Title of Invention	A PROCESS FOR VAPOR PHASE NITRATION OF BENZENE USING NITRIC ACID OVER MOLYBDENUM SILICA CATALYST
Abstract	The present invention relates to a process for the vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst to obtain mono -nitrobenzene. Nitration of benzene is an important reaction for the production of nitro benzene, which is an important intermediate in chemical and pharmaceutical industries. Conventionally nitrobenzene is produced by liquid phase reactions employing mixed acids. A sulfuric acid/nitric acid mixture is the most commonly used nitrating agent. Generation of large amount dilute sulfuric acid, organic wastes and products of their neutralization makes the benzene nitration a environmentally harmful process. This process is a clean and environment friendly process without use of sulphuric acid.

Title of Invention

A PROCESS FOR VAPOR PHASE NITRATION OF BENZENE USING NITRIC ACID OVER MOLYBDENUM SILICA CATALYST

Abstract

The present invention relates to a process for the vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst to obtain mono -nitrobenzene. Nitration of benzene is an important reaction for the production of nitro benzene, which is an important intermediate in chemical and pharmaceutical industries. Conventionally nitrobenzene is produced by liquid phase reactions employing mixed acids. A sulfuric acid/nitric acid mixture is the most commonly used nitrating agent. Generation of large amount dilute sulfuric acid, organic wastes and products of their neutralization makes the benzene nitration a environmentally harmful process. This process is a clean and environment friendly process without use of sulphuric acid.

