KR102376676B1 - Burner and heat treatment facility - Google Patents

Abstract

When the fuel gas guided by the fuel gas supply pipe on the inner periphery of the air supply pipe and the air guided by the air supply pipe are mixed and combusted, the tip of the fuel gas supply pipe is installed so as to taper to the outer periphery toward the front. An air introduction hole and an air guide for guiding the air from the air supply pipe into the flame retaining cylinder are provided in the flame retainer, and a main injection port for ejecting fuel gas from the center of the fuel gas supply pipe to the tip of the fuel gas supply pipe; A control device for controlling the amount of fuel gas and/or air was provided by providing a plurality of partial sand openings to be ejected from the vicinity of the injection ports.

Description

BURNER AND HEAT TREATMENT FACILITY

The present invention provides a burner device in which a fuel gas supply pipe is installed on the inner periphery of the air supply pipe, and fuel gas guided through the fuel gas supply pipe and air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe are mixed and combusted; It relates to a heat treatment facility using such a burner device. In particular, in the burner device, even when the amount of fuel gas guided through the fuel gas supply pipe is reduced, the fuel gas is appropriately mixed with the air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe to generate a flame. It is maintained properly and has a feature in that it can increase the turn-down ratio of the burner.

Conventionally, in a heat treatment facility such as an industrial furnace, a fuel gas supply pipe is provided on the inner periphery side of an air supply pipe, and fuel gas guided through the fuel gas supply pipe and the fuel gas supply pipe are guided to the outer periphery of the fuel gas supply pipe through the air supply pipe. A burner device that mixes air and burns it is widely used.

Here, in such a burner device, if the amount of fuel gas guided through the fuel gas supply pipe and the amount of air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe are generally reduced, the fuel gas and air are not sufficiently mixed. There was a problem that a large turn-down ratio could not be ensured because the combustion could not be continued because it was not maintained.

Therefore, conventionally, in order to respond to the case where the flame in a burner apparatus was extinguished as mentioned above, providing a pilot burner and an electric ignition device in a burner apparatus was performed.

However, when a pilot burner is installed in this way, a facility for separately supplying fuel gas or the like to the pilot burner is required, and there are problems such as high cost and an enlargement of the device.

Also, in the prior art, as shown in Patent Document 1, the central portion of the ejection hole forming portion provided so as to protrude in a tapered shape from the tip of the burner body to which the mixed gas obtained by mixing fuel gas and air is supplied to the tip. At the same time, a hole for forming a flame retardant is provided in the tapered inclined portion at the same time as providing a main blowing hole in the It is shown that a cylindrical protective part is provided, and the said mixed gas ejected from the hole for flame retardant formation is made to burn in a protective part.

However, in Patent Document 1, a mixed gas in which fuel gas and air are mixed in advance is guided to a jet hole forming portion provided at the tip of the burner body portion, and the mixture is blown out from a flame retardant forming hole provided in an inclined portion of the jet hole forming portion. Since gas is combusted within the protection part, when the quantity of the fuel gas in mixed gas was decreased, there existed a problem that it became difficult to burn mixed gas stably.

Further, in Patent Document 2, a plurality of turning and branching combustion air toward the front in opposite directions on the entire circumferential wall of the main body of the inverted cone shape with the passage port of the injection fuel opened. It is shown that the front slit and the rear slit are opened radially across the front and rear two ends at a distance, while the rear slit is opened up to the passage hole.

However, as shown in Patent Document 2, the injection fuel passage port is opened in the central portion of the inverted cone-shaped main body, and fuel is only injected through the passage port of this central portion, so when the amount of injected fuel is reduced, The fuel injected from the central passage port is not necessarily necessarily combusted in sufficient contact with the combustion air that turns and diverges from the front slit and the rear slit toward the front. There was a problem that it would be difficult to maintain it.

Also in Patent Documents 3 and 4, burners are proposed in which the amount of fuel to be supplied is changed to satisfy a high turn-down ratio in which combustion can be achieved over a wide range.

However, even as shown in Patent Documents 3 and 4, there is still a problem in that it is difficult to reliably maintain the flame when the amount of fuel to be injected is reduced.

