UA120283C2 - DEVICE FOR CLEANING Flue GASES FROM SULFUR, NITROGEN AND CARBON OXIDES - Google Patents

Abstract

The invention is intended for use in industries where the combustion of solid or liquid fuels is used. The device includes a supercharger connected to the first mixing chamber, which is connected to the first confuser of the first heat exchanger-ejector (TOE), and through the flue gas supply pipe - to the environment. The first TOE comprises a series-connected first confuser, inside which at the outlet is a nozzle of the first irrigation device connected to the tank for the refrigerant, and the first diffuser. The output of the first diffuser of the first TOE is connected to the second confuser of the second TOE. The second TOE contains a series-connected second confuser, inside which is the outlet of the nozzle of the second irrigation device, combined with a water tank, a second mixing chamber and a second diffuser. The outlet of the second mixing chamber of the second TOE is connected to a corresponding second diffuser connected to the separator of the liquid from the flue gases. The claimed device improves the quality of flue gas cleaning from pollutants and reduces energy costs.

Description

The invention relates to devices for cleaning flue gases from sulfur, nitrogen, and carbon oxides, and is intended for use in various industries, for example, energy, chemical, metallurgical, etc., where solid or liquid fuel combustion is used.

The content of sulfur, nitrogen, and carbon oxides in the outgoing flue gases, which are formed during the burning of solid or liquid fuel, is a serious environmental threat. For example, such chemical compounds as sulfur dioxide 50" and sulfur dioxide 5Oz, nitrogen oxides MO, carbon oxides

Co", when combined in the atmosphere with water vapor, form acids Na5Oz, Na25O", NMO»Zz,

NMO", NgSoOz, which cause a harmful effect on human health, lead to the death of forests and fruit trees, and a decrease in the yield of agricultural crops.

The closest to the claimed technical solution is a contact device for cleaning waste gases from sulfur dioxide and dust (see patent of Ukraine for a utility model Mo 51948, publ. 10.08.2010, bulletin Mo 15), which includes two stages of cleaning.

The first stage is a Venturi tube consisting of a baffle, an irrigation device, a rectangular pipe neck, the cross-section of which changes due to regulating plates, and a diffuser. The second stage is a shock-inertia device, which consists of an inlet nozzle, which is connected to a venturi tube, an impeller (located in the shock-inertia device), drop-absorbing plates, an outlet nozzle, an overflow hole and a hopper.

This device is selected as the closest analogue.

The claimed device and the device according to the closest analogue have the following common features: a cleaning unit, which includes a confusor, a mixing chamber (in the closest analogue - the neck of a pipe of a rectangular configuration, the cross-section of which changes due to regulating plates) and a diffuser; irrigation device located inside the confusor of the cleaning unit; liquid separator (the closest analogue is a shock-inertia device).

The disadvantages of the device of the closest analogue include the following: the liquid separator creates too high local resistances, which leads to an increase in pumping costs;

The operation of the device requires a constant supply of a large amount of water to separate the suspension from the gas flow.

The invention is based on the task of creating a device for cleaning flue gases from oxides of sulfur, nitrogen, carbon, in which, by replacing the cleaning unit (introduction of a heat exchanger-ejector) and introducing new units, the use of which will improve heat exchange and accelerate the reaction of the release of pollutants, to ensure an increase in quality cleaning and improving the energy efficiency of work.

The task is solved in a device for cleaning flue gases from sulfur, nitrogen and carbon oxides, which contains a cleaning unit, which includes a first confusor, a first mixing chamber and a diffuser, a first irrigation device located inside the cleaning unit, a flue gas supply nozzle and a liquid separator from flue gases, by the fact that it contains a supercharger, a pre-cooling unit, inside which the first irrigation device is located, and a second mixing chamber and a second irrigation device, while each irrigation device is a nozzle, as a pre-cooling unit, a first ejector heat exchanger containing the first confusor, inside of which the nozzle of the first irrigation device is located at the outlet, connected to the container for the cooling agent, and the first diffuser, the cleaning unit additionally contains the second heat exchanger-ejector and the second confusor, the nozzle of the second irrigation device is located at the outlet, connected to the water container , output to the compressor is connected to the first mixing chamber, which is connected to the environment and to the first confusor through the flue gas supply pipe, the first diffuser is connected to the second confusor, and the second diffuser is connected to the flue gas liquid separator.