Full Text	The present invention relates to a process for vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst. The invention particularly relates to a process for the preparation of mono-nitrobenzene wherein the nitration of benzene is carried out in vapor phase using molybdenum silica catalyst and nitric acid. By the process of present invention nitrobenzene has been prepared in high yield in a continuous process without any waste byproduct formation making it an environment friendly process. Major part of nitrobenzene (95% or more) produced is converted to aniline, which has hundreds of downstream products. Nitrobenzene also is used as a processing solvent in specific chemical reactions. Conventionally nitrobenzene is produced by liquid phase reactions employing mixed acids. A suiruric acid/nitric acid mixture is the most commonly used nitrating agent. Generation of large amount dilute sulfuric acid, organic wastes and products of their neutralization makes the benzene nitration one of the most environmentally harmful processes. Vapor-phase nitration of benzene to nitrobenzene over zeolite is expected to be a clean process without sulfuric acid waste. A number of heterogeneous catalysts have been proposed for this process. In the prior art, vapor phase nitration of aromatic compounds, benzene and toluene at temperature ranging from about 275° C to about 310° C is described in McKee and Wilhelm, Industrial and Engineering Chemistry, 28(6), 662-667 (1936) and U.S. Pat. No. 2,109,873. McKee and Wilhelm catalyzed their reaction with silica gel. Bauxite and alumina were reported to be ineffective as catalyst in the vapor phase nitration of benzene. US. Patent No. 2,431.585 describes vapor phase nitration of aromatic hydrocarbons at temperature from 130°C to 430°C, using metal phosphates of calcium, iron, magnesium and solid supported phosphoric acid catalysts. U.S. patent 4551568 describes the vapor phase nitration of benzene over solid mixed oxide catalyst comprising WCh and MOa, which exhibited a fairly high and stable activity. U.S. Pat. No. 3,966,830, Jpn. Pat. No. 58-157748, and U.S. Pat. No. 4, 426, 543 describe the nitration of aromatics using zeolite catalysts. The lower conversion of benzene to nitrobenzene and faster deactivation of zeolite catalysts are the drawbacks of these processes for commercial application. US patent 5030776 describes a process for nitrating benzene using nitric acid as a nitrating agent under continuous or intermittent feeding of sulfuric acid as a catalyst on a solid carrier. Vapor phase nitration of benzene has been claimed in US patent 5.004,846 wherein nitric acid is used as a nitrating agent and a composite oxide or acidic sheet clay mineral ion exchanged with polyvalent metal as a catalyst. International patent WO 96/36587 describes a solvent free process for the nitration of aromatic compounds in which the aromatic compound is reacted with nitric acid in presence of an acid anhydride wherein the process is catalyzed by an aluminosilicate catalyst. Nitric acid and acid anhydride react with each other in-situ to form acyl nitrate and this acts as a nitrating agent for aromatic compounds. For example benzene, naphthalene, anthracene, toluene etc. are nitrated to mononitrated compounds. A mixture of orth-meta-para nitrotoluenes is obtained which is then distilled at a pressure of 30 mmHg and a temperature of 30UC to remove acetic acid as a byproduct. These prior art processes for the vapor phase nitration of benzene for the preparation of nitrobenzene have the limitations of low conversions low space-time yield, low yield, short catalyst life, contamination of the products by undesirable by-products and the complicated nature of catalysts. These prior art processes use concentrated nitric acid as nitrating agent, which leads to the oxidation products deactivating the catalyst. The novelty of the present invention lies in the use of xMo03: (1-x) SiO2 catalyst with or without promotor for vapour phase nitration of benzene in high yield and selectivity for nitro benzene. The main objective of the present invention is to provide a process for vapor phase nitration of benzene using nitric acid and over molybdenum silica catalyst. Another object of the present invention is use of ethyl silicate-40 as silica source for the preparation of high surface area MoCVSiCh catalyst. Yet another object of the present invention is the use of xMoO3: (1-x) SiO2 catalyst, where x = 0.05-0.2, preferably x = 0.2 for vapor phase nitration of benzene using nitric acid and over molybdenum silica catalyst. Accordingly the present invention provides a process for vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst comprising reacting benzene with nitric acid along with an inert gas a conventional downflow reactor containing inert ceramic packing as preheater and granulated molybdenum silica catalyst of composition Mo03: (1-x) SiO2, wherein x = 0.05-0.2 with or without 0.5-2%) of a transition metal oxide as a promotor, at a temperature in