CN1343651A - Process for hydrogenating benzoic acid - Google Patents
Process for hydrogenating benzoic acid Download PDFInfo
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- CN1343651A CN1343651A CN 00124807 CN00124807A CN1343651A CN 1343651 A CN1343651 A CN 1343651A CN 00124807 CN00124807 CN 00124807 CN 00124807 A CN00124807 A CN 00124807A CN 1343651 A CN1343651 A CN 1343651A
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Abstract
A process for hydrogenating benzoic acid features that the fused benzoic acid is in contact with hydrogen at 120-200 deg.C and 1-12 MPa under the existance of Pd/C catalyst and Ni-contained non-crystal alloy cocatalyst. Its advantages include less generation of CO, high catalytic activity, less consumption of Pd/C catalyst and high productivity.
Description
The present invention relates to a kind of benzoic method of hydrotreating, particularly a kind of benzoic acid hydrogenation method of using the Pd/C catalyzer.
As good hydrogenation catalyst, the Pd/C catalyzer is widely used in the numerous areas of industries such as petrochemical complex, pharmacy, fine chemistry industry, especially in the SNIA technology of preparation hexanolactam and the phthalic acid process for refining in the polyester industrial very big consumption is arranged in chemical fibre industry.
The toluene method of SNIA company prepares in the operational path (SNIA technology) of hexanolactam, and benzoic acid hydrogenation is the important step of preparation caprolactam technology.The SNIA technology of producing hexanolactam comprises that mainly toluene oxidation system phenylformic acid, benzoic acid hydrogenation prepare hexahydrobenzoic acid, hexahydrobenzoic acid and make processes such as hexanolactam through amidation.What wherein the benzoic acid hydrogenation process was used is precious metals pd/C catalyzer.The primary product of Pd/C catalysis benzoic acid hydrogenation reaction is hexahydrobenzoic acid (CCA), and side reaction is mainly hydrogenation of carboxylic acids and generates corresponding alcohol, and the CCA decarboxylation generates CO
2And CO.CO is adsorbed on the surface of Pd by force, causes the Pd/C poisoning of catalyst, reduces activity of such catalysts.Active production and the benefit of giving on the low side of recycling catalyst brought two direct consequences, and the one, produce load and can not improve; The 2nd, sharply increase live catalyst feed rate and palladium and reclaim frequency, thereby strengthened the possibility of precious metals pd loss.Common fresh Pd/C (5% charge capacity) catalyst activity is at Z
0=1.0-1.2 (Z
0For estimating the value of Pd/C catalyst activity, the hydrogen-absorption speed of representation unit time catalyzer) between, and the active Z of Pd/C fluctuates about 0.2 in the actual production, far below fresh Pd/C activity of such catalysts, keep catalyst activity levels, must regularly add live catalyst to hydrogenation system.So the performance of benzoic acid hydrogenation Pd/C catalyzer is the key of restriction benzoic acid hydrogenation technical development and SNIA technological development, also is the bottleneck problem in the hexanolactam manufacturing process always.
The purpose of this invention is to provide a kind of benzoic method of hydrotreating, this method can make Pd/C activity of such catalysts used in the reactive system improve a lot, and has satisfactory stability.
Benzoic method of hydrotreating provided by the present invention comprise with the fusion phenylformic acid in reactor in the presence of the Pd/C catalyzer, in temperature is 120-200 ℃, pressure is 1.0-12.0 MPa (MPa), the phenylformic acid flow be the 5-12 ton/hour, hydrogen flowing quantity be the 550-1200 kilogram/hour condition under contact with hydrogen; It is characterized in that in said reactor, also existing the amorphous alloy catalyst auxiliary agent of a kind of Ni of containing.
The amorphous alloy catalyst auxiliary agent of the said Ni of containing is for being the amorphous alloy catalyst of main active component with nickel in the benzoic acid hydrogenation method provided by the present invention, be 45 ± 1 ° at 2 θ in its X-ray diffractogram and locate to occur a diffuse maximum (steamed bun shape diffuse scattering peak), this catalyzer is basically by the Ni of 60-98 weight %, the Fe of 0-20 weight %, 0-20 weight % is selected from a kind of metal in the group of being made up of Cr, Co, Mo, Mn and W, and the aluminium of 0.5-30 weight % is formed.Nickel in this amorphous alloy catalyst preferably exists with the form of amorphous nickel, but might exist with the form of amorphous nickel and crystallite attitude nickel concurrent, and perhaps the form with amorphous nickel, crystallite attitude nickel and a small amount of crystalline state nickel concurrent exists.