A well-known device for cleaning flue gases from carcinogenic substances (see patent of Ukraine for utility model Mo 111416), in which a condensation ejector filter (CEF) containing a confusor, a mixing chamber and a diffuser is used as a node for mixing and heat exchange of flue gases. This device contains an interconnected supercharger, a unit for mixing and heat exchange of flue gases - KEF, nozzles for spraying refrigerant located inside the KEF, a collector of harmful fractions, a pipeline for the supply of the cleaning component, a reversible flow separator and a container for storing and supplying the refrigerant.

The output of the supercharger is connected to the KEF confusor, the diffuser of which is connected to the reversible flow separator, in the lower part of which a collector of harmful fractions is installed. The nozzles for spraying the refrigerant are located in the KEF mixing chamber and are connected by the refrigerant supply pipeline to the container for storing and supplying the refrigerant. The technical result is an increase in the degree of purification of flue gases from carcinogenic substances to 85...90 95.

The claimed device and the device according to the patent of Ukraine for utility model Mo 111416 have different operating modes (flow speeds, temperatures) using different working substances. Due to the fact that the pressure temperature in the claimed device is much higher than in the device according to the patent of Ukraine for utility model Mo 111416, this makes it possible to use lower speeds of the mixture flow. The device according to the patent of Ukraine for the utility model Mo 111416 is aimed at achieving another technical result, and does not solve the task - cleaning flue gases from sulfur, nitrogen and carbon oxides.

The claimed device is explained by a drawing where:

Fig. 1 - scheme of the device for cleaning flue gases from sulfur, nitrogen and carbon oxides;

Fig. 2 - graph of flue gas temperature dependence on consumption of liquid cooling agent (nitrogen).

The device for cleaning flue gases from sulfur, nitrogen and carbon oxides contains a blower 1, the first mixing chamber 2, a nozzle from the supply of flue gases to the first mixing chamber, the first heat exchanger-ejector (TOE) 4, a container for a cooling agent 5, a nozzle 6 of the first irrigation device, the second heat exchanger-ejector 7, water tank 8, the nozzle 9 of the second irrigation device and the separator of liquid from flue gases 10. The first heat exchanger-ejector 4 contains the first baffler 11 and the first diffuser 12. The second heat exchanger-ejector 7 contains the second baffler 13, the second mixing chamber 14 and the second diffuser 15.

At the same time, the output of the supercharger 1 is connected to the input of the first mixing chamber 2, which is connected to the first confusor 11 of the first TOE 4, which is connected to the first diffuser 12 of the first TOE 4, and through the flue gas supply nozzle 3 is connected to the environment. Inside the first confusor 11 at the outlet is the nozzle 6 of the first irrigation device, connected by a pipeline to the container for the cooling agent 5.

The output of the first diffuser 12 is connected to the second confusor 13 of the second TOE 7, the output of which is connected to the second mixing chamber 14. At the output of the second confusor 13 is located

From the nozzle 9 of the second irrigation device, connected through a pipeline to the water tank 8. The outlet of the second mixing chamber 14 is connected to the second diffuser 15 of the second TOE 7, which is connected to the liquid separator from flue gases 10.

The claimed device works as follows.

