JPH09178162A - Regenerator and regenerative burner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make even the temperature distribution of a regenerator by making even, the flow rate distribution of combustion exhaust gas and air for combustion. SOLUTION: A regenerating device used for improving the thermal conversion efficiency of a heating furnace is provided with a barrier block 9 in the exhaust gas inlet side space 4a of a regenerator housing container 1 in which a regenerator 2 is housed and an air supply nozzle 10 in an exhaust gas outlet side space 4b. Combustion exhaust gas is dispersed and supplied to the regenerator 2 by the barrier block 9 and air for combustion is partly concentrated and supplied to the regenerator 2 by the air supply nozzle 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat storage device and a heat storage type burner, and more particularly to a heat storage device and a heat storage type burner in which the temperature distribution of a heat storage body is flattened to eliminate a partial increase in temperature. Is.

[0002]

2. Description of the Related Art Conventionally, a heat storage device is shown in FIGS.
As shown in FIG.
The heat storage body 2 provided with is stored, the heat storage body storage container 1 is provided with an exhaust gas inlet side space 4a and an exhaust gas outlet side space 4b, and channels 5 and 6 are provided in each. As shown by the arrow, the combustion exhaust gas G flows from the flow path 5 into the heat storage body 2 through the exhaust gas inlet side space 4a, and the sensible heat of the combustion exhaust gas G is stored in the heat storage body 2 and discharged through the flow path 6. ing.
As shown by the arrow, the combustion air A flows into the heat storage body 2 from the flow path 6 through the exhaust gas outlet side space 4b, and then flows into the heating furnace or the like from the flow path 5. At that time, the combustion air A A is preheated by the heat storage body 2. A heat storage type burner is provided with a burner on the flow path 5 side of such a heat storage device.

[0003]

However, in the above heat storage device, as shown in FIG. 8, the honeycomb pressure resistance (pressure loss) of the heat storage body 2 becomes uniform as shown in FIG. On the other hand, it shows a substantially flat characteristic. But,
The flow rate distribution of the combustion exhaust gas G is, as shown in FIG.
The flow rate on the side wall 1a side is the highest, and the flow rate on the side wall 1b side is the lowest. Therefore, the flow rate of the combustion exhaust gas is the largest on the wall side 1a side, and the amount of sensible heat accumulated in the combustion exhaust gas is large.

FIG. 1C shows the flow rate distribution of the combustion air A. The combustion air A has the largest flow rate on the side wall 1b side. As a result, as is clear from the average temperature distribution shown in FIG. 7D, the wall side 1a of the heat storage body has the highest average temperature. This has the disadvantage that the heat-resistant temperature of the heat storage body must be set in accordance with this highest temperature, which is expensive. In addition, there is a drawback that the heat storage temperature is partially saturated, the amount of heat released to the outside increases, and the heat conversion efficiency of the heating furnace and the like deteriorates. Further, the sensible heat of the combustion exhaust gas is discharged, and the shutoff valve becomes an abnormally high temperature, which may damage the shutoff valve.

The present invention has been made in view of the above problems, and a heat storage device and a heat storage system capable of averaging the flow distributions of combustion exhaust gas and combustion air to average the temperature distribution of a heat storage body. The purpose is to provide a burner.

[0006]

SUMMARY OF THE INVENTION The present invention has been made to achieve the above object, and the invention according to claim 1 is a heat storage device in which a fluid is bent and flows. An exhaust gas inlet side space and an exhaust gas outlet side space are provided in the provided heat storage body storage container, respectively, and a non-uniform flow preventer for preventing a non-uniform flow of the fluid flowing into the heat storage body through the exhaust gas inlet side space and the exhaust gas outlet side space. The heat storage device is provided in each of the exhaust gas inlet side space and the exhaust gas outlet side space, wherein the flow of the fluid is dispersed by a non-uniform flow preventer to eliminate the non-uniform flow of the fluid.

Further, according to a second aspect of the present invention, in a heat storage type burner including a combustion burner in a heat storage device in which a fluid bends and flows, a heat storage body container provided with a heat storage body has an exhaust gas inlet side space, Exhaust gas outlet side space is provided respectively, the non-uniform flow prevention device for preventing the non-uniform flow of the fluid flowing into the heat storage body through the exhaust gas inlet side space and the exhaust gas outlet side space, the exhaust gas inlet side space and the exhaust gas outlet side space, And, a heat storage type burner characterized in that a combustion burner is provided on the combustion air discharge side of the heat storage device, by dispersing the flow of the fluid by the drift preventer, by making the flow distribution uniform, The uneven flow of the fluid is eliminated, and the deterioration of the heat conversion efficiency is eliminated.