The add-on of the amorphous alloy catalyst auxiliary agent of the said Ni of containing is the 0.1-10 weight % of said Pd/C catalyst weight in the benzoic acid hydrogenation method provided by the invention, preferred 1-7 weight %, more preferably 1-5 weight %.
Said amorphous alloy catalyst auxiliary agent and the Pd/C catalyst mix that contains Ni is even in the benzoic acid hydrogenation method provided by the invention; This nickeliferous auxiliary agent can add separately, perhaps also can add after the Pd/C catalyzer is pre-mixed evenly in order to increase mixed effect.Said auxiliary agent can be fixed or be suspended in the reactor with the fixed bed form, also can pass in and out reactor with continuous or intermittent mode according to the needs of operation.Said reactor generally is meant industrial used overflow stirred-tank reactor, does not use other suitable reactor but do not get rid of.
Said Pd/C catalyzer is the Pd/C catalyzer that particularly generally uses in the benzoic acid hydrogenation technology in the prior art in the benzoic acid hydrogenation method provided by the invention, and the present invention has no particular limits it.
The hydrogenation technique condition is the processing condition of the routine that benzoic acid hydrogenation adopted described in the benzoic acid hydrogenation method provided by the present invention, the present invention has no particular limits it, general condition is that temperature is 120-200 ℃, pressure is the 1.0-12.0 MPa, the phenylformic acid flow be the 5-12 ton/hour, hydrogen flowing quantity be the 550-1200 kilogram/hour.Wherein preferred processing condition are that temperature is 150-180 ℃, and pressure is 1.2-6.0MPa, the phenylformic acid flow be the 6-10 ton/hour, hydrogen flowing quantity be the 850-1000 kilogram/hour.
Used in the method provided by the invention is that the amorphous alloy catalyst of main active component can prepare by following steps with nickel:
(1). the mother alloy preparation
Will be by the nickel of 40 to 70 weight %, 30 to the aluminium less than 50 weight %, the melts of the alloy that Cr, Co, Mo or W formed of the iron of 0 to 15 weight % and 0 to 15 weight % is preferably greater than 10000 ℃/second speed of cooling fast setting with greater than 1000 ℃/second;
(2). mother alloy thermal treatment
(1) resulting mother alloy is heat-treated in the inert gas environment that is selected from hydrogen, argon gas or nitrogen, and heat treated condition is that temperature is 300-900 ℃, preferred 450-750 ℃; Heat treatment time is 0.5-5 hour, and the preferred time is 1-3 hour;
(3). activation (alkaline purification)
(2) resulting heat treated alloy is taken out aluminium with alkaline solution handle, make the extraction and make the gained catalyzer meet described composition of the presently claimed invention of most of aluminium in the alloy with the alkaline solution reaction; Said alkaline solution can be the solution of mineral alkali or organic bases, preferably the aqueous solution of alkali metal hydroxide, more preferably aqueous sodium hydroxide solution; The temperature of alkaline purification is a room temperature-120 ℃, is preferably 50-100 ℃; The alkaline purification time is 0.5-5 hour, is preferably 1-3 hour; The concentration and the consumption of alkaline solution have no particular limits, can according to desired catalyzer form and prior art in during the preparation Raney nickel catalyst employed alkaline purification condition determine; For example when using aqueous sodium hydroxide solution, the concentration of aqueous sodium hydroxide solution can be 10-40 weight %, and its consumption can be mother alloy: NaOH=1: (0.5-4) (weight ratio);
(4). washing
With (3) resulting sample temperature is room temperature-100 ℃, preferred 60-100 ℃ water washing, and the pH of washing back solution is preferably 7-13; Washing back sample can be kept in the water, also can be kept in the ethanol, is preferably under the condition of controlled atmosphere to preserve.
X-ray diffraction (XRD) figure of the amorphous alloy auxiliary agent that Fig. 1 makes for embodiment 1.
