RU2378573C1 - Recuperative burner for gaseous fuel - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to heat engineering, can be used for burning of gaseous fuel during the process of heating of working space of industrial furnaces and other thermal aggregates. Technical result is achieved in recuperative burner for gaseous fuel, containing casing, located in casing with annular gap pipe of primary air, combustion chamber, heat exchanger, implemented of pipe bundle, provided for combustion materials, herewith pipes of heat exchanger pass through mounted between casing and pipe of primary air helical spiral for air direction, washing heat exchanger pipes.

EFFECT: increasing of air warming temperature and reduction of fuel consumption.

2 cl, 1 dwg

Description

The invention relates to heat engineering and can be used to burn gaseous fuel in the process of heating the working space of industrial furnaces and other thermal units.

Known regenerative burner for burning gaseous or liquid fuels (SU 1400519, publ. 1988) / 1 /. The burner comprises an air supply housing, a primary air pipe placed in the housing with an annular gap, a combustion chamber with an output nozzle connected to a fuel pipe connected to the fuel pipe. In the gap between the primary air pipe and around the combustion chamber, a shell is formed that forms the inner and outer annular cavities of the recuperator. The structural solution of the known burner is mainly aimed at reducing the formation of nitrogen oxides in the combustion products. Moreover, the design of the burner is ineffective from the point of view of using the heat of the combustion products of fuel, because to intensify heat transfer between the combustion products and the air supplied to the combustion, it uses a needle heat exchange surface of the primary air pipe. In this constructive embodiment, the use of needle surfaces for heat transfer intensification is ineffective, since with this method of intensification the heat transfer coefficients increase only significantly at Reynolds numbers above 5000 (see V.M. Antufiev. Efficiency of various forms of convective heating surfaces. - M. - L.: Energy, 1966, 184 pp. With the picture). In recuperative burners, with their relatively small sizes and low speeds of air and combustion products, it is problematic to provide Reynolds numbers in excess of 1000.

A more efficient means of intensifying heat transfer is the heat exchange unit, which is equipped with a regenerative burner (SU 1684570, publ. 1991) / 2 /. Known burner contains placed in a ceramic block coaxially installed fuel pipe, air pipe and heat transfer unit with annular gaps between them. The heat exchange unit is made in the form of chimneys and air pipes fastened together, installed in a checkerboard pattern and equipped with holes located in the cavities between adjacent pipes. The holes in the air pipes are facing the axis of the burner, and in the chimneys - to the periphery of the ceramic block.

The air supplied for combustion through the openings of the pipes in the form of a system of jets is directed to the outer surface of the inner row of chimneys. Washing their surface in the transverse direction, the air enters the inner annulus and, moving in the direction of the outlet nozzle of the burner, flows through the holes into the cavity of the air pipes and then onto the blades of the swirler, where, after receiving a rotational movement, it goes to the outlet nozzle of the burner and mixes with fuel. The combustion products through the channels located in the masonry of the furnace, then move along the outer surface of the air pipes and flow jet into the cavity of the air pipes. Passing through these pipes, the products of combustion wash their inner surface and are discharged into the smoke collector and further into the pipe. Thus, the use of the known recuperative burner increases the efficiency of heat transfer and reduces fuel consumption for heating the charge due to the multiple leakage of air onto the heat exchange surface. A factor limiting the use of the jet method of intensification of the convective component of heat transfer in the considered regenerative burners is the fact that in order to ensure a high rate of jets flowing onto the heat exchange surface, and hence high heat transfer coefficients, it is necessary to have high speeds, and therefore, small hole diameters at a small, well-defined distance between them. On the other hand, for well-defined air and combustion products, depending on the power of the burner, the number of holes is limited. This excludes the possibility of increasing the heat transfer surface, and hence the possibility of increasing the amount of heat transferred from the combustion products to the heated air, since an increase in the heat transfer surface will lead to an increase in the number of openings, and therefore, to a decrease in the speed of the jets and the efficiency of the jet heat transfer.

The objective of the present invention is to develop the design of a regenerative burner, which improves the efficiency of use of heat of the exhaust gases and thereby reduce fuel consumption for heating of heating units.

In the claimed solution, the heat exchanger is made of a bundle of pipes intended for the passage of combustion products, the heat exchanger pipes pass through a screw spiral mounted between the body and the primary air pipe to direct the air of the heat exchanger washer pipe.

The heat exchanger mounted between the inner wall of the housing and the outer surface of the primary air pipe is made in the form of a large number of pipes of relatively small diameter, which significantly increases the heat transfer surface. Unlike the prototype, these are solid pipes without perforation designed to pass only hot flue gases, while the flue gases pass inside the pipes and the air outside. In the claimed design, the heat exchanger pipes pass through a helix mounted between the housing and the primary air pipe to direct the air washing the heat exchanger pipes. Due to this constructive technique, practically transverse washing with an air flow of the outer surface of the heat exchanger tubes is organized, which allows to increase the air flow rate and increase the heat transfer coefficients, and hence the air heating temperature. Rings are inserted inside the heat exchange tubes at a certain distance from each other, which turbulent the flow of combustion products, which leads to intensification of heat exchange between the combustion products and the pipe walls and has an additional effect on increasing the temperature of the air heating.

