TH84126A - Methods of reducing nitrogen oxides in gases. - Google Patents

Abstract

DC60 (02/08/49) Gas pass-through assembly method with N2O and NOx on the sequence of two catalyst beds, adding reducing agents for NOx and for N2O between catalyst beds in quantities. That does not It only reduces NOx, but also reduces N2O in the specified proportion. This reaction is set to Reducing the N2O content of the gas is not more than 95% based on the N2O content at the inlet of the first catalyst bed. By decomposition to nitrogen and oxygen in the catalyst bed And not only does a chemical reduction occurs for NOx, but also a chemical reduction for N2O in the second catalyst bed. This is so that the N2O content of the gas is reduced to at least 50 percent based on the N2O content at the inlet of the second catalyst bed. The assembly method is through gas passage with N2O and NOx on the sequence of two catalyst beds, adding reducing agents for NOx and for N2O between the catalyst beds in unrelated quantities. It only reduces NOx, but also reduces N2O in the specified proportion. This reaction is set to Reducing the N2O content of the gas is not more than 95% based on the N2O content at the inlet of the first catalyst bed. By decomposition to nitrogen and oxygen in the catalyst bed And not only does a chemical reduction occurs for NOx, but also a chemical reduction for N2O in the second catalyst bed. This is so that the N2O content of the gas is reduced to at least 50 percent based on the N2O content at the inlet of the second catalyst bed.

Claims (9)

1. A method of reducing the amount of NOx and N2O in the gas, including measures: a) the passage of gas containing N2O and NOx onto two catalyst beds, with one Catalyst for N2O decomposition to nitrogen and oxygen and second catalyst bed It has a catalyst for the chemical reaction of NOx and N2O with a reducing agent. B) Selection of temperature, pressure and three-dimensional velocity in the first catalyst bed so that The reduction in gas N2O content that occurs in this bed was not greater than 95% based on the N2O content at the entrance of the first catalyst bed and c) the addition of reducing agents for NOx and reducing agents for N2O between catalyst bed at First and second in sufficient quantities for chemical elimination for total NOx and at least 50% N2O based on the amount of N2O at the entrance of the second catalyst bed. 1, which is characterized by determining the temperature in the catalyst bed First and second to be less than 500 ํ a well, should have a temperature of 350 to 450 ํ. 3. Method according to claim 1, which is characterized by determining the gas pressure in the accelerator bed. The first and second reactions are at least 2 bars, preferably in the range of 4 to 25 bars. 4. Method according to claim 1, which is characterized by the gas with NOx and N2O. Catalytic bed conduction at three-dimensional velocity from 5000 to 50000 h-1 on a volume basis. Combined bed catalyst This two-bed catalyst 5. Method according to claim 1, which is unique in that it is to use a zeolite-type catalyst containing metal. Zeolite with iron in the catalyst bed, at least One bed. 6. Method according to Clause 5, which is unique in that this iron or zeolite zeolite is of type MFI, BEA, FER, MOR, FAU and / or MEL. 7. Claim Method. Clause 6 is unique in that zeolites containing MFI and / or FER steels are selected in the first catalyst bed. 8. Method according to claim 6, which is unique to zeolites. 9. The method of claim 6, which is unique in that zeolites with MFI steels, are selected for use in the second catalyst bed. Steel-containing ZSM-5 zeolites were selected in the first and second catalyst beds 1 0. Method to claim 1, which is unique in that iron-containing zeolites, which were treated Treated with steam was treated with a stream applied in at least one catalyst bed. 1. Method according to claim 1, which is characterized by the zeolite containing iron, where the ratio of Special aluminum lattice to this aluminum lattice, minimum 0.5, will be used as a catalyst. Reaction in at least one catalyst bed 1 2. The method described in Clause 1 is unique in that it uses reducing agents containing at least nitrogen, hydrocarbons, carbon monoxide, hydrogen or mixtures containing at least one of these components. Two of the best, as a reducing agent for NOx and as a reducing agent for N2O 1. 3. Method according to Clause 11, which is unique in that ammonia is used as a reducing agent for NOx and as a reducing agent for N2O 1. 4. The method according to Clause 13 is unique in that ammonia is used as a reducing agent for NOx in quantities from 0.9 to 2.5 mol. If so, then from 0.9 to 1.4 mol. 1.0 to 1.2 mol per mole of NOx and ammonia is used as reducing agent for N2O in quantities from 0.5 to 2.0 mol. If so, from 0.8 to 0.8 mol per mole of N2O to be eliminated 1. 5. Method according to claim 11, which is unique in that ammonia is used as a reducing agent for NOx and hydrocarbon as a reducing agent for N2O 1. 6.The method described in Clause 15 is unique in that hydrocarbons will be used in As a reducing agent for 0.2 to 1 mol of N2O, if so, 0.2 to 0.7 mol per mol of N2O to be eliminated 1. 7. The procedure in Clause 1, which is unique in that it is incorporated in the Process for the production of nitric acid 1 8. The procedure in Clause 1, which is unique in that it is included in the The process of operating gas turbines 1 9. The procedure in Clause 1, which is unique in that it is incorporated in the The process of operating the power station