Hydrogenation process for benzoic acid provided by the invention is compared with existing method and since the CO that reaction produces absorbed by nickeliferous auxiliary agent or transform (as CO in the presence of nickeliferous auxiliary agent with H2Reaction changes into methane), reduced the poisoning of Pd/C catalyst, catalyst activity obviously improves, thereby has higher benzoic acid disposal ability and production Efficient, operational stability also improve greatly, and owing to reduced the additional speed of fresh Pd/C catalyst, Thereby reduced palladium and reclaimed frequency, reduced the possibility of precious metals pd loss; Simultaneously because the CO of system amount Reduce, also reduced the load of the pressure-variable adsorption that needs for processing CO. In a word, adopt the present invention to carry The method of confession greatly improves operability, and cost obviously reduces, and has especially solved the caprolactam worker Bottleneck problem in the skill.
The following examples will be described further processing method provided by the invention.
Embodiment 1
The preparation of a kind of amorphous alloy nickel auxiliary agent that present embodiment explanation the present invention is used.
48 gram nickel, 48 gram aluminium, 1.5 gram iron, 2.5 gram chromium are joined in the silica tube, it is heated to fusion more than 1300 ℃ in high frequency furnace, make its alloying, with indifferent gas this alloy liquid being sprayed onto a rotating speed from the nozzle under the silica tube then is on 800 rev/mins the copper roller, logical water coolant in the copper roller, alloy liquid forms the flakey band through throwing away along copper roller tangent line after the cooling fast, the flakey band is below 100 microns through being ground to particle diameter, obtains mother alloy.Mother alloy is heat-treated in hydrogen environment, and heat treated temperature is 600 ℃, and constant temperature time is 3 hours.Mother alloy after heat treatment slowly joins in the there-necked flask that fills 500 grams, 20% aqueous sodium hydroxide solution, controls its temperature and is 100 ℃ and constant temperature and stirred 1 hour.After stopping heating and stirring, decantation liquid is 7 with 80 ℃ distilled water washs to pH value.Prepared amorphous alloy auxiliary agent is numbered ZA-1, is kept in the water it standby.Its XRD figure is seen Fig. 1.
Embodiment 2
The preparation of a kind of amorphous alloy nickel auxiliary agent that present embodiment explanation the present invention is used.
48 gram nickel, 52 gram aluminium are joined in the silica tube, it is heated to fusion more than 1300 ℃ in high frequency furnace, make its alloying, with indifferent gas this alloy liquid being sprayed onto a rotating speed from the nozzle under the silica tube then is on 800 rev/mins the copper roller, logical water coolant in the copper roller, alloy liquid forms the flakey band through throwing away along copper roller tangent line after the cooling fast, the flakey band is below 100 microns through being ground to particle diameter, obtains mother alloy.Mother alloy is heat-treated in hydrogen environment, and heat treated temperature is 700 ℃, and constant temperature time is 2 hours.Mother alloy after heat treatment slowly joins in the there-necked flask that fills 1000 grams, 20% aqueous sodium hydroxide solution, controls its temperature and is 100 ℃ and constant temperature and stirred 1.5 hours.After stopping heating and stirring, decantation liquid is 7 with 100 ℃ distilled water washs to pH value.Prepared auxiliary agent is numbered ZA-2, is kept in the water it standby.
Embodiment 3
The preparation of a kind of amorphous alloy nickel auxiliary agent that present embodiment explanation the present invention is used.
48 gram nickel, 48 gram aluminium, 2.5 gram iron, 1.5 gram molybdenums are joined in the silica tube, it is heated to fusion more than 1300 ℃ in high frequency furnace, make its alloying, with indifferent gas this alloy liquid being sprayed onto a rotating speed from the nozzle under the silica tube then is on 800 rev/mins the copper roller, logical water coolant in the copper roller, alloy liquid forms the flakey band through throwing away along copper roller tangent line after the cooling fast, the flakey band is below 100 microns through being ground to particle diameter, obtains mother alloy.Mother alloy is heat-treated in hydrogen environment, and heat treated temperature is 700 ℃, and constant temperature time is 2 hours.Mother alloy after heat treatment slowly joins in the there-necked flask that fills 1000 grams, 20% aqueous sodium hydroxide solution, controls its temperature and is 100 ℃ and constant temperature and stirred 1.5 hours.After stopping heating and stirring, decantation liquid is 7 with 100 ℃ distilled water washs to pH value.Prepared auxiliary agent is numbered ZA-3, is kept in the water it standby.
