RU158820U1 - Gas oil burner - Google Patents

Abstract

1. Gas-oil burner, comprising a housing with a nozzle for supplying air, connected to an embrasure of the burner installed in the hole of the furnace, a mixing chamber, a pipe with a nozzle for supplying air when the burner is operating on fuel oil, located along the axis of the housing, an insert fixed to the outer surface of the pipe with the possibility of rotation and intended for the formation of pinch on the air path, a peripheral annular manifold with a nozzle and gas-distributing holes located in the pinch zone of the air path, a fuel oil nozzle installed inside the pipe, the spray part of which is located in the embrasure of the burner, characterized in that the nozzle is mounted with the possibility of axial movement relative to the embrasure of the burner to its outlet. 2. A gas-oil burner according to claim 1, characterized in that it is equipped with a channel with a shutter located at the base of the embrasure and an opening in the base of the embrasure for supplying recirculating flue gases.

Description

The utility model relates to the field of energy, in particular to devices for burning liquid and gaseous fuels, and can be used in fire engineering devices for various purposes.

Known gas-oil burner designed to burn gaseous and liquid fuels [patent No. 1525404, IPC F23EM 17/00 (2006/01). Oil-gas burner / V.A. Galitskaya. R.A. Zakirov, V.P. Stelmakov (RF). - No. 4392350 / 24-06; Declared 16.03.88., Publ. 11/30/89, Bull. No. 44 - 2 s. 2 ill.]. The burner contains a housing with a nozzle for supplying air, connected to the embrasure of the burner installed in the furnace opening, a mixing chamber, a pipe with a nozzle for supplying air during operation of the burner on fuel oil, located along the axis of the housing, an insert fixed to the outside of the pipe and can be rotated and intended for the formation of pinch on the air path, a fuel oil nozzle mounted inside the pipe so that its spray part is located in the mixing chamber, a peripheral annular manifold with a pipe and gas-distributing holes located in the pinch zone of the air path.

Gas-oil burner operates as follows. In the first case, when the burner is running on gas, air is supplied to the mixing chamber from the air supply pipe in the form of an annular flow. When the air stream reaches the insert, it is preloaded, as a result of which its feed rate increases. At the same time, the gas enters the manifold through the nozzle and, distributed through the gas-distributing holes, flows out of them in the form of transverse jets into a high-speed air stream, an intensive mass exchange of air and gas takes place in the mixing chamber, and due to the rotation of the insert carried out by means of a traction, the determining size changes flow. Further, the resulting gas-air mixture enters the embrasure of the burner, where it begins to ignite and burn.

In the second case, when the burner is operated on gas and fuel oil, air is supplied from the air supply pipe to the mixing chamber in the form of an annular flow. When the air stream reaches the insert, it is preloaded, as a result of which its feed rate increases. At the same time, the gas enters the manifold through the nozzle and, distributed through the gas-distributing holes, flows out of them in the form of transverse jets into a high-speed air flow, and an intensive mass exchange of air and gas occurs. Then, fuel oil enters the mixing chamber through the spraying part of the fuel oil nozzle, and air enters through the pipe in the pipe for intensive atomization of the fuel oil. Intensive mass transfer of air, gas and fuel oil takes place in the mixing chamber, after which the mixture enters the burner embrasure, where it ignites and burns.

The advantage of the burner is that it improves the quality of fuel combustion due to the intensive mass transfer of air and gas.

The disadvantage of the burner is that the resulting gas-oil mixture is heterogeneous and has a low quality. This is due to the fact that when spraying fuel oil in the mixing chamber, the gas-distributing holes are clogged by unburned atomized particles of fuel oil. As a result, the supply of gas is hindered, and thus an insufficient amount of gas leads to a decrease in the quality of the resulting gas-oil mixture, which leads to the difficulty of joint simultaneous combustion of gas and fuel oil.

The closest in technical essence and the achieved result is a gas-oil burner [patent No. 139470 IPC F23D 17/00 (2006.01). Gas-oil burner (V.D. Katin, A.Yu. Berezutsky (RF). - No. 2013149014/06; Declared November 1, 2013. Published on 04/20/2014, Bull. No. 11-2 pp., 1 ill.]. Burner contains a housing with a pipe for supplying air, connected to an embrasure of the burner installed in the furnace opening, a mixing chamber, a pipe with a pipe for supplying air during operation of the burner on fuel oil, located along the axis of the housing, a fuel oil nozzle mounted inside the pipe, an insert fixed to the outer surface of the pipe with the possibility of rotation and intended for the formation of pinch on the air duct, peri The serial annular collector pipe and gazorazdayuschimi holes located in the pinch zone of an air path, wherein a part of fuel oil spray nozzle located in the embrasure.

