KR20210151163A - Method and apparatus for denitrification treatment of sinter flue gas - Google Patents

Abstract

A method and apparatus for denitration treatment of sinter flue gas, the method comprising: igniting a sinter material (70); and controlling an atmosphere in which the sintered material 70 is burned by spraying a reducing medium to the ignited sintered material 70 to react the reducing medium with an oxidizing agent around the sintered material 70; Transfer mechanism 10 for transferring the sintered material 70; Installed corresponding to the transfer mechanism 10, the ignition device 20 for igniting the sintered material; Located downstream of the ignition device 20, the ignited sinter and a reaction control device 30 for adding a reducing medium to the material 70 .

Description

Method and apparatus for denitrification treatment of sinter flue gas

The present invention relates to the technical field of steel smelting equipment, and more particularly, to a method and apparatus for denitration treatment of sinter flue gas.

Until now, in the steel sintering process, flue gas treatment is basically the final treatment. Besides the activated carbon process, the simultaneous denitration technology widely used in China and abroad is the Selective Catalytic Reduction (SCR) technology. Selective catalytic reduction denitrification is the reduction of NO in flue gases via ammonia to N ₂ and water using a catalyst in an oxygen-containing atmosphere. When the reaction temperature is 300-45°C, the denitration rate can reach 70%-90%. This technology is mature and reliable, so it is now widely used worldwide, especially in developed countries. However, such process equipment requires a lot of investment, the flue gas must be preheated, expensive catalysts, short service life, high operating cost, ammonia leakage, the equipment is easily corroded, and the problem of hazardous waste disposal. In addition, denitrification processes in which nitrogen oxides are first oxidized using ozone or catalyst and then removed with an adsorbent exist at home and abroad.

The present invention discloses a method and apparatus for denitration treatment of sinter flue gas, and solves the conventional short service life and high operating cost problems.

According to one aspect of the present invention, the step of igniting the sintering material (S10); Disclosed is a method for denitration treatment of sintered flue gas, comprising: spraying a reducing medium to the ignited sintered material to react the reducing medium with an oxidizing agent around the sintered material (S20).

In addition, the reducing medium includes a reducing agent that reacts with oxygen surrounding the sintering material.

In addition, the reducing agent reacts with a gas produced by the combustion of the sintered material.

In addition, the reducing agent undergoes a reduction reaction with nitrogen oxides generated by combustion of the sintered material.

In addition, the reducing agent includes a combustible material.

In addition, the reducing agent is methane, propane, acetylene, hydrogen, methanol, ethanol, coal gas, natural gas, gasoline, heavy oil, powdered coal, charcoal, coke, sawdust, hydrogen sulfide, hydrogen cyanide, phosgene, N-butane, N-hexane, N-heptane, N-pentane, propanol, methyl ethyl ketone, vinyl acetate, silane, cyclohexane, hydrogen chloride, butyne, liquefied gas, petroleum gas, ethyl ether, toluene, benzene, acetone, allylene, ethylene, propylene, butene, at least one of butane and coal water slurry.

In addition, the reducing agent further includes water or water vapor.

In addition, the reducing medium further includes a supporting agent, and the supporting agent includes at least one of oxygen, air, or circulating exhaust gas.

According to another aspect of the present invention, a transport mechanism for transporting the sintered material; an ignition device that is installed to correspond to the transport mechanism and ignites the sintered material; There is further disclosed an apparatus for denitration of sintered flue gas, which includes a reaction control device positioned downstream of the ignition device and configured to add a reducing medium to the ignited sintered material.

In addition, the ignition device is installed above the transport mechanism.

In addition, the reaction control device includes a feeder disposed on the upper portion of the transfer mechanism, the feeder having a control valve for controlling the amount of the reducing medium added.

In addition, the reaction control device, disposed on the upper portion of the transfer mechanism, includes a pipeline equipped with a control valve for controlling the amount of the reducing medium added.

In addition, the denitration treatment device is installed in the lower portion of the transport mechanism, the air box for collecting the flue gas after the sintered material is burned; and an air duct communicating with the air box and having a fan therein; more include

Further, the conveying mechanism includes a conveying trolley, and a plurality of the conveying trolleys are sequentially connected in a conveying direction of the sintered material.

In addition, the air box is provided in plurality, and the plurality of air boxes are arranged at intervals.

The denitrification treatment method of sintered flue gas of the present invention controls the combustion atmosphere of the sintered material such as oxygen content by spraying a reducing medium on the surface of the sintering material during sintering to react the reducing medium with the surrounding oxidizing agent, thereby generating nitrogen oxides In addition, it is possible to reduce nitrogen oxide emissions by reacting with nitrogen oxides already generated in the sintering process to reduce nitrogen oxides to nitrogen, and the cost is low.

BRIEF DESCRIPTION OF THE DRAWINGS It is a structural explanatory drawing of the denitration processing apparatus of the Example of this invention.

