate of about 109 g/Hr,
through a preheater 2 and a transport line 1, a mixed
solution consisting of dibutyl carbonate, phenol, and
phenyl titanate [Ti(OPh)4] (this phenyl titanate: adduct
with phenol; molecular weight without the adduct
phenol: 420; vapor pressure: about 15 Pa at 230°C) (the
mixed solution in which the ratio by weight of dibutyl
carbonate to phenol was adjusted to about 65/35, and Ti
as atoms was adjusted to about 10,000 ppm of the whole
liquid) from the middle stage of a continuous multi-
stage distillation column 3, which is composed of a
condensation part, which is 2 inch in the internal
diameter, 0.5 m in the column length and filled with 10
stages of sieve trays, and a recovery part which is 2
inch in the internal diameter, 1 m in the column length
and filled with Dixon packing (6 mmϕ). The condensation
part was disposed in the lower part of the stage where
the mixture was supplied continuously, and the recovery

part was disposed in the upper part.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 10 and a
reboiler 11, and the temperature at the bottom of the
multi-stage distillation column is controlled to be
about 230°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 90 g/Hr.
After the low boiling point liquid mixture
containing 1-butanol as a by-product was removed from
the top of the column through a line 4, and then it was
liquefied by the cooler 5, and a part of it was removed
continuously to a storage tank 8 at 19 g/Hr and the
rest was refluxed to the distillation column (reflux
ratio=1.9). The liquid removed to the storage tank 12
was composed of: phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight. The liquid
removed to the storage tank 8 was composed of 1-
butanol: about 99% by weight, phenol: about 0.5% by
weight, and dibutyl carbonate: about 0.2% by weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,

like the continuous multi-stage distillation column 3,
is composed of a condensation part, which is 2 inch in
the internal diameter, 0.5 m in the column length and
filled with 10 stages of sieve trays, and a recovery-
part which is 2 inch in the internal diameter, 1 m in
the column length and filled with Dixon packing (6 mmϕ),
and the condensation part was disposed in the lower
part of the stage where the reaction liquid containing
the catalyst was supplied continuously from the storage
tank 12 to this distillation column 15, and the
recovery part was disposed in the upper part.
The reaction was carried out by supplying
continuously through a line 13 the reaction liquid,
which was removed from the bottom of the continuous
multi-stage distillation column 3 through the line 10
to the storage tank 12, to the continuous multi-stage
distillation column 15 at 100 g/Hr after preheating
with a preheater 14. The heat required for the
reaction and distillation was supplied by circulating
the liquid in the lower part of the column through a
line 22 and a reboiler 24, and the temperature at the
bottom of the multi-stage distillation column is
controlled to be about 220°C.
The reaction liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was

removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4).
The liquid removed to the storage tank 24 was
composed of dibutyl carbonate : about 5% by weight,
butyl phenyl carbonate: about 74% by weight, diphenyl
carbonate: about 10% by weight. The liquid removed to
the storage tank 20 was composed of about 1-butanol:
0.3% by weight, phenol: about 18% by weight, and
dibutyl carbonate: about 81% by weight.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 34 and a
reboiler 35, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 210°C. The bottom liquid was continuously removed

from the bottom of the continuous multi-stage
distillation column 27 through the line 34 to the
storage tank 36 at about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by
the cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr.
The liquid removed to the storage tank 33 is
composed of dibutyl carbonate: about 6% by weight,
butyl phenyl carbonate: about 8 6% by weight, diphenyl
carbonate: about 7.5% by weight.
The distillation separation was carried out
by continuously feeding the liquid, which was
continuously removed to the storage tank 33, through a
line 37 passing a preheater 38 at about 100 g/Hr to the
middle stage of a continuous multi-stage distillation
column 39, which was a column filled with Dixon packing
(6 mmϕ) with an internal diameter of 2 inch and a length
of 2 m. The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through the line 4 6 and
reboiler 47, and the temperature at the bottom of the
multi-stage distillation column is controlled to be
about 230°C.
The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 39 through a line 4 6 to a storage
tank 48 at about 8 g/Hr. After removing from the top

of the column through the line 4G, the distillate was liquefied by a cooler 41 and
was removed continuously to a storage tank 44 at about 92 g/Hr.
The liquid remove to the storage tank 44 is composed of dibutyl
carbonate: about 6% by weight, bytyl phenyl carbonate: about 94% by weight.
The liquid removed to a storage tank 48 was solid at ambient
temperature but had a coloring of red. The analysis of the liquid indicated that
Ti content of about 5 ppm.
Comparative Example 2
[Production of aromatic carbonate]
Aromatic carbonate was produced using a device shown in Fig. 1.
The reaction was carried out by supplying continuously at a rate of about 100
g/Hr, through the preheater 2 and the transport line 1, a mixed solution
consisting of dibutyl carbonate, phenol and, as a catalyst, di (phenyl salicylate)
titanate diphenolate (molecular weight: 660, vapor pressure: 1 Pa or below at
23°C) (the mixed solution in which the ratio by weight of dibutyl carbonate an
phenol was adjusted to about 65/35, and Ti as atoms was adjusted to about:
110,000 ppm of the whole liquid) from the middle stage of a continuous multi-
stage distillation column 3, which is composed of the condensation part,
which is 2 inch in the internal diameter, 0.5 m in the column
length and filled with 10 stages of sieve trays, and the recovery part which is 2

inch in the internal diameter, 1 m in the column length
and filled with Dixon packing (6 mmϕ).
The condensation part was disposed in the
lower part of the stage where the mixture liquid was
supplied continuously, and the recovery part was
disposed in the upper part. The heat required for the
reaction and distillation was supplied by circulating
the liquid in the lower part of the column through a
line 10 and a reboiler 11, and the temperature at the
bottom of the multi-stage distillation column is
controlled to be about 230°C.
The reaction liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 95 g/Hr. The catalyst was dissolved in the
reaction liquid.
After the low boiling point liquid mixture
containing 1-butanol as a by-product was removed from
the top of the column through a line 4, and then it was
liquefied by the cooler 5, and a part of it was removed
continuously to a storage tank 8 at 5 g/Hr and the rest
was refluxed to the distillation column (reflux
ratio=2).
The liquid removed to the storage tank 12 was
composed of phenol: about 26% by weight, dibutyl
carbonate: about 50% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.6% by weight and the

catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 90% by weight, phenol:
about 7% by weight, and dibutyl carbonate: about 3% by
weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve
trays, and the recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ), and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part.
The reaction was carried out by supplying
continuously through a line 13 the reaction liquid,
which was removed from the bottom of the continuous
multi-stage distillation column 3 through the line 10
to the storage tank 12, to the continuous multi-stage
distillation column 15 at 95 g/Hr after preheating with
a preheater 14. The heat required for the reaction and
distillation was supplied by circulating the liquid in

the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C.
The reaction liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at about 19 g/Hr. After the low boiling point
liquid mixture containing dibutylcarbonate as a by-
product was removed from the top of the column through
a line 16, and then it was liquefied by a cooler 17,
and a part of it was removed continuously to a storage
tank 20 at 76 g/Hr and the rest was refluxed to the
distillation column (reflux ratio=4).
The liquid removed to the storage tank 24 was
composed of dibutyl carbonate: about 0.3% by weight,
butyl phenyl carbonate: about 38% by weight, diphenyl
carbonate: about 14% by weight and also the catalyst.
The liquid removed to the storage tank 20 was composed
of 1-butanol: about 0.7% by weight, phenol: about 33%
by weight, and dibutyl carbonate: about 65% by weight,
butyl phenyl carbonate: about 1% by weight. No deposit
or the like were found in the distillation column on
inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the

liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 192
g/Hr to about 0.1m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 34 and a
reboiler 35, and the temperature at the bottom of the
multi-stage distillation column is controlled to be
about 210°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 27 through the line 34 to the
storage tank 36 at about 90 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by a
cooler 29 and was removed continuously to a storage
tank 33 at about 102 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
0.6% by weight, butyl phenyl carbonate: about 73% by
weight, diphenyl carbonate: about 26% by weight.
The distillation separation was carried out
by continuously feeding the liquid, which was
continuously removed to the storage tank 33, through a
line 37 passing a preheater 38 at about 101 g/Hr to the
middle stage of a continuous multi-stage distillation
column 39, which was a column filled with Dixon packing

