EA008661B1 - Flexible nozzle mixing burner comprising a swirl chamber - Google Patents

Abstract

The invention relates to an externally mixing burner comprising a burner head (2), at least one fuel gas pipe (3), and at least one pipe (4) for an oxygen-containing gas. The burner head is provided with outlets from the fuel gas pipe and from the pipe for the oxygen-containing gas. The inventive burner is characterized in that gas supply tubes (6, 7) for fuel gas and oxygen-containing gas are provided, each of which is connected to a source of fuel gas or oxygen-containing gas and at least one of which eccentrically extends into a swirl chamber (8, 9) that is mounted between the gas supply tube and the fuel gas pipe and/or between the gas supply tube and the pipe for oxygen-containing gas. The invention further relates to a method for operating an externally mixing burner comprising at least one fuel gas pipe and at least one pipe for oxygen-containing gas through which fuel gas or oxygen-containing gas flows to the burner head. Said method is characterized in that the fuel gas and/or the oxygen-containing gas is/are eccentrically delivered into a swirl chamber in which a rotational flow is impressed on the fuel gas or the oxygen-containing gas while the fuel gas or the oxygen-containing gas is fed to the fuel gas pipe or the pipe for oxygen-containing gas after being discharged from the swirl chamber.

Description

The present invention relates to an external mixing burner having a head and at least one pipe for supplying combustible gas and at least one pipe for supplying oxygen-containing gas, the outlet openings of which are located in the head of the burner. The invention further relates to a method for controlling the operation of an external mixing burner, which has at least one pipe for supplying combustible gas and at least one pipe for supplying oxygen-containing gas, through which a stream of combustible gas, respectively, a stream of oxygen-containing gas, enters the burner head.

External mixing burners are used in a wide variety of applications. So, for example, for heating and melting metals or glass, many burners of various designs are used.

However, at present, there is no burner that can be used at all stages of the melting process and at various furnace loads.

Based on the foregoing, the present invention was based on the task of developing a burner that would allow the possibility of its effective application in many fields and at any stage of a process.

The problem set in the invention is solved due to the fact that the burner has gas supply lines for combustible gas and oxygen-containing gas, which are connected to sources of combustible and oxygen-containing gases, respectively, and at least one of which eccentrically enters the swirl chamber, which is located between the gas supply pipe for fuel gas and a pipe for supplying combustible gas and / or between a gas supply pipe for oxygen-containing gas and a pipe for supplying oxygen gas.

In one of the preferred embodiments of the inventive burner, at least one of the gas supply pipelines branches upstream of the turbulence chamber into two pipelines, one of which eccentrically enters the turbulence chamber, and the other directly enters the combustible gas supply pipe, respectively, into a tube for supplying oxygen-containing gas.

In a particularly preferred embodiment of the inventive burner in gas supply pipelines, especially in the part located behind the branching point of at least one of them into two pipelines, valves are provided with which a device for controlling the degree of their opening or degree control is functionally connected their opening, the change of which allows you to adjust the shape of the flame of the burner.

These valves, it is advisable to perform in the form of electromagnetic valves. Such electromagnetic valves allow discrete changes in the shape of the flame. With increased requirements for regulating the shape of the flame, instead of a part or instead of all solenoid valves, control valves can be used. Such control valves allow you to smoothly change the shape of the flame.

In a preferred embodiment, the swirl chamber has a circular shape in cross section with a plane perpendicular to the longitudinal axis of the combustible gas supply pipe. In a particularly preferred embodiment, the gas supply pipe tangentially enters the swirl chamber. These options individually can reduce, and together to minimize the friction of the swirling flow.

With regard to the method of the type indicated at the beginning of the description, the object of the invention is solved by the fact that the combustible gas and / or oxygen-containing gas is eccentrically fed into the swirl chamber, in which the flow of combustible gas, respectively, the flow of oxygen-containing gas is twisted and, after exiting, the combustible gas respectively, the oxygen-containing gas is directed into the tube for supplying combustible gas, respectively, into the tube for supplying oxygen-containing gas.

In one preferred embodiment of the method according to the invention, the flow rate is controlled and / or the flow rate per unit of time supplied to the burner through the turbulence chamber and not through it of combustible and oxygen-containing gases is supplied through the valves, which are controlled by the opening degree or opening degree of which they are controlled in such a way that the flame formed by the burner has the desired and customizable shape by control and / or regulation.

Fuel-oxygen burners are often used, for example, for fire heating of industrial furnaces in which metals or glass are melted. When burning fuel in a mixture with air, the nitrogen contained in it as its main component is a ballast gas. Therefore, in order to reduce the volume of exhaust gases generated in the combustion of a combustible mixture in burners, an oxygen-containing gas was used as an oxidizer, the oxygen content of which exceeds the oxygen content in the air. A related advantage is an increase in flame temperature due to a reduced nitrogen content in the combustible mixture and a decrease in the heat content of the exhaust gases, which makes it possible to increase the thermal efficiency and effectively reduce the amount of nitrogen oxides generated during the combustion of the combustible mixture.

Both air and oxygen are suitable as oxidizing agents according to the invention.

