RU2005957C1 - Burner device of preliminary mixing - Google Patents

Abstract

FIELD: burning of gas fuel. SUBSTANCE: burner has housing with outlet nozzle, gas manifold and gas supply pipes; located in housing and in detachable water-cooled outlet nozzle is mixing chamber which is made of two cylinders connected by means of converging tube; pipes are bent at right angle and are arranged in mixing chamber in concentric rows at some distance from each other and from wall of chamber; geometric sizes of converging tube and those of lesser cylinder of mixing chamber are related by definite relationships. EFFECT: enhanced efficiency. 3 cl, 3 dwg

Description

 The invention relates to energy and can be used in the combustion of gas fuels, in particular containing hydrogen, for example, coke oven gas or its mixtures with other gases, and can be used mainly in ferrous metallurgy for heating heating furnaces, as well as in furnaces of various heat engineering devices.

 Known burner devices containing a mixer of cylindrical shape and made with it at the same time an annular collector with radially arranged holes for peripheral gas supply inside it.

 The radial flow pattern of gas jets into the mixing chamber across the air flow creates a noticeable hydraulic resistance in the path of air and gas movement, which leads to an increase in the required air and gas pressure in front of the burner, and, therefore, to a reduction in regulation limits.

 In addition, the radial method of mixing gas jets with insufficient gas pressure in front of the burner does not provide sufficient continuity in filling the air stream with gas jets, which impairs the mixing rate of gas and air and, as a result, reduces the efficiency of the burner device. To intensify the mixing of gas with air, it is necessary to increase the gas pressure in the annular gas supply manifold, i.e., in general, in front of the burner, which will ensure the free development of each gas stream and the achievement of a sufficient depth of their penetration into the air stream.

 The need to increase, in this case, the gas pressure in front of the burner again leads to a decrease in the control range and a decrease in the stability of the burner device.

 Known burner, consisting of a housing having a conical air channel and independently fed gas channels located concentrically along the axis of the burner, which are respectively connected by cylindrical rings located concentrically along the axis of the burner, which are respectively connected by cylindrical rings with holes for the passage of gas into the air stream, one of the rings serves as a turbulizer of the gas stream of the other ring.

 This burner has been used in sectional furnaces for high-speed heating of a tube billet before rolling and can only work on natural gas.

 The disadvantage of this burner is the possibility of ignition of the jets that come out of the large ring perpendicular to the smaller one, which is closer to the mouth of the burner and the latter burns up, and even its complete destruction. To avoid burner failure, they are forced to shut off the supply of secondary gas, i.e., to a large ring, while the burner power decreases by more than 2 times, and this sometimes becomes insufficient to heat the pipe billet without reducing its speed through the furnace, i.e., the productivity of the furnace decreases, the operation of the mill is disrupted. Sometimes when the first (smaller) rings are burned, nothing is done in the burners, that is, gas is supplied by both pipes, but in this case the torch loses its speed (rigidity) and does not create a sufficient rotating gas stream around the pipe billet, since it decreases convective heat transfer, in addition, the quality of heating the workpiece decreases, so-called one-sided heating appears, which complicates the operation of the mill.

 A known burner (prototype), in which the gas is supplied to the mixing chamber with a bundle of gas supply pipes parallel to each other, the rear ends of which are installed in a tube board placed in a cylindrical housing, which is a continuation of the mixing chamber, and the outlet ends are provided with blind walls exceeding the outer the diameter of the latter is 1.05-1.2 times, and in the side walls - with radial holes placed in several staggered rows in a checkerboard pattern, with the total cross-sectional area all gas supplying pipes cross sectional area equal to the annulus of the housing.

 In this burner, the implementation of a bunch of gas supply pipes with a total flow area equal to the cross-sectional area of the annular space, allows to achieve a uniform distribution of gas in the air flow. However, here, the outflow of gas from the gas supply pipes through the lateral radial openings across the air flow creates additional hydraulic resistance in the path of movement of air, gas and the resulting gas-air mixture.

 The well-known burner has proven itself in the combustion of low-calorie hydrocarbon gas fuels, eliminating any significant moisture and impurity content.

 The operation of such burners on hydrogen-containing fuels, for example, coke oven gas or its mixtures with other gases, the gas-air mixture of which is characterized by high flame propagation rates, in comparison with hydrocarbon-air mixtures leads to a breakthrough of the flame into the mixer, which forces to reduce the limits of performance regulation.

 The presence in the coke oven gas of such impurities as vapors of naphthalene, resinous substances can lead to the gradual clogging of small radial holes in the gas supply pipes, and the presence of moisture contributes to the accumulation of condensate in the burner body, which is not provided for drainage.

