DE1277211B - Process for the production of a silver carrier catalyst - Google Patents

Description

Process for the production of a supported silver catalyst Silver catalysts are well known. When applied to a support, they are mainly preferred Catalysts for the oxidation of ethylene to ethylene oxide.

One of the difficulties encountered with their use is in the relatively low adhesion of the silver to the carrier material. Since that Silver easily off the support when handling or using the catalyst if it falls off or dusts away, the catalytic effectiveness of the known silver-supported catalysts decreases more or less quickly. Furthermore, the separation of the silver from the carrier particles leads to it to blockages and channeling in the catalyst bed, which leads to conversion and Decrease the yield.

Such supported silver catalysts are described in French patent specification 1 110 846 described. Thereafter, in one case, silver nitrate is precipitated with sodium carbonate and on a silica material in the presence of an ethylene glycol-water mixture applied and then heated to 4000 C for 1 hour. Both the conversion with 15.3% and the yield with 37.401% are completely unsatisfactory. Far better According to this patent, results are obtained when using more than molar ratios of alkaline earth salts with silver salts to form a coprecipitate and in the presence of an ethylene glycol-water mixture. applies to a carrier and heated to 4000 C for one hour. From a calcium nitrate-silver nitrate mixture a calcium carbonate-silver carbonate coprecipitate is obtained in a molar ratio of 4: 1, which contains 9.0 g of silver in 45 g of coprecipitate.

This coprizpitat is, as described above, on 100 g of carborundum applied and used 100 cm3 of the product obtained as a catalyst. Experiments have shown that when using a carborundum with a Bulk density of about 2.4 100 cms of this catalyst mass has an amount of silver of 25.2 g included. These 100 cm3 give an ethylene conversion of 45 O / u with one yield from 650/0. Using an amount of 336 cmS of this catalyst gives an ethylene conversion of S50 / o with a yield of 700/0. If you relate the achieved Sales on the existing active ingredient quantity, d. H. Silver in the catalyst mass, result, as shown in the following comparative tests, only very much unsatisfactory activities. Furthermore, these known catalyst compositions show As has been shown in experiments, probably due to the very considerable silver content the quality of being a Show the "migration" of temperature while working, d. that is, it is not possible to use these catalysts at a constant temperature to work for extended periods of time. In contrast, catalyst compositions are according to the invention obtained, on the one hand, a better temperature control than the known catalysts allow and on the other hand, based on the amount of silver used in the catalyst, show far higher yields and activities. That is, they yield far less Volume and, in absolute terms, lower silver contents, better sales and higher yields.

The process according to the invention for producing a supported silver catalyst by heating one of a reducible, water-insoluble silver compound, an alumina carrier and an aliphatic polyalcohol and optionally Water and / or a promoter existing mixture is that you as Silver compound silver oxide, silver carbonate or silver oxalate and as polyalcohol Diethylene glycol is used and initially reduced by heating to 110 to 1400 C, volatile substances are then removed at 140 to 2000 C and optionally at 4000 C heated.

The amount of diethylene glycol used is between that those responsible for the formation of a molecular film on the particles of the silver compound, of the carrier material and, if appropriate, of the promoter necessary is, and that amount which is carried by the particles after the excess has run off is just held back. The silver compound is through the diethylene glycol reduced, and the volatile reaction products are evaporated by at temperatures is heated from 110 to 1400 C and then from 140 to 2000 C.

Thereafter, the finished catalyst can optionally still on a higher temperature, preferably up to about 4000 C, can be heated to the desired Adjust catalyst activity.

Another means of managing or controlling the effectiveness or The selectivity of the supported silver catalysts according to the invention lies in their incorporation one or more promoters, such as sodium oxide, barium oxide, gold chloride, tin chloride, etc.