Hereinafter, the present invention will be further described by combining examples, but the present invention is not limited to the contents of the specification.

The present invention comprises the steps of igniting the sintered material (S10); Disclosed is a method for denitration treatment of sintered flue gas, comprising: spraying a reducing medium to the ignited sintered material to react the reducing medium with an oxidizing agent around the sintered material (S20).

The denitrification treatment method of sintered flue gas of the present invention controls the combustion atmosphere of the sintered material, such as oxygen content, by spraying a reducing medium on the surface of the sintering material during sintering to react the reducing medium with the surrounding oxidizing agent, thereby generating nitrogen oxides In addition, it is possible to reduce nitrogen oxide emissions by reacting with nitrogen oxides already generated in the sintering process to reduce nitrogen oxides to nitrogen, and the cost is low.

In this embodiment, the reducing medium comprises a reducing agent that reacts with oxygen surrounding the sintering material. In the sintering production process, the reducing agent may cause a direct oxidation-reduction reaction with oxygen to effectively suppress the formation of nitrogen oxides, reduce nitrogen oxide emissions, and reduce operating costs.

In the above embodiment, the reducing agent reacts with a gas generated by the combustion of the sintering material, and the reducing agent is reacted with nitrogen oxide generated by the combustion of the sintering material by a reduction reaction. When the sintering material is burned, some gases are still produced, of which the same nitrogen oxides are present, and the reducing agent can cause redox reactions with these gases, especially nitrogen oxides, and reduce nitrogen oxides to nitrogen to reduce nitrogen oxide emissions It is safe and reliable because it does not produce dangerous by-products.

In the above embodiment, the reducing agent is methane, propane, acetylene, hydrogen, methanol, ethanol, coal gas, natural gas, gasoline, heavy oil, coal, charcoal, coke, sawdust, hydrogen sulfide, hydrogen cyanide, phosgene, N-butane, N -Hexane, N-heptane, N-pentane, propanol, methyl ethyl ketone, vinyl acetate, silane, cyclohexane, hydrogen chloride, butyne, liquefied gas, petroleum gas, ethyl ether, toluene, benzene, acetone, allylene, ethylene, propylene , butene, butane, coal water slurry, coke, sawdust, etc. contain one or more of combustible materials, or contain water and water vapor that can be decomposed into hydrogen at high temperatures, and hydrogen can reduce reaction with an oxidizing agent or nitrogen oxides . The reducing agent used in the present invention may be one of the above materials, or may be a mixture of a plurality of the above materials, for example, various gas mixing, solid mixing, gas and liquid mixing, etc. may all be implemented, and such a mixture All of them are very cheap and do not cause pollution.

In the above embodiment, the reducing medium further includes a supporting agent, wherein the supporting agent includes at least one of oxygen, air, or circulating exhaust gas. The combustible material and the combustion auxiliary material are mixed according to the set ratio, and it is carried out in an appropriate mixing ratio according to the requirements of various gas atmospheres. Reaction efficiency can be improved by adding a supporting agent, and it helps to further reduce the production of nitrogen oxides.

According to another aspect of the present invention, the conveying mechanism 10 for conveying the sintered material 70; is installed to correspond to the conveying mechanism 10, the ignition device 20 for igniting the sintered material; to correspond to the conveying mechanism Installed, located downstream of the ignition device 20 in the transport direction of the sintered material 70, the reaction control device 30 for adding a reducing medium to the ignited sintered material 70; A denitration treatment apparatus is disclosed. In the present invention, by adding the reaction control device 30, after the ignition device 20 ignites the sintered material, the reducing medium is sprayed on the sintered material to burn the reducing medium and react with the surroundings, thereby reducing the generation of nitrogen oxides. In addition, it also reacts with nitrogen oxides already generated in the sintering process, thereby reducing nitrogen oxides to nitrogen, thereby reducing the amount of nitrogen oxides, and the cost is low.

In the above embodiment, the ignition device 20 is installed on the upper portion of the conveying mechanism 10, and can effectively ignite the sintered material in the conveying mechanism 10. As shown in FIG.

In the above embodiment, the reaction control device 30 includes a feeder disposed above the conveying mechanism 10 and provided with a control valve for controlling the addition amount of the reducing medium. By installing the feeder on the upper part of the transfer mechanism 10, the reducing medium can be sprayed conveniently, the reaction efficiency can be improved, the waste of the reducing medium can be reduced, and the control valve can control the amount of the reducing medium added. Effective control of the combustion atmosphere of the sintering material, such as oxygen content and temperature, can be implemented, and it can suppress the formation of nitrogen oxides.