the range of 100-250°C, at a reactant weight hourly space velocity (WHSV) in the range of 0.15 to 0.5, condensing the resultant product followed by washing with known alkali to obtain mono-nitrobenzene. In an embodiment of the invention, the catalyst used is in the form of a pellet. In another embodiment of the invention, the mesh size of granulated molybdenum silica catalyst used is in the range of -10 to +20 mesh size. In another embodiment of the invention, the catalyst used is M0O3: (1-x) SiO2 where x is 0.2. In another embodiment of the invention, the MoCVSiO2 catalyst used is in amorphous or crystalline form. In another embodiment of the invention, the molybdenum silica catalyst is in amorphous form. In another embodiment of the invention, the molybdenum silica catalyst is used along with a promoter comprising 1-2% transition metal oxides selected from the group consisting of Fe2O3, CuO, NiO and Co3O4. In another embodiment of the invention, the promoter is Fe2O3 In another embodiment of the invention, the nitric acid used is 10 to 70% nitric acid. In another embodiment of the invention, the molar ratio of nitric acid to benzene is in the range of 4:1 tol: 4,preferably 1:2. In another embodiment of the invention, the nitration is carried out in a conventional downflow reactor containing inert ceramic packing as preheater. In another embodiment of the invention, the molybdenum silica catalyst used is M0O3: (1-x) SiO2, wherein x is preferably 0.2. In another embodiment of the invention, the nitration is carried out at a temperature preferably in the range of 120-200°C and at a reactant weight hourly space velocity (WHSV) in the range of 0.1 to 1.0. The present invention is described in further detail with reference to the examples, which are given by way of illustration only and therefore should not be construed to restrict the scope of the invention. EXAMPLE 1 MoCVSiCh catalyst used in the present invention was prepared using ammonium molybdate (AR. Grade Loba make) as molybdenum source and ethyl silicate-40 (CAS registry no. 18594- 71-7, supplied by Chemplast) as silica source. 35.28 g of ammonium molybdate [(NKO e Mo? 624 4H2O] was dissolved in 150 ml hot distilled water and added drop wise to the solution of 120 g ethyl silicate-40 in 50 ml isopropyl alcohol with constant stirring. The resulting greenish gel was air dried, ground and calcined at 500 °C in air in a muffle furnace. The catalyst was characterized using XRD, surface area using BET, chemical analysis by AAS and XRF. XRD showed amorphous nature of the catalyst and BET showed the surface area of 372 m2/g. The molar composition of the catalyst was 0.2 MoOs: 0.8 SiO2. Molar composition of the xMoCb: (1-x) SiO2 catalyst was varied where x = 0.05-0.2. The catalyst was molded in the form of a pellet, which is granulated to -10 to +20 mesh size for its use in nitration reaction. EXAMPLE 2 Fe2O3/MoO3/SiO2 catalyst used in the present invention was prepared using ammonium molybdate (AR. Grade Loba make) as molybdenum source, ferric nitrate (SD fine) as iron source and ethyl silicate-40 (CAS registry no. 18594-71-7, supplied by Chemplast) as silica source. 5.65 g. of ferric nitrate was dissolved in 100 ml of isopropyl alcohol which was added to a solution 118.9 g of ethylsilicate-40 in 100 ml of isopropyl alcohol under constant stirring. 35.28 g of ammonium molybdate [(NtLOeMoTCh^PkO] was dissolved in 150 ml hot distilled water and was added drop wise to the above solution with constant stirring. The resulting reddish gel was air dried, ground and calcined at 500 °C in air in a muffle furnace. The catalyst was characterized using XRD, surface area using BET, chemical analysis by AAS and XRF. The molar composition of the catalyst was 0.007 F2O3 : 0.2 Mo03: 0.793 Si02. The catalyst was molded in the form of a pellet, which is granulated to -10 to +20 mesh size for its use in nitration reaction. Similarly CuO, NiO, Co3C«4 containing MoCVSiCh catalysts were prepared by using respective metal nitrates and the molar composition was maintained xMO/ 0.2MoO3/0.793SiO2 where x was 0.05 to 0.2 moles of respective metal oxides. ExampIe-3 10 g of catalyst prepared by the procedure given in the Example 1 was loaded in a tubular glass reactor of 15 mm diameter and 25 mm length. The upper part of the reactor was packed with inert ceramic beads as preheating zone. Benzene and nitric acid (70%) were fed to the reactor using syringe pumps. Reaction conditions were as follows. Reaction temperature = 120 °C Carrier gas = N2 Benzene/HNCh = 1.4: 1 (molar ratio) WHSV (benzene) = 0.17 The product was condensed at 9 °C and collected in a receiver. The product was analyzed by gas chromatography. Results after 25 hours from beginning of reaction are shown below. Conversion of benzene =68.0% Yield for nitrobenzene = 68.0% Selectivity of nitrobenzene = 100% There was negligible deactivation in catalyst activity and selectivity during this period. EXAMPLE 4 Example 3 was repeated except increasing the Weight Hourly Space Velocity (WHSV) to 0.34. Reaction conditions were as follows. Reaction temperature = 120 °C Carrier gas = NZ Benzene/HMOs = 1.4:1 (molar ratio) WHSV = 0.34 Results after 81 hours from beginning of reaction are shown below. Conversion of benzene = 63.4 % Yield for nitrobenzene = 62.77% Selectivity of nitrobenzene = 99.8% There was no deactivation in the activity and selectivity of the catalyst during this period. EXAMPLE 5 Example 3 was repeated except that benzene/HNOa ratio was changed. The reaction conditions were as follows. Reaction Temperature = 120 ° C Carrier gas = N2 Benzene/HNCb = 1.6:1 (molar ratio) WHSV =0.17 Results after 25 hours from beginning of reaction are shown below. Conversion of benzene =56.2% Yield for nitrobenzene = 55.75% Selectivity of nitrobenzene = 99.2% There was no deactivation in the catalyst activity and selectivity during this period. EXAMPLE 6 The catalyst prepared as per Example-1, further calcined at 600 °C and was characterized by XRD and BET surface area measurements. The XRD showed the presence of crystalline form MoC3 and amorphous form of silica. The surface area of the catalyst was 215 m2/g. The catalyst was molded in the form of a pellet, which is granulated to -10 to +20 mesh size for its use in nitration. The nitration reaction was carried out as mentioned in the Example 2. The reaction conditions were as follows. Reaction temperature = 120 °C Carrier gas = Na Benzene/HNCh =1.4:1 (molar ratio) WHSV =0.17 Results after 25 hours from beginning of reaction are shown below. Conversion of benzene = 48.56% Yield for nitrobenzene = 47.8% Selectivity of nitrobenzene =98.5% There was no deactivation in the activity and selectivity of the catalyst during this period. EXAMPLE 7 Example 3 was repeated except that temperature of the reaction was changed. The reaction conditions were as follows. Reaction Temperature = 180 ° C Carrier gas = N2 Benzene/HNOs = 1.4:1 (molar ratio) WHSV =0.17 Results after 25 hours from beginning of reaction are shown below. Con version of benzene =50.2% Yield for nitrobenzene = 49.7% Selectivity of nitrobenzene = 99.0% No deactivation of the catalyst was seen during this period. EXAMPLE 8 Example 3 was repeated except that the catalyst with 0.7mol% Fe2O3 prepared as per example 2. The reaction conditions were as follows. Reaction Temperature = 120 ° C Carrier gas = Na Benzene/HNO} = 1.4:1 (molar ratio) WHSV =0.17 Results after 25 hours from beginning of reaction are shown below. Conversion of benzene = 75% Yield for nitrobenzene = 75% Selectivity of nitrobenzene = 100% No deactivation of the catalyst was seen during this period. Advantages: This process has the following advantages over prior art processes : a) No use of sulphuric acid b) Solid acid catalyst easy for separation and use c) Negligible deactivation of catalyst, long life of catalyst d) A good conversion (more than 80%) and 100% selectivity for nitrobenzene. e) Ease of operation and scale up. We Claim: 1. A process for the vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst comprising reacting benzene with nitric acid along with an inert gas a conventional downflow reactor containing inert ceramic packing as preheater and granulated molybdenum silica catalyst of composition MoO3: (1-x) SiO2, wherein x = 0.05-0.2 with or without 0.5-2% of a transition metal oxide as a promotor, at a temperature in the range of 100-250°C, at a reactant weight hourly space velocity (WHSV) in the range of 0.15 to 0.5, condensing the resultant product followed by washing with known alkali to obtain mono-nitrobenzene. 2. A process as claimed in claim 1 ,wherein the catalyst used is in the form of a pellet. 3. A process as claimed in claims 1-2, wherein the mesh size of granulated molybdenum silica catalyst used is in the range of-10 to +20 mesh size. 4. A process as claimed in claims 1-3, wherein the catalyst used is Mo03: (1-x) SiO2 where x is preferably 0.2. 5. A process as claimed in claims 1-4, wherein the MoO3/SiO2 catalyst used is in amorphous or crystalline form, preferably in amorphous form. 6. A process as claimed in claim 1-5 wherein the promotor used with Mo03/Si02 catalyst is 1-2% transition metal oxides selected from the group consisting of Fe203j CuO, NiO and Co3O4,preferably Fe2O3 7. A process as claimed in claims 1-6, wherein the nitric acid used is 10 to 70% nitric acid. 8. A process as claimed in claim 1-7, wherein the molar ratio of nitric acid to benzene used is 4:1 tol: 4, preferably 1:2. 9. A process as claimed in claim 1-8, wherein the nitration is carried out at a temperature in the range of 120-200 °C. 10. A process as claimed in claim 1-9, wherein the inert gas used is selected from the group consisting of nitrogen, helium and argon. 11. A process as claimed in claim 1-10, wherein the reactant weight hourly space velocity used is in the range of 0.1 to 1. 12. A process for the vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst substantially as herein described with reference to the examples accompanying this specification.