The method according to the invention can - as explained below will - be done in different ways. The silver compound and the particulate carrier can be dry blended together, whereupon one with further mixing the polyhydric alcohol in liquid or vaporized Introduces form in an amount sufficient to wet the solid particles. One can also impregnate the particulate carrier with the polyhydric alcohol, after which something is allowed to run off and then mixed with the silver compound, so that all of the solids are wetted by the polyhydric alcohol. It can also initially a slurry of the silver compound and the polyhydric alcohol in one for moistening the carrier material, preferably an absorbent one Carrier material, the necessary amount to be prepared, whereupon the carrier material immersed in or mixed with the slurry. Then the excess of the polyhydric alcohol drained.

The ratio of silver compound to carrier is preferably so chosen that the finished catalyst contains 0.5 to 20 percent by weight silver. A catalyst with 6 to 130/0 silver is best for the production of ethylene oxide manufactured.

The reduction of the silver compound can be done in various ways, z. B. by heating the moistened with the polyhydric alcohol for a long enough time Mass in an oven or with an infrared lamp or in an open bowl Temperatures between 110 and 1400 C. Then the material is used to remove the volatile constituents heated to 140 to 2000 C, which is advantageous in an air-blown Oven takes place, or the volatile ones are ignited while heating in an open dish Reaction products. The catalysts obtained in this way can then still be used then heat to 4000 C and above to achieve the desired catalyst activity to adjust.

The following examples serve to further illustrate the invention.

Example 1 15 cm 3 of diethylene glycol became 112 g of granular clay with a particle size corresponding to 1.41 to 2.38 mm clear mesh size given. After a fairly even distribution of the diethylene glycol through the 17.7 g of silver oxalate were evenly mixed in with the carrier mass. This mixture was heated in an oven to 1300 for 2 hours.

The mass was then heated to 1500 ° C. for 48 hours in order to remove the diethylene glycol decomposition products expel. During the entire heating period, the oven was running on a slow Purged air flow. The carrier granules had a firmly adhering, moss-like appearance Covered with completely evenly distributed, very small silver metal particles.

50 cm8 of the catalyst prepared in this way were placed in a reaction tube. A mixture of air and ethylene containing 3.20 / 0 ethylene was passed through the catalyst heated to about 2500 C at a throughput rate of 560 parts by volume of feed gas (measured under standard conditions of temperature and pressure) per part by volume of catalyst and per hour. With an ethylene conversion of 50%, the ethylene oxide yield was 720/0. Manufacture of the catalyst Silver content Experiment silver compound temperature in the reduction and compression (g / 100 ml Silver compound volatilization stage as well as catalyst in the aftertreatment) A Ag2O .. ....... ......... 120 ° C (2 hours), then 160 to 185 ° C 8.0 (20 to 24 hours) and 4000 B AgC2O4 .................. 120 ° C (2 hours), then 160 to 185 ° C 7.9 (20 to 24 hours) and 4000 C Ag2CO3. .......... ....... 150 to 160 ° C (16 hours), then 170 ° C 7.8 (6 hours) and 400 ° C (3 hours) D Ag2CO8 .................... 120 to 1300 C (2 hours), 9.0 2000C (0.5 hours) E Ag2CO3 ..................... 1500 C (1 hour) 7.8 French Made from AgNO3 and Ca (NO0) 2 with Na2CO3 1110846 precipitated AgCO3 + CaCO3 .......... 400 ° C (1 hour) 25.2 Patent specification Example 6 Example 7 and the like ... ............. 400 ° C (1 hour) 25.2 Example 2 From AgNO3 with Na2CO (3 precipitated Ag2CO3 coprecipitated ............ 400 ° C (1 hour) 12.7 Example 2 60 cm 3 of diethylene glycol were added to 448 g of granular alumina with a particle size corresponding to 1.41 to 2.38 mm clear mesh size. After the diethylene glycol had been completely distributed in the carrier mass, 74 g of silver oxalate were evenly mixed into the moistened mass. The mass was then heated at 1200 ° C. for 2 hours, then at 160 to 1650 ° C. for 15 hours and finally at 1850 ° C. for 4 hours.