(6 mmϕ) with an internal diameter of 2 inch and a length of 2 m. The heat
required for the distillation separation was supplied by circulating the liquid in
the lower part of the column through a line 46 and a reboiler 47, and the
temperature at the bottom of the multi-stage distillation colum was controlled to
be about 200°C.
The bottom liquid was continuously removed from the bottom of
the continuous multi-stage distillation column 39 through the line 46 to a storage
tank 48 at about 19 g/Hr. After removing from the top of the column through a
line 40, the distillate was liquefied by a cooler41 and was removed continuously
to the storage tank 44 at about 82 g/Hr.
The liquid removed to the storage tank 44 is composed of dibutyl
carbonate: about 0.7% by weight, butyl phenyl carbonate: about 90% by weight,
diphenyl carbonate: about 9% by weight. White liquid that was solidified at
ambient temperature was continuously removed to a storage tank 48 and
contained diphenyl carbonate: about 100% by weight, and butyl phenyl
carbonate was below the detection limit. The analysis of the liquid indicated that
Ti content was about 0.8 ppm. Inspection of the distillation column revealed no
deposit or the like.
Example 2
[Production of aromatic carbonate]
Aromatic carbonate was produced using a

device shown in Fig. 1. The reaction was carried out
by supplying continuously at a rate of about 109 g/Hr,
through the preheater 2 and the line 1, a mixed
solution consisting of dibutyl carbonate, phenol and,
as a catalyst, butyl titanate trimer [(BuO)3-Ti-O-Ti-
(OBu)2-O-Ti-(OBu)3] (result of element analysis: C=50.5,
H=9.5, 0=21.1, Ti=18.9; since oxygen derived from BuO
is 16.8, the number of bridging oxygen is 2, that is,
there are two Ti-O-Ti bonds; molecular weight: 760;
vapor pressure: 1 Pa or below at 230°C) (the mixed
solution in which the ratio by weight of dibutyl
carbonate to phenol was adjusted to about 65/35, and Ti
as atoms was adjusted to about 10,000 ppm of the whole
liquid, and this catalyst was dissolved in this
mixture) from the middle stage of a continuous multi-
stage distillation column 3, which was composed of a
condensation part, which was 2 inch in the internal
diameter, 0.5 m in the column length and filled with 10
stages of sieve trays, and a recovery part which was 2
inch in the internal diameter, 1 m in the column length
and filled with Dixon packing (6 mmϕ).
The condensation part was disposed in the
lower part of the stage where the mixture liquid was
supplied continuously, and the recovery part was
disposed in the upper part. The heat required for the
reaction and distillation was supplied by circulating
the liquid in the lower part of the column through a
line 10 and a reboiler 11, and the temperature at the

bottom of the multi-stage distillation column was
controlled to be about 230°C.
The reaction liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 90 g/Hr. The catalyst was dissolved in the
reaction liquid.
After the low boiling point liquid mixture
containing 1-butanol as a by-product was removed from
the top of the column through a line 4, and then it was
liquefied by the cooler 5, and a part of it was removed
continuously to the storage tank 8 at 19 g/Hr and the
rest was refluxed to the distillation column (reflux
ratio=1.9). The liquid removed to the storage tank 12
was composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and also the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation

part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve
trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ), and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part.
The reaction was carried out by continuously
supplying through a line 13 the reaction liquid, which
was removed from the bottom of the continuous multi-
stage distillation column 3 through the line 10 to the
storage tank 12, to the continuous multi-stage
distillation column 15 at 100 g/Hr after preheating
with a preheater 14. The heat required for the
reaction and distillation was supplied by circulating
the liquid in the lower part of the column through a
line 22 and a reboiler 24, and the temperature at the
bottom of the multi-stage distillation column was
controlled to be about 220°C.
The reaction liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,

and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4).
The liquid removed to the storage tank 24 was
composed of dibutyl carbonate: about 5% by weight,
butyl phenyl carbonate: about 74% by weight, diphenyl
carbonate: about 10% by weight and also the catalyst.
The liquid removed to the storage tank 20 was composed
of 1-butanol: about 0.3% by weight, phenol: about 18%
by weight, and dibutyl carbonate: about 81% by weight.
No deposit or the like were found in the distillation
column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with the device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 192
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of
the column through a line 34 and a reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column is controlled to be about 210°C.

The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 90 g/Hr. After removing from the top of the
column through the line 28, the distillate was
liquefied by a cooler 29 and was removed continuously
to a storage tank 33 at about 102 g/Hr.
The liquid removed to the storage tank 33 is
composed of dibutyl carbonate: about 0.6% by weight,
butyl phenyl carbonate: about 73% by weight, diphenyl
carbonate: about 26% by weight.
The distillation separation was carried out
by continuously feeding the liquid, which was
continuously removed to the storage tank 33, through
the line 37 passing a preheater 38 at about 101 g/Hr to
the middle stage of the continuous multi-stage
distillation column 39, which was a column filled with
Dixon packing (6 mmϕ) with an internal diameter of 2
inch and a length of 2 m. The heat required for the
distillation separation was supplied by circulating the
liquid in the lower part of the column through the line
46 and reboiler 47, and the temperature at the bottom
of the multi-stage distillation column is controlled to
be about 200°C.
The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 39 through the line 46 to the
storage tank 48 at about 19 g/Hr.

After removing from the top of the column through the line 40, the
distillated was liquefied by the cooler 41 and was removed continuously to the
storage tank 44 at about 82 g/Hr. The liquid removed to the storage tank 44 is
composed of dibutyl carbonate: about 0.7% by weight, butyl phenyl carbonate:
about 90% by weight, diphenyl carbonate; about 9% by weight.
White liquid that was solidified at ambient temperature was
continuously removed to the storage tank 48 and contained diphenyl carbonate:
about 100% by weight, and butyl phenyl carbonate was below the detection limit.
The analysis of the liquid indicated that Ti content was below the detection limit.
No deposit of the like were found in the distillation column on inspection.
Example 3
[Production of aromatic carbonate]
Aromatic carbonate was produced using a device shown in Fig.
1. The reaction was carried out by supplying continuously at a rate of
about 109 g/Hr, through the preheater 2 and the transport line 1, a mixed
solution consisting of dibutyl carbonate, phenol and, as a catalyst, an organic
polytitanoxan composition (Matsumoto Trading Co. Ltd. Orgatics TA-22)
containing butyl titanate dimer [(BuO)3-Ti-O-Ti- (Obu)3] (molecular weight:
550; vapor pressure:1 Pa or below at 230° C) (the mixed solution
in which the ratio by

weight of dibutyl carbonate and phenol was adjusted to
65/35, and Ti as atoms was adjusted to about 10,000 ppm
of the whole liquid, and this catalyst was dissolved in
this mixture) from the middle stage of the continuous
multi-stage distillation column 3, which was composed
of a condensation part, which was 2 inch in the
internal diameter, 0.5 m in the column length and
filled with 10 stages of sieve trays, and a recovery
part which was 2 inch in the internal diameter, 1 m in
the column length and filled with Dixon packing (6 mmϕ).
The condensation part was disposed in the
lower part of the stage where the mixture liquid was
supplied continuously, and the recovery part was
disposed in the upper part. The heat required for the
reaction and distillation was supplied by circulating
the liquid in the lower part of the column through the
line 10 and reboiler 11, and the temperature at the
bottom of the multi-stage distillation column was
controlled to be about 230°C. The reaction liquid was
continuously removed from the bottom of the continuous
multi-stage distillation column 3 through the line 10
to a storage tank 12 at 90 g/Hr. After the low boiling
point liquid mixture containing 1-butanol as a by-
product was removed from the top of the column through
a line 4, and then it was liquefied by the cooler 5,
and a part of it was removed continuously to the
storage tank 8 at 19 g/Hr and the rest was refluxed to
the distillation column (reflux ratio=1.9).

The liquid removed to the storage tank 12 was
composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and also the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the continuous multi-stage distillation
column 3, the reaction was carried out using the
continuous multi-stage distillation column 15. The
continuous multi-stage distillation column 15, as in
the case of the continuous multi-stage distillation
column 3, was composed of the condensation part, which
is 2 inch in the internal diameter, 0.5 m in the column
length and filled "with 10 stages of sieve trays, and
the recovery part which is 2 inch in the internal
diameter, 1 m in the column length and filled with
Dixon packing (6 mmϕ), and the condensation part was
disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part. The reaction was carried
out by supplying continuously through the line 13 the
reaction liquid, which was removed from the bottom of
the continuous multi-stage distillation column 3

through the line 10 to the storage tank 12, to the
continuous multi-stage distillation column 15 at 100
g/Hr after preheating with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through the line 22 and
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by the cooler 17, and a part
of it was removed continuously to a storage tank 20 at
83 g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:
about 5% by weight, butyl phenyl carbonate: about 74%
by weight, diphenyl carbonate: about 10% by weight and
also the catalyst. The liquid removed to the storage
tank 20 was composed of 1-butanol: about 0.3% by
weight, phenol: about 18% by weight, and dibutyl
carbonate: about 81% by weight. No deposit or the like
were found in the distillation column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried

out with the device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through the line 25 passing a preheater 26 at about 100
g/Hr to about 0.1m above the middle stage of the
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of
the column through the line 34 and reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column is controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by
the cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 86% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed
continuously to the storage tank 33, through the line
37 passing a preheater 38 at about 100 g/Hr to the

middle stage of the continuous multi-stage distillation column 39, which was a
column filled with Dixon packing (6 mmϕ) with an internal diameter of 2 inch
and 2 m length.
The heat required for the distillation separation was supplied by
circulating the liquid in the lower part of the column through the line 46 and
reboiler 47, and the temperature at the bottom of the multi-stage distillation
column is controlled to be about 230° C. The bottom liquid was continuously
removed from the bottom of the continuous multi-stage distillation column 39
through the line 46 to the storage tank 48 at about 8 g/Hr. After removing from
the top of the column through the line 40, the distillate was liquefied by the
cooler 41 and was removed continuously to the storage tank 44 at about 92 g/ Hr.
The liquid removed to the storage tank 44 is composed of dibutyl carbonate:
about 6% by weight, butyl phenyl carbonate: about 94% by weight. White liquid
that was solidified at ambient temperature was continuously removed to the
storage tank 48 and contained diphenyl carbonate: about 100% by weight and
butyl phenyl carbonate was below the detection limit. The analysis of the liquid
indicated that Ti content was below the detection limit. No deposit or the like
were found in the distillation column on inspection.
Comparative Example 3
[Production of aromatic carbonic acid ester]

