KR19980012318U - Combustion chamber structure of gas boiler - Google Patents

Abstract

The present invention relates to a combustion chamber structure of a gas boiler. More specifically, the combustion chamber housing constituting the combustion chamber is more reliably protected from internal heat to prevent heat loss, thereby preventing corrosion of the combustion chamber housing and shortening the lifespan. The combustion chamber structure of the gas boiler is made possible.

The combustion chamber structure of the gas boiler according to the present invention forms an air passage 23 between the combustion chamber housing 21 constituting the combustion chamber and the heat insulator 22 formed therein, and the inlet 23a and the air passage 23. The outlet port 23b is formed so that a part of the air supplied to the combustion chamber during the operation of the exhaust fan 5 passes through the air passage 23.

Description

Combustion chamber structure of gas boiler

The present invention relates to a combustion chamber structure of a gas boiler. More specifically, the combustion chamber housing is more reliably protected from internal heat to prevent damage caused by heat, thereby preventing corrosion of the combustion chamber housing and preventing shortening of life. It relates to a combustion chamber structure of a gas boiler.

In general, a gas boiler burns gas using fuel, heats water using heat generated during the combustion process, and circulates the heated water along a heating pipe in a room to heat the bathroom, sink, and the like. It has a function of supplying hot water.

Among the gas boilers having the above function, there is a bidirectional circulating pump for circulating the heating water. FIG. 1 is a schematic diagram of a conventional gas boiler using a bidirectional circulating pump.

As shown, the gas boiler is a gas inlet pipe 1 through which external gas is introduced, a gas valve 2 installed on the gas inlet pipe 1 to regulate the pressure of the gas supplied to the burner, and the gas inlet. The burner 3 which mixes and combusts the gas and air which flowed in through the pipe 1, the flue 4 which discharges the burned exhaust gas, and the burner 3 inhales air, An exhaust fan 5 forcibly discharged is included.

In addition, the gas boiler is a water tank for temporarily storing the heating water returned as installed on the heating return pipe (6), the heating return pipe (6) to return the heating water from the heating pipe (not shown) in the room to be heated. (7), a circulating pump (8) for circulating the heating water and selecting and changing the flow of the heating water when using heating and hot water, a heat exchanger (9) for heating the heating water, and supplying the heated heating water to the heating pipe. Heating water supply pipe (10), water replenishment pipe (11) to replenish the heating water, automatic refill water valve (12) installed on the water replenishment pipe (11), direct water supplying direct water to the heat exchanger (9) when using hot water Supply pipe 13, a hot water supply pipe 14 for discharging the heated hot water from the heat exchanger, and a flow switch (15) for detecting the flow of direct water when using hot water.

In addition, a bypass tube 16 is connected between any one outlet 8a of the bidirectional circulation pump 8 and the water tank 7, and an inlet pipe 17 is provided between the water tank 7 and the heat exchanger 9. ) Is connected, and an outlet pipe 18 is provided between the heat exchanger 9 and the inlet port 8b of the bidirectional circulation pump 8. The heating water supply pipe 10 is connected to another outlet 8c of the bidirectional circulation pump 8.

The bidirectional circulating pump 8 changes the discharge direction of the heating water according to the rotational direction. The structure of the bidirectional circulation pump 8 has already been filed with a patent application (application number: 96-13427) on April 29, 1996. As a result, a detailed description thereof will be omitted.

As described above, the gas boiler using the bidirectional circulation pump 8 functions as follows.

The heating water returned through the heating return pipe (6) enters the heat exchanger (9) through the water tank (7) and the inlet pipe (17) by the bidirectional circulation pump (8), and is heated in the heat exchanger (9). Heating water is supplied to the heating pipe of each room through the outflow pipe 18, the circulation pump 8 and the heating water supply pipe 10.

At this time, the bidirectional circulating pump 8 closes the outlet 8a of the bypass pipe 16 and opens the outlet 8c of the heating water supply pipe 10 to supply the heating water to the heating water supply pipe 10.

In addition, when using hot water, the heating water is circulated only in the boiler instead of flowing to the heating pipes in each room in order to increase the heat exchange efficiency with the hot water.

That is, when the hot water is used, the direction of rotation of the bidirectional circulating pump 8 is changed. In this case, the bidirectional circulating pump 8 opens the discharge port 8a on the bypass pipe 16 side and discharge port on the heating water supply pipe 10 side. Block (8c) to supply the heating water to the bypass pipe (16).

Therefore, the heating water circulates through the passage consisting of the heat exchanger 9, the outlet pipe 18, the circulation pump 8, the bypass pipe 16, and the inlet pipe 17.

In this way, the gas boiler is capable of heating and using hot water. The use of hot water, that is, a direct flow of water in the direct water supply pipe 13 is detected by the flow switch 15, and the flow switching of the heating water is performed as described above. It is made by the circulation pump 8 is changed in the rotation direction in accordance with the hot water use state detection of (15).

