Title of Invention

A CYLINDRICAL CATALYST BODY

Abstract The invention relates to a cylindrical catalyst body 1 which is characterized in that indentations are provided on the circumferential surface 3 of the catalyst body 1. These indentations are preferably configured as grooves 4 and webs 5 which run parallel to the longitudinal axis 2 of the catalyst body 1.
Full Text 27 April 2006
4465-X-23.706
CATALYST SUPPORT
The invention relates to a catalyst support, such as
may be used, for example, for the steam reforming of
hydrocarbons.
So that as high a conversion rate as possible and as
high an output as possible are obtained during
heterogeneously catalysed reactions in the gas phase,
as large a contact surface as possible should be
provided between the gas phase and the catalyst
surface, so that an intensive exchange between the
catalyst and the gaseous reaction components becomes
possible. Thus, for heterogeneously catalysed
reactions, reactors have been developed in which the
catalyst is provided as a loose heap of small catalyst
bodies. The heap must in this case be designed in such
a way that, on the one hand, a large surface is
provided as a contact surface between a solid catalyst
and gaseous reactants, but, on the other hand, the
pressure drop across the reactor also does not become
too great. Otherwise, the gas throughput through the
reactor drops or a high compression of the reaction gas
is required. The catalyst introduced into the reactor
is to be in as high a fraction as possible for the
catalysed reaction. The heap of catalyst should
therefore not have too high a density, since,
otherwise, the catalyst fraction which is arranged in
further-inward portions of the catalyst body and is
therefore not available for a catalysis of the reaction
rises too sharply. The catalyst body should therefore
have as high a ratio as possible of the surface of the
catalyst body to its weight. Finally, the catalyst

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bodies must have sufficiently high mechanical
stability, so that they do not disintegrate under
mechanical load and collapse into a finely particulate
powder or granulate which blocks the flow paths within
the catalyst packing and leads to an increase in the
pressure drop. Finally, the catalyst bodies must also
be shaped such that, when introduced into the reactor,
they form the desired heap, that is to say the catalyst
bodies should not, for example, be tilted on edge, so
as not to form within the reactor any larger cavities
which are not filled with catalyst.
In addition to simple spheres or granulates, therefore,
a whole series of catalyst bodies have been developed,
which provide a uniform heap and as large a surface as
possible. Although there is already a high diversity of
forms for catalyst bodies, there is still always room
for further developments.
Reactors filled with catalysts or catalyst bodies are
usually operated continuously for a lengthy period of
time of several months to several years, so that slight
increases in value in output during the production of
the desired compounds already have major economic
effects on the viability of the plant.
Likewise, an albeit slight increase in the stability of
the catalyst moulded bodies usually means a significant
economic benefit, since the operating time of the plant
can be prolonged and few interruptions in the
production process for renewing the catalyst packing
are required.
DE 39 35 073 describes a method for the catalytic
dehydration of hydrocarbons, in particular of aromatic
alkyls, at increased temperature in the presence of
steam and metal-oxide catalyst moulded bodies. The
moulded bodies have a gearwheel-like configuration with

— 3 —
at least three teeth, the following dimension ratios
applying:
(a) the ratio tip diameter (d2) : root diameter
(d1) is about 1.2 to 2.5 : 1;
(b) the ratio space width at the tooth root (b1):
tooth width (b2) at the tooth crown is 0.1 to
0.9 : 1;
(c) the space width at the tooth root (b1) is at
least 0.1 mm.
DE 39 34 032 Al describes a heat-transmission or
filling-body element, with a core region which extends
in the longitudinal direction and on which are arranged
projections running in the longitudinal direction and
having a T-shaped cross section.
DE 31 41 942 Al describes catalyst moulded bodies with
an essentially cylindrical configuration, having a
plurality of longitudinal depressions which extend
radially inwards from the cylinder circumference and
delimit elevations which lie between them and the
maximum width of which is greater than that of the
depressions.
DE 31 18 835 Al describes a catalyst structure for the
partial oxidation of n-butane for the production of
maleic acid anhydride. The catalysts are in the form of
a tablet, in the centre of which a hole or a cavity is
arranged.
DE 29 14 079 describes heaped exchange bodies with
reactive material, which are suitable, in particular,
for the enrichment of trace substances from large water
masses. The heaped bodies have a mechanically stable
outer contour and a liquid-accessible reactive surface
protected from mechanical attack by adjacent bodies.

