SU1488665A1 - Device for afterburning waste gas - Google Patents

Description

The invention relates to environmental protection and can be used in the oil, petrochemical, engineering industry and other areas of the national economy for the disposal of waste gases with unstable flow. The aim of the invention is to increase the cleaning efficiency and increase A-A

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device life due to increased gas turbulization in the combustion chamber. On burner stones and under them additional nozzles 9 are made for supplying waste gases, the total area of the flow section of which is equal to the total area of the flow section of the main nozzles 8. Additional nozzles 9 are made in the center of the upper and lower planes of the burning stones parallel to the axes of the burners. Such an implementation of additional nozzles allows to improve the displacement, of hot and cold gases, to cool the burner stone, the burner tunnel and the inside of the device below the additional nozzles. As a result, the burnout of the toxic components of waste gases increases and the life of the device increases. 1 hp f-ly, 2 ill.

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The invention relates to the Protection of the environment and can be used in the oil, petrochemical, chemical, engineering industry and other sectors of the economy for the disposal of waste gases with unstable flow.

The purpose of the invention is to increase the cleaning efficiency and increase the service life of the device due to the increased turbulization of gases in the combustion chamber.

Figure 1 presents a device for the afterburning of waste gases, top view; figure 2 is the same longitudinal section.

The device for afterburning of waste gases consists of a heat-insulated body 1, burner 2, burner stone 3, burner tunnel 4, common gas pipeline 5 of waste gas, main 6 and additional 7 branch pipes, main nozzles 8, the total flow areas of which are calculated at 50% of the maximum discharge flow gas, additional nozzles 9 of waste gas, regulating the throttling system 10 and the flue gas duct 11.

The device works as follows.

The waste gas from the common pipeline 5 enters the main 6 and an additional 7 branch pipes. From the additional nozzle 7, the waste gas flows through the additional nozzles 9 into the burner tunnel 4.

Due to the installation of additional nozzles 9 of waste gas under the burner stone 3 and parallel to the burner axes, waste gases pass above and below the burner stone 3, they intensively cool it, the burner tunnel 4 and the inside of the device below the additional nozzles 9. The direction of movement of the waste gases coincides with the direction of the torch of the fuel gas. Gas flows expand, merge and mix. The proximity and dispersion of the nozzle of the waste gas to the flare also enhances the mixing of hot and cold gases, resulting in an increase in the burnout of toxic components of the discharge gas and the service life of the device for the afterburning of the waste gases.

Then the gases rise and mix with the waste gases released from the main nozzles, tangentially installed to the device body, which greatly enhances the spin, turbulization and mixing of gases.

Such an implementation of additional nozzles 9 with a total flow area equal to the total flow area of the main nozzles 8 allows the regulating choke 10 to maintain the maximum pressure before the main nozzles at a flow rate of 50% of the maximum flow. At a flow rate of more than 50% of the maximum flow rate, the waste gas begins to flow into the additional nozzles, and the pressure ahead of the main nozzles remains maximum and constant. In this case, the pressure of the waste gas in the main pipe and the velocity of the gas coming out of the main nozzles, with a change in the flow rate are much larger maximum constant values. Accordingly, maximum turbulization and intensive mixing of cold and hot gases are observed. The temperature in the device is lower than the level of the main nozzles and in the burner tunnel, even with an increase in load, it rises only to 50% of the maximum flow rate, and with an increase in the discharge gas flow rate of more than 50% of the maximum flow rate, the temperature starts to decrease, and at the maximum flow rate of the discharge gas, how the heat gain is needed only for the disposal of waste gases supplied to the additional nozzles, and ¹ neutralized waste gases fed to the burner tunnel are mixed with the top combustion products while reducing the temperature of the torch. The device significantly reduces overheating of the walls, as a result of which the service life of the device for the afterburning of waste gases and the burnout of toxic impurities of waste gases increase.

Exhaust gases through the flue 11 are removed from the device.

The implementation of the device for afterburning of waste gases will increase

complete afterburning due to intense turbulence and heat and mass transfer

in the device, which will enable

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reduce fuel consumption per process

neutralization.

Claims (2)

Claim 1. Device for afterburning of waste gases, containing a heat-insulated body, a vertical chamber, burners, nozzles for supplying waste gas and a flue exhaust channel, characterized in that, in order to increase the cleaning efficiency and increase the service life of the device by increasing the turbulization of gases in the combustion chamber, above and below them, additional discharge nozzles of discharge hectares are made, for the total area of the flow area of which is equal to the total area of the flow area of the main nozzles. I o 2. The device according to claim 1, of which is that the additional nozzles are made in the center of the upper and lower planes of the burner stones, in which the burner devices are installed, parallel to the axes of the burners.