According to a third aspect of the present invention, in a heat storage device in which a fluid flows in a bent manner, a heat storage body container provided with a heat storage body and an exhaust gas contained in the heat storage body container are included. A side space and an exhaust gas outlet side space, an air nozzle communicating with the exhaust gas inlet side space, a barrier block provided in the exhaust gas inlet side space for preventing uneven flow of a fluid flowing in via the air nozzle, and the exhaust gas A heat storage device, which is provided so as to project into the outlet space and is provided with an air supply nozzle for partially concentrating combustion air and supplying the air to the heat storage body. The temperature distribution of the combustion exhaust gas is made uniform, or the combustion air is partially concentrated to enhance the preheating effect of the combustion air by the heat storage body and solve the partial abnormal high temperature state due to the drift of the fluid. To.

According to a fourth aspect of the present invention, in a heat storage type burner having a combustion burner in a heat storage device in which a fluid flows in a bent manner, a heat storage container containing a heat storage, and the heat storage container. Exhaust gas inlet side space and exhaust gas outlet side space respectively provided in the container, an air nozzle communicating with the exhaust gas inlet side space, and provided in the exhaust gas inlet side space for preventing uneven flow of fluid flowing through the air nozzle A barrier block provided, an air supply nozzle that is provided so as to project into the exhaust gas outlet side space and partially concentrates combustion air to the heat storage body, and a combustion burner that is provided in the air nozzle. A heat storage type burner characterized by being provided with a barrier block to make the flow of fluid uniform so as to make the flow rate distribution uniform, and to partially concentrate it by an air supply nozzle. To enhance the preheating effect of the combustion air by supplying combustion air Te, it is intended to eliminate the abnormally high temperature state due to drift of the fluid.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing an embodiment of a heat storage device according to the present invention. The same figure (a) is sectional drawing of a heat storage device, and the same figure (b) is X- of a heat storage device.
It is sectional drawing along the Y line. In the figure, the heat storage body 2 is stored in the heat storage body storage container 1, and the exhaust gas inlet side space 4a and the exhaust gas outlet side space 4b are provided in the heat storage body storage container 1.
A flow path 5 is provided in the exhaust gas inlet side space 4a. On the side wall 1a of the heat storage container 1, there is provided a heat-resistant barrier block 9 made of ceramics or the like that projects into the inside. An air supply nozzle 10 connected to a pipe 11 is inserted in the exhaust gas outlet space 4b. The barrier block 9 and the air supply nozzle 10 are a drift preventing device that disturbs the fluid to substantially average the flow rate distribution.

FIG. 2 is a diagram showing an embodiment of a heat storage type burner according to the present invention, in which the heat storage device is provided with a combustion burner. The figure (a) is sectional drawing of the heat storage type burner, and the figure (b) is sectional drawing which followed the XY line of the heat storage type burner. In the figure, the heat storage body 2 is stored in the heat storage body storage container 1, the exhaust gas inlet side space 4a and the exhaust gas outlet side space 4b are provided in the heat storage body storage container 1, and the exhaust gas inlet side space 4a is provided with a flow path 5 It is provided in. A barrier block 9 having heat resistance such as ceramics is provided on the side wall 1a.
An air supply nozzle 10 is inserted in the exhaust gas outlet space 4b. As described above, the barrier block 9 and the air supply nozzle 10 are drift preventers. The pipe forming the flow path 5 is attached to the burner tile 7. Fuel nozzles 8A and 8B are provided in the burner tile 7 and the pipe, respectively. The burner tile 7 is provided on the side wall of the heating furnace F so that the opening of the fuel nozzle 8A faces the inside of the furnace. The fuel nozzles 8A and 8B are not limited to the positions shown in this embodiment.

Next, the air supply nozzle 10 will be described with reference to FIGS. FIG. 3 shows an air supply nozzle 1
0 is a diagram showing an embodiment of No. 0. The figure (a) is a top view and the figure (b) is sectional drawing which followed the XY line. In the figure, the air supply nozzle 10 connected to the pipe 11 is a short tube having a flow path 12 formed therein. An opening 10a is formed at the tip of the air supply nozzle 10, and a barrier 10b is provided at the tip. The combustion air supplied from the pipe 11 to the air supply nozzle 10 flows into the heat storage body 1 from the opening 10 a through the flow path 12. Opening 1
0a is arranged at a position where the combustion air is concentratedly supplied to the part where the temperature is highest.

FIG. 4 is a view showing another embodiment of the air supply nozzle. The figure (a) is a top view and the figure (b).
Is a sectional view taken along the line XY. In the figure,
The air supply nozzle 10 connected to the pipe 11 is a tapered short pipe in which a flow path 12 is formed. Air supply nozzle 10
An opening 10a is formed at the tip of the, and a barrier 10b is provided at the tip. Similarly, in this air supply nozzle 10, the opening 10a of the air supply nozzle 10 is arranged immediately below the heat storage body where the combustion air has the highest temperature, and the combustion air is supplied intensively through the opening 10a. I have to.