Aromatic carbonate was produced using a
device shown in Fig. 1. The reaction was carried out
by supplying continuously at a rate of about 109 g/Hr,
through a preheater 2 and a transport line 1, a mixed
solution consisting of dibutyl carbonate, phenol and,
as a catalyst, titanium methyl phenoxide (Azumax Co.
Ltd. Ti-A KT881) (molecular weight: 476; vapor
pressure: 1 Pa or below at 230°C) (the mixed solution in
which the ratio by weight of dibutyl carbonate to
phenol was adjusted to 65/35, and Ti as atoms was
adjusted to about 10,000 ppm of the whole liquid) from
the middle stage of a continuous multi-stage
distillation column 3, which was composed of a
condensation part, which was 2 inch in the internal
diameter, 0.5 m in the column length and filled with 10
stages of sieve trays, and a recovery part which was 2
inch in the internal diameter, 1 m in the column length
and filled with Dixon packing (6 mmϕ) (at the time of
supplying, the catalyst was dissolved in the solution).
The condensation part was disposed in the
lower part of the stage where the mixed solution was
supplied continuously, and the recovery part was
disposed in the upper part. The heat required for the
reaction and distillation was supplied by circulating
the liquid in the lower part of the column through a
line 10 and a reboiler 11, and the temperature at the
bottom of the multi-stage distillation column was
controlled to be about 230°C. The reaction liquid was

continuously removed from the bottom of the continuous
multi-stage distillation column 3 through the line 10
to a storage tank 12 at 90 g/Hr. After the low boiling
point liquid mixture containing 1-butanol as a by-
product was removed from the top of the column through
a line 4, and then it was liquefied by the cooler 5,
and a part of it was removed continuously to a storage
tank 8 at 19 g/Hr and the rest was refluxed to the
distillation column (reflux ratio=1.9).
The liquid removed to the storage tank 12 was
composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve
trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled

with Dixon packing (6 mmϕ) , and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part. The reaction was carried
out by continuously supplying through a line 13 the
reaction liquid, which was removed from the bottom of
the continuous multi-stage distillation column 3
through the line 10 to the storage tank 12, to the
continuous multi-stage distillation column 15 at 100
g/Hr after preheating with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:

about 5% by weight, butyl phenyl carbonate: about 74%
by weight, diphenyl carbonate: about 10% by weight and
the catalyst. The liquid removed to the storage tank
20 was composed of 1-butanol: about 0.3% by weight,
phenol: about 18% by weight, and dibutyl carbonate:
about 81% by weight. No deposit or the like were found
in the distillation column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of
the column through a line 34 and a reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column was controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by a

cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 86% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed to
the storage tank 33, through a line 37 passing a
preheater 38 at about 100 g/Hr to the middle stage of a
continuous multi-stage distillation column 39, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 2 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 46 and a
reboiler 47, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 39 through the line 46 to a storage
tank 48 at about 8 g/Hr. After removing from the top
of the column through a line 40, the distillate was
liquefied by a cooler 41 and was removed continuously
to the storage tank 44 at about 92 g/Hr. The liquid
removed to a storage tank 44 is composed of dibutyl
carbonate: about 6% by weight, butyl phenyl carbonate:
about 94% by weight. White liquid that was solidified
at ambient temperature was continuously removed to a

storage tank 48 and contained diphenyl carbonate: about 100% by weight, and
butyl phenyl carbonate was below the detection limit. The analysis of the liquid
indicated that Ti content was 0.8 ppm. No deposit or the like were found in the
distillation column on inspection.
Example 4
[Production of aromatic carbonate]
Aromatic carbonate was produced using a device shown in Fig. 1.
The reaction was carried out by supplying continuously at a rate of about 109
g/Hr, through a preheater 2 and a transport line 1, a mixed solution consisting of
dibutyl carbonate, phenol and, as a catalyst, an organic polytitanoxan
composition (Nippon Soda Co. Ltd. B-4) containing butyl titanate tetsramer
(molecular weight; 970; vapor pressure: 1 Pa or below at 230Oc), (the mixed
solution in which the ration by weight of dibutyl carbonate to phenol was
adjusted to about 65/35, and Ti as atoms was adjusted to about 10,000 ppm of
the whole liquid, and this catalyst was dissolved in this solution) from the
middle stage of a continuous multi-stage distillation column 3, which was
composed of a condensation part, which was 2 inch in the internal diameter, 0.5
m in the column length and filled with 10 stages of sieve trays, and a recovery
part which was 2 inch in the internal diameter, 1 m
in the column length and filled with Dixon packing (6mmϕ).

The condensation part was disposed in the
lower part of the stage where the mixture was supplied
continuously, and the recovery part was disposed in the
upper part. The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 10 and a
reboiler 11, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 90 g/Hr. The catalyst was dissolved in the
reaction liquid. After the low boiling point liquid
mixture containing 1-butanol as a by-product was
removed from the top of the column through a line 4,
and then it was liquefied by the cooler 5, and a part
of it was removed continuously to a storage tank 8 at
19 g/Hr and the rest was refluxed to the distillation
column (reflux ratio=1.9).
The liquid removed to the storage tank 12 was
composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.

After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5m
in the column length and filled with 10 stages of sieve
trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ) , and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part. The reaction was carried
out by supplying continuously through a line 13 the
reaction liquid, which was removed from the bottom of
the continuous multi-stage distillation column 3
through the line 10 to the storage tank 12, to the
continuous multi-stage distillation column 15 at 100
g/Hr after preheating with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously

removed from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:
about 5% by weight, butyl phenyl carbonate: about 74%
by weight, diphenyl carbonate: about 10% by weight and
the catalyst. The liquid removed to the storage tank
20 was composed of 1-butanol: about 0.3% by weight,
phenol: about 18% by weight, and dibutyl carbonate:
about 81% by weight.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of

the column through a line 34 and a reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column was controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by a
cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 86% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed to
the storage tank 33, through a line 37 passing a
preheater 38 at about 100 g/Hr to the middle stage of a
continuous multi-stage distillation column 39, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 2 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 4 6 and a
reboiler 47, and the temperature at the bottom of the
multi-stage distillation column is controlled to be
about 230°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage

distillation column 39 through the line 46 to a storage tank 48 at about 8 g/Hr.
After removing from the top of the column through the line 40, the distillate was
liquefied by the cooler 41 and was removed continuously to the storage tank 44
at about 92 g/Hr. The liquid removed to the storage tank 44 is composed of
dibutyl carbonate: about 6% by weight, bytyl phenyl carbonate: about 94% by
weight. White liquid that was solidified at ambient temperature was
continuously removed to a storage tank 48 and contained dephenyl carbonate:
about 100% by weight, and butyl phenylcarbonate was below the detection limit.
The analysis of the liquid indicate that Ti content was below the detection limit.
No deposit or the like were found in the distillation column on inspection.
Comparative Example 4
[Production of aromatic carbonic acid ester]
Aromatic carbonate was produced using a device shown in Fig. 1.
The reaction was carried out by supplying continuously at a rate of about 109
g/Hr, through the preheater 2 and the transport line 1, a mixed solution
consisting of dibutyl carbonate, phenol and, as catalyst, monobutyltin
butyloxide oxide
(molecular weight: 660 or above; vapore pressure: 1 Pa
or below at 230° C) (the mixed solution in which the
ratio by weight of dibutyl carbonate to phenol was adjusted to about 65/35, and
Tin as atoms was adjusted to about 10;000 ppm of the whole liquid, and this

catalyst was dissolved in this solution) from the
middle stage of a continuous multi-stage distillation
column 3, which was composed of a condensation part,
which was 2 inch in the internal diameter, 0.5 m in the
column length and filled with 10 stages of sieve trays,
and a recovery part which was 2 inch in the internal
diameter, 1 m in the column length and filled with
Dixon packing (6 mmϕ).
The condensation part was disposed in the
lower part of the stage where the mixture was supplied
continuously, and the recovery part was disposed in the
upper part. The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 10 and a
reboiler 11, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 90 g/Hr. The catalyst was dissolved in the
reaction liquid. After the low boiling point liquid
mixture containing 1-butanol as a by-product was
removed from the top of the column through a line 4,
and then it was liquefied by the cooler 5, and a part
of it was removed continuously to a storage tank 8 at
19 g/Hr and the rest was refluxed to the distillation
column (reflux ratio=1.9).
The liquid removed to the storage tank 12 was

composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve
trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ), and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part. The reaction was carried
out by supplying continuously through a line 13 the
reaction liquid, which was removed from the bottom of
the continuous multi-stage distillation column 3
through the line 10 to the storage tank 12, to the

continuous multi-stage distillation column 15 at 100
g/Hr after preheating with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:
about 5% by weight, butyl phenyl carbonate: about 74%
by weight, diphenyl carbonate: about 10% by weight.
The liquid removed to the storage tank 20 was composed
of 1-butanol: about 0.3% by weight, phenol: about 18%
by weight, and dibutyl carbonate: about 81% by weight.
No deposit or the like were found in the distillation
column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with the device shown in Fig. 2. The distillation

separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of
the column through a line 34 and a reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column is controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by a
cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 86% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed to
the storage tank 33, through a line 37 passing a
preheater 38 at about 100 g/Hr to the middle stage of a
continuous multi-stage distillation column 39, which