 The aim of the invention is to expand the range of stable operation of the burner, including the combustion of hydrogen-containing fuels, increase the efficiency of gas combustion, stability of combustion and operational reliability, improve the combustion conditions of gas containing condensate, ensure ease of layout, accelerate installation and reduce repair time.

This goal is achieved by the fact that in the proposed burner pre-mixing device comprising a housing with an annular gas supply manifold installed therein, gas supply pipes evenly spaced across the collector section, a mixing chamber and nozzles for supplying air and gas, according to the invention, the gas supply pipes are bent under angle of 90 ^about in the direction of the outflow of the gas-air mixture and are installed in the mixing chamber by at least three coaxially arranged rows, which are coaxial concentric nical circles equidistant between themselves and from the inner surface of the mixing chamber by a distance equal to the diameter of the smaller circle. The mixing chamber is located in a removable water-cooled part of the housing and is made on a cone, in the form of a confuser, passing into the cylinder, while the length of the confuser part is not less than the diameter of the larger base of the cone, mating with the cylindrical part of the mixing chamber located in the collector. The length of the cylindrical mixing chamber is half the diameter of the latter, while the cross-sectional area of the cylindrical part of the mixing chamber located inside the annular gas supply manifold is 5-6 times less than the output section of the confuser.

 The number of gas supply pipes in each subsequent row exceeds the number of gas supply pipes of the previous row by 2 times.

 The ends of the gas supply pipes are extended into the cavity of the annular gas supply manifold by a length equal to (0.3-0.5) of the inner diameter of the pipes, and for the periodic removal of condensate, a drain fitting with a tap is installed at the lower point of the collector.

 The proposed burner device is made of four nodes interconnected by means of flange connections, which ensures high operational reliability of the burner, accelerates its installation and simplifies repair, since it is enough to replace a failed node, and also provides convenience when installation.

 The proposed quantitative ratio of the gas supply pipes in their rows contributes to the most uniform distribution of gas over the cross section of the mixer and its mixing with air, which increases the efficiency of gas combustion and reduces its consumption. It is also the most optimal from the point of view of design.

 The use in the device of a removable water-cooled head with a mixing chamber in the form of a confuser turning into a cylindrical part, with a length of the confuser part not less than the diameter of the larger base, and a length of a cylindrical section of half its diameter with a cross section of 5-6 times less than the input section of the confuser , increases the resistance of the burner head, improves the mixing of gas with air and prevents the passage of flame into the mixer, which extends the range of stable operation of the device and increases the efficiency combustion gas.

 The inlet ends of the gas supply pipes into the cavity of the annular manifold by a length equal to 0.3-0.5 of the inner diameter of the pipes exclude the possibility of condensate entering the mixer when operating on condensate-containing gases. This improves the conditions for increasing the efficiency of burning fuels containing condensate, and the installation of a fitting with a tap at the lower point of the collector allows timely removal of accumulated liquid.

 An additional search for solutions known in science and technology showed that the advanced technical solutions in the proposed burner preliminary mixing device to achieve the goals in the known solutions were not found.

 Therefore, the proposed burner device meets the criterion of "significant differences".

 In FIG. 1 shows the proposed burner device, a longitudinal section; in FIG. 2 is a view along arrow A in FIG. 1; in FIG. 3 is a section BB in FIG. 1.

The device comprises a housing with a water-cooled head 1 and a cylindrical part 2, an air pipe-transition 3, a pipe 4 for supplying air. In the head of the housing 1 in order to cool it, a coil 5 is placed along which water circulates. The cylindrical body portion is an annular gas supply manifold 6 with a side inlet of gas through the pipe 7, the gas feed pipe 8, bent at an angle of ⁹⁰ ° in the direction of the expiration gas mixture and uniformly spaced therearound in three rows in a ratio of quantity of 1: 2: 4, with the air supply side . In the lower part of the gas supply annular collector 6, a drain pipe 9 with a valve 10 is installed. The air pipe-transition 3 is a truncated cone adjacent to the mixer 2 with its large base. The pipe 4 for supplying air is made in the form of a tap along the diameter of the smaller base of the cone-shaped air pipe-transition 2 and is equipped with a peep 11, coaxial with the central axis of the burner device. The peeper 11 has a cap-cap 12 with a protective heat-resistant glass 13. The connection of the main components of the housing of the burner device is flange. Asbestos gaskets 14 are installed at the junction points of the burner device housing 1 with the air pipe-transition 3, and the flange connection of the air pipe-transition 3 with the air supply pipe 4 is sealed with a paronite gasket 15. The mixing chamber consists of a confuser 16, a transfer cylinder 17 located in a water-cooled head 1, and a cylindrical part 18 located inside the manifold 6.