Full Text

The present invention relates to a process for vapor phase nitration of benzene using
nitric acid over molybdenum silica catalyst.
The invention particularly relates to a process for the preparation of mono-nitrobenzene
wherein the nitration of benzene is carried out in vapor phase using molybdenum silica catalyst
and nitric acid. By the process of present invention nitrobenzene has been prepared in high yield
in a continuous process without any waste byproduct formation making it an environment
friendly process.
Major part of nitrobenzene (95% or more) produced is converted to aniline, which has
hundreds of downstream products. Nitrobenzene also is used as a processing solvent in specific
chemical reactions. Conventionally nitrobenzene is produced by liquid phase reactions
employing mixed acids. A suiruric acid/nitric acid mixture is the most commonly used nitrating
agent. Generation of large amount dilute sulfuric acid, organic wastes and products of their
neutralization makes the benzene nitration one of the most environmentally harmful processes.
Vapor-phase nitration of benzene to nitrobenzene over zeolite is expected to be a clean
process without sulfuric acid waste. A number of heterogeneous catalysts have been proposed
for this process.
In the prior art, vapor phase nitration of aromatic compounds, benzene and toluene at
temperature ranging from about 275° C to about 310° C is described in McKee and Wilhelm,
Industrial and Engineering Chemistry, 28(6), 662-667 (1936) and U.S. Pat. No. 2,109,873.
McKee and Wilhelm catalyzed their reaction with silica gel. Bauxite and alumina were reported
to be ineffective as catalyst in the vapor phase nitration of benzene.
US. Patent No. 2,431.585 describes vapor phase nitration of aromatic hydrocarbons at
temperature from 130°C to 430°C, using metal phosphates of calcium, iron, magnesium and solid
supported phosphoric acid catalysts.
U.S. patent 4551568 describes the vapor phase nitration of benzene over solid mixed
oxide catalyst comprising WCh and MOa, which exhibited a fairly high and stable activity.
U.S. Pat. No. 3,966,830, Jpn. Pat. No. 58-157748, and U.S. Pat. No. 4, 426, 543
describe the nitration of aromatics using zeolite catalysts. The lower conversion of benzene to
nitrobenzene and faster deactivation of zeolite catalysts are the drawbacks of these processes for
commercial application.
US patent 5030776 describes a process for nitrating benzene using nitric acid as a
nitrating agent under continuous or intermittent feeding of sulfuric acid as a catalyst on a solid
carrier. Vapor phase nitration of benzene has been claimed in US patent 5.004,846 wherein nitric
acid is used as a nitrating agent and a composite oxide or acidic sheet clay mineral ion
exchanged with polyvalent metal as a catalyst.
International patent WO 96/36587 describes a solvent free process for the nitration of
aromatic compounds in which the aromatic compound is reacted with nitric acid in presence of
an acid anhydride wherein the process is catalyzed by an aluminosilicate catalyst. Nitric acid and
acid anhydride react with each other in-situ to form acyl nitrate and this acts as a nitrating agent
for aromatic compounds. For example benzene, naphthalene, anthracene, toluene etc. are nitrated
to mononitrated compounds. A mixture of orth-meta-para nitrotoluenes is obtained which is then
distilled at a pressure of 30 mmHg and a temperature of 30UC to remove acetic acid as a
byproduct.
These prior art processes for the vapor phase nitration of benzene for the preparation of
nitrobenzene have the limitations of low conversions low space-time yield, low yield, short
catalyst life, contamination of the products by undesirable by-products and the complicated
nature of catalysts. These prior art processes use concentrated nitric acid as nitrating agent,
which leads to the oxidation products deactivating the catalyst.
The novelty of the present invention lies in the use of xMo03: (1-x) SiO2 catalyst with or
without promotor for vapour phase nitration of benzene in high yield and selectivity for nitro
benzene.
The main objective of the present invention is to provide a process for vapor phase
nitration of benzene using nitric acid and over molybdenum silica catalyst.
Another object of the present invention is use of ethyl silicate-40 as silica source for the
preparation of high surface area MoCVSiCh catalyst.
Yet another object of the present invention is the use of xMoO3: (1-x) SiO2 catalyst,
where x = 0.05-0.2, preferably x = 0.2 for vapor phase nitration of benzene using nitric acid and
over molybdenum silica catalyst.
Accordingly the present invention provides a process for vapor phase nitration of benzene using
nitric acid over molybdenum silica catalyst comprising reacting benzene with nitric acid along with an inert gas a conventional downflow reactor containing inert ceramic packing as preheater and granulated molybdenum silica catalyst of composition Mo03: (1-x) SiO2, wherein x = 0.05-0.2 with or without 0.5-2%) of a transition metal oxide as a promotor, at a temperature in the range of 100-250°C, at a reactant weight hourly space velocity (WHSV) in the range of 0.15 to 0.5, condensing the resultant product followed by washing with known alkali to obtain mono-nitrobenzene.
In an embodiment of the invention, the catalyst used is in the form of a pellet.
In another embodiment of the invention, the mesh size of granulated molybdenum silica catalyst used is in the range of -10 to +20 mesh size.
In another embodiment of the invention, the catalyst used is M0O3: (1-x) SiO2 where x is 0.2.
In another embodiment of the invention, the MoCVSiO2 catalyst used is in amorphous or crystalline form.
In another embodiment of the invention, the molybdenum silica catalyst is in amorphous form.
In another embodiment of the invention, the molybdenum silica catalyst is used along with a promoter comprising 1-2% transition metal oxides selected from the group consisting of Fe2O3, CuO, NiO and Co3O4.
In another embodiment of the invention, the promoter is Fe2O3
In another embodiment of the invention, the nitric acid used is 10 to 70% nitric acid.
In another embodiment of the invention, the molar ratio of nitric acid to benzene is in the range of 4:1 tol: 4,preferably 1:2.
In another embodiment of the invention, the nitration is carried out in a conventional downflow reactor containing inert ceramic packing as preheater.
In another embodiment of the invention, the molybdenum silica catalyst used is M0O3: (1-x) SiO2, wherein x is preferably 0.2.
In another embodiment of the invention, the nitration is carried out at a temperature preferably in the range of 120-200°C and at a reactant weight hourly space velocity (WHSV) in the range of 0.1 to 1.0.