The flow of flue gases through the nozzle C is fed into the first mixing chamber 2, where the blower 1 also supplies air from the surrounding environment at a speed of 10...20 m/s. The mixing of ambient air with flue gases is carried out to oxidize the oxides of pollutants contained in the flue gases and reduce the temperature. The resulting mixture is fed at a speed of 10...15 m/s to the first confusor 11 of the first TOE 4, where it is accelerated to a speed of 60...70 m/s. A liquid cooling agent (for example, nitrogen) is injected into the flow through the nozzle 6 of the first irrigation device. As a result of contact with the finely dispersed cooling agent, instant mixing occurs with a decrease in the flow temperature to the temperature of the start of the pollutant release reaction. The cooled stream is fed to the second confusor 13 of the second TOE 7, where it is accelerated to 70...80 m/s, fed to the second mixing chamber 14, where water is injected into the stream through the nozzle 9 of the second irrigation device. When a stream of flue gas containing oxides of pollutants, for example 5Оз, СО», MO», comes into contact with finely dispersed water, a reaction occurs with the formation of acids, the molecules of which condense on microparticles of dust, forming nuclei: 5ЗОз--Н2О-Нео5ох, 2МО "2NhO-NMOzaNMO",

СО» nHgO-nNosO.

Next, the flow enters the liquid compartment 10, where the acid condensate is separated, and the flue gases are released into the environment.

The starting temperature of the hydration reaction (release of pollutants from flue gases) is 400...500 "C. Usually, the temperature of flue gases entering the cleaning device is 600...700 "C, i.e. much higher. Therefore, the claimed device provides cooling of flue gases before cleaning in the pre-cooling unit.

The consumption of liquid cooling agent, required to reduce the temperature of the flue gases from the initial to the required one, depending on the initial temperature and consumption of the flue gases, 60 can be determined using the equation:

in. sva"Sra"iasp"Srp" p st sah Sra- Sp" Srp

Ist is the temperature of the "flue gases - liquid cooling agent" mixture, "С; ba. consumption of liquid cooling agent, m/s;

Or. heat capacity of the liquid cooling agent, W/(kg-"С); ev. temperature of the liquid cooling agent, "С; ba. consumption of flue gases, mz/s;

Shit heat capacity of flue gases, W/(kg-"С); ev. temperature of flue gases, "С.

This greatly simplifies device setup and increases the energy efficiency of its operation.

For example, when using liquid nitrogen for cooling flue gases. According to the above equation, the consumption of liquid nitrogen, necessary for cooling flue gases at different consumption rates, was calculated. According to the results of the calculations, a graph of the dependence of the temperature of the "flue gases - liquid nitrogen" mixture on the consumption of liquid nitrogen was constructed (see Fig. 2): 1 - volume flow of flue gases 4.05 m/s; 2 - volumetric consumption of flue gases 5.248 m/s;

C - volume flow of flue gases 6.286 m/s; 4 - volumetric consumption of flue gases 7.662 m/s.

According to the resulting graph of dependence, the necessary temperature of the "flue gases - liquid nitrogen" mixture is selected, at which a reaction with the formation of acids will occur when the flow comes into contact with water, and the liquid nitrogen consumption necessary to achieve it is determined.

Such calculations can be carried out for different cooling agents.

The claimed device improves the quality of cleaning flue gases from pollutants and reduces energy costs.

Claims (1)

FORMULA OF THE INVENTION A device for cleaning flue gases from sulfur, nitrogen and carbon oxides, containing a cleaning unit, which includes a first confusor, a first mixing chamber and a diffuser, a first Zo irrigation device located inside the cleaning unit, a flue gas supply nozzle and a liquid separator from smoke gases, which is characterized by the fact that it contains a supercharger, a pre-cooling unit, inside which the first irrigation device is located, and a second mixing chamber and a second irrigation device, while each irrigation device is a nozzle, as a pre-cooling unit, a first ejector heat exchanger is used, which contains the first confusor, inside of which the nozzle of the first irrigation device is located at the outlet, connected to the container for the cooling agent, and the first diffuser, the cleaning unit additionally contains the second heat exchanger-ejector and the second confusor, the nozzle of the second irrigation device is located at the outlet, connected to the container for water , the output of the supercharger is connected to the first mixing chamber, which is connected to the environment and to the first confusor through the flue gas supply pipe, the first diffuser is connected to the second confusor, and the second diffuser is connected to the flue gas liquid separator.