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DE 27 19 543 A describes ceramic bodies for receiving a
catalyst, in particular for the forming of
hydrocarbons. The ceramic body is in the form of a
tube, in the inner cavity of which are arranged webs
running radially outwards from the longitudinal axis.
DE 24 25 058 describes filling bodies consisting of
ceramic material which are in the form of tubular
segments. The tubular segments have a plurality of
longitudinal ducts running parallel to one another. In
this case, a plurality of longitudinal ducts may be
arranged around a central longitudinal duct.
The object on which the invention is based was,
therefore, to provide a catalyst body which makes it
possible to produce as homogeneous a catalyst heap as
possible, while as large a surface of the catalyst body
as possible is to be provided.
This object is achieved by means of a catalyst body
having the features of Patent Claim 1. Advantageous
developments are the subject-matter of the dependent
claims.
According to the invention, a cylindrical catalyst body
is provided, which on its circumferential surface has
grooves running parallel to the longitudinal axis of
the catalyst body and webs running between the grooves.
The catalyst body is characterized in that the grooves
and the webs running between the grooves are in their
cross section in the form of a segment of a circle.
The grooves and webs provided on the circumferential
surface of the catalyst body enlarge the surface of the
catalyst body, so that, with the quantity of active
mass being the same, a larger contact surface between
the catalyst and the gaseous reaction partners is also
provided, as compared with a straightforward
cylindrical shape. As a result, with the catalyst

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quantity being constant, a higher throughput of the
reaction partners through the reactor can be brought
about, and, as a result, also an increase in the output
per unit time. The grooves are in their cross section
in the form of a segment of a circle. What is
considered in this context to be a cross section is a
section perpendicular to the longitudinal axis of the
catalyst body. Owing to the arcuate configuration of
the grooves, stress notches are avoided, which may lead
to a fracture of the catalyst body. Webs, the cross
section of which is in the form of a segment of a
circle, run between the grooves. Owing to the arcuate
configuration of the cross section of the web surface,
edges are avoided, which, for example, may break when
the catalyst bodies are being introduced into the
reactor. In the catalyst body according to the
invention, the selected radius of the segment of a
circle of the webs is different from the radius of the
segment of a circle of the grooves. The catalyst bodies
therefore cannot come together in such a way that a web
of one catalyst body comes to bear in the groove of
another catalyst body, in which case the corresponding
surfaces of web and groove bear one against the other
in a planar manner and cause a reduction in the
available catalyst surface. If the radius of the cross
section of the webs is smaller than the radius of the
grooves, the webs may admittedly come to bear in the
grooves, but the surfaces of groove and web do not lie,
planar, one on the other. In the preferred embodiment,
the radius of the segment of a circle of the webs is
larger than the radius of the segment of a circle of
the grooves. Thus, the webs cannot penetrate into the
grooves and come to bear there. The selected radius of
the segments of a circle of the grooves is preferably
between 1 and 5 mm, in particular preferably between 2
and 3 mm. The radius of the segments of a circle of the
webs is preferably between 2 and 5 mm, in particular
preferably between 3 and 4 mm.

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Preferably, the catalyst body has a central duct which
extends along the longitudinal axis of the catalyst
body. Thus, the surface of the catalyst body can be
further enlarged and the density or weight of the
catalyst body further lowered, without any appreciable
loss of stability of the catalyst body having to be
accepted.
The central duct preferably has a circular cross
section.
According to a preferred embodiment, the catalyst body
has secondary ducts which run parallel to the
longitudinal axis, but eccentrically with respect to
this. By means of the secondary ducts, a further
enlargement of the surface of the catalyst body is
achieved, and the quantity of active material required
for producing the catalyst body is further reduced.
The secondary ducts preferably have a circular cross
section.
The selected number of secondary ducts is preferably
greater than 7, in particular preferably greater than
8, and is particularly preferably equal to 9. The
selected number of secondary ducts is preferably as
high as possible, so that the surface of the catalyst
body can be configured as large as possible and in
order to keep as low as possible the pressure drop
caused by the catalyst body. On the other hand, a
compromise must be found in terms of the stability of
the catalyst body. The webs between the secondary ducts
or between the central duct and the secondary ducts
must still be sufficiently wide to ensure that the load
caused by the heap on the individual catalyst support
can still be absorbed.
The longitudinal axes of the secondary ducts are
preferably arranged on a circle or a surface of

