KR20000012485U - Material temperature homogenizer for regenerative burner - Google Patents

Abstract

The present invention relates to a temperature homogenizing device for a regenerative burner that can minimize the temperature difference of the upper and lower parts of the heated object by transferring the flame generated from the combustion part of the regenerative burner to the upper and lower parts of the heated object. A regenerative burner having a combustion section provided on both sides of the combustion furnace, each combustion section having a heat accumulator for accumulating latent heat contained in the exhaust gas, comprising: a separating wall provided between the combustion sections to distinguish the combustion section in which the heat accumulator is embedded; A connecting pipe installed at each end of the combustion section separated by the separating wall to move combustion air and exhaust gas, and a first pipe installed on the connecting pipe to control the direction of combustion air and exhaust gas flowing through the connecting pipe. Adjusting the amount of combustion air which is installed between the second and third valves and the second and third valves and moves toward the connecting pipe. A first branch pipe is installed between the valve, the first valve and the second valve, and the other end is connected to the switching valve to discharge the exhaust gas, and the other end is installed between the control valve and the third valve. It includes a second branch pipe connected to the switching valve to supply combustion air.

Description

Material temperature homogenizer for regenerative burner

The present invention relates to a temperature homogenizing device for a regenerative burner that can minimize the temperature difference of the upper and lower parts of the heated object by transmitting the flame generated in the combustion part of the regenerative burner to the upper and lower parts of the heated object.

In general, regenerative burners for recovering the waste heat contained in the combustion gas to increase the temperature of the combustion air are used in heating furnaces and other industrial furnaces, and the regenerative burners have a combustion furnace (as shown in FIGS. 1 and 2). The inside of 1) is provided with a skid (1a) for supporting the object to be heated (A), the combustion section (3) in the intake and exhaust holes (2) (2a) formed on both sides of the combustion furnace (1) 3a) are provided respectively, and the fuel nozzles 4 and 4a to which fuel is supplied are provided in the upper and lower parts of each said combustion part 3 and 3a.

And inside the combustion section (3) (3a) there is a built-in regenerator (5) (5a) for accumulating the sensible heat contained in the exhaust gas, and at the end of each combustion section (3) (3a) a connecting pipe ( 6) (6a) is provided and the connecting pipe (6) (6a) is connected to the switching valve (7) to be switched in all directions.

On the other hand, the switching valve 7 is provided with a suction pipe 8a for sucking external combustion air and an exhaust pipe 8 for discharging the exhaust gas to the outside, and the combustion air and exhaust pipes are provided in the suction pipe 8a and the exhaust pipe 8. A suction fan 9a and an exhaust fan 9 for forcibly circulating gas are provided, respectively.

Therefore, after placing the heated object A on the upper part of the skid 1a installed in the combustion furnace 1, the valve installed in the fuel nozzle 4 is opened and the valve installed in the fuel nozzle 4 is closed to burn the combustion part. When the fuel is supplied only to the side (3) and the suction fan 9a is operated, the combustion air sucked into the suction fan 9a exchanges heat through the regenerator 5 through the switching valve 7 and then heats up. Is supplied to the intake and exhaust holes 2 formed on the combustion section 3 side in a raised state and mixed with fuel.

At this time, when the ignition device (not shown) mounted to the combustion unit 3 is operated, fuel mixed with air is ignited and burned in the combustion furnace 1, and the combustion gas of high temperature (over 1000 ° C) generated at this time is skid. After heating the heated object (A) seated on the upper portion of (1a) is moved to the combustion section (3a) through the intake and exhaust holes (2a) formed on the other side and the heat exchange in the heat accumulator (5a) built therein The low temperature (200 ° C. or less) exhaust gas discharged through the heat storage device 5a is forcedly circulated by the exhaust fan 9 and discharged to the outside.

In this manner, after the combustion unit 3 is operated for a predetermined time, the valve installed in the fuel nozzle 4 is closed, the valve installed in the fuel nozzle 4a is opened, and the switching valve 7 is switched to operate the combustion unit 3a. The exhaust gas is discharged to the combustion unit 3 side, and the skid 1a is overheated while cooling water continuously circulates inside the skid 1a supporting the heated object A. Will be prevented.

Thus, the flame which generate | occur | produced in the combustion part 3 (3a) heats to-be-heated object A through the intake and exhaust hole 2 and 2a.