The present invention is described in further detail with reference to the examples, which are
given by way of illustration only and therefore should not be construed to restrict the scope of
the invention.
EXAMPLE 1
MoCVSiCh catalyst used in the present invention was prepared using ammonium molybdate
(AR. Grade Loba make) as molybdenum source and ethyl silicate-40 (CAS registry no. 18594-
71-7, supplied by Chemplast) as silica source.
35.28 g of ammonium molybdate [(NKO e Mo? 624 4H2O] was dissolved in 150 ml hot distilled
water and added drop wise to the solution of 120 g ethyl silicate-40 in 50 ml isopropyl alcohol
with constant stirring. The resulting greenish gel was air dried, ground and calcined at 500 °C in
air in a muffle furnace. The catalyst was characterized using XRD, surface area using BET,
chemical analysis by AAS and XRF. XRD showed amorphous nature of the catalyst and BET
showed the surface area of 372 m2/g. The molar composition of the catalyst was 0.2 MoOs: 0.8
SiO2. Molar composition of the xMoCb: (1-x) SiO2 catalyst was varied where x = 0.05-0.2. The
catalyst was molded in the form of a pellet, which is granulated to -10 to +20 mesh size for its
use in nitration reaction.
EXAMPLE 2
Fe2O3/MoO3/SiO2 catalyst used in the present invention was prepared using ammonium
molybdate (AR. Grade Loba make) as molybdenum source, ferric nitrate (SD fine) as iron source
and ethyl silicate-40 (CAS registry no. 18594-71-7, supplied by Chemplast) as silica source.
5.65 g. of ferric nitrate was dissolved in 100 ml of isopropyl alcohol which was added to a
solution 118.9 g of ethylsilicate-40 in 100 ml of isopropyl alcohol under constant stirring.
35.28 g of ammonium molybdate [(NtLOeMoTCh^PkO] was dissolved in 150 ml hot distilled
water and was added drop wise to the above solution with constant stirring. The resulting reddish
gel was air dried, ground and calcined at 500 °C in air in a muffle furnace. The catalyst was
characterized using XRD, surface area using BET, chemical analysis by AAS and XRF. The
molar composition of the catalyst was 0.007 F2O3 : 0.2 Mo03: 0.793 Si02. The catalyst was
molded in the form of a pellet, which is granulated to -10 to +20 mesh size for its use in nitration
reaction.
Similarly CuO, NiO, Co3C«4 containing MoCVSiCh catalysts were prepared by using respective
metal nitrates and the molar composition was maintained xMO/ 0.2MoO3/0.793SiO2 where x
was 0.05 to 0.2 moles of respective metal oxides.
ExampIe-3
10 g of catalyst prepared by the procedure given in the Example 1 was loaded in a tubular glass
reactor of 15 mm diameter and 25 mm length. The upper part of the reactor was packed with
inert ceramic beads as preheating zone. Benzene and nitric acid (70%) were fed to the reactor
using syringe pumps. Reaction conditions were as follows.
Reaction temperature = 120 °C
Carrier gas = N2
Benzene/HNCh = 1.4: 1 (molar ratio)
WHSV (benzene) = 0.17
The product was condensed at 9 °C and collected in a receiver. The product was analyzed
by gas chromatography. Results after 25 hours from beginning of reaction are shown below.
Conversion of benzene =68.0%
Yield for nitrobenzene = 68.0%
Selectivity of nitrobenzene = 100%
There was negligible deactivation in catalyst activity and selectivity during this period.
EXAMPLE 4
Example 3 was repeated except increasing the Weight Hourly Space Velocity (WHSV) to 0.34.
Reaction conditions were as follows.
Reaction temperature = 120 °C
Carrier gas = NZ
Benzene/HMOs = 1.4:1 (molar ratio)
WHSV = 0.34
Results after 81 hours from beginning of reaction are shown below.
Conversion of benzene = 63.4 %
Yield for nitrobenzene = 62.77%
Selectivity of nitrobenzene = 99.8%
There was no deactivation in the activity and selectivity of the catalyst during this period.
EXAMPLE 5
Example 3 was repeated except that benzene/HNOa ratio was changed. The reaction conditions
were as follows.
Reaction Temperature = 120 ° C
Carrier gas = N2
Benzene/HNCb = 1.6:1 (molar ratio)
WHSV =0.17
Results after 25 hours from beginning of reaction are shown below.
Conversion of benzene =56.2%
Yield for nitrobenzene = 55.75%
Selectivity of nitrobenzene = 99.2%
There was no deactivation in the catalyst activity and selectivity during this period.