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cylinder, the centre point or axis of which is formed
by the longitudinal axis of the catalyst body. The
catalyst support thereby acquires an essentially
rotationally symmetrical configuration, with the result
that a higher degree of freedom in the arrangement of
the catalyst body in the packing of the reactor is
achieved, that is to say the homogeneity of the packing
of the catalyst body is increased, thereby achieving a
uniform gas flow through the reactor packing. The
diameter of the circle on which the centre points or
longitudinal axes of the secondary ducts are arranged
is preferably between 10 and 20 mm, preferably between
12 and 16 mm.
The centre point of the segment of a circle of the webs
is preferably arranged on the longitudinal axis of the
corresponding secondary duct. As a result, the web,
which delimits the secondary ducts relative to the
outside of the catalyst body, acquires a uniform
thickness, and the forces acting on the outside of the
catalyst body can be introduced, due to the arcuate
shape of the web, into the catalyst body, with the
result that the stability of the latter is increased.
The arcuate shape of the web can be seen in a view of
the end face of the catalyst body.
The secondary ducts arranged in the catalyst body
preferably have a smaller diameter than the central
duct. The selected diameter of the central duct may be
relatively large, in order thereby to enlarge the
surface of the catalyst body and to reduce the pressure
drop caused by the individual catalyst body. The
diameter of the central duct is in this case selected
such that the webs arranged between the central duct
and secondary ducts have a sufficient thickness to
ensure the required stability of the catalyst body.
The selected diameter of the central duct is preferably
between 4 and 8 mm. The selected diameter of the

secondary ducts is preferably between 1.5 and 3 mm. The
selected thickness of the webs, which delimit the
secondary ducts relative to the outside of the catalyst
body or are arranged between the secondary ducts or
between the secondary ducts and the central duct, is
preferably greater than 1 mm, preferably greater than
1.5 mm, and particularly preferably between 1.6 and
4 mm.
In order to achieve as uniform a heaping of the
catalyst bodies as possible in the reactor, the
catalyst body according to the invention is preferably
configured such that its extent in the direction of the
longitudinal axis corresponds approximately to the
diameter of the catalyst body perpendicularly to the
longitudinal axis. Preferably, the selected ratio of
the diameter of the catalyst body to its longitudinal
extent is between 0.9 and 1.5. The selected diameter of
the catalyst body is preferably between 15 mm and
30 mm, preferably between 18 and 25 mm, and is
particularly preferably about 21 mm. The extent of the
catalyst body in the direction of the longitudinal axis
is preferably between 15 mm and 30 mm, preferably
between 18 mm and 25 mm, and is particularly preferably
about 16 mm.
In order to achieve as long a useful life as possible
for the heaping of the catalyst bodies, the catalyst
bodies must have sufficiently high strength. This may
be achieved, on the one hand, by the geometric
construction of the catalyst body and, on the other
hand, by the strength of the material from which the
catalyst body is produced. Preferably, the catalyst
body has a lateral pressure resistance of more then
700 N. The lateral pressure resistance can be measured
by determining the force which is at least required in
order to bring about a bursting of the catalyst body
when the latter is tension-mounted between two planar

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jaws, the planar surfaces of the jaws being arranged
parallel to the longitudinal axis of the catalyst body.
The catalyst body is particularly suitable for use in
the steam reforming of hydrocarbons. In a version as a
catalyst for the steam reforming of hydrocarbons, the
catalyst body is preferably constructed essentially
from, in each case calculated as a metal oxide:
- NiO 10 - 20% by weight
- CaO 10 - 20% by weight
- A12O3 up to 100% by weight.
The catalyst body may contain slight guantities of
impurities. The fraction of Na and of SiO2 in the
catalyst body is preferably less than 0.05% by weight.
The catalyst body according to the invention can be
produced by means of conventional methods, for example
by extrusion. The constituents of the catalyst body are
in this case ground into a fine powder which preferably
has an average grain size D50 of 5 to 300 urn, if
appropriate mixed with a lubricant, such as graphite or
a long-chain fatty acid, and then, if appropriate after
being mixed with water, converted into the desired
form.
A further subject of the invention is the use of the
above-described catalyst body for the steam reforming
of hydrocarbons.
The invention is explained in more detail further
below, with reference to an accompanying figure in
which:
Fig.l shows a cross section through an embodiment of
the catalyst body according to the invention.

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Fig. 1 shows a cross section through the catalyst body
1 according to the invention perpendicularly to the
longitudinal axis 2 of the catalyst body 1 or to the
end face of the catalyst body according to the
invention. The outer circumferential surface 3 of the
catalyst body 1 is composed of a sequence of grooves 4
and webs 5. The grooves 4 and webs 5 form in each case
segments of a circle in a view of the cross section,
the selected radius 6 of the segments of a circle of
the grooves 4 being smaller than the radius 7 of the
segments of a circle of the webs 5. In the case of
catalyst bodies arranged next to one another,
therefore, the webs 5 of the one catalyst body 1 cannot
bear in a planar manner against the surface of the
grooves 4 of the other catalyst body. Along the
longitudinal axis 2 of the catalyst body 1 runs a
central duct 8. Nine secondary ducts 10 are arranged at
regular intervals around the central duct 8 on a
circle 9, the centre point of which coincides with the
longitudinal axis 2 of the catalyst body 1, and run
parallel to the central duct 8. The diameter 11 of the
secondary ducts 10 is smaller than the diameter 12 of
the central duct 8. The longitudinal axis 13 of the
secondary ducts 10 in this case coincides with the
longitudinal axis or the centre point of the segments
of a circle of the assigned webs 5, so that the
secondary ducts are delimited relative to the outside
of the catalyst body 1 by an arcuate web 14 which has
an essentially constant thickness. The thickness of the
webs 15 arranged between two secondary ducts 10 in this
case corresponds approximately to the thickness of the
arcuate webs 14. In the embodiment shown, the selected
thickness of the webs 16 which are arranged between the
central duct 8 and secondary ducts 10 is greater than
the thickness of the webs 15 which are arranged between
two secondary ducts 10. The diameter 17 of the catalyst
body 1 corresponds approximately to the longitudinal
extent of the catalyst body in the direction of the
longitudinal axis 2.

