DE3117708C2 - Gas burner - Google Patents

Abstract

The gas burner contains a chamber (1) in which gas distribution pipes (2) are arranged, which are provided with axially arranged outlet bores (3). In the inlet section of each gas distribution pipe (2), an intermediate wall (4) with bores (5) is arranged perpendicular to the gas movement and at the same distance, which are evenly distributed around its circumference in order to guide the gas flowing in the pipe (2) towards the pipe periphery.

Description

The invention relates to a gas burner according to the preamble of patent claim 1.

A gas burner of this type is disclosed in DE-OS 30 46 682, which was not published prior to this date but represents fictitious prior art. This gas burner has a chamber in which hot air can be supplied and in which gas distribution pipes are arranged in rows passing through them. Axially and radially arranged outlet bores are provided in the gas distribution pipes, with adjacent gas distribution pipes being arranged relative to one another in such a way that their end faces on the side of the outlet bores lie in different planes relative to the plane of the chamber. As a result, the gas jets on each gas distribution pipe form their own burning flame, with each gas distribution pipe arranged lower down also heating the wall of the protruding gas distribution pipe with its flame, as a result of which the gas flowing in the pipe is heated to a high temperature. If this gas burner, e.g. If hot air is supplied, for example during operation in melting furnaces, the gas is only insufficiently preheated by the hot air due to the heat transfer through the pipe walls, since the gas flows essentially in the middle of the pipe.

A gas-oil burner is also known which contains a gas chamber with a side nozzle for gas supply and an air chamber with a side nozzle for air supply (book by Maizels P. B., Vigdorchik D. Ja. "Gas burner devices", Publishing House for Construction Literature, Moscow 1964, p. 282). The gas chamber of the burner is closed on one side and has a pipe grid on the other side, to which gas distribution pipes are welded, which run through the air chamber along the central axis of the holes intended for air outlet. An end piece - a nozzle with holes intended for gas outlet - is screwed onto the end of each gas distribution pipe. In the middle of the burner, along its axis, a pipe is attached, into which a small pipe with an oil supply nozzle is inserted. This burner is designed primarily for gas combustion in boiler furnaces, where the temperature of the combustion products can be lower than in metallurgical furnaces for melting cast iron and steel. Therefore, cold air is usually supplied to the gas burners. When the burner is used in melting furnaces, hot air with a temperature of 450 to 650°C must be supplied to reach a temperature of 1800°C. In this case, the gas is not sufficiently preheated by the hot air due to the heat passing through the walls of the gas distribution pipes, since the open pipe ends on the side of the gas chamber mean that the gas flows mainly through the central parts of the pipes and not along the heated walls, which is also facilitated by the arrangement of the holes for gas outlet in the end nozzles on the front sides of the gas distribution pipes. In addition, during high-temperature combustion of gas, the walls of the end nozzles may melt and the holes in them intended for gas outlet may enlarge, which leads to disruption of gas distribution in the tubes, an increase in the flame length and a decrease in temperature.

Gas burners are also known that contain gas distribution pipes that run through a chamber intended for air distribution (book by Maizels P.B., Vigdorchik D.Ja. "Gas burner devices", Bauliteratur publishing house, Moscow 1964, pp. 200-203). Nozzles are screwed onto the ends of the gas distribution pipes, which have channels for gas outlet, and these nozzles are arranged in the nozzles intended for air inlet. However, due to the considerable distances between the nozzles intended for air outlet and thus between the gas distribution pipes, these burners can only be used where it is necessary to achieve lower temperatures than in gas furnaces for melting and superheating ferrous metals and ferrous metal alloys, namely in steam and hot water boilers. In addition, the burners have large housing dimensions for short-flame gas combustion. It is possible for the gas in the nozzle to burn and the nozzle walls to melt when hot air and high-temperature combustion of the gas are used.

The invention is based on the object of developing the generic gas burner in such a way that the heat transfer from the hot air via the respective gas distribution pipe to the gas is intensified.

This object is solved by the characterizing features of patent claim 1.

With such a design of the burner, the gas jets are directed towards the walls of the gas distribution pipes and the gas moves along these pipe walls so that the gas is preheated by the hot air, which increases the efficiency of gas combustion.

Advantageous embodiments of the invention are characterized in the subclaims.

The structural design of the gas distribution pipe according to claim 2 ensures a reduction in the length of the entire burner flame and an increase in the temperature therein.

When drilling holes with a diameter smaller than 0.05 of the outer diameter D of the gas distribution pipe, the resistance to gas flow through the holes increases considerably, but the heat transfer and the depth of penetration of the gas into the air stream when it exits the gas distribution pipes decrease, which leads to a reduction in the temperature in the burning flame.

When the holes are made with a diameter greater than 0.3 of the external diameter D of the gas distribution pipe, the number of holes provided on each gas distribution pipe decreases, which worsens the gas distribution in the pipes and thus the heat transfer and the mixing of the gas with air, and consequently causes the flame temperature to drop.

The structural arrangement of the gas distribution pipes according to patent claim 3 makes it possible to ensure good mixing of the gas with air and good preheating of the gas with minimal lengths of the gas distribution pipes and to achieve a short high-temperature flame.