FIG. 5 is a view showing another embodiment of the air supply nozzle. The figure (a) is a top view and the figure (b).
Is a sectional view taken along the line XY, and FIG. 7C is a perspective view thereof. In the figure, the air supply nozzle 10 is a flow path 1.
2 is a tapered short pipe formed and connected to the pipe 11. An opening 10 is provided at the tip of the air supply nozzle 10.
a is formed, and the barrier 10 is formed at the tip of the air supply nozzle 10.
b is provided. The barrier 10b is provided with a notch 10d so that the combustion air can flow out slightly forward, and a barrier 10c is formed at the center of the barrier 10b. As described above, the combustion air is intensively supplied from the opening 10a of the air supply nozzle 10 to the heat storage body having the highest temperature through the opening 10a, and the combustion air is also forwardly supplied through the notch 10d. Is supplied.

Next, the flow of the combustion exhaust gas and the combustion air in the heat storage device and the heat storage type burner in which the non-uniform flow preventer including the barrier block and the air supply nozzle is inserted will be described with reference to FIGS. 1 to 6. The flow of the combustion exhaust gas G is shown in FIGS. 1 and 2, and the combustion exhaust gas G flows through the flow path 5
Through the exhaust gas inflow side space 4a, a large amount of combustion exhaust gas G ₁ flows toward the side wall 1a of the heat storage body container 1, collides with the barrier block 9, and changes the flow direction to change the direction of the flow to the thin tube 3 of the heat storage body 2. Flow into. Therefore, the flow distribution of the combustion exhaust gas G is dispersed by the barrier block 9. Therefore, the flow rate flowing into the heat storage body 2 is made relatively uniform, and the temperature distribution is averaged.

On the other hand, the combustion air A flows into the air supply nozzle 10 through the pipe 11 and is blocked by the barrier 10b.
It mainly flows into and immediately above the opening 10a and diffuses. As a result, a large amount of combustion air partially flows into the thin tube 3 of the heat storage body 2. The position where a large amount of combustion air flows in partially
It is set on the side wall 1a side where the heat storage body 2 has the highest temperature. Of course, the combustion air A also flows to the side wall 1b side, flows into the thin tube 3 of the heat storage body 2, absorbs the heat accumulated in the heat storage body, and is supplied into the heating furnace. Therefore, the combustion air intensively flows into the portion where the heat accumulated by the sensible heat of the combustion exhaust gas reaches the highest temperature, so that the average temperature distribution of the heat storage body 2 can be made more uniform.

Further, in the air supply nozzle 10, as shown in FIG. 5, a notch 10d is provided in the barrier 10b,
Since the flow state of the fluid can be adjusted, there is an advantage that the average temperature distribution of the heat storage body 2 can be set more evenly. Therefore, the flow rate distribution of the combustion air blown out through the air supply nozzle 10 can be adjusted according to the characteristics of the heat storage device and the heat storage type burner. Further, by making the air supply nozzle tapered, it is possible to reduce the pressure loss when the combustion exhaust gas G is discharged outside the furnace.

Next, the heat storage device (heat storage type burner) according to this embodiment will be described with reference to FIGS. 6 (a) and 6 (b). The same figure shows the temperature distribution characteristics of the exhaust side of the heat storage body exhaust gas by two types of heat storage devices (heat storage type burners). The temperature distribution curve (a) in the same figure shows the temperature distribution on the exhaust side of the conventional heat storage body exhaust gas, and the temperature distribution curve (b) shows the temperature distribution on the exhaust side of the heat storage body exhaust gas after the drift prevention measures provided with the non-uniform flow preventer according to the present invention. Is shown.

In the heat storage type burner shown in FIG. 4A, the temperature deviation was 260 ° C. as apparent from the temperature distribution curve (a), but as shown in the temperature distribution curve (b), the drift prevention device was used. By including the above, the extremely high temperature portion is eliminated, the difference between the high temperature and the low temperature, that is, the temperature deviation becomes 90 ° C., and the temperature distribution is averaged. Further, in the heat storage type burner of FIG. 6B, the temperature deviation was 300 ° C. as apparent from the temperature distribution curve (a), but as shown in the temperature distribution curve (b), the drift prevention device was provided. As a result, the temperature deviation between the maximum temperature and the minimum temperature is reduced to 130 ° C. On the other hand, this temperature distribution can be made even more flat by using the air supply nozzles shown in FIGS. 4 to 5 than the air supply nozzle by the short pipe shown in FIG. it can.

