KR19990053125A - Extinguishing Method in case of Overheating - Google Patents

Abstract

The present invention relates to a fire extinguishing method when a gas boiler is overheated. More specifically, the present invention relates to a fire extinguishing method for preventing a gas boiler from being inoperable for a long time due to overheating and reheating quickly. The present invention relates to a fire extinguishing method for descending overheating.

The fire extinguishing method having a rapid recovery function of the present invention includes a microcomputer for controlling the entire stroke, an overheat sensor for detecting an overheat state of the gas boiler, a circulation pump for circulating heating water, and a combustion system. Performed in a conventional gas boiler including an air supply fan for supplying air, and the microcomputer detects the temperature data input from the overheat prevention sensor while performing the combustion stroke, and if the detected temperature does not reach the overheat prevention temperature, normal proportional control When the overheat protection temperature is reached, the overheating is displayed on the room cone, and the microcomputer outputs control signals to the circulation pump and the supply fan to continue operation for a certain time and to force the boiler to return to the heating mode. It features.

Description

Extinguishing Method in case of Overheating

The present invention relates to a fire extinguishing method when a gas boiler is overheated. More specifically, the heating water temperature is lowered to prevent the gas boiler from being inoperable for a long time due to overheating so that it can be quickly reheated. It relates to a fire extinguishing method in the event of overheating.

Since gas boilers do not cause pollution due to their ease of use and low emission of environmental pollutants, they are increasingly being used for home and industry. Gas boilers are used to heat indoors or to supply hot water by using combustion heat generated when burning gas.

1 and 2 is a schematic view showing an embodiment of a conventionally used domestic gas boiler, the former is a schematic configuration diagram of the boiler, the latter is a partial block circuit diagram of the boiler will be described briefly the configuration and operation state.

As shown in FIG. 1, the gas boiler is for igniting the gas valve 3 for adjusting the amount of gas supplied through the gas supply pipe and the gas supplied from the gas valve 3, and generates an flame igniter. (Ignition plug for performing ignition using a high voltage power generated from the ignition transformer 7) and a burner 8 provided with an infrared sensor 7 for detecting a combustion state, and the burner 8 generated in the burner 8 A heat exchanger 9 for raising the heating water and the direct water by using heat, an exhaust port 10 for discharging the exhaust gas generated after the combustion in the burner 8, and controlling the moving direction of the heating water It includes a bi-directional circulation pump (2), and a water tank (6) supplied with direct water through an automatic replenishment water valve (not shown) to replenish the lack of heating water. Installed between the water tank (6) and the circulation pump (2) is a hot water heat exchanger (15) for producing hot water, and installed between the gas valve (3) and the burner (8) is a gas burner (8) uniformly It is a manifold 11 to supply.

When the gas valve 3 is opened according to the control signal of the microcomputer 17, gas flows into the burner 8 along the gas supply pipe, and the burner 8 mixes and combusts gas and air at an appropriate ratio, and burns the combustion gas. While heating the heat exchanger (9) while rising, it is discharged through the exhaust port (10). As the gas boiler burns fuel as described above and uses a high temperature heat generated at this time, there is a risk of fire.

In order to prevent such a danger, various safety devices are installed in the boiler, and the overheat prevention sensor 14 installed at the heating exit side of the heat exchanger 9 has a heating water temperature higher than a predetermined temperature so that the gas boiler It detects this in case of overheating and acts as a safety device to force the boiler off.

Once the overheat protection sensor 14 is activated, the microcomputer 17 detects this and stops the operation of the boiler. The on / off switch installed in the room cone 16 conventionally maintains the current operating mode (heating or hot water mode). By turning off (164 in FIG. 3) and turning off the power, all the functions of the gas boiler were simultaneously turned off and an error was displayed through the display window of the room cone 16. Since all functions are paralyzed at the same time, it takes a lot of time for the heating water temperature to naturally fall, so it takes a lot of time to release the superheat, causing inconvenience to the user.

The present invention has been made to solve the above problems, an object of the present invention is to lower the heating water temperature to prevent the gas boiler from falling into an inoperable state for a long time due to overheating so that the heating can be re-executed quickly To provide a fire extinguishing method in the event of overheating.

Fire extinguishing method having a rapid return function of the present invention for achieving the above object, the microcomputer for controlling the entire stroke, the overheat sensor for detecting the overheated state of the gas boiler, the circulation to circulate the heating water Performed in a gas boiler including a pump and an air supply fan for supplying air for combustion, the microcomputer senses temperature data input from the overheat prevention sensor while performing the combustion stroke, and the detected temperature does not reach the overheat prevention temperature. If not, perform normal proportional control, and if the overheat protection temperature is reached, overheat is displayed on the room cone, and the microcomputer outputs control signals to the circulation pump and the supply fan to continue operation for a certain time, and the boiler operation mode is heating mode. Forced return to

1 is a configuration diagram showing an embodiment of a conventionally used gas boiler,

2 is a partial block circuit diagram of the gas boiler of FIG.