was a column filled with Dixon packing (6 mmϕ) with an internal diameter of 2
inch and a length of 2 m.
The heat required for the distillation separation was supplied by
circulating the liquid in the lower part of the column through a line 46 and a
reboiler 47, and the temperature at the bottom of the multi-stage distillation
column was controlled to be about 230° C. The bottom liquid was continuously
removed from the bottom of the continuous multi-stage distillation column 39
through the line 46 to a storage tank 48 at about 8 g/Hr. After removing from
the top of the column through a line 40, the distillate Was liquefied by a cooler 41
and was removed continuously to a storage tank 44 at about 92 g/Hr. The liquid
removed to the storage tank 44 is composed of dibutyl carbonate: about 6% by
weight, butyl phenyl carbonate: about 94% by weight. White liquid that was
solidified at ambient temperature was continuously removed to a storage tank 48
and contained diphenyl carbonate: about 100% by weight, and butyl phenyl
carbonate was below the detection limit. The analysis of the liquid indicated
that Sn content was 0.9 ppm. No deposit or the like were found in the distillation
column on inspection.
Example 5
[Production of aromatic carbonic acid ester]
Aromatic carbonate was produced using a device
shown in Fig. 1. The reaction was carried out

by supplying continuously at a rate of about 109 g/Hr,
through a preheater 2 and a line 1, a mixed solution
consisting of dibutyl carbonate, phenol and, as a
catalyst, titanate containing butyl titanate hexamer
[(BuO)3-Ti-O-(Ti-(OBu)2.O)4-Ti-(OBu)3] (result of element
analysis: C=48.3, H=9.1, 0=21.9, Ti=20.7; since oxygen
derived from BuO is 16.1, the number of bridging oxygen
is 5, that is, there are 5 Ti-O-Ti bonds; molecular
weight: 1390; vapor pressure: 1 Pa or below at 230°C)
(the mixed solution in which the ratio by weight of
dibutyl carbonate to phenol was adjusted to about
65/35, and Ti as atoms was adjusted to about 10,000 ppm
of the whole liquid, and this catalyst was dissolved in
this solution) from the middle stage of the continuous
multi-stage distillation column 3, which was composed
of a condensation part, which was 2 inch in the
internal diameter, 0.5 m in the column length and
filled with 10 stages of sieve trays, and a recovery
part which was 2 inch in the internal diameter, 1 m in
the column length and filled with Dixon packing (6 mmϕ).
The condensation part was disposed in the
lower part of the stage where the mixture was supplied
continuously, and the recovery part was disposed in the
upper part. The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 10 and a
reboiler 11, and the temperature at the bottom of the
multi-stage distillation column was controlled to be

about 230°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 90 g/Hr. The catalyst was dissolved in the
reaction liquid. After the low boiling point liquid
mixture containing 1-butanol as a by-product was
removed from the top of the column through a line 4,
and then it was liquefied by the cooler 5, and a part
of it was removed continuously to a storage tank 8 at
19 g/Hr and the rest was refluxed to the distillation
column (reflux ratio=1.9).
The liquid removed to the storage tank 12 was
composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and also the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve

trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ), and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part. The reaction was carried
out by supplying continuously through a line 13 the
reaction liquid, which was removed from the bottom of
the continuous multi-stage distillation column 3
through the line 10 to the storage tank 12, to the
continuous multi-stage distillation column 15 at 100
g/Hr after preheating with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation

column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:
about 5% by weight, butyl phenyl carbonate: about 74%
by weight, diphenyl carbonate: about 10% by weight and
the catalyst. The liquid removed to the storage tank
20 was composed of 1-butanol: about 0.3% by weight,
phenol: about 18% by weight, and dibutyl carbonate:
about 81% by weight. No deposit or the like were found
in the distillation column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of
the column through the line 34 and reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column is controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.

After removing from the top of the column
through the line 28, the distillate was liquefied by a
cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 86% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed to
the storage tank 33, through a line 37 passing a
preheater 38 at about 100 g/Hr to the middle stage of a
continuous multi-stage distillation column 39, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 2 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 46 and a
reboiler 47, and the temperature at the bottom of the
multi-stage distillation column is controlled to be
about 230°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 39 through the line 46 to the
storage tank 48 at about 8 g/Hr. After removing from
the top of the column through the line 40, the
distillate was liquefied by the cooler 41 and was
removed continuously to the storage tank 44 at about 92
g/Hr. The liquid removed to a storage tank 44 is
composed of dibutyl carbonate: about 6% by weight,

butyl phenyl carbonate: about 94% by weight. White liquid that was
solidified at ambient temperature was continuously removed to the storage
tank 48 and contained diphenyl carbonate: about 100% by weight, and butyl
phenyl carbonate was below the detection limit. The analysis of the liquid
indicated that Ti content was blow the detection limit. No deposit or the like
were found in the distillation column on inspection.
Example 6
[Production of aromatic carbonic acid ester]
Aromatic carbonate was produced using a device shown in Fig.1.
The reaction was carried out by supplying continuously at a rate of about 109
g/Hr, through a preheater 2 and a line 1, a mixed solution consisting of
dibutyl carbonate, phenol and, as a catalyst, an adduct with phenol of phenyl
titanate tetramer [(PhO)3-Ti-O-(Ti (OPh)2-O)2-Ti- (OPh)3] (result of element
analysis: C=65.2, H=4.8, O=17.6, Ti=12.4; According to 1H-NMR analysis,
PhOH and PhO groups exist at a ratio of 4:10. In one molecule, there are 4 Ti
atoms and 3 oxygen atoms not derived from PhOH and PhO groups, that is,
the number of bridging oxygen atoms is 3, and therefore 3 Ti-O-Ti bonds
exist; molecular weight without the adduct phenol: 1170, vapor pressure: 1 Pa
or below at 230° C) (the mixed solution in which the ratio by weight of dibutyl
carbonate to phenol was adjusted to about 65/35, and Ti as atoms was
adjusted to about 10,000 ppm of the whole liquid) consisting of

dibutyl carbonate, phenol and, as a catalyst, an adduct
with phenol of phenyl titanate tetramer [(PhO)3-Ti-O-
(Ti (OPh)2-O)2-Ti-(OPh)3] (result of element analysis:
C=65.2, H=4.8, O=17.6, Ti=12.4; According to 1H-NMR
analysis, PhOH and PhO groups exist at a ratio of 4:10.
In one molecule, there are 4 Ti atoms and 3 oxygen
atoms not derived from PhOH and PhO groups, that is,
the number of bridging oxygen atoms is 3, and therefore
3 Ti-O-Ti bonds exist; molecular weight without the
adduct phenol: 1170; vapor pressure: 1 Pa or below at
230°C) from the middle stage of the continuous multi-
stage distillation column 3, which was composed of a
condensation part, which was 2 inch in the internal
diameter, 0.5 m in the column length and filled with 10
stages of sieve trays, and a recovery part which was 2
inch in the internal diameter, 1 m in the column length
and filled with Dixon packing (6 mmϕ).
The condensation part was disposed in the
lower part of the stage where the mixture was supplied
continuously, and the recovery part was disposed in the
upper part. The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 10 and a
reboiler 11, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage

tank 12 at 90 g/Hr. After the low boiling point liquid
mixture containing 1-butanol as a by-product was
removed from the top of the column through a line 4,
and then it was liquefied by the cooler 5, and a part
of it was removed continuously to a storage tank 8 at
19 g/Hr and the rest was refluxed to the distillation
column (reflux ratio=1.9). The catalyst was dissolved
in the liquid phase.
The liquid removed to the storage tank 12 was
composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve
trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ), and the condensation part

was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part. The reaction was carried
out by supplying continuously through a line 13 the
reaction liquid, which was removed from the bottom of
the continuous multi-stage distillation column 3
through the line 10 to the storage tank 12, to the
continuous multi-stage distillation column 15 at 100
g/Hr after preheating with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:
about 5% by weight, butyl phenyl carbonate: about 74%

by weight, diphenyl carbonate: about 10% by weight and
the catalyst. The liquid removed to the storage tank
20 was composed of 1-butanol: about 0.3% by weight,
phenol: about 18% by weight, and dibutyl carbonate:
about 81% by weight. No deposit or the like were found
in the distillation column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of
the column through a line 34 and a reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column was controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by a
cooler 29 and was removed continuously to a storage

tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 8 6% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed to
the storage tank 33, through a line 37 passing a
preheater 38 at about 100 g/Hr to the middle stage of a
continuous multi-stage distillation column 39, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 2 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 4 6 and a
reboiler 47, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 39 through the line 46 to the
storage tank 48 at about 8 g/Hr. After removing from
the top of the column through the line 40, the
distillate was liquefied by a cooler 41 and was removed
continuously to a storage tank 44 at about 92 g/Hr.
The liquid removed to a storage tank 44 is composed of
dibutyl carbonate: about 6% by weight, butyl phenyl
carbonate: about 94% by weight. White liquid that was
solidified at ambient temperature was continuously
removed to a storage tank 48 and contained diphenyl