[0020]

As described above, according to the present invention,
Since the temperature distribution on the output side of the heat storage body can be made flat by providing the non-uniform flow preventive device in the upper part of the heat storage body container and the exhaust gas outlet side space, the maximum temperature of the heat storage body can be reduced. There is. Therefore, since a heat storage body having a low heat resistant temperature can be used, there is an advantage that an inexpensive heat storage device and a heat storage type burner can be provided. Further, since the amount of heat discharged through the heat storage body to the outside of the furnace can be reduced, there is an advantage that the heat exchange efficiency of the heating furnace can be improved.
Further, since the combustion air blown out from the air supply nozzle can be concentratedly supplied to the region where the temperature tends to reach a high temperature according to the temperature distribution of the heat storage body, it is possible to prevent the heat storage body from partially becoming an abnormally high temperature state. There is an advantage that can be.

[Brief description of the drawings]

FIG. 1 is a diagram showing an embodiment of a heat storage device according to the present invention.

FIG. 2 is a diagram showing an embodiment of a regenerative burner according to the present invention.

FIG. 3 is a diagram showing an embodiment of an air supply nozzle.

FIG. 4 is a diagram showing an embodiment of an air supply nozzle.

FIG. 5 is a diagram showing an embodiment of an air supply nozzle.

FIG. 6 is a diagram showing a temperature distribution on the output side of the heat storage body.

FIG. 7 is a diagram showing an example of a conventional heat storage device.

FIG. 8 is a diagram showing characteristics of a conventional heat storage device.

[Explanation of symbols]

 1 Heat Storage Body Container 2 Heat Storage Body 3 Narrow Tube 4a Exhaust Gas Inlet Side Space 4b Exhaust Gas Outlet Space 5 Flow Path 7 Burner Tile 8A, 8B Fuel Nozzle 9 Barrier Block 10 Air Supply Nozzle 11 Piping 12 Flow Path

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shinichiro Fukushima 1-2-1, Marunouchi, Chiyoda-ku, Tokyo Japan Steel Pipe Co., Ltd. (72) Ken Tada 1-2-1 Marunouchi, Chiyoda-ku, Tokyo Date Inside the Steel Pipe Co., Ltd. (72) Toshiaki Hasegawa, Toshiaki Hasegawa 2-53-1, Shirute, Tsurumi-ku, Yokohama-shi, Kanagawa Japan Furnace Industries Co., Ltd. No. 53 within Japan Furnace Industry Co., Ltd.

Claims (4)

[Claims] 1. In a heat storage device in which a fluid flows in a bent manner, a heat storage medium storage container provided with a heat storage medium is provided with an exhaust gas inlet side space and an exhaust gas outlet side space, respectively, and the exhaust gas inlet side space and the exhaust gas outlet side are provided. A heat storage device, characterized in that each of the exhaust gas inlet side space and the exhaust gas outlet side space is provided with a non-uniform flow preventing tool for preventing non-uniform flow of a fluid flowing into the heat storage body via a side space. 2. A heat storage type burner comprising a combustion burner in a heat storage device in which a fluid flows in a bent manner, wherein an exhaust gas inlet side space and an exhaust gas outlet side space are respectively provided in a heat storage body accommodation container provided with a heat storage body, The non-uniform flow prevention device for preventing non-uniform flow of the fluid flowing into the heat storage body through the exhaust gas inlet side space and the exhaust gas outlet side space is provided in the exhaust gas inlet side space and the exhaust gas outlet side space, and the combustion air of the heat storage device. A heat storage type burner characterized by having a combustion burner on the discharge side. 3. A heat storage device in which a fluid flows in a bending manner, wherein a heat storage body storage container stores a heat storage body, and an exhaust gas inlet side space and an exhaust gas outlet side space respectively provided in the heat storage body storage container, An air nozzle communicating with the exhaust gas inlet side space, a barrier block provided in the exhaust gas inlet side space for preventing uneven flow of a fluid flowing in via the air nozzle, and provided so as to project into the exhaust gas outlet side space. And an air supply nozzle that partially concentrates combustion air and supplies the heat storage body with the heat storage body. 4. A heat storage type burner comprising a combustion burner in a heat storage device in which a fluid bends and flows, and a heat storage body accommodating container accommodating a heat storage body, and an exhaust gas inlet side provided in each of the heat storage body accommodating containers. A space and an exhaust gas outlet side space, an air nozzle communicating with the exhaust gas inlet side space, a barrier block provided in the exhaust gas inlet side space for preventing uneven flow of a fluid flowing in through the air nozzle, the exhaust gas outlet A heat storage type characterized by comprising an air supply nozzle provided so as to project into the side space and partially concentrating combustion air to supply the heat storage body, and a combustion burner provided on the air nozzle side. Burner.