The proposed burner pre-mixing device operates as follows:
Through the pipe 7, a gas, for example, coke gas, is supplied to the annular collector 6, framing the cylindrical part of the mixing chamber 2, and from there it uniformly enters through the gas supply pipes 3 into the mixing chamber. Through the outlet 4 and the transition pipe-diffuser 3 in the mixing chamber is supplied fan air. When flowing out of the pipes, gas is picked up in parallel by flowing jets of air in the annulus formed by the horizontal sections of the gas supply pipes. The vertical sections of the gas supply pipes radially directed in three rows to the central axis of the mixing chamber play the role of a swirler, contribute to the turbulence of the air flow and thus intensify the mixing processes of gas and air jets.

 Thus, the mixing of gas with air begins already at the cut of the gas supply pipes in the mixer itself and continues in the water-cooled part of the housing 1. Due to the fact that the water-cooled part of the mixing chamber with its inside is cone-shaped, the intensity of further mixture formation increases significantly, and Means the quality of the prepared mixture.

 The water cooling of the head housing using a specially placed coil 5 prevents its overheating and plays the role of a barrier that prevents the passage of flame inside the mixer. The supply of cold water is carried out from below, and the discharge already worked out from the coil is from above.

 Ignition of a pre-cooked gas-air mixture occurs already at the exit from the cylindrical part of the water-cooled head in contact with the red-hot walls of the burner tunnel (embrasure).

 When condensate-containing gas fuels, such as coke oven, blast furnace, and ferroalloy gases, are burned in the proposed burner device, to prevent condensate from entering the mixer through gas supply nozzles, their inlet ends are welded in the radial holes of the mixing chamber body with an excess of (0, 3-0.5) of their inner diameter. Drops of condensate falling from the incoming gas flow down the cylindrical wall of the mixing chamber to the lower part of the annular gas-supplying manifold, from where it is periodically removed through the drain pipe 9 with a valve 10.

 Thus, thanks to such a technical solution for removing condensate from gas before it enters the mixing chamber, the conditions are improved and the efficiency of burning gaseous fuels containing to some extent condensate is improved. For visual control of the quality of combustion, an eye-catcher 11 is equipped with heat-resistant glass 13 in a safety cap-cap 12.

 The peephole, mounted coaxially with the longitudinal central axis of the entire burner device, simultaneously acts as a pilot hole when igniting the burner device, for this it is necessary to unscrew the cap-cap with protective heat-resistant glass.

 The ignition of the proposed gas burner device is carried out from a portable electric gas igniter.

 Due to the fact that the gas supply unit in the form of an annular collector is made integral with the mixing chamber, this makes the burner device compact.

 The connection of the main four nodes of the proposed burner device: the mixing chamber, its head, the air pipe-junction and the air outlet, using flange connections provides additional operational reliability of the burner device, speeds up, simplifies maintenance and, if necessary, repair, as it is enough to replace only a failed unit, without dismantling the entire burner device.

 Using the burner preliminary mixing device of the proposed design will expand the control range and increase the stability when burning gas with different calorific values, including ensuring effective and stable operation of the burner on hydrogen-air mixtures without flame penetration into the mixer and when using artificial gaseous fuels containing condensate and a certain amount of associated impurities remaining during poor-quality gas cleaning.

The proposed burner device passed pilot-industrial tests on the furnaces of the garage for thawing bulk cargo N 4 CherMK during heating with coke oven gas with a calorific value of 16.8-17.6 MJ / m ³ and showed reliability in a wide range of capacity control. (56) Copyright certificate of the USSR N 300715, cl. F 23 D 17/00, 1971.

 USSR author's certificate N 308271, cl. F 23 D 14/02, 1971.

 USSR author's certificate N 918672, cl. F 23 D 14/00, 1982.

Claims (3)

 1. PRELIMINARY MIXING BURNER, comprising a housing with an air supply nozzle and an outlet nozzle and a mixing chamber located in their cavity in the form of axially mounted cylinders of different diameters coupled by a confuser, as well as an annular gas supply manifold with a supply pipe located in the housing, connected to the gas supply pipes evenly spaced over its cross section, characterized in that the outlet nozzles are made removable and water-cooled, the gas supply pipes are bent at a right angle tangentially along gas-air mixture and placed on at least three concentric circles at a distance between themselves and the side wall of the larger cylinder of the mixing chamber, equal to the diameter of the smaller circle, the length of the confuser not less than the diameter of its larger base, the length of the smaller cylinder equal to half its diameter and cross-sectional area this cylinder is 5-6 times smaller than the cross-sectional inlet section of the confuser, and a drain fitting with a tap is installed in the lower part of the collector.  2. The device according to claim 1, characterized in that the number of gas supply pipes in each subsequent row doubles the number of these pipes in the previous row.  3. The device according to paragraphs. 1 and 2, characterized in that the ends of the gas supply pipes are brought into the cavity of the manifold for a length equal to 0.3 - 0.5 of their inner diameter.

Images