carbonate: about 100% by weight, and butyl phenyl carbonate was below the
detection limit. The analysis of the liquid indicated that Ti content was below
the detection limit. No deposit or the like were found in the distillation
column on inspection.
Example 7
(Preparation of the catalyst)
To a reaction flask equipped with a stirrer, a thermometer, a
heating and cooling device and a reflux condenser, 3400g (10 mol) of tetra-n-
butoxytitanium and 1700 g of n-butanol were added and the liquid was
cooled to a temperature of 0° C while being mixed well. While maintaining
the liquid temperature at 0° C, a , mixture of 90 g (5 mol) of water and 2000 g
of n-butanol was added for 1 hour. After the addition the temperature was
raised to 80° C and stirred for 5 hours. The flask was connected to a rotary
evaporator equipped with a vacuum controller, vacuum pump and oil bath
for heating after cooling down the liquid to room temperature (about 20° C).
The low boiling point components were distilled by reducing the pressure to
about 25k Pa while maintaining the liquid temperature at 80° C. When
almost all the distillates came out, the temperature was raised slowly to 23° C
and further the pressure was reduced to 1 Pa, and after confirming that were
no distillate, nitrogen was added to return to normal
pressure and the temperature was returned to room
temperature (about 20° C) to obtain

about 2750 g of a pale yellow viscous liquid. This
liquid is a catalyst A. The result of element analysis
showed that the composition is C: 52.3%, H; 9.9%, 0:
20.4%, Ti: 17.4% and there is one Ti-O-Ti bond since
the number of oxygen atoms except for the oxygen
derived from BuO was 1 against Ti atom 2. Thus the
catalyst A described above is presumed to be a mixture
containing butyl titanate dirtier [(BuO)3-Ti-O-Ti(OBu)3]
as a main component.
[Production of aromatic carbonic acid ester]
Aromatic carbonate was produced using a
device shown in Fig. 1. The reaction was carried out
by supplying continuously at a rate of about 109 g/Hr,
through a preheater 2 and a line 1, a mixed solution
consisting of dibutyl carbonate, phenol and, as a
catalyst, the catalyst A (the mixed solution in which
the ratio by weight of dibutyl carbonate to phenol was
adjusted to about 65/35, and Ti as atoms was adjusted
to about 10,000 ppm of the whole liquid, and this
catalyst was dissolved in this solution) from the
middle stage of a continuous multi-stage distillation
column 3, which was composed of a condensation part,
which was 2 inch in the internal diameter, 0.5 m in the
column length and filled with 10 stages of sieve trays,
and a recovery part which was 2 inch in the internal
diameter, 1 m in the column length and filled with
Dixon packing (6 mmϕ).
The condensation part was disposed in the

lower part of the stage where the mixture was supplied
continuously, and the recovery part was disposed in the
upper part. The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 10 and a
reboiler 11, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 90 g/Hr. The catalyst was dissolved in the
reaction liquid. After the low boiling point liquid
mixture containing 1-butanol as a by-product was
removed from the top of the column through a line 4,
and then it was liquefied by the cooler 5, and a part
of it was removed continuously to a storage tank 8 at
19 g/Hr and the rest was refluxed to the distillation
column (reflux ratio=1.9).
The liquid removed to the storage tank 12 was
composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and also the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the reaction in the continuous multi-

stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
as in the case of the continuous multi-stage
distillation column 3, was composed of a condensation
part, which is 2 inch in the internal diameter, 0.5 m
in the column length and filled with 10 stages of sieve
trays, and a recovery part which is 2 inch in the
internal diameter, 1 m in the column length and filled
with Dixon packing (6 mmϕ), and the condensation part
was disposed in the lower part of the stage where the
reaction liquid containing the catalyst was supplied
continuously from the storage tank 12 to this
distillation column 15, and the recovery part was
disposed in the upper part. The reaction was carried
out by supplying continuously through a line 13 the
reaction liquid, which was removed from the bottom of
the continuous multi-stage distillation column 3
through the line 10 to the storage tank 12, to the
continuous multi-stage distillation column 15 at 100
g/Hr after preheating with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage

distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:
about 5% by weight, butyl phenyl carbonate: about 74%
by weight, diphenyl carbonate: about 10% by weight and
the catalyst. The liquid removed to the storage tank
20 was composed of 1-butanol: about 0.3% by weight,
phenol: about 18% by weight, and dibutyl carbonate:
about 81% by weight. No deposit or the like were found
in the distillation column on inspection.
[Purification of diaryl carbonate]
Purification of diaryl carbonate was carried
out with a device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of

the column through a line 34 and a reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column is controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by
cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 86% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed to
the storage tank 33, through a line 37 passing a
preheater 38 at about 100 g/Hr to the middle stage of a
continuous multi-stage distillation column 39, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 2 m.
The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 4 6 and a
reboiler 47, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage

distillation column 39 through the line 46 to a storage tank 48 at about 8
g/Hr. After removing from the top of the column through a line 40, the
distillate was liquefied by a cooler 41 and was removed continuously to a
storage tank 44 at about 92 g/Hr. The liquid removed to the storage tank 44
is composed of dibutyl carbonate: about 6% by weight, butyl phenyl
carbonate: about 94% by weight. White liquid that was solidified at ambient
temperature was continuously removed to a storage tank 48 and contained
diphenyl carbonate: about 100% by weight, and butyl phenyl carbonate was
below the detection limit. The analysis of the liquid indicated that Ti content
was below the detection limit. No deposit or the like were found in the
distillation column on inspection.
Example 8
(Preparation of the catalyst)
To a reaction flask equipped with a stirrer, a thermometer, a
heating and cooling device and a reflux condenser, 3400g (10 mol) of tetra-n-
butoxytitanium and 1700 g of n-butanol were added and the liquid was
cooled to a temperature of 0°C while being mixed well. While maintaining
the liquid temperature at 0oC, a mixture of 216 g (12 mol) of water and 2000 g
of n-butanol was added slowly for 1 hour. After the addition the
temperature was raised to 80° C and stirred for 5 hours. The
flask was connected to a rotary evaporated with a vacuum controller,

vacuum pump and oil bath for heating after cooling down
the liquid to room temperature (about 20°C). The low
boiling point components were distilled by reducing the
pressure to about 25K Pa while maintaining the liquid
temperature at 80°C. When almost all the distillates
came out, the temperature was raised slowly to 230°C and
further the pressure was reduced to 1 Pa, and after
confirming that there were no distillate, nitrogen was
added to return to normal pressure and the temperature
was returned to room temperature (about 20°C) to obtain
about 2320 g of pale yellow viscous liquid. This
liquid is a catalyst B. The result of element analysis
showed that the composition is C: 48.3%, H; 9.1%, O:
21.9%, Ti: 20.7%, and the number of bridging oxygen
atoms was 5 since the oxygen atom derived from BuO was
16.1, and there were 5 Ti-O-Ti bonds. The molecular
weight was 1390 and the vapor pressure was 1 Pa or less
at 230°C. Thus the catalyst B described above is
presumed to be a mixture containing butyl titanate
hexamer [(BuO)3-Ti-O-(Ti(OBu)2-O)4-Ti-(OBu)3] as a main
component.
[Production of aromatic carbonic acid ester]
Aromatic carbonate was produced using a
device shown in Fig. 1. The reaction was carried out
by supplying continuously at a rate of about 109 g/Hr,
through a preheater 2 and a line 1, a mixed solution
consisting of dibutyl carbonate, phenol and, as a
catalyst, the catalyst B (in which the ratio by weight

of dibutyl carbonate to phenol was adjusted to about
65/35, and Ti as atoms was adjusted to about 10,000 ppm
of the whole liquid, and this catalyst was dissolved in
this solution) from the middle stage of a continuous
multi-stage distillation column 3, which was composed
of a condensation part, which was 2 inch in the
internal diameter, 0.5 m in the column length and
filled with 10 stages of sieve trays, and a recovery
part which was 2 inch in the internal diameter, 1 m in
the column length and filled with Dixon packing (6 mmϕ).
The condensation part was disposed in the
lower part of the stage where the mixture was supplied
continuously, and the recovery part was disposed in the
upper part. The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 10 and a
reboiler 11, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 230°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 3 through the line 10 to a storage
tank 12 at 90 g/Hr. The catalyst was dissolved in the
reaction liquid. After the low boiling point liquid
mixture containing 1-butanol as a by-product was
removed from the top of the column through a line 4,
and then it was liquefied by the cooler 5, and a part
of it was removed continuously to a storage tank 8 at
19 g/Hr and the rest was refluxed to the distillation

column (reflux ratio=1.9).
The liquid removed to the storage tank 12 was
composed of phenol: about 23% by weight, dibutyl
carbonate: about 56% by weight, butyl phenyl carbonate:
about 12% by weight, diphenyl carbonate: about 0.2% by
weight, 1-butanol: about 0.3% by weight and also the
catalyst. The liquid removed to the storage tank 8 was
composed of 1-butanol: about 99% by weight, phenol:
about 0.5% by weight, and dibutyl carbonate: about 0.2%
by weight.
After the reaction in the continuous multi-
stage distillation column 3, the reaction was carried
out using a continuous multi-stage distillation column
15. The continuous multi-stage distillation column 15,
like the continuous multi-stage distillation column 3,
was composed of a condensation part, which is 2 inch in
the internal diameter, 0.5 m in the column length and
filled with 10 stages of sieve trays, and a recovery
part which is 2 inch in the internal diameter, 1 m in
the column length and filled with Dixon packing (6 mmϕ),
and the condensation part was disposed in the lower
part of the stage where the reaction liquid containing
the catalyst was supplied continuously from the storage
tank 12 to this distillation column 15, and the
recovery part was disposed in the upper part. The
reaction was carried out by supplying continuously
through a line 13 the reaction liquid, which was
removed from the bottom of the continuous multi-stage