In addition, as shown in Patent Document 5, a pair of heat storage chambers in which a heat storage material is accommodated are provided in the vicinity of the burner device, and in one heat storage chamber, for combustion heated by the heat stored in the heat storage material accommodated in the heat storage chamber Air is injected toward the fuel gas ejected from the fuel gas supply pipe in the burner device to burn the fuel gas, while in the other heat storage chamber, the fuel gas is burned to release the subsequent combustion exhaust gas. In a heat processing apparatus characterized in that the operation of sucking the thermal storage material accommodated in the thermal storage chamber and accumulating heat is performed, and the operation in the one thermal storage chamber and the other thermal storage chamber is alternately switched, the combustion air is injected Since it takes several seconds for the switching valve to switch between the intake and intake time, and the air flow becomes unstable during that time, the fuel gas supply is cut off and the flame is extinguished in the past. Therefore, it is necessary to provide an ignition device such as a pilot burner or an electric ignition device and re-ignite it every time the combustion air is switched, and there is a problem that the structure and control of the combustion device become complicated. Moreover, since it will become difficult to maintain the atmospheric temperature of burner apparatus vicinity when a flame|flame is extinguished, it became a factor to which furnace internal temperature will fluctuate.

Japanese Patent Application Laid-Open No. 2007-263452 Publication No. 63-142522 in Japan Japanese Patent Application Laid-Open No. 51-150129 Publication No. 62-910 in Japan Japanese Patent Laid-Open No. 2007-24335

This invention makes it a subject to solve the above problems in a burner apparatus.

In particular, a fuel gas supply pipe is installed on the inner periphery of the air supply pipe, and fuel gas guided through the fuel gas supply pipe and air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe are mixed and combusted. In the burner device, Even when the amount of fuel gas guided through the fuel gas supply pipe is reduced, the fuel gas is properly mixed with the air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe, so that the flame is properly maintained, and the burner turns The task is to make the down ratio large.

In the burner device according to the present invention, in order to solve the above problems, a fuel gas supply pipe is provided on the inner periphery side of the air supply pipe, the fuel gas guided through the fuel gas supply pipe, and the fuel gas supply pipe through the air supply pipe In the burner device for mixing and burning air guided to the outer periphery of the air supply pipe, the fuel gas supply pipe provided on the inner periphery of the air supply pipe is provided with a flame retardant that tapers toward the outer periphery toward the front, , an air introduction hole for guiding the air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe into the flameproofing tube, and a portion of the air introduction hole to protrude on the upstream side of the air flow to supply air from the air supply pipe to the air a main injection port for discharging fuel gas guided through the fuel gas supply pipe from the center of the fuel gas supply pipe to the tip of the fuel gas supply pipe, and a periphery of the main injection port A plurality of sub-injection ports to be blown out by the ? are provided, and a control device for controlling the amount of fuel gas supplied to the fuel gas supply pipe and/or the amount of air supplied to the air supply pipe is provided.

And, in the burner device of the present invention, the fuel gas guided through the fuel gas supply pipe is ejected from the main injection port in the central portion of the tip of the fuel gas supply pipe and from a plurality of partial sand openings provided around the main injection port. , The air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe is installed in the flame retention container tapered toward the outer periphery toward the front end of the fuel gas supply pipe by the air guide unit installed in the flame retention container It is guided into the flameproof container through the air inlet hole. In this way, even when the amount of fuel gas guided through the fuel gas supply pipe is reduced, the fuel gas is ejected from the plurality of partial sand openings provided around the main injection port in addition to the main injection port, and the fuel ejected from the plurality of partial sand openings. As the gas flows along the taper, the gas is sufficiently mixed with the air guided into the flame-retardant container through the air introduction hole by the air guide installed in the flame-retardant container from the air supply pipe and is combusted, and the flame is stably maintained.

In addition, the air introduction hole is a slit in the oblique direction with respect to the air flow, and since the air guide part protrudes on the upstream side of the air flow, it can receive a lot of air flow and rotate it in the oblique direction to guide it into the flame chamber, Mixing with fuel gas is further accelerated|stimulated by the stirring effect.

