PL187009B1 - Method of purifying flue gas from a cyclohexane oxidation process - Google Patents

Abstract

1. A method of cleaning waste gases from cyclohexane oxidation, consisting of is from the gas stream separated from the expansion of the crude cyclohexane oxidation product and from the stream of post-reaction gases discharged from the cyclohexane oxidation process, na by catalytic combustion of oxygenated organic compounds and hydrocarbons contained in them aliphatic series of methane and carbon monoxide at a temperature of 600 - 1000 ° K, characterized in that the stream of post-reaction gases discharged from the cyclohexane oxidation process is divided into three parts in the proportion of 2.70 - 2.90: 1.00 - 1.10: 0.30 - 0.32, the first of which after mixing with air is passed through the first catalyst bed to burn the pollutants at a temperature of 653 - 873 K and a pressure of 0.01 - 0.03 MPa with a flow rate of not less than 7500 hours and the resulting exhaust gas is then passed through a second bed of the same catalyst and the second part is communicated with air and fed together with the connected third part and stream gases obtained after decompression of the crude product of cyclohexane oxidation and exhaust gases after the first catalyst bed to the second bed of the same catalyst containing 0.5% - by weight of palladium deposited on alumina, on which catalytic combustion of pollutants occurs at a temperature of 673 - 973 K, a pressure of 0.01 - 0.03 MPa, at a flow rate gas streams not greater than the gas flow rate to the first to be fed a catalyst bed, wherein both catalyst beds are located in one apparatus.

Description

The subject of the invention is a method of purifying exhaust gases from the cyclohexane oxidation process by catalytic combustion of oxygenated organic compounds contained therein, aliphatic hydrocarbons of a series of methane and carbon monoxide, prior to their discharge into the atmosphere.

In the process of oxidation of cyclohexane with air or oxygen-containing gases, carried out in the liquid phase under conditions of increased pressure and temperature, a crude oxidation product is obtained, which is a cyclohexane solution of cyclohexanol, cyclohexanone and other oxygen organic compounds and a stream of post-reaction gases discharged from the cyclohexane oxidation process, which contain unreacted oxygen, gaseous cyclohexane oxidation products, mainly methane series aliphatic hydrocarbons and other gases introduced with the oxidizing agent and volatile cyclohexane vapors of cyclohexane oxygen oxidation products, cyclohexanol, cyclohexanone, carbon monoxide and carbon dioxide as well as aliphatic monocarboxylic acids. The discharged gas stream from cyclohexane oxidation is then cooled and subjected to an absorption operation to remove cyclohexane, cyclohexanol and cyclohexanone. The stream of these gases for medium-sized cyclohexane oxidation installations reaches tens of millions of cubic meters per year and should not be directly discharged into the atmosphere due to the presence of methane aliphatic hydrocarbons in concentrations up to 8.1 g, cyclohexane up to 1.3 g. g and carbon monoxide up to 40 g in normal cubic meters.

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The second gas stream containing the above-mentioned components, which should not be discharged into the atmosphere, is the gas stream obtained after decompression of the crude cyclohexane oxidation product. This stream, after cooling and after absorption to remove cyclohexane, cyclohexanol and cyclohexanone for medium-sized cyclohexane oxidation plants, reaching a size of more than one million cubic meters per year, contains up to 195 g of methane aliphatic hydrocarbons, up to 30 g of cyclohexane and up to 400 g of oxide carbon in a normal cubic meter.

In industrial practice, the most common method of destroying pollutants in these waste gas streams is their non-catalytic, catalytic, or both simultaneous combustion.

