KR20000008516U - Flue Assembly Structure of Gas Boiler - Google Patents

Abstract

The present invention relates to a flue gas assembling structure of a gas boiler which can prevent leakage of exhaust gas by inserting a seal ring into a coupling portion of the exhaust duct and the flue, thereby improving the airtightness. Grooves 120a and 123a were formed at the coupling portions between the 123 and the sealing rings 130 to prevent gas leakage by preventing gaps generated therebetween.

Description

Flue Assembly Structure of Gas Boiler

The present invention relates to a flue assembling structure of a gas boiler, and more particularly, to a flue assembling structure of a gas boiler which can prevent leakage of exhaust gas by inserting a seal ring at a coupling portion of the exhaust duct and the flue to improve airtightness. It is about.

Gas boilers can be divided into various types according to the control method or sealed state, and can be classified into condensing and non-condensing types according to heat sources for heating heating water. Among them, the condensing method has a sensible heat exchanger that directly heats the heating water by using the heat burned by the burner, and a latent heat exchanger that heats the heating water by using latent heat of exhaust gas passing through the sensible heat exchanger. In the non-condensing method, only the sensible heat exchanger is provided.

1 is a diagram illustrating a condensing gas boiler as an example. The blower 10 and the burner 12 are disposed on the upper part of the combustor 4, and the upper part of the combustor 4 combusts the air supply and gas sucked through the intake duct 6 according to the operation of the blower 10. A burner 12 is provided, and a sensible heat exchanger 14 and a latent heat exchanger 16 are arranged under the burner 12 in sequence. The sensible heat exchanger (14) heats the heating water in the process of exchanging heat by directly contacting the sensible heat generated from the burner, and the latent heat exchanger (16) uses latent heat generated during thermal contact with the exhaust gas. To heat the heating water.

Exhaust gas passing through the latent heat exchanger 16 is discharged to the outside through the exhaust duct 20 and the flue 23, the condensate generated in the heat exchange process is collected in the exhaust hood 18 and then discharged to the outside.

In the lower left of the boiler, a circulation pump 22 for circulating the heating water is disposed. When the circulation pump 22 is operated, the heating water which has finished heating in the room flows into the heating water filter 24 through the line L1. The heating water filter 24 removes impurities contained in the heating water, and the filtered heating water is sent to the upper water separator 26. The water separator 26 is for discharging air contained in the heating water, and discharges the air through the upper air vent.

An overpressure preventing valve 32 is provided between the heating water filter 24 and the water separator 26 to prevent the pressure of the heating water from being excessively raised, and sends a portion of the heating water to the expansion tank 48 to supply pressure. Will be adjusted. The heating water passing through the water separator 24 is supplied to the latent heat exchanger 16 through the line L2 by the operation of the circulation pump 22, and then heated while passing through the sensible heat exchanger 14. Discharged to (L3). Heating water discharged through the line (L3) is supplied to the room according to the operation of the three-way valve (28).

In the middle of the boiler is shown a heat exchanger that uses hot water for heating to obtain hot water. In accordance with the operation of the hot water flow switch 36, the cold water introduced through the line (L6) is heated in the process of passing through the hot water heat exchanger 34, and then discharged through the line (L7).

In the lower right part of the boiler, a gas supply device is installed. According to the operation of the gas valve 44, the gas introduced through the line L8 is supplied to the nozzle 8 above the combustor 4 through the line L9. The gas thus supplied is ignited and combusted by the spark delivered through the ignition transformer 42 and the ignition rod. This series of combustion processes the controller 40 receiving the input signal from the room temperature controller 38 operated by the user. Controlled by

In a flue gas assembling structure of a conventional gas boiler having such a configuration, if the diameters of the exhaust duct and the flue are not precisely processed, adhesiveness may be deteriorated and exhaust gas or leaks through the gaps between these coupling parts may flow into the room. .