Further, in the burner device according to the present invention, the main injection port for ejecting fuel gas from the central portion of the fuel gas supply pipe is provided so as to protrude from the front end side of the plurality of partial sand openings for ejecting fuel gas around the main injection port, , it is preferable to provide a guide for guiding the fuel gas ejected from each of the partial sand openings around the main injection port. In this way, even when the amount of fuel gas guided through the fuel gas supply pipe is reduced, the fuel gas ejected from each partial sand opening around the main injection port passes through the guide part without being influenced by the outside. It is properly guided to the position of the air guided from the air inlet hole into the flame chamber, and the air is sufficiently mixed to maintain the flame. In addition, as described above, when the plurality of partial sand dunes are installed to be inclined toward the outer periphery of the fuel gas supply pipe and guided along the tapered portion of the flameproofing tube, The fuel gas is properly guided from the air inlet hole to the position of the air guided into the flameproofing container through the guide portion without being influenced by the outside, so that it is sufficiently mixed with the air to maintain the flame more reliably.

Further, in the heat treatment facility according to the present invention, using the burner device as described above, the control device controls the amount of fuel gas guided through the fuel gas supply pipe, and controls combustion so that heat treatment can be performed. did.

And, in this heat processing facility, the combustion of fuel gas can be controlled by controlling the amount of fuel gas supplied to the fuel gas supply pipe and/or the amount of air supplied to the air supply pipe by the control device, Even when the amount of fuel gas guided through the fuel gas supply pipe is reduced as described above, the fuel gas ejected from each partial sand opening around the main injection port is discharged from the air supply pipe by the air guide unit as described above. Combustion is sufficiently mixed with the air guided into the flame chamber through the inlet hole, and the flame is maintained, increasing the burner turn-down ratio and controlling the combustion of fuel gas in a wide range.

Further, in the heat treatment facility according to the present invention, a pair of heat storage chambers in which the heat storage material is accommodated are provided in the vicinity of the burner device, and in one heat storage chamber, heating is performed by the heat stored in the heat storage material accommodated in the heat storage chamber. Combustion after burning the fuel gas in the other heat storage chamber while performing an operation|movement which injects the used combustion air toward the fuel gas ejected from the fuel gas supply pipe in the said burner apparatus to burn fuel gas. The operation of sucking the exhaust gas into the thermal storage chamber and accumulating heat in the received thermal storage material can be performed, and the operation in the one thermal storage chamber and the other thermal storage chamber can be switched alternately.

Here, in the heat processing facility in which a pair of heat storage chambers in which the heat storage material is accommodated are provided in the vicinity of the burner device as described above, when the operation in the one heat storage chamber and the other heat storage chamber is alternately switched, the burner By reducing the amount of fuel gas supplied to the fuel gas supply pipe in the device, the fuel gas is ejected from the main injection port in the central portion of the fuel gas supply pipe and a plurality of partial sand openings in the periphery of the fuel gas supply pipe, It is possible to continue combustion of fuel gas by mixing with the air guided into the flame-retaining container through a portion of the air introduction hole in the flame-retaining container. In this way, when the operation in one heat storage chamber and the other heat storage chamber is alternately switched, the flame in the burner device is not extinguished, and even if a pilot burner or electric ignition device is not installed, one The operation of alternately switching the operation in the thermal storage chamber and the other thermal storage chamber can be continuously and stably performed.

In the burner device of the present invention, even when the amount of fuel gas guided through the fuel gas supply pipe is reduced as described above, the fuel gas is the main injection port of the fuel gas supply pipe and a plurality of portions provided around the main injection port. The fuel gas ejected from the sand dunes and ejected from the plurality of partial sand dunes is provided so as to protrude toward the outer periphery of the flame retainer toward the upstream side of the air flow as described above in the flame retainer installed at the tip of the fuel gas supply pipe. It is guided through the air inlet hole, so that it is sufficiently mixed with air to burn, and the flame is maintained.