However, in the conventional heat storage burner, the flame generated from the combustion unit 3 (3a) is uniformly supplied to the upper and lower portions of the heated object A, and the heated object A is uniformly heated. Since the lower part of (A) is cooled by the cooling water circulating inside the skid 1a, there is a problem that a temperature deviation occurs in the upper and lower parts of the heated object A.

The present invention is designed to solve the above problems, by forming a partition for dividing the inner side of the combustion portion into the upper and lower parts to control the intensity of the flame delivered to the heated object to uniformly heat the heated object. It is an object of the present invention to provide a temperature homogenizer for a regenerative burner.

The present invention for achieving the above object is a combustion burner is installed on both sides of the combustion furnace and each combustion section has a heat storage burner with a heat storage built in to accumulate the sensible heat contained in the exhaust gas, to distinguish the combustion unit in which the heat storage is built-in A separation pipe provided between the combustion sections, a connection pipe installed at each end of the combustion section divided by the separation wall to move combustion air and exhaust gas, and combustion air and exhaust air flow through the connection pipe provided on the connection pipe. A first valve, a second valve, a third valve for controlling the direction of the gas, a control valve installed between the second valve and the third valve, for controlling the amount of combustion air moving toward the connecting pipe, and the first valve. It is installed between the second valve and the other end is connected between the switching valve and the first branch pipe for discharging the exhaust gas, and is installed between the control valve and the third valve and the other side The end part includes a second branch pipe connected to the switching valve to supply combustion air.

1 is a schematic view showing a typical regenerative burner.

2 is a cross-sectional view showing a combustion part of a conventional regenerative burner;

3 is a schematic view showing a regenerative burner having a material temperature homogenizing device according to the present invention;

4 is a cross-sectional view showing a combustion unit in which the material temperature homogenizing device is installed according to the present invention;

5a to 5d is a cross-sectional view showing the movement of air in the combustion mode and exhaust mode of the material temperature homogenizer according to the present invention,

6a to 6d is a flame distribution diagram inside the regenerative combustion unit is installed the material temperature homogenizer according to the present invention.

* Description of the symbols for the main parts of the drawings *

30: dividing wall 40, 40a: combustion section

50, 50a: heat storage 60, 60a: connector

70: first valve 71: second valve

72: third valve 80: switching valve

90: first branch engine 91: second branch engine

100: control valve 101: flow meter

110: suction pipe 120: exhaust pipe

130: suction fan 140: exhaust fan

Hereinafter, the present invention will be described in detail with reference to FIGS. 3 and 4.

The present invention is installed on both sides of the combustion furnace 10, as shown in Figure 3, installed between the fuel nozzles 20, 20a installed in the combustion furnace 10, as shown in Figure 4 and Is divided by the dividing wall 30, and combustion parts 40 and 40a are formed, and inside each combustion part 40 and 40a, intake and exhaust holes 11 and 11a are formed in the combustion furnace 10. Through the inside of the combustion furnace (10).

In each of the combustion parts 40 and 40a, there is a built-in heat storage device 50 and 50a for accumulating the sensible heat contained in the exhaust gas, and a connection pipe (at the end of each of the combustion parts 40 and 40a). 60, 60a are provided, and the first and second valves 70, 71, and third valves 72 are sequentially installed in the connecting pipes 60 and 60a.

In addition, between the first valve 70 and the second valve 71, a first branch pipe 90 connected to the switching valve 80 is installed, and the second valve 71 and the third valve 72 are provided. Between the switching valve 80 and the second branch pipe 91 is provided between the supply portion between the second branch pipe 91 is connected to the combustion section 40 between the second valve (71). The control valve 100 and the flow meter 101 for adjusting the amount of combustion air is provided.

Meanwhile, the switching valve 80 is provided with a supply pipe 110 through which combustion air is supplied and a discharge pipe 120 through which exhaust gas is discharged, and a suction fan 130 at the end of the supply pipe 110 and the discharge pipe 120. The exhaust fan 140 is provided, respectively.

When the present invention configured as described above is used in the combustion mode, as illustrated in FIG. 5A, the valves installed in the first, second, and third valves 70, 71, 72, and the suction pipe 110 are opened to the exhaust pipe 120. When the suction fan 130 is operated while the installed valve is closed, combustion air is supplied to the connecting pipes 60 and 60a through the switching valve 80 and the second branch pipe 91.