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Patent Claims
1. Cylindrical catalyst body, which on its
circumferential surface (3) has grooves (4) running
parallel to the longitudinal axis (2) of the catalyst
body (1) and webs (5) running between the grooves (4),
characterized in that the grooves (4) and the webs (5)
running between the grooves (4) are in their cross
section in the form of a segment of a circle, the
selected radius (7) of the segment of a circle of the
webs (5) being larger than the radius (6) of the
segment of a circle of the grooves (4), and, further,
the catalyst body (1) having a central duct (8) which
extends along the longitudninal axis (2) of the
catalyst body (1), and the catalyst body (1) having
secondary ducts (10) which run parallel to the
longitudinal axis (2) of the catalyst body (1), but
eccentrically with respect to this, the longitudinal
axes (13) of the secondary ducts (10) being arranged on
a circle (9), the centre point of which is formed by
the longitudinal axis (2) of the catalyst body (1), and
the centre point of the segment of a circle of the
webs (5) being arranged on the longitudinal axis (13)
of the secondary duct (10).
2. Catalyst body according to Claim 1, characterized
in that the central duct (8) has a circular cross
section.
3. Catalyst body according to Claim 1 or 2,
characterized in that the secondary ducts (10) have a
circular cross section.
4. Catalyst body according to one of Claims 1 to 3,
characterized in that the number of secondary


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ducts (10) is greater than 7, preferably greater
than 8, in particular preferably equal to 9.
5. Catalyst body according to one of Claims 1 to 4,
characterized in that the secondary ducts (10) have a
smaller diameter than the central duct (8) .
6. Catalyst body according to one of Claims 1 to 5,
characterized in that the selected diameter of the
central duct (8) is between 4 and 8 mm.
7. Catalyst body according to one of Claims 1 to 6,
characterized in that the selected diameter of the
secondary ducts (10) is between 1.5 and 3 mm.
8. Catalyst body according to one of the preceding
claims, characterized in that the selected ratio of the
diameter (17) of the catalyst body to its longitudinal
extent is between 0.9 and 1.5.
9. Catalyst body according to one of the preceding
claims, characterized in that the catalyst body (1) has
a lateral pressure resistance of more than 700 N.
10. Catalyst body according to one of the preceding
claims, characterized in that the catalyst body (1) is
essentially constructed from, in each case calculated
as a metal oxide:

- NiO 10 - 20% by weight
- CaO 10 - 20% by weight
- A12O3 up to 100% by weight
11. Catalyst body according to one of the preceding
claims, characterized in that the fraction of Na and of
SiO2 in the catalyst body (1) is less than 0.05% by
weight.
AMENDED PAGE

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12. Use of the catalyst body according to Claim 10
or 11 for the steam reforming of hydrocarbons.

The invention relates to a cylindrical catalyst body 1 which is characterized in that indentations are provided on the circumferential surface 3 of the catalyst body 1. These indentations are preferably configured as grooves 4 and webs 5 which run parallel
to the longitudinal axis 2 of the catalyst body 1.


Documents:


Patent Number 258832
Indian Patent Application Number 3867/KOLNP/2007
PG Journal Number 07/2014
Publication Date 14-Feb-2014
Grant Date 10-Feb-2014
Date of Filing 10-Oct-2007
Name of Patentee SUD-CHEMIE IP GMBH & CO. KG.
Applicant Address LENBACHPLATZ 6, D-80333 MUNCHEN
Inventors:
# Inventor's Name Inventor's Address
1 SELIG GERHARD BERGWEG 15, D-83104, TUNTENHAUSEN
2 RINGER NORBERT TRABERHOFTSTR 3, D-83026, ROSENHEIM
3 MULLER HANS-JOACHIM AM HOCHWALD 19, D-82319 STARNBERG
PCT International Classification Number B01J 35/02,C01B 3/40
PCT International Application Number PCT/EP2006/003939
PCT International Filing date 2006-04-27
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 102005019596.2 2005-04-27 Germany