- 1 008661 holding gas with an increased oxygen content compared to air. The advantage associated with the use of air as an oxidizing agent is its constant and free availability. The advantages associated with the increased oxygen content in the oxidizing agent are already discussed above.

In principle, air can also be used as an oxygen-containing gas. Air is a free, universally available oxidizing agent.

According to a further embodiment of the invention, oxygen-enriched air is used as the oxygen-containing gas. The advantage associated with the use of oxygen-enriched air is that it still remains a rather cheap oxidizing agent and, at the same time, already partially has the advantages associated with the use of oxygen for fuel combustion and consisting in lower nitrogen content in comparison with air and the possibility of achieving a higher combustion temperature.

According to another preferred embodiment of the invention, a gas is used as the oxygen-containing gas, the oxygen content of which exceeds the oxygen content in the air, especially more than 30 vol.%. The advantages described directly above, which are provided by the presence of oxygen in the oxidizing agent for the combustion process, are more pronounced in this embodiment.

In a particularly preferred embodiment of the invention, it is proposed to use a gas with an oxygen-containing gas, the oxygen content of which exceeds 70 vol.%, Especially exceeds 99.5 vol.%. In this embodiment, the advantages provided by the presence of oxygen in the oxidizing agent are manifested to the maximum extent, however, the cost of the oxidizing agent increases, and therefore, in practice, in each particular case, it is necessary to carefully evaluate which oxygen content in the corresponding gas is technically feasible or necessary and economically viable.

In a preferred embodiment, it is proposed to twist the flow of combustible gas. A related advantage is the effective mixing of the combustible gas with oxygen while forming a slightly shortened flame.

In another preferred embodiment, it is proposed to twist a stream of oxygen-containing gas. The advantage of this option also lies in some shortening of the flame and some simplification of the design of the burner and thereby in simplifying its manufacture.

In a most preferred embodiment, it is proposed to subject the flow of combustible gas and the flow of oxygen-containing gas in a unidirectional swirl. The advantage achieved in this case is the formation of an exceptionally short and calm flame.

In another embodiment of the invention, the flow of combustible gas and the flow of oxygen-containing gas is proposed to be subjected to multidirectional swirling. This option is recommended if you need to create an extremely short, branching flame.

A significant advantage of the invention lies in the possibility of a smooth change in the length of the flame (without the need to change the flow of combustible gas during burner operation). At the same time, there is also no need to make structural changes to the burner (for example, changing nozzles). So, in particular, the solution proposed in the invention allows to reduce the instantaneous flame length to one third of its maximum possible length.

The solution proposed in the invention is most suitable for use in the processes of melting solid material to a liquid state, since in such processes the shape of the melting materials changes, with which the shape of the flame can be adjusted.

Another significant advantage of the invention is the possibility of a smooth change in the length of the flame and the ability to start and stop again immediately during the operation of the burner the gas flow swirling without the need to turn off the burner and make any design changes to it, such as, for example, changing the usual disk swirler. The flame shape is varied by changing the outflow mode of at least one of the two gas flows solely by controlling the degree of opening of the valves described above using the control or regulation device provided by the invention.

The inventive external mixing torch is most suitable for melting metals or glass.

Below the invention is described in more detail by the example of one of the variants of its implementation with reference to the accompanying drawings, in which is shown in FIG. 1 - proposed in the invention burner;

in FIG. 2 is a section through a burner of plane AA and in FIG. 3 - section of the burner plane BB.

The drawings appended to the description, in particular, show a burner 1 with a head 2, a pipe 4 for supplying oxygen-containing gas and a pipe 3 for supplying combustible gas (not shown in Fig. 1). Both tubes are arranged concentrically to each other, and, in particular, the tube 3 for supplying combustible gas is located inside the tube 4 for supplying oxygen-containing gas. Burner 1 of a similar nazi design

- 2 008661 are also equipped with a direct-flow burner. As a combustible gas in such a burner, for example, natural gas is used.

Below, as an example, the operation of burner 1 in the unidirectional swirl mode of both gas flows is considered. When the valve 10 is open, natural gas is supplied from the gas supply pipe 6 through the pipe 6a to the turbulence chamber 8. It spins the flow of natural gas. Valve 11 is closed.

The oxygen-enriched air enters through the gas supply pipe 7 and pipe 7a into the turbulence chamber 9. In it, the flow of oxygen-enriched air swirls in the same direction as the flow of natural gas. Valve 12 is open and valve 13 is closed.

The stream of oxygen-enriched air coming out of the swirl chamber 9 enters the tube 4. The natural gas stream flows from the swirl chamber into the tube 3.

At the exit of the burner head 2, both gas flows are mixed together to form a combustible mixture, during the combustion of which a characteristic flame arises. The shape of the flame arising from the combustion of a combustible mixture depends directly on whether each of the valves 10, 11, 12 and 13 is closed or open.

When a flow of combustible gas is supplied to the burner head, for example, with the valve 11 open and the valve 10 closed, that is, without swirling the natural gas stream, the flame lengthens. In this case, the flame lengthens in comparison with the flame arising in the example considered above with swirling of both gas flows.

