RU2520136C1 - Flare facility for combustion of waste gas - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: flare facility for combustion of waste gas, in the pipe of which at least one burner device is installed, which contains a combustion chamber, a cone with air inlet openings, in which ignition of waste gas is performed, an electric gas burner, a casing with an air supply branch pipe connected to a branch pipe of the combustion chamber for tangential air supply to it, and ribs for air cooling of the combustion chamber.

EFFECT: high degree of combustion of gaseous hydrocarbons, hydrogen sulphide and other gases.

3 dwg

Description

The invention relates to a device for the combustion of combustible gases, hydrocarbons, hydrogen sulfide and other gases in flare plants of gas refineries, oil refineries, gas fields and oil fields, steam generators, gas heaters, air heaters and other installations.

Known burner devices of flare plants of high and low pressure, designed for the combustion of gas discharges from equipment. For example, the Astrakhan gas processing plant has a flare farm consisting of two flare systems: two high-pressure systems that are designed to receive gas discharges from equipment at a design pressure higher than or equal to 16 kg / cm ² . Two low pressures that are designed to receive gas discharges from equipment with a design pressure below 16 kg / cm ² . A disadvantage of the known burner devices of flare plants is the absence of combustion chambers with the proper organization of the combustion process of gaseous hydrocarbons and hydrogen sulfide. Secondly, due to a change in gas pressure in gas burners, incomplete combustion of gaseous hydrocarbons and hydrogen sulfide is observed, and in some cases the torch detaches from the burners, due to the fact that the speed of the gas jets leaving the burners becomes greater than the rate of combustion, which leads to increased emissions of pollutants into the atmosphere / cm. K.A. Gilzin ″ Air-Jet Engines ″, Military Publishing, M., 1956, p.149 /. At the same time, the known torch burner devices are the closest prototype analogues, since they contain features that match those of the claimed invention, in particular:

- high and low pressure systems for gas discharges from equipment,

- pipes of torch burner devices.

A disadvantage of the known torch burner devices is the low degree of combustion of exhaust gases from the equipment, and therefore, the proposed torch burner devices use combustion chambers with cones and electric gas burners in the torch burner devices located in the pipes of high and low pressure gas discharge systems from equipment for the implementation of a high degree of combustion of gaseous hydrocarbons, hydrogen sulfide and other gases.

The above set of essential features during implementation ensures the achievement of the goal, while each of this set of characteristics is necessary, and all together are sufficient to obtain a positive effect, the implementation of a high degree of combustion of gaseous hydrocarbons, hydrogen sulfide and other gases. Based on the above arguments, the conclusion that the claimed technical solution meets the criteria of the invention is ″ inventive step ″.

The given set of essential features can be implemented many times in practice with the same goal. The repeated possibility of implementing / in the manufacture of the claimed technical solution with the above set of essential features also fully meets another main criterion of the invention - ″ industrial applicability ″.

The essence of the technical solution is illustrated by drawings, in which:

- figure 1 shows the burner device / circuit / in longitudinal section,

- figure 2 shows the placement of combustion chambers with electric gas burners in the pipe of the flare unit - longitudinal section,

- figure 3 in longitudinal section shows an electric gas burner.

The torch burner device consists of a combustion chamber 1 having a cone 2 with windows 3 for air inlet and an electric-gas burner 4. A pipe 5 for low-pressure air inlet is connected to the casing 6 and communicates with the pipe 7 of the combustion chamber for tangential air supply to combustion chamber.

Figure 2 shows the installation of the combustion chambers 1 in the pipe 8 of the flare unit, in which several combustion chambers can be placed. In this design, atmospheric air is supplied to the combustion chambers separately through the nozzles 9 and through the windows 10. The fins 11 for air cooling of the combustion chambers.

Figure 3 shows an electric-gas burner 4, which is identical in design and operation to plasma torches / cm. B.A. Artamonov ″ Electrophysical and electrochemical methods of processing materials ″, v.2, Higher School, 1983, pp. 69-90 [1] /. It consists of a housing 12, a cover 13, an anode-nozzle 14, made in the plate 15. Electrical insulating gasket 16. A pointed cathode rod 17 is installed inside the housing and cover, separated from the walls by means of an insulating material 18. The pipe 19 serves to enter the exhaust gas gas burner, which are plasma-forming, containing hydrogen sulfide, carbon dioxide, sulfur dioxide, methane and others. It is installed at an angle and offset relative to the axis of the housing for a tangential gas supply. For air cooling of the burner, it is equipped with ribs 20, 21 and 22. The electric-gas burner is connected to a constant current source 23.