3 is a front view of the room cone,

4 is a flow chart illustrating the method of the invention.

<Explanation of symbols for main parts of the drawings>

1: gas boiler, 2: circulation pump,

3: gas valve, 4: control unit,

5: infrared sensor, 6: combustion chamber,

7: ignition transformer, 8: burner,

9: heat exchanger, 10: exhaust port,

11: manifold, 12: air supply fan,

13: water tank, 14: overheat protection sensor,

15: hot water heat exchanger, 16: room cone,

17: microcomputer, 161: temperature display,

162: heating thermostat, 163: heating timer,

164: on / off switch.

Hereinafter, with reference to the accompanying drawings, a fire extinguishing method of the present invention will be described in detail.

The method of the present invention is applied when an overheat check error occurs during use of a gas boiler. In general, when an overheat check error occurs in a gas boiler, the gas boiler is turned off when the power on / off switch 164 connected to the room cone 16 is turned off. It is configured to stop all operation functions of.

Accordingly, the gas supplied through the gas valve 3 is cut off, the combustion in the burner 8 is stopped, the rotation of the air supply fan 12 (or the exhaust fan) is stopped, and the circulation pump 2 also stops operating. Therefore, the temperature of the heating water, which has reached the overheating temperature, drops very slowly. However, in the related art, since the boiler could be reactivated only when the heating water temperature was lowered below the superheat temperature, it took a long time to restart the boiler.

In the method of the present invention, while performing a normal combustion stroke, the microcomputer 17 always receives temperature data from the overheat prevention sensor 14. This is the same as the conventional method. In this state, if the heating water temperature does not reach the overheat inspection temperature, the microcomputer 17 maintains a normal proportional control combustion state.

However, when the heating water temperature reaches the overheat inspection temperature, the microcomputer 17 closes the gas valve 3 and is supplied to the burner 8 without turning off the on / off switch 164 of the room cone 16 as in the prior art. Shut off the gas. Since the fuel supply is cut off, the combustion stroke in the burner 8 is stopped. The interruption of the combustion stroke can be confirmed by the microcomputer 17 by reading an electric signal input from the infrared sensor 5.

When it is confirmed that the combustion stroke is stopped, the microcomputer 17 does not stop all the functions of the electric equipment as in the prior art but continuously operates the electric equipment that can lower the heating water temperature. Such electrical equipment may be, for example, a circulation pump 2, an air supply fan 12, or the like.

In other words, the circulation pump 2 discharges heat by forcibly circulating high temperature heating water, and the air supply fan 12 introduces external cool air into the gas boiler in a high temperature state to heat the heat exchanger 9. It is to take the action of lowering the temperature. At this time, if necessary, it is possible to detect the water level of the water stored in the water tank 13 and supply the cold direct water to lower the temperature of the heating water.

At the same time as operating the air supply fan 12 and the circulation pump 2 as described above, the microcomputer 17 forcibly controls the electric appliance in the heating mode regardless of the current operation mode (hot water use mode or heating mode). In the heating mode, the heating water passes through a long flow path formed of a heat exchanger (9), a water tank (13), a heating water discharge pipe, an indoor pipe, and a heating water return pipe.

Therefore, the heating water temperature can be lowered more quickly because the hot water has a higher chance of dissipating heat than the hot water mode that moves the short flow path while forming a closed circuit inside the gas boiler.

When the heating water temperature is lowered as described above, the overheat prevention sensor 14 is turned off, so that the user can perform heating by operating the boiler again through the room cone.

As described above, according to the present invention, the gas boiler is prevented from falling into an inoperable state for a long time due to overheating, and thus, the heating can be quickly performed.

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

Claims (2)

A microcomputer 17 for controlling the entire stroke, an overheat sensor 14 for detecting an overheat state of the gas boiler, a circulation pump 2 for circulating heating water, and an air supply fan for supplying air for combustion In the gas boiler containing (12), A first step of sensing temperature data input from the overheat prevention sensor 14 in the microcomputer 17 while performing a combustion stroke; A second step of performing normal proportional control if the sensed temperature does not reach the overheat prevention temperature and displaying the occurrence of overheating in the room cone 16 when the overheat prevention temperature is reached; And A method of extinguishing during overheating, characterized in that the microcomputer (17) outputs an operation control signal to the circulation pump (2) and the air supply fan (12) to continue operation for a predetermined time. The method of claim 1, further comprising the step of forcibly returning the operating mode of the boiler to the heating mode while starting operation for a predetermined time in the third step.