Embodiment 4-6
These embodiment illustrate nickel auxiliary agent that embodiment of the invention 1-3 the provides activation situation to the Pd/C catalyzer.The activation situation characterizes (representing with Z) by estimating the hydrogenation effect that adds auxiliary agent front and back Pd/C catalyzer.Used Pd/C catalyzer is the recycling catalyst sample of taking from the Shijiazhuang chemical fibre limited liability company caprolactam production apparatus benzoic acid hydrogenation production line (down together).
The Z value is that the Pd/C activity of such catalysts characterizes the hydrogen-absorption speed of representation unit time catalyzer.Usually the spending rate according to beginning hydrogen calculates.The method of measuring the Z value is: get Pd/C catalyzer 2g, add (or not adding) contain that the Ni auxiliary agent mixes and the autoclave of packing in, add the 200g phenylformic acid again, with high purity nitrogen displacement 3-4 time, begin heating when filling nitrogen to 20 atm, replace 3-4 time with High Purity Hydrogen during to 150 ℃, fill hydrogen to 110atm, start stirring and pick up counting simultaneously, when the still internal pressure is reduced to 90atm, immediate record reaction times and temperature of reaction, and rapidly pressure is brought up to 110atm, according to identical method, repeat multi-pass operations as requested, and continue record each reaction times (reducing to 90atm) from 110atm, catalyst sample is finished circulating reaction usually 7 times, utilizes γ=Δ P/ Δ t formula to calculate the wear rate of hydrogen, is X-coordinate with time, γ is ordinate zou mapping, is the hydrogen consumption speed γ of beginning with the ordinate zou intersection point
0, catalyst activity is Z=γ
0/ 4.
The measuring method of Z value can be with reference to " hexanolactam device analysis method compilation " (chemical fibre limited liability company in Shijiazhuang writes).
Table 1 has been listed the Pd/C catalyst activity that adds behind the catalyst adjuvant that embodiment of the invention 1-3 provides.
Comparative Examples 1
The explanation of this Comparative Examples does not add the Pd/C activity of such catalysts situation when containing the Ni auxiliary agent.
Method according to embodiment 4-6 is estimated the Pd/C activity of such catalysts, and different is not add the amorphous alloy auxiliary agent that contains Ni, and the results are shown in Table 1 for gained.
Table 1.
The active Z of numbering auxiliary agent nickel promoter addition Pd/C
(accounting for Pd/C weight), %
Embodiment 4 ZA-1 2.5 0.50
Embodiment 5 ZA-2 2.5 0.47
Embodiment 6 ZA-3 2.5 0.48
Comparative Examples 10 0.16
Embodiment 7-11
Present embodiment explanation promoter addition is to the active influence of Pd/C.
Method according to embodiment 4-6 is estimated the Pd/C activity of such catalysts, and different is the add-on that changes the amorphous alloy auxiliary agent, and the results are shown in Table 2 for gained.
Table 2.
The active Z of numbering auxiliary agent nickel promoter addition Pd/C
(accounting for Pd/C weight), %
Embodiment 7 ZA-1 0.75 0.32
Embodiment 8 ZA-1 1 0.37
Embodiment 9 ZA-1 2 0.41
Embodiment 10 ZA-1 2.5 0.50
Embodiment 11 ZA-1 3.5 0.60
Embodiment 12-15
These embodiment illustrate the implementation result of the present invention in once secret commerical test.
The method of mentioning among Pd/C catalyst activity evaluation method and the embodiment 4-6 is consistent.The benzoic acid hydrogenation condition is: 180 ℃ of temperature of reaction, hydrogen pressure 2.0MPa (gauge pressure).When not adding the amorphous alloy auxiliary agent, the active Z=0.16 of recycling catalyst generates gas CO, CO
2, CH
4Total amount is 300ppm, and the magnitude of recruitment of fresh Pd/C catalyzer is double centner/sky (kg/d), and the device load is 5-6 ton/hour (t/h); After progressively adding the amorphous alloy auxiliary agent that contains Ni according to method of the present invention, the Pd/C activity of such catalysts steadily improves (its result is as shown in table 3), under the situation that adds 1.2% nickel auxiliary agent, the magnitude of recruitment of fresh Pd/C catalyzer is reduced to 75kg/d, the device load increases to 9t/h, CO, CO in the tail gas of reaction back
2, CH
4Amount reduces greatly, and CCA purity improves, H
2Utilization ratio improves.