As a result, in the heat processing facility using the burner apparatus in this invention, the turn-down ratio of a burner is enlarged and it becomes possible to control combustion of fuel gas in a wide range.

Further, in the heat treatment facility, a pair of heat storage chambers in which the heat storage material is accommodated are provided in the vicinity of the burner device, and in one heat storage chamber, for combustion heated by the heat stored in the heat storage material accommodated in the heat storage chamber Air is injected toward the fuel gas ejected from the fuel gas supply pipe in the burner device to burn the fuel gas, while in the other heat storage chamber, the combustion exhaust gas after burning the fuel gas is removed When the operation of accumulating heat in the thermal storage material accommodated in the thermal storage chamber is alternately switched, when the operation in one thermal storage chamber and the other thermal storage chamber is alternately switched, the flame in the burner device is not extinguished Even if a pilot burner or an electric ignition device is not provided, temperature fluctuations in the furnace are eliminated even during the operation of alternately switching the switching valves for the operation in one heat storage chamber and the other heat storage chamber.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic explanatory drawing of the burner apparatus used in one Embodiment of this invention.
Fig. 2 is a schematic cross-sectional explanatory view showing a state in which fuel gas and air flow in the tip portion of the burner device used in the embodiment.
3 : is the schematic explanatory drawing which looked at the front-end|tip part of the burner apparatus used for the said embodiment from the front.
4 is an air introduction hole for guiding air guided to the outer periphery side of the fuel gas supply pipe to the fuel gas supply pipe side in the flame retaining cylinder in the burner device used in the above embodiment. It is a schematic cross-sectional explanatory drawing which shows the state in which the air guide part is installed.
5 : shows the 1st heat processing facility using the burner apparatus in the said embodiment, (A) increases the quantity of the fuel gas supplied to the fuel gas supply pipe, and the quantity of the air supplied to the air supply pipe, The flame A schematic cross-sectional explanatory diagram showing a state in which the combustion amount is increased by increasing It is a schematic cross-sectional explanatory drawing which showed the state.
6 is a second heat treatment facility in which a pair of heat storage chambers in which a heat storage material is accommodated are provided in the vicinity of the burner device in the above embodiment. The combustion air is injected toward the fuel gas ejected from the fuel gas supply pipe in the burner device to burn the fuel gas, while the combustion exhaust gas after burning the fuel gas is stored in the heat storage material accommodated in the other heat storage chamber. It is a schematic cross-sectional explanatory drawing which showed the state to make.
7 shows combustion air heated by the heat stored in the heat storage material accommodated in one heat storage chamber when switching operations in one heat storage chamber and the other heat storage chamber in the second heat treatment facility. is injected toward the fuel gas ejected from the fuel gas supply pipe in the burner device to burn the fuel gas, and the combustion exhaust gas after burning the fuel gas is stored in the heat storage material accommodated in the other heat storage chamber. It is a schematic cross-sectional explanatory drawing which showed the state which made the flame in the said burner apparatus small and flame-retaining in the state made to stop.
Fig. 8 shows combustion air heated by the heat stored in the heat storage material accommodated in the other heat storage chamber by switching operations in one heat storage chamber and the other heat storage chamber in the second heat treatment facility. In the burner device, the fuel gas is injected toward the fuel gas ejected from the fuel gas supply pipe to burn the fuel gas, while the combustion exhaust gas after burning the fuel gas is stored in the heat storage material accommodated in one heat storage chamber. It is a schematic cross-sectional explanatory drawing.

EMBODIMENT OF THE INVENTION Hereinafter, the burner apparatus and heat processing equipment which concern on embodiment of this invention are demonstrated concretely with reference to an accompanying drawing. In addition, the burner apparatus and heat processing equipment which concern on this invention are not limited to what was shown in the following embodiment, In the range which does not change the summary of invention, WHEREIN: It is a thing which can be changed suitably and can be implemented.