The burner device of the flare unit provides reception and combustion of gas discharges from the equipment of gas processing, oil refineries, gas fields and oil fields with a design pressure above or below 16 kg / cm ² . In the pipe 8 creates an upward flow of atmospheric air from the blower located on the surface of the earth / not shown in the drawing /.

Works torch device flare installation as follows. The blower is turned on to supply atmospheric air to the burner. Then, under pressure, waste gas is supplied through the nozzles 19 of the electric-gas burners and the direct current source 23 is turned on. The gas is heated to a high temperature in electric-gas burners by an arc discharge between the cathode 17 and the anode-nozzle 14, which enters in the form of a plasma jet with a temperature of about 3500 ° С in the cone / sa / 2, where, when combined with air, it partially oxidizes and burns with increasing temperature. In this case, the exhaust gas can completely burn out in the cone / ax / 2, if the gas pressure is low and a small flow rate of air flowing through the cone / ca / may be enough to burn all the exhaust gas. At high pressures, this zone serves only as the space within which gas is ignited. A torch exiting the cone is flung into the space of combustion chamber 1, where there is the least pressure, and such places are located at the axes of two vortices formed by the eye flow of air due to helical motion, similar to that obtained when turning in the knee. With the proper ratio of the diameters of the supply pipe 5, 7 and chamber 1, a double vortex is formed, which contributes to the proper organization of the combustion process. A satisfactory air flow can be obtained with a nozzle diameter of 7 equal to about 0.6 of the diameter of the chamber / cm Kirillov ″ Gas turbines and gas turbine units ″, t.2, Mashgiz, M., 1956, pp. 79-80 [2] /. Only part of the air that flows near the axis of the vortices takes part in the combustion, and relatively cold air remains in the outer layers washing the wall of the combustion chamber. Particles of a dying waste gas, falling into rotating air, tend to move to the outer layers of the air, where they find enough oxygen for combustion.

Therefore, as the pressure of the exhaust gas increases, the cross section of the torch automatically increases and captures wider layers of vortices, with a high degree of gas combustion, which ensures a clean exhaust from the flare unit pipe 8 with complete combustion of gases, including hydrogen sulfide, which, as you know very toxic / cm. N.L. Glinka ″ General Chemistry ″, publishing house ″ CHEMISTRY ″, L., 1980, pp. 383-387 [3] /.

Burning in the space of the cone and the chamber / ah / 1 occurs with a slight excess of air, since in the combustion zone there is no intensive mixing of cold air. Therefore, it is possible to operate the torch burner in a wide range of loads, i.e. waste gas pressure, the lower limit of which can reach 1/20 of full load / cm. 2, p. 80 /. The material of the combustion chambers 1 with cones 2 is the first of chromium-nickel steel, the second of high-chromium steel or other materials.

Thus, the implementation of the burner device of the flare installation with combustion chambers having a cone, with a tangential supply of atmospheric air / corner / s / chamber / s / combustion, ensures the correct organization of the combustion process of the waste gas and its high degree of combustion. At the same time, dissociation-association reactions contribute to the achievement of a high degree of combustion of waste gases. In an arc column, molecules dissociate according to the following schemes:

H ₂ = + 431.57 kJ / mol; H ₂ +942.75 kJ / mol; About ₂ +502.80 kJ / mol and others / cm. 1, p. 71 /. In this case, additional absorption of heat occurs during thermal dissociation of all gases included in the composition of the waste gas, including sulfur sulfide.

The dissociation products formed in the column of the arc discharge exit the anode nozzle 14 of the electric gas burner / ok / into the cone / sa / 2 with high speed and mix with air oxygen, while the plasma-forming gas associates / is converted from atomic to molecular /; at the same time, the heat expended on its dissociation is released, which heats the air, which contributes to the normal combustion process with a slight excess of air.