Table 3.
Active Z CO, the CO of numbering auxiliary agent nickel promoter addition Pd/C
2, device load
(accounting for Pd/C weight), % CH
4Amount t/h
Embodiment 12 ZA-1 0.2 0.23 250 6.5
Embodiment 13 ZA-1 0.5 0.25 220 7-8
Embodiment 14 ZA-1 0.8 0.28 190 8-8.5
Embodiment 15 ZA-1 1.2 0.30 170 8.5-9
Claims (6)
1, a kind of benzoic method of hydrotreating, comprise with the fusion phenylformic acid in reactor in the presence of the Pd/C catalyzer, be 120-200 ℃ in temperature, pressure is the 1.0-12.0 MPa, the phenylformic acid flow be the 5-12 ton/hour, hydrogen flowing quantity be the 550-1200 kilogram/hour condition under contact with hydrogen; It is characterized in that in said reactor, also existing the amorphous alloy catalyst auxiliary agent of a kind of Ni of containing.
2, according to the method for claim 1, wherein the amorphous alloy catalyst catalyst adjuvant of the said Ni of containing is for being the amorphous alloy auxiliary agent of main active component with nickel, be 45 ± 1 ° at 2 θ in its X-ray diffractogram and locate to occur a diffuse maximum, this catalyzer is basically by the Ni of 60-98 weight %, the Fe of 0-20 weight %, 0-20 weight % is selected from a kind of metal in the group of being made up of Cr, Co, Mo, Mn and W, and the aluminium of 0.5-30 weight % is formed.
3, according to the process of claim 1 wherein that the add-on of amorphous alloy catalyst auxiliary agent of the said Ni of containing is the 0.001-0.1 weight % of said Pd/C catalyst weight.
4, according to the method for claim 3, wherein the add-on of the amorphous alloy catalyst auxiliary agent of the said Ni of containing is the 0.01-0.07 weight % of said Pd/C catalyst weight.
5, according to the method for claim 4, wherein the add-on of the amorphous alloy catalyst auxiliary agent of the said Ni of containing is the 0.01-0.05 weight % of said Pd/C catalyst weight.
6, according to the process of claim 1 wherein that the described condition that contacts with hydrogen is that temperature is that temperature is 150-180 ℃, pressure is 1.2-6.0MPa.
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CN104844449A (en) * | 2015-01-14 | 2015-08-19 | 西安工程大学 | Benzoic acid based anhydrous and solvent-free method for preparing heptanaphthenic acid |
CN112473719A (en) * | 2021-01-25 | 2021-03-12 | 潍坊科技学院 | Preparation method of porous carbon-nitrogen material loaded nano bimetallic catalyst and use method of catalyst in benzoic acid hydrogenation reaction |
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TWI811766B (en) | 2021-08-18 | 2023-08-11 | 元瀚材料股份有限公司 | 1,4-cyclohexyldiamine derivative and fabricating method for 1,4-diamine cyclic compound derivative |
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JP3023809B2 (en) * | 1991-12-24 | 2000-03-21 | 雪印乳業株式会社 | Method for hydrogenating and reducing cyclic organic compounds |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN104844449A (en) * | 2015-01-14 | 2015-08-19 | 西安工程大学 | Benzoic acid based anhydrous and solvent-free method for preparing heptanaphthenic acid |
CN112473719A (en) * | 2021-01-25 | 2021-03-12 | 潍坊科技学院 | Preparation method of porous carbon-nitrogen material loaded nano bimetallic catalyst and use method of catalyst in benzoic acid hydrogenation reaction |
CN112473719B (en) * | 2021-01-25 | 2021-06-29 | 潍坊科技学院 | Preparation method of porous carbon-nitrogen material loaded nano bimetallic catalyst and use method of catalyst in benzoic acid hydrogenation reaction |
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