In the burner apparatus 10 in this embodiment, as shown in FIG. 1, while air is supplied into the air supply pipe 11 from the air introduction part 11a by the air supply device X, while fuel gas is The supply device Y causes fuel gas to be supplied from the fuel gas introduction part 12a into the fuel gas supply pipe 12 disposed on the inner peripheral side of the air supply pipe 11, and by the air supply device X The control device Z controls the amount of air to be supplied into the air supply pipe 11 and the amount of fuel gas to be supplied into the fuel gas supply pipe 12 by the fuel gas supply device Y.

Then, as described above, the air supplied into the air supply pipe 11 and the fuel gas supplied into the fuel gas supply pipe 12 are guided to the tip side of the burner device 10 to be mixed and burned. Further, in the burner device 10, when the air supplied into the air supply pipe 11 and the fuel gas supplied into the fuel gas supply pipe 12 are mixed at the tip of the burner device 10 and burned, the A spark plug 13 is installed in the central portion of the fuel gas supply pipe 12 so as to reach the tip side of the burner device 10, and the mixed gas obtained by mixing air and fuel gas is ignited by the spark plug 13. to start combustion.

And in the burner apparatus 10 in this embodiment, as shown in FIGS. An air inlet hole 14a for providing a flame retardant tube 14, and guiding the air guided to the outer periphery of the fuel gas supply pipe 12 through the air supply pipe 11 to the flame retardant tube 14 into the flame retardant tube 14. are provided at appropriate intervals in the circumferential direction, and protrude from the air supply pipe (11) to the upstream side of the air flow in the portion of each air inlet hole (14a) in the flame retaining tube (14). An air guide portion 14b for receiving and guiding into each of the air introduction holes 14a (see Fig. 4F) is provided.

In addition, a blowout member 15 for jetting fuel gas guided through the fuel gas supply pipe 12 is attached to the tip of the fuel gas supply pipe 12, and the tip center portion of the jetting member 15 is provided. A main injection port 15a for ejecting fuel gas from the central portion of the fuel gas supply pipe 12 is provided, and a partial sand opening 15b for ejecting fuel gas outward from the periphery of the rear side of the main injection port 15a. is provided in the circumferential direction through a required interval, and a concave guide portion 15c is provided for guiding the fuel gas ejected from each of the partial sand openings 15b around the main injection openings 15a.

In this way, a plurality of partial sand openings 15b for ejecting fuel gas outward from the periphery of the rear side of the main injection openings 15a are provided in the circumferential direction through a required interval, and at the same time, around the main injection openings 15a. If the guide portion 15c for guiding the fuel gas ejected from each of the partial sand openings 15b in the The fuel gas ejected from each of the partial sand openings 15b around the injection port 15a is guided to the outer peripheral side of the tip of the fuel gas supply pipe 12 through the guide portion 15c around the main injection port 15a. It proceeds along the flame retention container 14 that is widened in a tapered shape by the Coanda effect, and is sufficiently mixed with the air guided into the flame retention container 14 through the air introduction hole 14a and burned, The flame will be maintained.

Next, as a 1st heat processing facility, the case where the said burner apparatus 10 is used for the industrial furnace 20 as shown to Fig.5 (A), (B) is demonstrated.

Here, in this industrial furnace 20, the tip end of the burner device 10 is attached so as to penetrate the furnace wall 21, and by the control device Z and the fuel gas supply device Y The amount of air to be supplied into the air supply pipe 11 from the air inlet 11a by the air supply device X while controlling the fuel gas supplied from the fuel gas inlet 12a into the fuel gas supply pipe 12 is to control.

And in the said burner apparatus 10, in increasing the combustion amount of the fuel gas in the industrial furnace 20, as shown to FIG.5(A), as shown in FIG.5(A), the fuel gas supplied to the fuel gas supply pipe 12 Increase the amount and the amount of air supplied to the air supply pipe 11, and increase the amount of combustion by increasing the flame.

On the other hand, in the said burner apparatus 10, when reducing the combustion amount of fuel gas in the industrial furnace 20, as shown to FIG.5(B), the fuel gas supplied to the fuel gas supply pipe 12 is The amount and the amount of air supplied to the air supply pipe 11 are reduced, and the flame is reduced to reduce the amount of combustion.