distillation column 3 through the line 10 to the
storage tank 12, to the continuous multi-stage
distillation column 15 at 100 g/Hr after preheating
with a preheater 14.
The heat required for the reaction and
distillation was supplied by circulating the liquid in
the lower part of the column through a line 22 and a
reboiler 24, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 220°C. The reaction liquid was continuously
removed from the bottom of the continuous multi-stage
distillation column 15 through the line 22 to a storage
tank 24 at 17 g/Hr. After the low boiling point liquid
mixture containing dibutylcarbonate as a by-product was
removed from the top of the column through a line 16,
and then it was liquefied by a cooler 17, and a part of
it was removed continuously to a storage tank 20 at 83
g/Hr and the rest was refluxed to the distillation
column (reflux ratio=4). The liquid removed to the
storage tank 24 was composed of dibutyl carbonate:
about 5% by weight, butyl phenyl carbonate: about 74%
by weight, diphenyl carbonate: about 10% by weight and
the catalyst. The liquid removed to the storage tank
20 was composed of 1-butanol: about 0.3% by weight,
phenol: about 18% by weight, and dibutyl carbonate:
about 81% by weight. No deposit or the like were found
in the distillation column on inspection.
[Purification of diaryl carbonate]

Purification of diaryl carbonate was carried
out with the device shown in Fig. 2. The distillation
separation was carried out by continuously feeding the
liquid, which was removed to the storage tank 24,
through a line 25 passing a preheater 26 at about 100
g/Hr to about 0.1 m above the middle stage of a
continuous multi-stage distillation column 27, which
was a column filled with Dixon packing (6 mmϕ) with an
internal diameter of 2 inch and a length of 1 m. The
heat required for the distillation separation was
supplied by circulating the liquid in the lower part of
the column through a line 34 and a reboiler 35, and the
temperature at the bottom of the multi-stage
distillation column is controlled to be about 210°C.
The bottom liquid was continuously removed from the
bottom of the continuous multi-stage distillation
column 27 through the line 34 to the storage tank 36 at
about 20 g/Hr.
After removing from the top of the column
through the line 28, the distillate was liquefied by a
cooler 29 and was removed continuously to a storage
tank 33 at about 80 g/Hr. The liquid removed to the
storage tank 33 is composed of dibutyl carbonate: about
6% by weight, butyl phenyl carbonate: about 86% by
weight, diphenyl carbonate: about 7.5% by weight. The
distillation separation was carried out by continuously
feeding the liquid, which was continuously removed to
the storage tank 33, through a line 37 passing a

preheater 38 at about 100 g/Hr to the middle stage of a
continuous multi-stage distillation column 39, which was a column
filled with Dixon packing (6 mm0) with an internal diameter of
2 inch and a length of 2 m:
The heat required for the distillation separation was supplied by
circulating the liquid in the lower part of the column through a line 46 and a
reboiler 47, and the temperature at the bottom of the multi-stage distillation
column was controlled to be about 230° C. The bottom liquid was
continuously removed from the bottom of the continuous multi-stage
distillation column 39 through the line 46 to a storage tank 48 at about 8
g/Hr. After removing from the top of the column through a line 40, the
distillate was liquefied by a cooler 41 and was removed continuously to the
storage tank 44 at about 92 g/Hr. The liquid removed to the storage tank 44
is composed of dibutyl carbonate: about 6% by weight, butyl phenyl
carbonate: about 94% by weight. White liquid that was solidified at ambient
temperature was continuously removed to a storage tank 48 and contained
diphenyl carbonate: about 100% by weight, and butyl phenyl carbonate was
below the detection limit. The analysis of the liquid indicated that Ti content
was below the detection limit. No deposit or the like were found in the
distillation column on inspection.
Example 9
(Preparation of the catalyst)

To a reaction flask equipped with a stirrer,
a thermometer, a heating and cooling device and a
reflux condenser, 3400g (10 mol) of tetra-n-
butoxytitanium and 1700 g of n-butanol were added and
the liquid was cooled to a temperature of 0°C while
being mixed well. While maintaining the liquid
temperature at 0°C, a mixture of 90 g (5 mol) of water
and 2000 g of n-butanol was added slowly for 1 hour.
After the addition the temperature was raised to 80°C
and stirred for 5 hours. The flask was connected to a
rotary evaporator equipped with a vacuum controller,
vacuum pump and oil bath for heating after cooling down
the liquid to room temperature (about 20°C). The low
boiling point components were distilled by reducing the
pressure to about 25K Pa while maintaining the liquid
temperature at 80°C. When almost all the distillates
came out, the temperature was raised slowly to 230°C and
further the pressure was reduced to 1 Pa, and after
confirming that there were no distillate, nitrogen was
added to return to normal pressure and the temperature
was returned to room temperature (about 20°C) to obtain
about 2750 g of pale yellow viscous liquid. This
liquid is a catalyst A. The result of element analysis
showed that the composition is C: 52.3%, H; 9.9%, 0:
20.4%, Ti: 17.4%, and there is one Ti-O-Ti bond since
the number of oxygen atoms except for the oxygen
derived from BuO was 1 against Ti atom 2. Thus the
catalyst A described above is presumed to be a mixture

containing butyl titanate dimer [(BuO)3-Ti-O-Ti (OBu)3]
as a main component.
To this flask, the stirrer, thermometer,
heating and cooling device and reflux condenser were
reattached and the liquid was heated to 80°C while
stirring. While keeping the liquid temperature at 80°C,
4700 g (50 mol) of distilled and dehydrated phenol was
added slowly. After the addition, the liquid was
heated to 180°C and low boiling point components were
evaporated. When there was almost no distillate, the
temperature of the liquid was slowly raised to 230°C to
remove distillates further. The flask was connected to
the vacuum controller and vacuum pump, the pressure was
reduced slowly to 1 Pa and distillates were removed.
Then the flask was taken out of the oil bath, cooled to
room temperature (about 20°C.) and the inside pressure of
the flask was returned to normal by nitrogen. Solid
substance of about 4300 g with red orange coloring was
obtained. This was the catalyst C. The result of
element analysis showed that the composition is C:
64.5%, H: 4.5%, 0: 16.7%, Ti: 14.3%. The catalyst C
described above is presumed to be a mixture containing
phenol adduct of phenyl titanate dimer [(PhO)3-Ti-O-
Ti(OPh)3.2PhOH] as a main component.
[Production of aromatic carbonic acid ester]
A mixture consisting of dimethyl carbonate,
phenol and, as a catalyst, the catalyst C was
continuously supplied as a liquid from an inlet line 50

through a preheater 51 to the location at 1 m from the
top of a multi-stage distillation column 49 as shown in
Fig. 3, which was composed of a packed column with 4 m
tall and 3 inch internal diameter filled with Dixon
packing (6 mm required for the reaction and distillation was supplied
by heating the liquid in the bottom of the column by
the reboiler (the liquid supply from the inlet line 50:
3.4 kg/Hr; composition of the liquid supply: DMC=about
68.3% by weight, PhOH=about 33.7% by weight, catalyst
C=13.5 mmol/Kg). The temperature at the bottom of the
column was about 201°C, the pressure at the top of the
column was about 800 KPa, the reflux ratio was about 1.
As the result of the reaction, the liquid containing
the component of the catalyst, and methyl phenyl
carbonate and diphenyl carbonate, which were the
reaction products, was obtained from the bottom 53 of
the column through lines 58 and 60. The gas distillate
from a line 54 disposed on the top 52 of the column was
condensed by a condenser 55. A part of the condensed
liquid was refluxed to a distillation column 49 through
an inlet line 56, and the rest was removed from a line
57. From this condensed liquid a low boiling point
product, methanol, was obtained. The amount of liquid
removed from the line 60 (average liquid composition:
methyl phenyl carbonate=50 g/Kg.Hr, diphenyl
carbonate=0.4 g/Kg/Hr) was about 2.3 Kg/Hr. No deposit
or the like were found in the distillation column on

inspection.
[Purification of aromatic carbonate]
Aromatic carbonate was purified using a
device shown in Fig. 2. The device was a continuous
multi-stage distillation column which was composed of a
column with 2 inch internal diameter and 1 m height,
filled with Dixon packing (6 mmϕ). Distillation
separation was carried out by feeding the liquid
removed from the aforementioned line 60, continuously
at a rate of about 100 g/Hr, through a line 25 and a
preheater 26, to a continuous multi-stage distillation
column 27 at the location about 0.1 m above the middle
stage. The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 34 and a
reboiler 35, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 210°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 27 through the line 34 to the
storage tank 36. After removing from the top of the
column through a line 28, the distillate was liquefied
by a cooler 29 and was removed continuously to a
storage tank 33. Distillation separation was carried
out by feeding the liquid, which was removed
continuously from the storage tank 33, continuously at
a rate of about 100 g/Hr, through a line 37 and the
preheater 38, to the middle stage of a continuous