In the same way, only a natural gas stream can be swirled, and an oxygen-containing gas stream can be fed without twist into the pipe 4 through the pipeline 7b through the open valve 13.

When the valves 10, 11, 12 and / or 13 are executed as control valves, their valves can be installed in intermediate positions, i.e., the degree of opening of these valves can be adjusted. This feature allows you to smoothly adjust or change the shape of the flame. Changing the shape of the flame during operation of the burner 1 is carried out without any problems by valve control devices 10, 11, 12, 13 or their control devices.

The shape of the flame should not depend on the flow rate of combustible and oxygen-containing gases supplied to the burner. Once selected, the flow rate of these gases remains constant during burner operation. Changing the shape of the flame from short, branching and wide to elongated and narrow is carried out only by selecting the states of each of the valves 10, 11, 12, 13, i.e. shutter positions in them.

Claims (17)

1. An external mixing burner (1) having a head (2) and at least one pipe (3) for supplying combustible gas and at least one pipe (4) for supplying oxygen-containing gas, the outlet openings of which are in the head (2) burners, characterized in that gas supply lines (6, 7) are provided for combustible gas and oxygen-containing gas, which are connected to sources of combustible and oxygen-containing gases, respectively, and at least one of which eccentrically enters the chamber (8, 9) swirls which is located between a gas supply pipe (6) for combustible gas and a pipe (3) for supplying combustible gas and / or between a gas supply pipe (7) for oxygen-containing gas and a pipe (4) for supplying an oxygen-containing gas. 2. The burner (1) according to claim 1, characterized in that at least one of the gas supply pipelines (6, 7) branches upstream into the turbulence chamber (8, 9) into two pipelines (6a, 6b, 7a, 7b) ), one (6a, 7a) of which eccentrically enters the turbulence chamber (8, 9), and the other (6b, 7b) of them directly enters the tube (3) for supplying combustible gas, respectively, in the tube (4) for supplying oxygen-containing gas. 3. The burner (1) according to claim 1 or 2, characterized in that in the gas supply pipelines (6, 7), especially in the part located behind the branching point of at least one of them into two pipelines (6a, 6b, 7a, 7b), valves (10, 11, 12, 13) are provided, with which a device for controlling the degree of their opening or controlling the degree of their opening is functionally connected, changing which allows you to adjust the shape of the burner flame (1). 4. The burner (1) according to one of claims 1 to 3, characterized in that the valves (10, 11, 12, 13) are made in the form of electromagnetic valves (10, 11, 12, 13). 5. The burner (1) according to one of claims 1 to 4, characterized in that the turbulence chamber (8, 9) has a circular shape in the cross section of a plane perpendicular to the longitudinal axis of the tube (3) for supplying combustible gas. 6. The burner (1) according to claim 5, characterized in that the gas supply pipe (6, 7, 6a, 7a) tangentially enters the turbulence chamber (8, 9). 7. A method of controlling the operation of a burner (1) with external mixing, which has at least one pipe (3) for supplying combustible gas and at least one pipe (4) for supplying oxygen-containing gas, through which the flow of combustible gas, respectively, the flow of oxygen-containing gas 3 008661 gas enters the burner head (2), characterized in that the combustible gas and / or oxygen-containing gas is eccentrically fed into the turbulence chamber (8, 9), in which the flow of combustible gas, respectively, the flow of oxygen-containing gas is twisted after exit from which Oh, combustible gas, respectively, oxygen-containing gas is sent to the tube (3) for supplying combustible gas, respectively, in the tube (4) for supplying oxygen-containing gas. 8. The method according to claim 7, characterized in that they control the flow rate and / or regulate the flow rate supplied per unit time to the burner head (2) through the turbulence chamber (8, 9) and not through it combustible and oxygen-containing gases, while supplying them through valves (10, 11, 12, 13), the degree of opening of which is controlled or the degree of opening of which is controlled so that the flame generated by the burner (1) has the required and adjustable shape by controlling and / or regulation. 9. The method according to claim 7 or 8, characterized in that air is used as the oxygen-containing gas. 10. The method according to claim 7 or 8, characterized in that oxygen-enriched air is used as the oxygen-containing gas. 11. The method according to claim 7 or 8, characterized in that as an oxygen-containing gas, a gas is used, the oxygen content of which exceeds the oxygen content in the air, first of all, exceeds 30% vol. 12. The method according to claim 11, characterized in that as an oxygen-containing gas, a gas is used, the oxygen content of which exceeds 70 vol.%, Primarily exceeds 99.5 vol.%. 13. The method according to one of claims 7 to 12, characterized in that the flow of combustible gas is subjected to swirling. 14. The method according to one of claims 7 to 13, characterized in that the stream is subjected to swirling oxygen-containing gas. 15. The method according to one of claims 7 to 14, characterized in that the flow of combustible gas and the flow of oxygen-containing gas is subjected to unidirectional swirling. 16. The method according to one of claims 7 to 14, characterized in that the flow of combustible gas and the stream of oxygen-containing gas are subjected to multidirectional swirling. 17. The use of a burner (1) with external mixing according to one of claims 1 to 6 for the melting of metal or glass.