Here, when the burner device 10 is used, as shown in FIG. 5B , even if the amount of fuel gas supplied to the fuel gas supply pipe 12 and the amount of air supplied to the air supply pipe 11 are reduced, , as described above, the fuel gas ejected from each of the partial sand openings 15b around the main injection port 15a passes through the guide portion 15c around the main injection port 15a through the fuel gas supply pipe 12. is guided to the outer periphery side of the tip of the and proceeds along the tapered flame-retaining cylinder 14, is sufficiently mixed with the air guided into the flame-retaining cylinder 14 through the air introduction hole 14a, and is combusted, making it difficult for the flame to misfire It becomes possible to secure a large turn-down ratio of the burner, and to control the combustion of fuel gas in a wide range.

Next, as a second heat treatment facility, as shown in FIGS. 6 to 8 , the tip of the burner device 10 is attached so as to penetrate the furnace wall 21 of the industrial furnace 20, and the burner In the vicinity of the device 10, a pair of heat storage chambers 30A and 30B in which the heat storage materials 31A and 31B are accommodated are provided on both sides of the burner device 10, and in each of the heat storage chambers 30A and 30B, respectively. A case in which the guide tubes 32A and 32B are provided on both sides of the burner apparatus 10 so as to penetrate the furnace wall 21 of the industrial furnace 20 will be described.

Here, in the said 2nd heat processing facility, as shown in FIG. 6, in the state which increased the quantity of the fuel gas ejected from the fuel gas supply pipe 12 in the said burner apparatus 10, the said one Combustion air heated by the heat stored in the thermal storage material 31A accommodated in the thermal storage chamber 30A is injected toward the fuel gas ejected from the fuel gas supply pipe 12 through the guide pipe 32A. While the operation of burning the fuel gas in the furnace 20 is performed, in the other heat storage chamber 30B, the combustion exhaust gas after burning the fuel gas as described above is discharged into the industrial furnace 20 as described above. It is sucked through the guide tube 32B and guided to the heat storage chamber 30B, and heat is stored in the heat storage material 31B accommodated in the heat storage chamber 30B.

In addition, illustration of piping and switching valve provided in heat storage chamber 30A, 30B in order to inject combustion air or to suck|suck combustion exhaust gas is abbreviate|omitted here.

Next, during the operation of the switching valve for alternately switching the operation in one heat storage chamber 30A and the other heat storage chamber 30B, as shown in Fig. 7, in one heat storage chamber 30A The operation of blowing the heated combustion air into the industrial furnace 20 through the guide pipe 32A is stopped, and the combustion exhaust gas after burning the fuel gas in the other heat storage chamber 30B is industrially discharged. The operation of guiding to the heat storage chamber 30B through the guide pipe 32B in the furnace 20 is stopped, and in this state, the amount of fuel gas supplied to the fuel gas supply pipe 12 and the air supply pipe ( 11) Decrease the amount of air supplied to Even if the amount of fuel gas supplied to the fuel gas supply pipe 12 and the amount of air supplied to the air supply pipe 11 are reduced in this way, when the burner device 10 is used, the The fuel gas ejected from each of the partial sand openings 15b in the periphery is guided to the outer peripheral side of the distal end of the fuel gas supply pipe 12 through the guide portion 15c in the periphery of the main injection port 15a, and the air is introduced. It is sufficiently mixed with the air guided into the flame chamber 14 through the hole 14a and burned to prevent the flame from extinguishing.

Thereafter, the operation in one heat storage chamber 30A and the other heat storage chamber 30B is switched, and as shown in FIG. 8 , the fuel gas supply pipe 12 in the burner device 10 is In a state in which the amount of fuel gas ejected from is increased, the combustion air heated by the heat stored in the thermal storage material 31B accommodated in the other thermal storage chamber 30B is fed through the guide tube 32B. The fuel gas is injected toward the fuel gas ejected from the fuel gas supply pipe 12 to burn the fuel gas in the industrial furnace 20, and in one heat storage chamber 30A, the fuel gas is injected as described above. The combustion exhaust gas after combustion is guided to the heat storage chamber 30A through the guide pipe 32A in the industrial furnace 20 and stored in the heat storage material 31A accommodated in the heat storage chamber 30A. do.