At the same time, due to thermal dissociation and ionization in the volume of the plasma jet along its entire length, the gas-air mixture reacts at tremendous speeds without delaying ignition, which ensures a high degree of combustion of the exhaust gas, including hydrogen sulfide and hydrocarbons / cm. A.S. Khachiyan ″ Internal combustion engines ″, Higher School, M., 1978, p. 68 [4] /. The device of the guide vanes 24 contributes to the rotation of the incoming air in the cone / s / 2 of the burner device of FIG. 2, mixing it with the plasma / s / stream / s /, the formation of a combustible mixture and its combustion, while the plasma jet / and / simultaneously plays the role burning igniter of a combustible mixture.

Thus, the use of combustion chambers 1 with cones 2 and electric gas burners 4, in which the plasma-forming gas is the gases coming from the discharge of gas processing, oil refining plants, gas fields and oil fields in one burner device of the flare unit provides a high degree of combustion of these gases, including hydrogen sulfide. Note that electric-gas burners can also be performed by cooling their walls with water, with the device of the shirts and the supply of water under pressure from the pump.

In connection with a change in the pressure of the gases supplied during the discharge from the equipment, the DC source 23 is additionally equipped with a device for changing the current strength, for example, a rheostat controlled by an electronic flare system / not shown in the drawing /. However, it is unacceptable to further heat the atmosphere and thereby further pollute the air with flames of burning gases. Their use now and in the future is thoughtless, unjustifiable waste of the planet's resources. Therefore, when discharging gases from equipment with a pressure above or below 16 kg / cm ^2, it is necessary, firstly, to use the potential energy of pressure of these gases on turbine expanders to produce useful electric energy of a sufficiently high power, and, secondly, the gases exhausted in them with low pressure are sent for combustion to the steam generators using the burner devices of FIG. 1, which provide a high degree of combustion of exhaust gases, including hydrogen sulfide, while the combustion products are released into the atmosphere with a low temperature without harming her. The received electric energy and steam energy is used for internal needs of the plant, oil or gas fields, and if there is no need for steam, it is converted into electric energy sent by wires to other energy consumers in steam turbine units with electric generators. When using the potential energy of gas pressure, they must be heated to a temperature of 70 ° C in gas heaters by entering a gas into the burner device of Fig. 1 before entering turbo expanders (s), while its temperature decreases to normal by expanding the heated gas in the turbine expander 18 -20 ° C, not lower than zero degrees.

In some cases, the torch burner can be operated with electric gas burners alone, in which the high temperature of the plasma (s) / jet (s) along the entire length, which can exceed 0, contributes to a high degree of combustion of gaseous hydrocarbons and hydrogen sulfide. 4 meters / cm. 1, p. 76-77 /. In this case, the length of the plasma jet / d / depends on the magnitude of the current strength.

However, this significantly increases the cost of electricity, especially when discharging gases from equipment with high pressure exceeding 16 kg / cm ² . Therefore, in order to reduce power consumption, it is advisable to carry out the burner device of the flare unit with combustion chambers having cones and electric-gas burners, while the plasma-forming gas in the arc discharge is heated to a temperature of about 3500 ° C, which is specified during the test of the burner device.

Technical and economic part

The new torch burner (s) / installation / ok / has a number of significant advantages over conventional burner devices.

Firstly, a high degree of combustion of gases discharged from the equipment of gas refineries, oil refineries, gas fields and oil fields, including hydrogen sulfide and hydrocarbons, is provided.

Secondly, burners with electric-gas burners can be used in steam generators when burning gases in the furnaces of boilers with an admixture of hydrogen sulfide, providing a high degree of combustion of gaseous hydrocarbons and hydrogen sulfide.

Thus, atmospheric pollution is significantly reduced, the amount of greenhouse gases and at the same time poisonous H ₂ in the air is reduced.

Claims (1)

Flare installation for burning exhaust gases, in the pipe of which at least one burner device is installed, containing a combustion chamber, a cone with windows for air inlet, in which ignition of the exhaust gas is carried out, an electric gas burner, a casing with an air supply pipe connected to the pipe combustion chambers for tangential supply of air into it, fins for air cooling of the combustion chamber.

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