In the above embodiment, the reaction control device 30 includes a pipeline disposed above the transport mechanism 10 and provided with a control valve for controlling the amount of the reducing medium added. By installing the feeder on the upper part of the transfer mechanism 10, the reducing medium can be sprayed conveniently, the reaction efficiency can be improved, the waste of the reducing medium can be reduced, and the control valve can control the amount of the reducing medium added. Effective control of the combustion atmosphere of the sintering material, such as oxygen content and temperature, can be implemented, and it can suppress the formation of nitrogen oxides.

In the above embodiment, the denitration treatment device is installed in the lower part of the transport mechanism 10, the air box 40 for collecting the flue gas after the sintered material is burned; and communicates with the air box 40, inside The fan 60 is provided with an air duct 50; further includes. Through the negative pressure generated by the fan 60, the gas generated by the sintering furnace can all be sucked into the flue through the air box 40, thereby effectively preventing the flue gas from leaking.

In the above embodiment, the conveying mechanism 10 includes a conveying trolley, and a plurality of conveying trolleys are sequentially connected in the conveying direction of the sintered material 70 . A plurality of air boxes 40 are provided, and a plurality of air boxes 40 are disposed at intervals. By installing the transport trolley, the production efficiency of the sintered material can be improved, and the installation of a plurality of air boxes 40 can greatly improve the effect of flue gas collection, and prevent flue gas leakage and environmental pollution.

Of course, the above-described embodiment of the present invention is merely an example for clearly explaining the present invention, and this does not limit the embodiment of the present invention. A person skilled in the art may make other changes or modifications based on the above description, and it is understood that it is not necessary to present all the embodiments one by one here. All obvious changes or modifications derived from the technical solutions of the present invention fall within the protection scope of the present invention.

10: transfer mechanism
20: ignition device
30: reaction control device
40: air box
50: air duct
60: fan
70: sintering material

Claims (15)

igniting the sintering material (S10);
spraying a reducing medium to the ignited sintered material to react the reducing medium with an oxidizing agent around the sintered material (S20);
A method for denitrification of sintered flue gas comprising a. The method of claim 1,
The reduction medium comprises a reducing agent that reacts with oxygen around the sintered material. The method of claim 1,
The reducing agent is a denitration treatment method, characterized in that it reacts with the gas generated by the combustion of the sintered material. 4. The method of claim 3,
The reducing agent is a denitration treatment method, characterized in that the reduction reaction with nitrogen oxides generated by the combustion of the sintered material. 3. The method of claim 2,
The reducing agent is a denitrification treatment method, characterized in that it includes a combustible material. 3. The method of claim 2,
The reducing agent is methane, propane, acetylene, hydrogen, methanol, ethanol, coal gas, natural gas, gasoline, heavy oil, powdered coal, charcoal, coke, sawdust, hydrogen sulfide, hydrogen cyanide, phosgene, N-butane, N-hexane, N- Heptane, N-pentane, propanol, methyl ethyl ketone, vinyl acetate, silane, cyclohexane, hydrogen chloride, butyne, liquefied gas, petroleum gas, ethyl ether, toluene, benzene, acetone, allylene, ethylene, propylene, butene, butane, A method for denitration treatment comprising at least one material in the coal water slurry. 3. The method of claim 2,
The reducing agent denitrification treatment method, characterized in that it further comprises water or water vapor. 3. The method of claim 2,
The reduction medium further comprises a supporting agent,
The denitration treatment method, characterized in that the supporting agent comprises at least one of oxygen, air, or circulating exhaust gas. The conveying mechanism 10 which conveys the sintering material 70;
An ignition device 20 that is installed to correspond to the conveying mechanism 10 and ignites the sintered material; and
a reaction control device 30 installed to correspond to the conveying mechanism, located downstream of the ignition device 20 in the conveying direction of the sintered material 70, and adding a reducing medium to the ignited sintered material 70;
A device for denitration of sintered flue gas comprising a. 10. The method of claim 9,
The ignition device (20) is a denitration treatment device, characterized in that installed above the transfer mechanism (10). 10. The method of claim 9,
The reaction control device (30) is disposed above the transfer mechanism (10), the denitration treatment apparatus, characterized in that it comprises a feeder provided with a control valve for controlling the amount of the reducing medium to be added. 10. The method of claim 9,
The reaction control device (30) is disposed above the transfer mechanism (10), the denitration treatment apparatus, characterized in that it comprises a pipeline equipped with a control valve for controlling the amount of the reducing medium added. 10. The method of claim 9,
The denitrification treatment device,
Doedoe installed in the lower portion of the transport mechanism 10, the air box 40 for collecting the flue gas after the sintered material is burned; and
an air duct 50 communicating with the air box 40 and having a fan 60 therein;
Denitration treatment apparatus further comprising a. 10. The method of claim 9,
The conveying mechanism 10 comprises a conveying trolley,
Denitration treatment apparatus, characterized in that a plurality of the conveying trolley is sequentially connected in the conveying direction of the sintered material (70). 14. The method of claim 13,
The air box 40 is provided in plurality, and the plurality of air boxes 40 are spaced apart from each other.

Images