On the other hand, the amount of heating water in the heating pipe decreases little by little due to evaporation, etc. If the amount of heating water decreases above a certain level, the float switch 7a in the water tank 7 detects this and automatically replenishes it. Open the water valve (12). When the automatic refill water valve 12 is opened, water is replenished in the heating pipe. When the water is replenished to a certain level, the float switch 7a detects this again and closes the automatic refill water valve 12.

The structure of the combustion chamber 20 in the above conventional gas boiler is demonstrated with reference to FIG.

The combustion chamber 20 has a heat insulating material 22 attached to the inner surface of the combustion chamber housing 21. Since the inside of the combustion chamber has a high temperature, the heat must be blocked from the outside. In addition, the combustion chamber housing 21 is damaged by high heat to prevent the phenomenon of corrosion.

To this end, the heat insulating material 22 is attached to the inner surface of the combustion chamber housing 21.

However, the heat insulating ability of the heat insulating material 22 is limited.

Therefore, when the amount of heat continuously generated in the combustion chamber 20 exceeds the heat insulating capacity of the heat insulator 22, the combustion chamber housing 21 is burned out and there is a problem in that corrosion occurs. If such burnout continues, the combustion chamber housing 21 must be replaced.

However, in order to suppress this, conventionally, measures have been taken to simply increase the thickness of the heat insulating material 22, change the material of the housing, or change the thickness of the housing 21, but this causes a problem of cost increase.

The present invention has been made to solve the above-described problems of the prior art, and provides a combustion chamber structure of the gas boiler to more effectively block the heat of the combustion chamber to prevent heat loss of the combustion chamber housing to prevent the shortening of life. For that purpose.

The combustion chamber structure of the gas boiler of the present invention for achieving the above object is characterized in that to form an air flow path between the combustion chamber housing and the heat insulating material to cool the housing and the heat insulating material by air.

1 is a schematic configuration diagram of a conventional gas boiler using a bidirectional circulating pump;

2 is a detailed configuration diagram of a combustion chamber structure of a conventional gas boiler;

3 is a detailed configuration diagram of a combustion chamber structure of a gas boiler according to the present invention.

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

1: gas inlet pipe 2: gas valve

3: burner 4: year

5: exhaust fan 6: heating return pipe

7: water tank 7a: float switch

8: circulation pump 9: heat exchanger

10: heating water supply pipe 11: water supply pipe

12: Automatic refill water valve 13: Direct water supply pipe

14: hot water supply pipe 15: flow switch

16: bypass tube 17: inlet pipe

18: outlet pipe 20: combustion chamber

21: combustion chamber housing 22: insulation

23: air passage 23a: inlet

23b: outlet

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

3 is a detailed configuration diagram showing a combustion chamber structure of a gas boiler according to the present invention.

As shown in the structure of the combustion chamber 20 of the present invention, an air flow path 23 is formed between the combustion chamber housing 21 and the heat insulator 22.

In addition, an inlet port 23a and an outlet port 23b are formed to allow air to flow through the air passage 23 between the combustion chamber housing 21 and the heat insulating material 22.

The heat insulator 22 is supported and fixed by a plurality of supports 24 between the combustion chamber housing 21.

The combustion chamber structure of the present invention operates as follows.

Air is sucked into the combustion chamber 20 by the action of the exhaust fan 5. Combustion is performed by mixing these air and gas. In the gas boiler shown in FIG. 1, the present invention is similarly applied to a gas boiler in which air is sucked in by the exhaust fan 5, and gas is supplied to the combustion chamber 20 by the exhaust fan 5.

However, in the combustion chamber structure of the present invention, some air flows through the air flow path 23 during the operation of the exhaust fan 5. Therefore, the heat in the combustion chamber 20 is first blocked by the heat insulator 22 and secondly by the air flowing in the air flow path 23.

The air flowing through the air flow path 23 is excellent in thermal insulation even if a small amount of air because the cool air continues to enter.

Therefore, since the thermal insulation effect is improved as compared with the case where the conventional heat insulating material 22 is directly attached to the inner surface of the combustion chamber housing 21, the combustion chamber housing 21 is more reliably protected than in the conventional case.

As described above, the combustion chamber structure of the gas boiler of the present invention can improve the thermal insulation effect due to the configuration of the air flow path 23, and thus protect the combustion chamber housing 21 from heat to prevent heat loss and to shorten the lifespan. Exerts the effect of preventing.

Although the present invention has been described in detail only with respect to the embodiments described, it will be apparent to those skilled in the art that various changes or modifications can be made within the spirit and scope of the present invention. It will have to belong to the claims.

Claims (1)

In the combustion chamber structure of a gas boiler, An air flow path 23 is formed between the combustion chamber housing 21 constituting the combustion chamber and the heat insulating material 22 formed therein, and an inlet port 23a and an outlet port 23b are formed in the air path 23 to exhaust the gas. Combustion chamber structure of a gas boiler, characterized in that a part of the air supplied to the combustion chamber during the operation of the fan (5) passes through the air passage (23).