The known method of destroying pollutants in exhaust gases from the cyclohexane oxidation process, given in Polish patent specification No. 134 494, consists in pre-combustion of the gas stream obtained after expansion of the crude cyclohexane oxidation product with the addition of methane and air. Combustion of the mixture is carried out in a flame, non-catalytic. The exhaust gases at 1800 ° K are mixed with the stream of gases discharged from the cyclohexane oxidation process and possibly with air, and then directed to the catalyst bed, which are copper and chromium oxides deposited on alumina, and oxidation of pollutants at 900 ° K is carried out in this description. Another solution for destroying pollutants was also presented, consisting in the fact that the flue gas after pre-combustion is mixed with a part of the gas stream discharged from the cyclohexane oxidation process before being sent to the first layer of the multilayer catalyst bed and the remaining part is directed to the subsequent layers of the catalyst bed. The methods according to the discussed description have disadvantages, which include the fact that the combustion of pollutants in the stream of gases discharged from the cyclohexane oxidation process and contained in the gas stream obtained after expansion of the crude cyclohexane oxidation product are burned separately in two or more apparatuses, which complicates the process and it increases the investment costs and the fact that the use of additional fuel, which is methane, increases the operating costs of the waste gas cleaning process.

The method of purifying exhaust gases from the cyclohexane oxidation process, known from another Polish patent specification No. 138 704, consists in oxidizing the gases at a temperature of 400 - 1500 ° K under a pressure of 0.1 - 1.0 MPa in the presence of a catalyst which is at least one metal of the platinum group deposited on a support, where it is recommended to supply the necessary oxygen for the oxidation by sucking in air from the surroundings with an ejector fed with a stream of gases withdrawn from the cyclohexane oxidation process. This method does not, however, solve the problem of destroying the impurities contained in the gas stream obtained after decompression of the crude cyclohexane oxidation product, and these gases always arise because the process uses an expansion operation.

The essence of the invention consists in the fact that the stream of post-reaction gases discharged from the cyclohexane oxidation process is divided into three parts in the proportion of 2.70 - 2.90: 1.00 - 1.10: 0.30 - 0.32. The first, after mixing with air, is passed through a catalyst bed containing 0.5% by weight of palladium on alumina, and catalytic combustion of pollutants is carried out at a temperature of 653 - 873 ° K, under a pressure of 0.01 - 0.03 MPa with a flow rate of not less than 7500 hours' ¹ . The resulting exhaust gas is then passed through a second catalyst bed. The second part of the post-reaction gas stream discharged from the cyclohexane oxidation process is combined with the air and fed together with the connected third part and the gas stream obtained after expansion of the crude cyclohexane oxidation product to the second bed of the same catalyst, on which catalytic combustion of pollutants takes place at a temperature of 673 - 933 ° C K, at a pressure of 0.01-0.03 MPa at a flow rate not greater than the flow rate of the gases fed to the first catalyst bed, both catalyst beds are placed in one apparatus. At the same time, the gas stream obtained after decompression of the crude cyclohexane oxidation product is compressed to the pressure of 0.01-0.03 MPa by means of an ejector fed with a part of the post-reaction gas stream discharged from the cyclohexane oxidation process.

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The advantages of the method according to the invention include the possibility of neutralizing the impurities contained in the gas stream separated from the expansion of the crude product of cyclohexane oxidation and in the stream of post-reaction gases discharged from the cyclohexane oxidation process in one apparatus with two catalyst beds and the fact that the supply of the gas stream separated from the expansion of the crude product Oxidation of cyclohexane having a high calorific value results in obtaining such temperatures on the second catalyst bed which ensure a high degree of conversion of organic oxygen compounds, aliphatic hydrocarbons of the methane, cyclohexane and carbon monoxide series. As a result, the investment costs are reduced compared to the costs for the installation, in which the pollutants in the above-mentioned streams would be destroyed in separate devices. An advantage of the method according to the invention is also the use of an injector fed with a part of the post-reaction gas stream discharged from the cyclohexane oxidation process to compress the gas stream separated from the expansion of the crude cyclohexane oxidation product to the required pressure. The method according to the invention does not require the use of additional fuel, e.g. methane, to obtain the correct combustion temperature of pollutants. An exemplary solution of the method according to the invention is shown in the drawing, in which Fig. 1 shows a schematic system of the installation for purification of post-reaction gases discharged from the cyclohexane oxidation process and gases obtained after depressurization of the crude cyclohexane oxidation product. The example below shows the process flow and the results obtained.