Gas-oil burner operates as follows.

In the first case, when the burner is running on gas, air from the nozzle enters in the form of an annular flow into the housing. When the insert air stream is reached, it is preloaded, as a result of which its feed rate increases. At the same time, the gas enters the annular manifold through the nozzle and is evenly distributed through the gas-distributing openings and flows out of them through a system of transverse jets into a high-speed air stream. Intensive mass exchange of air and gas takes place in the mixing chamber and due to the rotation of the insert, which is carried out by means of a thrust, a change in the determining size of the flow is ensured. Further, the resulting gas-air mixture enters the burner embrasure, where its ignition begins.

In the second case, when the burner is running on gas and fuel oil, air is supplied in the form of an annular flow from the pipe for supplying air to the mixing chamber. When the air stream reaches the insert, it is preloaded, as a result of which its feed rate increases. At the same time, the gas enters the manifold through the nozzle and, distributed through the gas-distributing holes, flows out of them in the form of transverse jets into a high-speed air flow, and an intensive mass exchange of air and gas occurs. Then the mixture of air and gas enters the burner embrasure. At the same time, fuel oil enters the burner port through the spraying part of the fuel oil nozzle, and air enters through the pipe in the pipe for intensive atomization of the fuel oil. Intensive mass exchange of air, gas and fuel oil takes place in the embrasure, after which ignition of a mixture of air, gas and fuel oil begins.

The advantage of a gas-oil burner is the effective joint combustion of gas and fuel oil in the burner. This is due to the fact that when the burner is running on gas and fuel oil, the gas through the pipe enters the manifold and, distributed through the gas distribution holes located in the mixing chamber, flows in the form of transverse jets into the high-speed air flow, and the sprayer part of the nozzle is located in the burner embrasure, thereby eliminating the proximity of the location of the spraying part of the nozzle from the gas-distributing holes and clogging them with nebulized particles of fuel oil.

The disadvantage of the burner is the increased release of toxic nitrogen oxides during the combined combustion of gas and fuel oil due to the stationary location of the spraying part of the fuel oil nozzle at the base of the embrasure. It is known that the yield of thermal nitrogen oxides during combustion is determined by the maximum flame temperature that occurs in this case. The flare core formed when burning fuel oil has a high temperature, which leads to an increased emission of nitrogen oxides.

The objective of the utility model is to create a gas-oil burner that improves the environmental efficiency of co-burning gas and fuel oil in the burner by reducing nitrogen oxide emissions.

To solve the problem in a gas-oil burner containing a housing with a nozzle for supplying air, connected to the loophole of the burner installed in the furnace opening, a mixing chamber, a pipe with a nozzle for supplying air when the burner is operated on fuel oil, located along the axis of the housing, an insert fixed to the outer surface of the pipe with the possibility of rotation and intended for the formation of pinch on the air path, a peripheral annular manifold with a pipe and gas distribution holes located in the pinch zone airway, a fuel oil nozzle installed inside the pipe, the spray part of which is located in the embrasure of the burner, the nozzle is mounted with the possibility of axial movement relative to the embrasure of the burner to its outlet, an additional channel with a shutter for supplying recirculated flue gases is located, located in front of the embrasure of the burner and an opening in the base embrasures for recirculation of flue gases into the embrasure of the burner.

Signs that distinguish the claimed solution from the known one are the installation of the nozzle with the possibility of axial movement relative to the embrasure of the burner to its exit, additional supply of the burner with a channel with a shutter for supplying recirculating flue gases, located in front of the embrasure of the burner and making an opening in the base at the base of the embrasure.

Thanks to the distinguishing features, emissions of highly toxic nitrogen oxides are significantly reduced during the joint combustion of gas and fuel oil in the burner. This is due to the fact that when the burner is running on gas and fuel oil, the gas through the pipe enters the manifold and, distributed through the gas distribution holes located in the mixing chamber, flows in the form of transverse jets into a high-speed air stream, the spraying part of the nozzle moves to the outlet of the embrasure. This leads to the movement of the torch core into the furnace of the furnace (boiler), in which the heat sink from the torch is several times greater than in the embrasure itself. In turn, this leads to a decrease in the maximum temperature and a decrease in the formation of thermal nitrogen oxides. In addition, the proposed burner provides for the supply of recirculating flue gases through a channel with a damper into the hole located at the base of the embrasure of the burner, which further reduces emissions of highly toxic nitrogen oxides.