multi-stage distillation column 39, which was composed of a column with 2
inch internal diameter and 2 m height, filled with Dixon packing (6 mm*).
The heat required for the distillation separation was supplied by circulating
the liquid in the lower part of the column through a line 46 and a reboiler 47,
and the temperature at the bottom of the multi-stage distillation column was
controlled to be about 230°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage distillation column 39 through
a line 46 to a storage tank 48. After being removed from the top of the
column through a line 40, the distillated was liquefied by a cooler 41 and was
removed continuously to a storage tank 44. The liquid removed to the
storage tank 44 contained methyl phenyl carbonate at about 94% by weight.
The analysis of the liquid indicated that Ti content was below the detection
limit. No deposit or the like were found in the distillation column on
inspection.
Comparative Example 5
Aromatic carbonate was purified as in Example 9 except that the
catalyst was changed from the catalyst C to phenoxy titanate [Ti (OPh)4]
(molecular weight: 420, vapor pressure: about 15 Pa at 23°C ). The amount
of the liquid (average composition: methyl phenyl earbonate=50
g/Kg.Hr, diphenyl carbonate=0.4 g/Kg/Hr) removed from the line 60 was
about 2.3 Kg/Hr. The liquid removed to the storage tank 44 contained

methyl phenyl carbonate : about 94% by weight. The analysis of the liquid
indicated that Ti was detected at 9 ppm. Inspection of the inside of the
column revealed white deposits on the wall of the distillation column and the
packing.
Example 10
(Preparation of the catalyst)
To a reaction flask equipped with a stirrer, a thermometer, a
heating and cooling device and a reflux condenser, 3400g (10 mol) of tetra-n-
butoxytitanium and 1700 g of n-butahol were added and the liquid was
cooled to a temperature of 0°C while being mixed well. While maintaining
the liquid temperature at 0°C, a mixture of 90 g (5 mol) of water and 2000 g of
n-butanol was added slowly for 1 hour. After the additional, the temperature
was raised to 80oC and stirred for 5 hours. The flask was connected to a
rotary evaporator equipped with a vacuum controller, vacuum pump and oil
bath for heating after cooling down the liquid to room temperature (about
20o C). The low boiling point components were distilled by reducing the
pressure to about 25 Kpa while maintaining the liquid temperature at 80o C.
When almost all the distillates came out, the temperature was raised slowly to
230o C and the pressure was reduced further to 1 Pa, and after
confirming that there were no distillate, nitrogen was added
to return to normal pressure and the temperature was returned
to room temperature (about 20o C) to obtain

about 2750 g of pale yellow viscous liquid. This
liquid is a catalyst A. The result of element analysis
showed that the composition is C: 52.3%, H; 9.9%, 0:
20.4%, Ti: 17.4%, and there is one Ti-O-Ti bond since
the number of oxygen atoms except for the oxygen
derived from BuO was 1 against Ti atom 2. Thus the
catalyst A described above is presumed to be a mixture
containing butyl titanate dimer [(BuO)3-Ti-O-Ti(OBu)3]
as a main component.
To this flask, the stirrer, thermometer,
heating and cooling device and reflux condenser were
reattached and the liquid was heated to 80°C while being
stirred. While keeping the liquid temperature at 80°C,
4700 g (50 mol) of distilled and dehydrated phenol was
added slowly. After the addition, the liquid was
heated to 180°C and low boiling point components were
evaporated. When there was almost no distillate, the
temperature of the liquid was slowly raised to 230°C to
further remove distillates. The flask was connected to
the vacuum controller and vacuum pump, the pressure was
reduced slowly to 1 Pa and distillates were removed.
Then the flask was taken out of the oil bath, cooled to
room temperature (about 20°C) and the inside pressure of
the flask was returned to normal by nitrogen. Solid
substance of about 4300 g with red orange coloring was
obtained. This was the catalyst C. The result of
element analysis showed that the composition is C:
64.5%, H: 4.5%, 0: 16.7%, Ti: 14.3%. The catalyst C

described above is presumed to be a mixture containing
phenol adduct of phenyl titanate dimer [(PhO)3-Ti-O-
Ti(OPh)3-2PhOH] as a main component.
[Production of aromatic carbonic acid ester]
A mixture consisting of methyl phenyl
carbonate (MPC) and the catalyst was continuously
supplied as a liquid from an inlet line 62 through a
preheater 63 to the location at 1 m from the top of a
multi-stage distillation column 61 as shown in Fig. 4,
which was composed of a pressure control device 68 and
a packed column with 4 m tall and 3 inch internal
diameter packed with Dixon packing (6 mmϕ) made of
stainless steel, and the reaction was carried out by
heating with the reboiler (the liquid supply from the
inlet line 62: 4.2 Kg/Hr; composition of the liquid
supply: MPC=about 99% by weight, catalyst C=12.5
mmol/Kg). The temperature at the bottom of the column
was about 195°C, the pressure at the top of the column
was about 30 KPa, the reflux ratio was about 2.1. As
the result of the reaction, the liquid containing
diphenyl carbonate, which was the reaction product, was
obtained from the bottom 65 of the continuous multi-
stage distillation column through the outlet 70 of the
column bottom liquid. The gas distillate from a gas
outlet 66 disposed on the top 64 of the column was
condensed by a condenser 67. A part of the condensed
liquid was refluxed, and the rest was removed from an
outlet 69 of the condensed liquid. From this condensed

liquid a by-product, dimethyl carbonate, was obtained.
From the liquid removed from the line 70, diphenyl
carbonate was obtained at a rate of 705 g/Kg/Hr. No
deposit or the like were found in the distillation
column on inspection.
[Purification of aromatic carbonate]
Aromatic carbonate was purified using a
device shown in Fig. 2. The device was a continuous
multi-stage distillation column which was composed of a
column with 2 inch internal diameter and 1 m tall,
filled with Dixon packing (6 mmϕ) . Distillation
separation was carried out by feeding the liquid
removed from the aforementioned line 60, continuously
at a rate of about 100 g/Hr, through a line 25 and a
preheater 26, to a continuous multi-stage distillation
column 27 at the location about 0.1 m above the middle
stage. The heat required for the distillation
separation was supplied by circulating the liquid in
the lower part of the column through a line 34 and a
reboiler 35, and the temperature at the bottom of the
multi-stage distillation column was controlled to be
about 210°C. The bottom liquid was continuously removed
from the bottom of the continuous multi-stage
distillation column 27 through the line 34 to a storage
tank 36. After removing from the top of the column
through the line 28, the distillate was liquefied by a
cooler 2 9 and was removed continuously to a storage
tank 33. Distillation separation was carried out by

feeding the liquid, which was removed continuously from the storage tank
33, continuously at a rate of about 100 g/Hr, through a line 37 and a
preheater 38, to the middle stage of the continuous multi-stage distillation
column with 2 inch internal diameter and 2 m height, filled with Dixon
packing (6 mmϕ), The heat required for the distillation separation was
supplied by circulating the liquid in the lower part of the column through a
line 46 and a reboiler 47, and the temperature at the bottom of the multi-stage
distillation column was controlled to be about 230o C. The bottom liquid was
continuously removed from the bottom of the continuous multi-stage
distillation column 39 through the line 46 to a storage tank 48. After being
removed from the top of the column through the line 40, the distillate was
liquefied by a cooler 41and was removed continuously to a storage tank 44.
To a storage tank 48, white liquid which was solidified at ambient
temperature was continuously removed and this was diphenyl carbonate,
about 100% by weight. The analysis of the liquid indicated that Ti content
was below the detection limit. No deposit or the like were found in the
distillation column on inspection.
Comparative Example 6
Aromatic carbonate was purified as in Example 10 except that the catalyst
was changed from the catalyst C to phenol adduct of phenoxy titanate

[Ti (OPh)4 2PhOH] (molecular weight without phenol adduct: 420, vapor
pressure: about 15 Pa at 230°C) (the liquid supplied from the inlet line 62: 4.2
Kg/Hr; composition of the liquid supplied: MPC=about 99 wt , %, catalyst
C=12.5 mmol/Kg). The temperature at the bottom of the column was about
195°C, the pressure at the top of the column was about 30 KPa, and the reflux
ration was about 2.1, To the storage tank 48, white liquid which was
solidified at ambient temperature was continuously removed and this was
diphenyl carbonate, about 100% by weight. The analysis of the liquid
indicated that Ti was detected at 5 ppm. Inspection of the inside of the
column revealed white deposits on the wall of the distillation column and the
packing.
Example 11 (Polycarbonate was obtained from diphenyl carbonate produced
by the method for production in
Example 1)
Diphenyl carbonate obtained in Example 1: 23.5 g and bisphenol A:
22.8 g were put in a vacuum reactor equipped with a stirrer and polymerized
at 8000 Pa for 30 minutes and 4000 Pa for 90 minutes while being purged with
nitrogen gas. After this, temperature was raised to 270oC and polymerization
was continued at 70 Pa for 1 hour. Aromatic polycarbonate obtained in such
a way was transparent without weight was 10,500.
Comparative Example 7 (Polycarbonate was obtained from

diphenyl carbonate produced by the method for production in Comparative
Example 1)
Diphenyl carbonate obtained in Example 2: 23.5 g and
bisphenol A: 22.8 g were put in a vacuum reactor equipped with a stirrer and
polymerized at 8000 Pa for 30 minutes and 4000 Pa for 90 minutes while
being purged with nitrogen gas. After this, temperature was raised to 270oC
and polymerization was continued at 70 Pa for 1 hour. Aromatic
polycarbonate obtained in such a way had red coloring and the number
average molecular weight was 9,800.
INDUSTRILA APPLICABILITY
According to the present invention, high purity diaryl carbonate
can be produced with a catalyst easily removed when producing aromatic
carbonate by an transesterification of a starting material and a reactant in the
presence of a metal-containing catalyst while distilling off by-product alcohol
and/or by-product dialkyl carbonate to the outside of the reaction system.
An aromatic polycarbonate produced by transesterification comprising diaryl
carbonate produced by the method of the present invention is free from
coloring and has high quality.

