SU1629695A1 - Waste gases reburning device - Google Patents

Abstract

The invention relates to environmental protection and can be used in 7, chemical, petrochemical and other fields of aryness. The purpose of the invention is to increase the fuel combustion efficiency by creating additional flue volume and increasing the degree of neutralization of toxic impurities by improving the mixing of the waste gases with the combustion products of the fuel. In the central part of the regenerative chamber 2, the clamp 4 is made in the form of a burner tunnel with an internal gas-permeable wall 5, the partitions of which are made tangentially to the device body. 2 Il. o th y os yu ate 10

Description

The invention relates to the field of environmental protection and can be used in the chemical, petrochemical, metallurgical and other industries.

The aim of the invention is to increase the completeness of fuel combustion by creating additional furnace volume and increasing the degree of neutralization of toxic impurities by improving the mixing of the waste gases with the combustion products of the fuel.

Figure 1 shows a device for the afterburning of waste gases; figure 2 - section aa in figure 1.

The device for afterburning of waste gases consists of a heat-insulated body 1, a regenerative chamber 2 with sections filled with a granular heat exchange nozzle (conventionally not shown), a burner 3 for burning fuel, pressing 4 with a gas-permeable wall 5 and partitions 6 made tangentially to the device body, the transfer device 7, the branch pipes 8 and 9 of the waste and neutralized gases and the inlet (outlet) gas pipeline 10.

The device works as follows.

Cold waste gases through the pipe 8 through the transfer device 7 and the inlet gas pipeline 10 enter the regenerative chamber 2 into one of the sections with a granular heat exchange nozzle, where they are heated by the heat accumulated by the nozzle in the previous period, after which the heated gases enter the high temperature zone. At the same time, through the burner 3, fuel is supplied, which is burned in the furnace volume formed by pinch 4. Products of complete combustion of fuel, rotating in the burner tunnel around the nozzle, through the gas-permeable wall 5 of clamp 4 enter it and advance to the center of the regenerative chamber, resulting in the contact area of the incoming gas flow of the combustion products of the fuel in the nozzle with the waste gas increases and the uniform distribution of the gas flow along the perimeter of the nozzle’s cross section improves, which contributes to velicheniyu completeness afterburning of the waste gases toxic impurities.

The partitions 6 of the gas-permeable wall 5, which are made tangentially to the device body, function as guides and help reduce the hydraulic resistance of the moving gas flow to the combustion products of the fuel.

Mixing with the combustion products of the fuel, the waste gases are heated to a predetermined disposal temperature, and the oxidation of toxic impurities occurs.

waste gases. Then the gases enter the downstream section with a granular heat exchanger nozzle, heat it, and then through the exhaust gas pipeline 10, the transfer device 7 and the nozzle 9 are released into the atmosphere. As the packed material is cooled in the first along the waste gases of the heat exchange section and the second heats up, the switching occurs after a certain period of time.

5, the transfer device 7, and the direction of movement of the gases change to the opposite.

Made in the central part of the regenerative chamber, the pinch in the form of a transfer tunnel with an internal gas-permeable wall reduces the flow area of the regenerative chamber, which improves the conditions for the movement of fuel to the center, and also creates a significant resistance to the movement of gases near the wall, which contributes to the distribution of waste gas to center of the chamber and significantly improves the mixing of high-temperature products

0 combustion of fuel coming out of the burning tunnel with waste gases, as a result of which the completeness of afterburning of toxic substances of waste gases is increased.

Efficient fuel combustion in a cyclone-type mountain tunnel is achieved by lengthening its design, i.e. the burner tunnel is made remote, which leads to cumbersome design and additional costs. In addition, on

The exit from the burner tunnel into the nozzle space creates significant resistance to the movement of combustible gases, which limits the power of the burner and increases their quantity.

5 In the proposed device, the burning time of the fuel is increased due to the additional volume of the burner tunnel made in the process of pressure. Due to the considerable resistance created by the nozzle, the combustion products of the fuel do not immediately fall into the regeneration channel, but after a certain time, this contributes to the complete burnout of combustible fuel components. still in the burner tunnel and

5 uniform distribution of the gas flow at the inlet to the nozzle of the regenerative chamber. In addition, due to the centrifugal force, the gas flow exiting the burner has a significant speed, moves along the outer wall of the tunnel and gradually displaces to the center, resulting in the residence time in the burner tunnel and the completeness of fuel combustion.

Improving the mixing of the combustion products of the fuel and the gases to be disinfected is accomplished by increasing the contact area at the exit of the flue gases from the burner tunnel. Combustion products, the exit from a pinch made in the form of a burner tunnel, cover the entire perimeter of the cross section of the chamber and, moving towards the center, are mixed with waste gas, most of which moves along the walls of the regenerative chamber and clamped.

The tangential arrangement of the burner devices and partitions of the gas-permeable wall of the pinch allows to reduce the resistance to the movement of the gas flow at the exit from the burner tunnel due to an increase in static pressure at the point of entry of the combustion products into the nozzle. The flow is fragmented into minute streams with low pulsation rates and small turbulence scales. In order to evenly mix the products of combustion of the fuel and the waste gas, it is advisable to first feed peripherally small streams. Made in the central part of the regenerative chamber, the clamp in the form of a burner tunnel with an internal gas-permeable wall meets these requirements.

The design of the device for the afterburning of waste gases eliminates the uneven distribution of the gas flow.

over the cross section of the regenerative chamber and produce an effective purification of waste gases. The presence of a pinch in the central part of the regenerative chamber, made in the form of a burner tunnel with a gas-permeable wall, ensures complete combustion of fuel and high-quality mixing of waste gases with products of combustion of fuel.

The use of a device for after-burning of exhaust gases will, by improving the completeness of fuel combustion and mixing the exhaust gas with fuel combustion products, accomplish the deactivation process at lower temperatures, which will entail a reduction in fuel consumption during the thermal decontamination process.

Claims (1)

Claims An afterburning device for exhaust gases comprising a heat-insulated casing, a regenerative chamber with a nozzle of granular refractory material, a burner, nozzles for inlet and outlet of gases, and a flip-flop, in order to increase the combustion efficiency by creating an additional furnace volume and increase the degree of neutralization of toxic impurities by improving the mixing of the waste gases with the combustion products of the fuel, in the central part of the regenerative chamber clamp in the form of a burner tunnel with an internal gas-permeable wall, the partitions of which are placed tangentially to the device body.