The proposed solution is illustrated in the drawing, which shows a gas-oil burner.

The gas-oil burner contains a housing 1 with a nozzle for supplying air 2, connected to an embrasure of the burner 3 installed in the furnace opening, a mixing chamber 4, a pipe with a nozzle 5 for supplying air when the burner is operating on fuel oil, located along the axis of the housing 1, insert 6, fixed on the outer surface of the pipe 5 with the possibility of rotation and intended for the formation of pinch on the air path, the peripheral annular collector 7 with pipe 8 and gas-distributing holes 9 located in the pinch zone of the air path, oil nozzle 10 mounted inside the pipe 5.

The spraying part of the fuel oil nozzle 10 is installed with the possibility of axial movement relative to the embrasure 3 of the burner to its outlet using the adjusting mechanism, which is a screw-nut connection 11 and located on the pipe 5 and nozzle 10. The burner is equipped with a channel 12 with a shutter 13 through which into the hole 14, made at the base of the embrasure 3, feed recirculating gases to the combustion zone of gas and fuel oil.

Gas-oil burner operates as follows. In the first case, when the burner is running on gas, the air from the nozzle 2 enters in the form of an annular flow into the housing 1. When the air flow of the insert 6 is reached, it is compressed, as a result of which its feed rate increases. At the same time, gas through the pipe 8 enters the annular manifold 7 and evenly distributed through the gas-distributing holes 9, flows out of them by a system of transverse jets into the high-speed air stream. Intensive mass transfer of air and gas takes place in the mixing chamber 4 and due to the rotation of the insert 6, which is carried out by means of a thrust, a change in the determining size of the flow is ensured. Next, the resulting gas-air mixture enters the embrasure 3 of the burner, where it begins to ignite and burn.

In the second case, when the burner is operated on gas and fuel oil, air is supplied in the form of an annular flow into the mixing chamber 4 from the pipe 2 for supplying air. When the air stream reaches insert 6, it is preloaded, as a result of which its feed rate increases. At the same time, the gas through the pipe 8 enters the collector 7 and, distributed through the gas-distributing holes 9, flows out of them in the form of transverse jets into a high-speed air stream, and intensive mass transfer of air and gas occurs. Then the mixture of air and gas enters the burner embrasure. At the same time, fuel oil enters the embrasure 3 of the burner through the spraying part of the fuel oil nozzle 10, and air enters through the nozzle in the pipe 5 to intensively spray the fuel oil. Due to the axial movement of the spraying part of the nozzle 10 to the outlet of the burner embrasure using the adjusting mechanism 11 located on the pipe 5 and the nozzle 10, the combustion zone, i.e. the core of the torch also moves into the furnace of the furnace (boiler), in which the heat sink from the torch is much higher than in the embrasure itself, which leads to a decrease in the yield of nitrogen oxides. To further reduce the emissions of highly toxic nitrogen oxides during gas and fuel oil combustion, recirculating flue gases are supplied through a channel 12 with a shutter 13 to a hole 14 at the base of the embrasure 3. Thus, in contrast to the prototype, emissions of highly toxic nitrogen oxides are significantly reduced when gas and liquid are combined fuel burner.

Claims (2)

1. Gas-oil burner, comprising a housing with a nozzle for supplying air, connected to an embrasure of the burner installed in the hole of the furnace, a mixing chamber, a pipe with a nozzle for supplying air when the burner is operating on fuel oil, located along the axis of the housing, an insert fixed to the outer surface of the pipe with the possibility of rotation and intended for the formation of pinch on the air path, a peripheral annular manifold with a nozzle and gas-distributing holes located in the pinch zone of the air path, a fuel oil nozzle installed inside the pipe, the spray part of which is located in the embrasure of the burner, characterized in that the nozzle is mounted with the possibility of axial movement relative to the embrasure of the burner to its outlet. 2. Gas-oil burner according to claim 1, characterized in that it is equipped with a channel with a shutter located at the base of the embrasure and an opening in the base of the embrasure for supplying recirculating flue gases.

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