Example. The numbering of the streams and assay apparatus of FIG. 1. For the installation of the purification of flue gases from the oxidation of cyclohexane directed stream of one reaction gases discharged from the oxidation of cyclohexane in an amount of 4350 m ³ / hr containing 3.40 g of a series of aliphatic hydrocarbons methane, 0.36 g of cyclohexane and 35.36 g of carbon monoxide in normal cubic meters and a stream of 5 gases obtained after decompression of the crude product of cyclohexane oxidation in the amount of 169 Nm ³ / hour containing: 227.78 g of aliphatic hydrocarbons of the methane series, 12.48 g of cyclohexane and 347, 50 g of carbon monoxide in normal cubic meters. Stream 1 was split into three parts before it was directed to the combustion reactor R1: into a stream 2 of 3050 Nm3 / hr, a stream 3 of 1125 Nm3 / h and a stream 4 of 355 Nm3 / h. Stream 2, after expansion in the reduction valve Z1, was mixed with air in the amount of 605 Nm3 / h and directed to the catalyst bed S1 of the combustion reactor R1 after being heated in the heat exchanger W1 to the temperature of 318 ° K with the heat of the exhaust gases leaving the steam boiler B1 and in the heat exchanger W2 to the temperature 424 ° K with the heat of the exhaust gases leaving the combustion reactor R1. The combustion temperature on the catalyst S1 bed was 660 ° K. The stream 3, after expansion in the reduction valve Z2, was mixed with air in the amount of 350 Nm ^J / h and directed to the catalyst S2 bed of the combustion reactor R1 after prior mixing with the gas mixture obtained after mixing in the J1 ejector of stream 4 with stream 5. The combustion temperature in the catalyst S2 bed was 919 ° K. The exhaust gas discharged to the atmosphere contained 0.40 g of methane series aliphatic hydrocarbons, 0.02 g of cyclohexane and 0.03 g of carbon monoxide in normal cubic meters. The catalyst beds S1 and S2 were placed in one apparatus.

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Flue gases into the atmosphere

Publishing Department of the UP RP. Circulation of 50 copies. Price PLN 2.00.

Claims (2)

Patent claims 1. Method of purifying exhaust gases from the cyclohexane oxidation process, consisting of the stream of gases separated from the expansion of the crude product of cyclohexane oxidation and the stream of post-reaction gases discharged from the cyclohexane oxidation process, by catalytic combustion of oxygen organic compounds contained in them, aliphatic hydrocarbons of a series of methane and oxide coal at a temperature of 600 - 1000 ° K, characterized in that the stream of post-reaction gases discharged from the cyclohexane oxidation process is divided into three parts in the proportion of 2.70 - 2.90: 1.00 - 1.10: 0.30 - 0, 32, the first of which, after mixing with air, is passed through the first catalyst bed, combustion of pollutants at a temperature of 653 - 873 ° K at a pressure of 0.01 - 0.03 MPa with a flow rate of not less than 7500 h ^1, and the resulting exhaust gas is then passed through through a second bed of the same catalyst and the other part is combined with air and fed together with a combined third part and a stream of gases obtained after decompression of the crude cyclohexane oxidation product and with flue gas after the first catalyst bed into a second bed of the same catalyst containing 0.5% - by weight of palladium deposited on alumina, on which catalytic combustion of pollutants takes place at a temperature of 673 - 973 ° K, at a pressure of 0.01-0.03 MPa, at a gas flow rate not greater than the flow rate of gases fed to the first catalyst bed, both catalyst beds are placed in one apparatus. 2. The method according to p. The process of claim 1, characterized in that the gas stream obtained after decompression of the crude cyclohexane oxidation product is compressed to a pressure of 0.01-0.03 MPa by means of an ejector fed with a part of the post-reaction gas stream discharged from the cyclohexane oxidation process.