Here, in the second heat treatment facility, when switching operations in one heat storage chamber 30A and the other heat storage chamber 30B as described above, the fuel supplied to the fuel gas supply pipe 12 . Even if the amount of gas and the amount of air supplied to the air supply pipe 11 are reduced, the flame in the burner device 10 is not extinguished, and even if a pilot burner is not provided, one heat storage chamber 30A It becomes possible to continuously and stably switch the operation of the operation in the heat storage chamber 30B on the other side.

In addition, in the heat processing facility in the said embodiment, although the example in which the said burner apparatus 10 is used for the industrial furnace 20 was shown, the heat processing facility which uses the said burner apparatus 10 is such an industrial furnace ( 20), although not shown, it can also be used for drying or heating of a ladle or the like.

10 burner device
11 air supply line
11a air inlet
12 fuel gas supply line
12a fuel gas inlet
13 spark plug
14 sore throat
14a air intake hole
14b air guide
15 ejection member
15a main nozzle
15b partial dunes
15c guide
20 industrial road
21 furnace wall
30A, 30B heat storage room
31A, 31B heat storage material
32A, 32B Concierge
F Combustion air flow
X air supply
Y fuel gas supply
Z control unit

Claims (5)

In the burner device, a fuel gas supply pipe is installed on the inner periphery of the air supply pipe, and fuel gas guided through the fuel gas supply pipe and air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe are mixed and combusted, wherein the air At the tip of the fuel gas supply pipe installed on the inner periphery of the supply pipe, a flame retardant that tapers toward the outer periphery is installed, and the air guided to the outer periphery of the fuel gas supply pipe through the air supply pipe is installed in the flame retainer. An air introduction hole for guiding inward, and an air guide for guiding air from the air supply pipe to the air introduction hole by protruding on the outer periphery of the flame retainer toward the upstream side of the air flow in the portion of the air introduction hole, A main injection port for ejecting the fuel gas guided through the fuel gas supply pipe from the central portion of the fuel gas supply pipe is provided at the front end of the fuel gas supply pipe, and a plurality of partial sand openings for ejecting the fuel gas around the main injection port are provided;
The main injection port is installed so as to protrude from the front end side of the plurality of partial sand openings, and a guide part for guiding the fuel gas ejected from each of the partial sand openings is provided around the main injection openings, and at the same time, the plurality of partial sand openings are fueled A control device is installed that is inclined toward the outer periphery of the gas supply pipe and controls either or both of the amount of fuel gas supplied to the fuel gas supply pipe and the amount of air supplied to the air supply pipe. burner device with In the description of claim 1,
The burner device, characterized in that the air introduction hole is a slit inclined in an oblique direction with respect to the air flow. A heat treatment facility characterized by performing heat treatment by controlling the amount of fuel gas guided through a fuel gas supply pipe by the control device using the burner device according to claim 1 or 2, and controlling combustion. In the description of claim 3,
A pair of heat storage chambers in which the heat storage material is accommodated are provided in the vicinity of the burner device, and in one heat storage chamber, combustion air heated by the heat stored in the heat storage material accommodated in the heat storage chamber is provided in the burner device. While the operation of burning the fuel gas by injecting it toward the fuel gas ejected from the fuel gas supply pipe is performed, in the other heat storage chamber, the combustion exhaust gas after burning the fuel gas is sucked into the heat storage material accommodated in this heat storage chamber A heat treatment facility, characterized in that the operation of accumulating heat is carried out, and the operation of the one heat storage chamber and the operation of the other heat storage chamber is alternately switched. In the description of claim 4,
When the operation in the one heat storage chamber and the other heat storage chamber is alternately switched, the amount of fuel gas supplied to the fuel gas supply pipe in the burner device is reduced, and Fuel gas is ejected from the main injection port and a plurality of partial sand openings around the main injection port, and the fuel gas is mixed with the air guided into the flame retention cylinder through a portion of the air introduction hole in the flame retention cylinder, thereby burning the fuel gas. Heat treatment equipment, characterized in that to continue.

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