When arranging the gas distribution pipes with respect to the chamber walls at a distance λ smaller than the diameter d ₃ and with a distance h between the pipes smaller than twice the diameter d ₃ , the resistance to the air movement between the gas distribution pipes increases considerably and the heat transfer decreases, the uniform distribution of air and gas in the outlet cross-section of the air chamber and the combustion process in a burner tunnel adjoining the air chamber are disturbed, the flame becomes longer and its temperature lower.

When arranging the gas distribution pipes with respect to the walls of the air chamber at a distance λ greater than 12.5 times the diameter d ₃ of the holes in the intermediate wall and with a distance h between the rows of gas distribution pipes greater than 25 times the diameter d ₃ , the dimensions of the burner and the burner tunnel increase, the heat transfer and the mixing conditions for gas and air deteriorate and the temperature of the flame decreases.

The invention is explained below with reference to the embodiments shown in the drawing. It shows

Fig. 1 is a schematic representation of the overall view of a gas burner in longitudinal section according to line II of Fig. 2;

Fig. 2 shows the section along line II-II of Fig. 1;

Fig. 3 shows the section along line III-III of Fig. 1;

Fig. 4 shows the section along line IV-IV of Fig. 1;

Fig. 5 shows the section along line VV of Fig. 1;

Fig. 6 an embodiment of the outlet part of the gas burner in longitudinal section;

Fig. 7 shows the section along line VII-VII of Fig. 6;

Fig. 8 is a view according to arrow A in Fig. 6, the direction of which coincides with the axis of the gas distribution pipes.

As can be seen from Fig. 1 and 2, the gas burner contains an air chamber 1 in which gas distribution pipes 2 are arranged, which are provided with axially arranged outlet bores 3. In the inlet section of each gas distribution pipe 2 , an intermediate wall 4 with bores 5 is arranged perpendicular to the direction of movement of the gas, which are evenly distributed around its circumference in order to guide the gas flowing in the gas distribution pipe 2 to the periphery thereof.

The gas distribution pipes 2 are connected to a front-side gas collector 6 .

Various variants are possible for the arrangement of the gas distribution pipes 2 , as shown in Figs. 3 to 8. Figs. 3 to 5 are based on a two-row arrangement of the gas distribution pipes 2 in the vertical planes, and Figs. 6 to 8 show a three-row arrangement of the pipes in the vertical planes. Variants with a single-row and multi-row arrangement of the gas distribution pipes 2 are possible.

Each gas distribution pipe 2 is further provided with two annular rows of radially arranged bores 7 , the diameter d ₁ of which corresponds to the diameter d ₂ of the axially arranged outlet bore 3 and the diameter d ₃ of the bores 5 in the transverse intermediate wall 4 and amounts to 0.05 to 0.3 of the outer diameter D of the gas distribution pipe 2 .

The gas distribution pipes 2 are arranged in rows in the chamber 1 in such a way that the edge rows of the gas distribution pipes 2 are located with respect to the walls of the chamber 1 at a distance λ which is 1.0 to 12.5 times the diameter d ₃ of the holes 5 in the intermediate wall 4 , while the distance h between the rows of pipes 2 is 2 to 25 times this diameter.

The burner works as follows.

Hot air is supplied to the chamber 1 , which flows around and heats the walls of the gas distribution pipes 2. Gas is then supplied to the front collector 6 , which enters the gas distribution pipes 2 through the holes 5 in the transverse partition walls 4 .

Due to the uniform distribution of the holes 5 along the circumference of each partition wall, the movement of the gas flow is ensured predominantly along the wall of the gas distribution pipe 2 , which makes it possible to intensify the process of heat transfer from the hot air through the walls of the pipes 2 to the gas. The heated gas, emerging from the axially and radially located holes 3 and 7 , enters the combustion chamber, where it mixes with the hot air and burns.

As a result of the preheating of the gas by the heat of the hot air stream, the flame length decreases and the flame temperature increases.

The gas burner operates stably at low and high gas and air flow rates, at air ratios greater and less than 1. The gas burner can operate with natural gas, generator gas, hydrogen and other fuel gases.

Claims (3)

1. Gas burner with gas distribution pipes provided in a hot air chamber, each having an axial outlet bore and two rows of annularly arranged, radial outlet bores in the region of the outlet side of the hot air chamber, characterized in that an intermediate wall ( 4 ) is provided in the inlet section of each gas distribution pipe ( 2 ), which is arranged perpendicular to the gas movement in the gas distribution pipe ( 2 ) and has evenly distributed bores ( 5 ) in the edge region of the intermediate wall ( 4 ). 2. Gas burner according to claim 1, characterized in that the diameter (d ₃ ) of the bores ( 5 ) in the intermediate wall ( 4 ) is equal to the diameter (d ₁ ) of the radial outlet bores ( 7 ) and the diameter (d ₂ ) of the axial outlet bore ( 3 ) and amounts to 0.05 to 0.3 of the external diameter (D) of the gas distribution pipe ( 2 ). 3. Gas burner according to claim 1 or 2, characterized in that when the gas distribution pipes ( 2 ) are arranged in rows in the hot air chamber ( 1 ), the edge rows on the outside in relation to the walls of the hot air chamber ( 1 ) are at a distance ( λ ) which is 1.0 to 12.5 times the diameter (d ₃ ) of the holes ( 5 ) in the intermediate wall ( 4 ), and the outside distance (h) between the rows of gas distribution pipes ( 2 ) is 2 to 25 times the diameter (d ₃ ) of the holes ( 5 ) in the intermediate wall ( 4 ).