The catalyst thus prepared was then used for adjustment the catalyst activity is heated to 4000 C for 3 hours and tested as in Example 1.

A 500% conversion of the ethylene resulted in a yield of 730/0 ethylene oxide.

Example 3 5.2 cm 3 of diethylene glycol became 214 g of 99.490% purer given to molten alumina, which had a bulk density of 1.86 g / cm3. To complete distribution of the diethylene glycol in the mass of the granules of clay a mixture of 16.1 g silver oxide and 1.35 g tin oxide mixed evenly into the mass. The mass moistened with the diethylene glycol was in an oven for 2 hours Heated 1250 C without air being passed through. Now the mass became one oven heated to 175 to 1800 C for 15 hours. The carrier particles were then completely uniform with a moss-like, particulate coating coated very small silver particles that adhered firmly to the carrier.

The catalyst thus prepared was then used for adjustment the catalyst activity heated to 4000 C and then tested as in Example 1.

When the ethylene was converted to 500%, there was a yield of ethylene oxide of 730/0.

Example 4 170 cm3 of diethylene glycol containing 0.18 g of gold chloride, were added to 4686 g of clay (cf. Example 3). After the complete distribution of the Di- Ethylene glycol through the whole mass of the carrier particles was moistened into the Carrier mass a mixture of 352 g silver oxide and 28.6 g tin oxide mixed in evenly. The material was then placed in an air-circulated oven at 1250 ° C. the Temperature was gradually increased to 175 to 1800 C and 17 hours at that Value held. The silver adhered firmly to the carrier granules in the form of a even, moss-like or particulate coating of very small silver particles.

The catalyst thus prepared was on for 3 hours heated to about 4000 C and tested as in Example 1. With a 500% conversion of the ethylene, the catalyst gave an ethylene oxide yield of 71%.

Example 5 Five catalysts A to E were prepared and with the supported silver catalysts of Examples 2, 6 and 7 of the French patent 1 110846 compared. An alumina with a particle size was used as the carrier used between 1.4 and 2.8 mm. The clay was mixed with that sufficient for wetting Amount of diethylene glycol mixed and then thoroughly mixed with the one used Mixed silver compound. The silver compounds used and the special The temperature and time ratios used for heating are as follows Given in the table.

The same are the corresponding values for the comparative examples listed according to the French patent specification.

The same are the conditions for the conversion of ethylene to ethylene oxide specified.

In the last column of the table, an activity factor is listed which was obtained from the factor of conversion and yield of the respective experiment and which is based on 1 g of the silver contained in the catalyst composition used in each case; The value obtained according to Example 6 of French patent specification 1,110,846 was arbitrarily set to 1 as a basis for comparison. Testing of the catalyst during the conversion of C2H4 to C2H40 Reaction I conversion of temperature contact time C2H4 yield of C2H4 activity factor (0 C) (seconds) (0/0) (0/0) 200 1 7 68.8 60.6 4.5 200 1 7 72.7 70.4 5.5 213 to 215 6.9 33.0 63.1 2.25 257 7 57.2 74.0 3.95 200 10 29.0 76.5 2.4 210 7 45.0 65.0 1 230 6.5 55 70 0.38 200 7 15.3 37.4 0.36 The result is an activity that is always a multiple of the activities that can be achieved even according to good values according to French patent specification 1110 846.

Claims (1)

Claim: Process for the production of a supported silver catalyst by heating one of a reducible, water-insoluble silver compound, an alumina carrier and an aliphatic polyalcohol and optionally water and / or a promoter consisting mixture, characterized in that the silver compound is silver oxide, silver carbonate or silver oxalate and the polyalcohol Diethylene glycol is used and initially reduced by heating to 110 to 1400 C, volatile substances are then removed at 140 to 2000 C and optionally at 4000 C heated. Documents considered: French patent specification No. 1 110 846.