Thus, a new technical result that can be achieved by using the claimed burner design is to increase the amount of heat taken from the flue gases and transfer it to the combustion air, which, accordingly, leads to an increase in the temperature of the air heating and lower consumption fuel.

The claimed burner is illustrated in the drawing. The burner contains an air manifold 1 with nozzles for supplying air 2 and exhaust of combustion products 3, a heat exchanger containing a bundle of pipes 4, a gas nozzle 5, a ceramic combustion chamber 6, an ignition and flame control electrode 7, a gas supply manifold 8. Heat exchanger pipes pass through a spiral spiral 9. Inside the heat exchange tubes 4, turbulent rings are inserted 10. To prevent overheating of the internal space of the burner, the combustion chamber is separated from this space by a lining 11 made of ceramic refractory fiber. To compensate for the temperature expansion that occurs when the combustion chamber 6 is heated up, a bellows 12 is installed in the air manifold 1, which is connected to the gas supply manifold 8 by a gas pipe 13. The burner has a smoke manifold 14. The heat exchanger pipes are closed by the outer casing 15 and the inner shell 16.

The principle of operation of a high-speed recuperative burner (the rate of expiration of combustion products over 150 m / s) is based on two-stage combustion of fuel. At the first stage, 100% of the fuel and about 40% of the air necessary for combustion are supplied to the combustion chamber 6, therefore, the fuel burns here with a lack of oxygen at relatively low temperatures, despite the significant heating of the air. Lack of oxygen and low temperatures in the first stage of fuel combustion do not allow nitrogen oxides to form in the combustion chamber. The combustion stabilizer in the first stage of fuel combustion is the heated walls of the combustion chamber. The rest of the fuel is burned in the second stage, in a stream of hot combustion products leaving the nozzle of the combustion chamber. In this case, air is supplied to the fuel afterburning through the annular gap between the nozzle of the combustion chamber and the end wall of the burner. Thus, a hot stream containing unburned fuel spreads in an environment of an air stream and in the presence of combustion products, which ensures complete combustion of the fuel at relatively low temperatures, thereby reducing the formation of nitrogen oxides NO _x in the first and second stages of combustion. Such a scheme makes it possible to stabilize combustion in the second stage and burn fuel in a jet propagating at high speed. In this case, gas combustion is carried out in an air environment due to the heat of the exhaust combustion products.

Air heating is carried out in the recuperator. In this case, all the flue gases located in the working space of the unit are sucked through the heat exchange pipes 4 of the heat exchanger using an ejector or smoke exhaust. Turbulent rings 10 intensify convective heat transfer between flue gases and the inner walls of the heat exchanger tubes. Having given heat to the walls of the pipes of the heat exchanger, the combustion products enter the smoke collector 14, and then are removed into the chimney through the pipe 3. For uniform distribution of flue gases through the pipes of the heat exchanger, the smoke collector 14 is made in the form of an annular cavity of variable height. Air is supplied to the burner by a fan into the air collector 1 tangentially through the pipe 2, washes the smoke collector from all sides, removing additional heat from it and cooling the outer case of the burner. After that, the air enters the spiral channel with heat exchange tubes formed by the outer casing 15, the inner shell 16 and the helical spiral 9. Thus, the air washes the outer surfaces of the heat exchanger tubes almost transversely, which significantly intensifies convective heat transfer on the air side. In addition, the spiral channel has a much smaller cross section for the passage of air, which means that the air will have a higher speed and the convective heat transfer coefficients on the air side of the heat exchanger will be higher than when longitudinally washing the heat exchanger pipes. Due to the increase in the heat exchange surface and the intensification of convective heat transfer on the smoke and air sides, the efficiency of the proposed design of the heat exchanger will be significantly higher than that of analogues.

Experimental tests of the design of the claimed burner showed its ability to obtain a temperature for heating the air supplied to the combustion to 800 ° C at a temperature of combustion products in the furnace 1100 ° C.

Claims (2)

1. A recuperative burner for gaseous fuel, comprising a housing, a primary air pipe placed in a housing with an annular gap, a combustion chamber, a heat exchanger made of a bundle of pipes intended for combustion products, the heat exchanger tubes passing through a spiral spiral mounted between the housing and the primary air pipe to direct the air washing the heat exchanger pipes. 2. The regenerative burner according to claim 1, characterized in that turbulent rings are mounted inside the tubes of the heat exchanger.

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