The present invention devised to solve this problem is to provide a flue gas assembly structure of the gas boiler that can prevent the leakage of the exhaust gas by inserting a sealing ring in the coupling portion of the exhaust duct and the flue to improve the airtightness. .

1 is an overall configuration diagram showing a conventional condensing boiler,

2 is an overall configuration diagram showing a condensing boiler according to the present invention,

3 is a partially enlarged view showing the flue assembly structure of the gas boiler according to the present invention.

♣ Explanation of symbols for main part of drawing ♣

10: blower 12: burner

14: sensible heat exchanger 16: latent heat exchanger

22: circulating pump 24: heating water filter

26: water separator 34: hot water heat exchanger

38: room temperature controller 40: controller

120: exhaust duct 123: year

130: sealing

An object of the present invention described above is a latent heat exchanger for heating heating water using latent heat of exhaust gas passing through a sensible heat exchanger together with a sensible heat exchanger for directly heating heating water using heat burned by a burner. In a gas boiler comprising a consensing boiler having a group and a non-condensing boiler having only a sensible heat exchanger, a sealing ring for preventing gas leakage is inserted in the coupling portion of the exhaust duct and the flue to prevent a gas leak. It is achieved by the flue assembly of the gas boiler, characterized in that.

Hereinafter, with reference to the accompanying Figures 2 and 3 will be described in detail with respect to the flue assembly structure of the gas boiler according to a preferred embodiment of the present invention, the same parts as the conventional structure described in Figure 1 are denoted by the same reference numerals. .

2 is an overall configuration diagram showing a condensing boiler according to the present invention, Figure 3 is a partially enlarged view showing the flue assembly structure of the gas boiler according to the present invention.

As described in FIG. 1, in operation of the gas boiler, the air introduced into the intake duct 6 in accordance with the rotation of the blower 10 is sent to the combustor 4 and then burned together with the gas by the burner 12. do. The combustion gas is heat exchanged through the two heat exchangers 14 and 16 in turn, and then discharged through the exhaust duct 120. The flue 123 is fitted in the upper portion of the exhaust duct 120 to discharge the exhaust gas introduced from the combustor 4 through the exhaust duct 120 into the atmosphere.

In the condensing boiler of this structure, as a way to prevent the exhaust gas from leaking from the coupling portion of the exhaust duct 120 and the flue 123, in the preferred embodiment of the present invention, the sealing ring 130 to these coupling portions The inserted structure was adopted.

That is, as shown in an enlarged view in FIG. 3, grooves 120a and 123a are formed at the coupling portion between the exhaust duct 120 and the flue 123, respectively, and then the grooves 120a and 123a are sealed. By fitting 130, it essentially blocks leakage of exhaust gas through gaps between them. In the present exemplary embodiment, the recesses 120a and 123a are formed to allow the seal ring 130 to be seated, but the sealing effect may be sufficiently provided even if the recess ring 130 is not formed according to the size of the seal ring 130.

In the preferred embodiment of the present invention described so far described the condensing boiler, it will be understood by those skilled in the art that the same can be applied to the non-condensing boiler having only a latent heat exchanger. , Description thereof is omitted.

According to the present invention described above, since the sealing can be prevented by inserting a sealing ring at the joint portion of the exhaust duct and the flue, it is possible to prevent the leakage of the exhaust gas. Therefore, there is an advantage of preventing a part of the exhaust gas from entering the room. have.

Claims (2)

Condensing boiler having a latent heat exchanger that heats the heating water by using latent heat of exhaust gas passing through the sensible heat exchanger, together with a sensible heat exchanger that directly heats the heating water by using the heat burned by the burner. And a non-condensing boiler having only a sensible heat exchanger. Combination portion of the exhaust duct 120 and the flue 123, the flue assembly structure of the gas boiler, characterized in that the sealing ring 130 is inserted to prevent the leakage of the gap generated between them. The method of claim 1, Flue assembly structure of the gas boiler, characterized in that the grooves (120a, 123a) are formed in each of the coupling portion between the exhaust duct 120 and the flue (123).