EXAMPLE 6
The catalyst prepared as per Example-1, further calcined at 600 °C and was characterized by
XRD and BET surface area measurements. The XRD showed the presence of crystalline form
MoC3 and amorphous form of silica. The surface area of the catalyst was 215 m2/g. The catalyst
was molded in the form of a pellet, which is granulated to -10 to +20 mesh size for its use in
nitration. The nitration reaction was carried out as mentioned in the Example 2. The reaction
conditions were as follows.
Reaction temperature = 120 °C
Carrier gas = Na
Benzene/HNCh =1.4:1 (molar ratio)
WHSV =0.17
Results after 25 hours from beginning of reaction are shown below.
Conversion of benzene = 48.56%
Yield for nitrobenzene = 47.8%
Selectivity of nitrobenzene =98.5%
There was no deactivation in the activity and selectivity of the catalyst during this period.
EXAMPLE 7
Example 3 was repeated except that temperature of the reaction was changed. The reaction
conditions were as follows.
Reaction Temperature = 180 ° C
Carrier gas = N2
Benzene/HNOs = 1.4:1 (molar ratio)
WHSV =0.17
Results after 25 hours from beginning of reaction are shown below.
Con version of benzene =50.2%
Yield for nitrobenzene = 49.7%
Selectivity of nitrobenzene = 99.0%
No deactivation of the catalyst was seen during this period.
EXAMPLE 8
Example 3 was repeated except that the catalyst with 0.7mol% Fe2O3 prepared as per example 2.
The reaction conditions were as follows.
Reaction Temperature = 120 ° C
Carrier gas = Na
Benzene/HNO} = 1.4:1 (molar ratio)
WHSV =0.17
Results after 25 hours from beginning of reaction are shown below.
Conversion of benzene = 75%
Yield for nitrobenzene = 75%
Selectivity of nitrobenzene = 100%
No deactivation of the catalyst was seen during this period.
Advantages: This process has the following advantages over prior art processes :
a) No use of sulphuric acid
b) Solid acid catalyst easy for separation and use
c) Negligible deactivation of catalyst, long life of catalyst
d) A good conversion (more than 80%) and 100% selectivity for nitrobenzene.
e) Ease of operation and scale up.
We Claim:
1. A process for the vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst comprising reacting benzene with nitric acid along with an inert gas a conventional downflow reactor containing inert ceramic packing as preheater and granulated molybdenum silica catalyst of composition MoO3: (1-x) SiO2, wherein x = 0.05-0.2 with or without 0.5-2% of a transition metal oxide as a promotor, at a temperature in the range of 100-250°C, at a reactant weight hourly space velocity (WHSV) in the range of 0.15 to 0.5, condensing the resultant product followed by washing with known alkali to obtain mono-nitrobenzene.
2. A process as claimed in claim 1 ,wherein the catalyst used is in the form of a pellet.
3. A process as claimed in claims 1-2, wherein the mesh size of granulated molybdenum silica catalyst used is in the range of-10 to +20 mesh size.
4. A process as claimed in claims 1-3, wherein the catalyst used is Mo03: (1-x) SiO2 where x is preferably 0.2.
5. A process as claimed in claims 1-4, wherein the MoO3/SiO2 catalyst used is in amorphous or crystalline form, preferably in amorphous form.
6. A process as claimed in claim 1-5 wherein the promotor used with Mo03/Si02 catalyst is 1-2% transition metal oxides selected from the group consisting of Fe203j CuO, NiO and Co3O4,preferably Fe2O3
7. A process as claimed in claims 1-6, wherein the nitric acid used is 10 to 70% nitric acid.
8. A process as claimed in claim 1-7, wherein the molar ratio of nitric acid to benzene used is 4:1 tol: 4, preferably 1:2.
9. A process as claimed in claim 1-8, wherein the nitration is carried out at a temperature in the range of 120-200 °C.
10. A process as claimed in claim 1-9, wherein the inert gas used is selected from the group consisting of nitrogen, helium and argon.
11. A process as claimed in claim 1-10, wherein the reactant weight hourly space velocity used is in the range of 0.1 to 1.
12. A process for the vapor phase nitration of benzene using nitric acid over molybdenum silica catalyst substantially as herein described with reference to the examples accompanying this specification.