The amount of combustion air supplied to the connecting pipes 60 and 60a is adjusted according to the opening and closing degree of the control valve 100, and the separated combustion air is the heat storage unit 50 having the combustion parts 40 and 40a. The heat exchange is performed while passing through 50a, and the temperature is increased to be supplied to the combustion furnace 10 through the intake / exhaust pipes 11 and 11a formed in the combustion furnace 10.

Combustion air supplied into the combustion furnace 10 is mixed with fuel injected from the fuel nozzles 20 and 20a and ignited by an ignition device (not shown), and the flame generated at this time is applied to the skid 12. The flame is transferred to the heated object A to be seated, and the flame is heated because the intensity of the upper and lower parts is different depending on the amount of combustion air supplied through the connecting pipes 60 and 60a as shown in FIG. 6A. If the flame supplied to the upper part of (A) is made small and the flame supplied to the lower part is made large, the heated object A can be heated uniformly.

On the other hand, when the heated object A is used in the exhaust mode to exhaust the heated exhaust gas, as shown in FIG. 5B, the first, second and third valves 70, 71, 72 and the exhaust pipe 120 are shown. When the exhaust fan 140 is operated while the valve installed at the suction pipe 110 is opened and the valve installed at the suction pipe 110 is closed, the exhaust gas that is discharged from the combustion furnace 10 and completed heat exchange with the heat accumulators 50 and 50a is connected to the connection pipe. 60, 60a and the switching valve 80 is moved.

At this time, the exhaust gas moved to the switching valve 80 is discharged to the outside through the exhaust pipe 120 without moving to the suction pipe 110 because the valve installed in the suction pipe 110 is closed.

As described above, one side of the combustion furnace 10 is operated in the combustion mode and the other side is operated in the exhaust mode, and after a predetermined time elapses, the combustion mode and the exhaust mode are switched. In this case, the flame of the combustion furnace 10 is shown in FIG. As shown in FIG. 2, the object to be heated (A) is transferred to the object to be heated (A).

Alternatively, as shown in FIG. 5C, in order to use the combustion unit 40 in the combustion mode and the combustion unit 40a in the exhaust mode, the first and third valves 70 and 72, the suction pipe 110, and the exhaust pipe 120 are disposed. When the suction fan 130 and the exhaust fan 140 are operated while the valve installed at the) is opened and the second valve 71 is closed, the combustion air is supplied to the combustion furnace 10 through the combustion unit 40 and the combustion is performed. The exhaust gas in the furnace 10 exchanges heat with the heat storage unit 50a installed in the combustion unit 40a and is moved through the connecting pipe 60a and the switching valve 80 to be discharged to the outside by the exhaust fan 140. At this time, the flame inside the combustion furnace 10 is transferred to the lower portion of the heated object A as shown in FIG. 6C.

When the upper portion of the heated object A is heated, the valve is operated as shown in FIG. 5D. In this case, only the switching valve 80 is switched in a state in which the lower portion of the heated object A is heated. The flame of is delivered as shown in Figure 6d.

Therefore, it is possible to uniformly heat the upper part or the lower part of the heated object A or to heat one side to a high temperature.

As described above, the present invention provides a pair of combustion units on both sides of the combustion furnace to control the size of the flame generated in each combustion unit, as well as selectively set the combustion mode or the exhaust mode to uniformly heat the heated object. It is a very useful design that can be heated to improve the efficiency of the regenerative burner.

Claims (1)

In the regenerative burner having a combustion section is installed on both sides of the combustion furnace, each combustion section has a built-in heat accumulator for accumulating the latent heat contained in the exhaust gas, In order to distinguish between the combustion parts 40 and 40a in which the heat accumulators 50 and 50a are built, the separation wall 30 provided between the combustion parts 40 and 40a and the separation wall 30. Connecting pipes 60 and 60a respectively installed at the ends of the combustion parts 40 and 40a separated by the moving pipes and moving the combustion air and exhaust gas, and installed on the connecting pipes 60 and 60a. First, second and third valves 70, 71 and 72 for adjusting the direction of combustion air and exhaust gas flowing through the 60 and 60a, and the second and second valves 71 and 3 Control valve 100 is installed between the 72 and controls the amount of combustion air moving to the connecting pipe 60 side, and is installed between the first valve 70 and the second valve 71 and the other side An end is connected to the switching valve 80 to discharge the exhaust gas, the first branch pipe 90, and is installed between the control valve 100 and the third valve 72, the other end is the switching valve 80 A second branch pipe (91) connected to the Regenerative burners material temperature equalized device for the configuration of features.