WE CLAIM:
1. A method for producing an aromatic carbonate, which comprises allowing to
react a starting material selected from the group consisting of a dialkyl carbonate
represented by the following formula (1), an alkylaryl carbonate represented by
the following formula (2) and a mixture thereof with a reactant selected from the
group consisting of an aromatic monohydroxy compound represented by the
following formula (3), an alkylaryl carbonate represented by the following formula
(4) and a mixture thereof in the presence of a metal-containing catalyst, with
distilling off by-product alcohols and/or by-product dialkyl carbonates to the
outside of the reaction system, thereby producing an aromatic carbonate
represented by the following formula (5) and/or the following formula (6)
corresponding to the starting material and the reactant,
wherein the metal-containing catalyst is an organic polytitanoxane composition of
a molecular weight of 480 or more which comprises at least two titanium atoms
and is dissolved in a liquid phase in the reaction system or present in the form of
liquid during the reaction,


(wherein R1, R2 and R3 in the formulas (1) to (4) independently represent an alkyl
group having 1 to 10 carbon atoms, an alicyclic group having 3 to 10 carbon
atoms or an aralkyl group having 6 to 10 carbon atoms, and Ar1, Ar2 and Ar3
independently represent an aromatic group having 5 to 30 carbon atoms), and

(wherein R.and Ar in the formulas (5) and (6) are each selected from R1, R2, R3,
Ar1 , Ar2 and Ar3 of the corresponding starting material and reactant).

2. The method as claimed in claim 1, wherein said organic polytitanoxane
composition contains at least one alkoxy group and/or aryloxy group as an
organic group.
3. The method as claimed in claim 1, wherein said organic polytitanoxane
composition is obtained by a polycondensation reaction of at least one raw
material selected from the group consisting of tetraalkoxytitanium,
tetrahalotitanium (TiX4: X being selected from C1 and Br) and titanium hydroxide.
4. The method as claimed in claim 3, wherein said organic polytitanoxane
composition is obtained by sequentially or simultaneously performing two steps
of:

1) preparing a partially hydrolyzed product by partially hydrolyzing
tetraalkoxytitanium and
2) distilling off a generated low boiling point component including alcohol
from the partially hydrolyzed product and subjecting the product to
polycondensation.
5. The method as claimed in claim 3, wherein said organic polytitanoxane
composition is obtained by subjecting tetraalkoxytitanium to heating,
deetherification and polycondensation.

6. The method as claimed in claim 3, wherein said organic polytitanoxane
composition is obtained by sequentially or simultaneously performing three steps
of:
1) preparing a partially hydrolyzed product by partially hydrolyzing
tetrahalotitanium,
2) distilling off a low boiling point component from the partially hydrolyzed
product and subjecting the product to polycondensation and
3) reacting the resultant with alcohol, removing HX therefrom and
alkoxylating the same.

7. The method as claimed in any one of claim 1 or claims 2 to 6, wherein said
polytitanoxane composition is used as is or after alkoxy group exchange by
reaching the composition with a composition containing at least one member
selected from alcohol, an aromatic hydroxy compound and carbonic acid ester.
8. The method as claimed in any one of claim 1 or claims 2 to 7, wherein said
titanium containing compound contains at least two Ti atoms in one molecule.
9. The method as claimed in claim 8, wherein said titanium containing compound
contains 2 to 6 Ti atoms in one molecule.

10. The method as claimed in claim 8, wherein said titanium containing
compound contains at least one Ti-O-Ti bond in one molecule.
11. The method as claimed in claim 1, wherein said metal-containing catalyst has
a vapor pressure at 230°C of 10 Pa or lower.
12. The method as claimed in any one of claim 1 or claims 2 to 11, wherein said
metal-containing catalyst is used in a proportion of 0.0001 to 30% by weight
based on the total weight of said starting material and said reactant.
13. The method as claimed in any one of claim 1 or claims 2 to 12, wherein said
aromatic hydroxy compound is phenol.


Title: A method for producing an aromatic carbonate.
Production of an aromatic carbonic ester through an ester exchange reaction
between a starting material and a reactant while distilling by-product alcohols
and/or by-product dialkyl carbonates off the reaction system, wherein use is
made of a specified catalyst.

Documents:

02109-kolnp-2007-abstract.pdf

02109-kolnp-2007-claims.pdf

02109-kolnp-2007-correspondence others 1.1.pdf

02109-kolnp-2007-correspondence others 1.2.pdf

02109-kolnp-2007-correspondence others 1.3.pdf

02109-kolnp-2007-correspondence others 1.4.pdf

02109-kolnp-2007-correspondence others.pdf

02109-kolnp-2007-description complete.pdf

02109-kolnp-2007-drawings.pdf

02109-kolnp-2007-form 1.pdf

02109-kolnp-2007-form 18.pdf

02109-kolnp-2007-form 2.pdf

02109-kolnp-2007-form 3.pdf

02109-kolnp-2007-form 5.pdf

02109-kolnp-2007-international exm report.pdf

02109-kolnp-2007-international publication.pdf

02109-kolnp-2007-international search report.pdf

02109-kolnp-2007-priority document 1.1.pdf

02109-kolnp-2007-priority document.pdf

2109-KOLNP-2007-(24-10-2011)-CORRESPONDENCE.pdf

2109-KOLNP-2007-(24-10-2011)-OTHERS.pdf

2109-KOLNP-2007-(29-06-2012)-CORRESPONDENCE.pdf

2109-KOLNP-2007-ABSTRACT.pdf

2109-KOLNP-2007-AMANDED CLAIMS.pdf

2109-kolnp-2007-correspondence 1.1.pdf

2109-KOLNP-2007-CORRESPONDENCE 1.2.pdf

2109-KOLNP-2007-CORRESPONDENCE OTHERS 1.5.pdf

2109-kolnp-2007-description (complete) 1.1.pdf

2109-KOLNP-2007-DESCRIPTION (COMPLETE).pdf

2109-kolnp-2007-drawings.pdf

2109-KOLNP-2007-ENGLISH TRANSLATION OF GRANTED JAPANESE CLAIMS.pdf

2109-KOLNP-2007-EXAMINATION REPORT.pdf

2109-kolnp-2007-form 1-1.1.pdf

2109-KOLNP-2007-FORM 1.pdf

2109-KOLNP-2007-FORM 18.pdf

2109-kolnp-2007-form 2-1.1.pdf

2109-KOLNP-2007-FORM 2.pdf

2109-KOLNP-2007-FORM 3 1.2.pdf

2109-kolnp-2007-form 3-1.1.pdf

2109-KOLNP-2007-FORM 3.pdf

2109-KOLNP-2007-FORM 5.pdf

2109-KOLNP-2007-GPA.pdf

2109-KOLNP-2007-GRANTED-ABSTRACT.pdf

2109-KOLNP-2007-GRANTED-CLAIMS.pdf

2109-KOLNP-2007-GRANTED-DESCRIPTION (COMPLETE).pdf

2109-KOLNP-2007-GRANTED-DRAWINGS.pdf

2109-KOLNP-2007-GRANTED-FORM 1.pdf

2109-KOLNP-2007-GRANTED-FORM 2.pdf

2109-KOLNP-2007-GRANTED-SPECIFICATION.pdf

2109-KOLNP-2007-INTERNATIONAL PRELIMINARY REPORT.pdf

2109-KOLNP-2007-INTERNATIONAL SEARCH REPORT.pdf

2109-kolnp-2007-others 1.1.pdf

2109-KOLNP-2007-OTHERS 1.2.pdf

2109-KOLNP-2007-OTHERS.pdf

2109-KOLNP-2007-PA.pdf

2109-KOLNP-2007-PETITION UNDER RULE 137.pdf

2109-KOLNP-2007-REPLY TO EXAMINATION REPORT 1.1.pdf

2109-KOLNP-2007-REPLY TO EXAMINATION REPORT.pdf

2109-KOLNP-2007-TRANSLATED COPY OF PRIORITY DOCUMENT.pdf

abstract-02109-kolnp-2007.jpg


Patent Number 253294
Indian Patent Application Number 2109/KOLNP/2007
PG Journal Number 28/2012
Publication Date 13-Jul-2012
Grant Date 11-Jul-2012
Date of Filing 11-Jun-2007
Name of Patentee ASAHI KASEI CHEMICALS CORPORATION
Applicant Address 1-2, YURAKU-CHO 1-CHOME, CHIYODA-KU, TOKYO, JAPAN
Inventors:
# Inventor's Name Inventor's Address
1 NOBUHISA MIYAKE C/O. ASAHI KASEI KABUSHIKI KAISHA OF 1-2, YURAKU-CHO 1-CHOME, CHIYODA-KU, TOKYO, 100-8440, JAPAN
PCT International Classification Number C07C 68/06
PCT International Application Number PCT/JP2005/023157
PCT International Filing date 2005-12-16
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2004-369314 2004-12-21 Japan
2 2004-369313 2004-12-21 Japan
3 2004-369315 2004-12-21 Japan
4 2004-369316 2004-12-21 Japan