Documents:

798-DEL-2002-Abstract-(13-04-2009).pdf

798-del-2002-abstract.pdf

798-DEL-2002-Claims-(13-04-2009).pdf

798-del-2002-claims.pdf

798-del-2002-correspondence-other.pdf

798-DEL-2002-Correspondence-Others-(13-04-2009).pdf

798-DEL-2002-Correspondence-Others-(24-03-2009).pdf

798-del-2002-correspondence-po.pdf

798-DEL-2002-Description (Complete)-(13-04-2009).pdf

798-del-2002-description (complete).pdf

798-del-2002-form-1.pdf

798-del-2002-form-18.pdf

798-del-2002-form-2.pdf

798-DEL-2002-Form-3-(13-04-2009).pdf

798-del-2002-form-3.pdf

798-DEL-2002-Petition-137-(24-03-2009).pdf

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Patent Number

234033

Indian Patent Application Number

798/DEL/2002

PG Journal Number

21/2005

Publication Date

22-May-2009

Grant Date

29-Apr-2009

Date of Filing

31-Jul-2002

Name of Patentee

COUNCIL OF SCIENTIFIC & INDUSTRIAL RESEARCH

Applicant Address

RAFI MARG, NEW DELHI-110001, INDIA.

Inventors:

#	Inventor's Name	Inventor's Address
1	MOHAN KERABA DONGARE	CATALYSIS DIVISION, NATIONAL CHEMICAL LABORATORY, PUNE 411008, MAHARASHTRA, INDIA.
2	PRATAP TUKARAM PATIL	CATALYSIS DIVISION, NATIONAL CHEMICAL LABORATORY, PUNE 411008, MAHARASHTRA, INDIA.
3	KUSUM MADHUKAR MALSHE	CATALYSIS DIVISION, NATIONAL CHEMICAL LABORATORY, PUNE 411008, MAHARASHTRA, INDIA.

PCT International Classification Number

B01J23/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA