KR20180007933A - Structure for preventing damage of heat exchanger components by combustion heat - Google Patents

Abstract

The purpose of the present invention is to provide a structure for preventing damage to heat exchanger components by combustion heat, capable of solving a problem that a packing provided on a connection portion of a sensible heat exchanger and a latent heat exchanger is damaged by combustion heat of combustion gas, and capable of preventing front and rear surfaces of the sensible heat exchanger from being discolored by combustion heat of combustion gas. To achieve the purpose of the present invention, the structure for preventing damage to heat exchanger components by combustion heat comprises: a sensible heat exchanger (40) for absorbing combustion sensible heat generated in a combustion chamber (30); a latent heat exchanger (50) for absorbing latent heat of steam included in combustion gas that is completed with heat exchange in the sensible heat exchanger (40); a packing (80) provided between a sensible heat connection portion (410) and a latent heat connection portion (510) which connect the sensible heat exchanger (40) with the latent heat exchanger (50); and a combustion heat blocking means (100) for blocking combustion heat of the combustion gas from being directly transferred to the packing (80).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat exchanger,

[0001] The present invention relates to a structure for preventing burn-out of a heat exchanger part by combustion heat, and more particularly, to a structure for preventing burn-out of a part for preventing leakage of a combustion gas provided at a connection part between a sensible heat exchanger and a latent heat heat exchanger. And a structure for preventing burn-out of the heat exchanger part by combustion heat that can prevent the wall surface of the sensible heat exchanger from being discolored by the heat of combustion.

A boiler is a device that heats a heating medium in a closed container by a heat source to heat a desired area. It consists of a burner that burns the fuel and a heat exchanger that transfers heat from the burned high temperature combustion gas to the heating water.

The heat exchanger of the initial boiler uses only the sensible heat generated during the burning of the burner, and the hot combustion gas is discharged through the exhaust duct as it is, the thermal efficiency of the boiler is very low and it takes a long time to obtain the hot water of high temperature.

Therefore, a boiler produced in recent years has a sensible heat exchanger that absorbs the sensible heat of the combustion gas generated in the combustion chamber to increase thermal efficiency, and a latent heat exchanger that absorbs the latent heat of the steam contained in the combustion gas after the heat exchange in the sensible heat exchanger A boiler of this type is called a condensing boiler.

The condensing boiler includes a blower for sucking outside air to supply air required for combustion, a burner for burning a mixture of air and fuel supplied through the blower, a sensible heat exchanger for absorbing combustion sensible heat generated in the burner, A latent heat exchanger for absorbing the latent heat of steam contained in the combustion gas having undergone the heat exchange in the sensible heat exchanger and an exhaust duct through which the combustion gas passing through the latent heat heat exchanger is discharged and a latent heat exchanger And a condensate receiver for collecting and discharging the condensed water generated by condensing the steam contained in the combustion gas passing through the condenser receiver.

Generally, in the condensing water heater and the boiler, the sensible heat exchanger and the latent heat heat exchanger are formed as separate modules, and the connection part of the sensible heat exchanger and the latent heat heat exchanger is connected by fastening means such as bolts and nuts. Packing is provided.

However, in the conventional condensing water heater and boiler structure, there is not enough means to block direct contact of the high-temperature combustion gas with the packing, and the packing is hardened and carbonized by the heat of combustion of the combustion gas, There is a problem of deterioration.

On the other hand, a condensing water heater and a boiler are provided with a water pipe arranged vertically on the outer wall of the combustion chamber for preheating the heating medium and cooling the combustion chamber. The sensible heat exchanger is provided with a tube through which the heating medium flows, Since the distance between the water pipe provided at the lowermost end and the space between the adjacent tubes and the heat exchanger facing the heat exchanger is relatively distant from the heat medium and is vulnerable to heat, the heat is discolored when the heat is directly contacted Durability is deteriorated, and there is a problem that the discolored portion is inferior in appearance.

There is a problem that the combustion of the combustion gas causes burning of the packing due to the combustion heat and discoloration of the heat exchanger, and no prior art has been searched to suggest a solution for this.

However, as a prior art related to a condensing boiler, a heat exchanger of a condensing boiler having a structure in which a sensible heat exchanger and a latent heat heat exchanger are manufactured as separate modules and their connection portions are assembled is disclosed in Patent No. 10-0473083, 1199621 and 10-1109856 disclose a general configuration of a fin-tube type heat exchanger.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a heat exchange apparatus and a heat exchange apparatus which prevent the packing of a connection portion between a sensible heat exchanger and a latent heat heat exchanger from being burned by combustion heat of a combustion gas, It is an object of the present invention to provide a burn-preventive structure of a heat exchanger part by combustion heat which can prevent discoloration by combustion heat of a combustion gas.

In order to achieve the above object, the present invention provides a burn-through prevention structure for a heat exchanger part, comprising: a sensible heat exchanger (40) for absorbing combustion sensible heat generated in a combustion chamber (30); A latent heat heat exchanger (50) for absorbing the latent heat of steam contained in the heat-exchanged combustion gas in the sensible heat exchanger (40); A packing 80 provided between the sensible heat coupling part 410 and the latent heat coupling part 510 to which the sensible heat exchanger 40 and the latent heat heat exchanger 50 are connected to prevent leakage of the combustion gas; And a combustion heat cut-off means (100) for blocking the heat of the combustion gas from being directly transferred to the packing (80).

A sensible heat flange 411 contacting the upper surface of the packing 80 is formed in the sensible heat connection part 410 and a latent heat flange part 511 in which the packing 80 is seated is formed in the latent heat connection part 510 The combustion heat shielding unit 100 includes a combustion heat inflow preventing protrusion 512 extending from an inner end of the latent heat flange unit 511 to an inner side of the inner end of the sensible heat flange unit 411 .

A sensible heat flange 411 contacting the upper surface of the packing 80 is formed in the sensible heat connection part 410 and a latent heat flange part 511 in which the packing 80 is seated is formed in the latent heat connection part 510 The combustion heat shielding means 100 includes a combustion heat inflow prevention protrusion 513 extending from an inner end of the latent heat flange portion 511 to contact with a bottom surface of the inner end of the sensible heat flange portion 411 .

The combustion heat inflow preventing protrusion 513 may be in surface contact with the bottom surface of the inner end of the sensible heat flange 411.

A sensible heat flange 411 contacting the upper surface of the packing 80 is formed in the sensible heat connection part 410 and a latent heat flange part 511 in which the packing 80 is seated is formed in the latent heat connection part 510 The combustion heat interrupting means 100 includes a combustion heat inflow preventing protrusion 412 bent at an inner end of the sensible heat flange 411 so as to be in contact with the upper surface of the inner end of the latent heat flange 511 .

The combustion heat inflow preventing protrusion 412 may be in surface contact with the upper surface of the inner end of the latent heat flange 511.

The front and rear surfaces of the combustion chamber 30 and the sensible heat exchanger 40 are provided with a sensible heat panel 41 which forms an outer wall and the front and rear surfaces of the combustion chamber 30 are located outside the sensible heat panel 41 A plurality of tubes 43 are provided in the sensible heat exchanger 40 and the heat medium flows along the interior of the sensible heat exchanger 40. The water pipe 42, A heating guide 90 for guiding the combustion gas to flow toward the tube 43 is provided on the inner surface of the sensible heat panel 41 located between the tubes 43 adjacent to the water pipe 42 .

The heating guide 90 includes a curved surface portion 91 formed to surround the inner surface of the water pipe 42 and a curved surface portion 91 extending from the lower end of the curved surface portion 91 in an inclined manner toward the tube 43 And a guide portion (92).

According to the structure for preventing the burning heat of the heat exchanger component by the combustion heat according to the present invention, since the combustion heat blocking means is provided at the connection portion between the sensible heat exchanger and the latent heat heat exchanger, the problem of burning and carbonization of the packing by burning heat is prevented, Durability can be improved.

Further, since the heating guide for guiding the flow of the combustion gas to the tube side is provided between the water pipe and the tube, the sensible heat panel provided on the front and rear surfaces of the sensible heat exchanger is discolored by the combustion heat of the combustion gas, can do.

1 is a schematic view of a condensing boiler to which the present invention is applied,
FIG. 2 is a cross-sectional view showing one embodiment of a combustion heat blocking means for preventing burning of packing due to heat of combustion according to the present invention;
3 is a cross-sectional view showing another embodiment of a combustion heat cutoff means for preventing burning of packing due to heat of combustion according to the present invention,
4 is a cross-sectional view showing still another embodiment of a combustion heat blocking means for preventing burning of packing due to combustion heat according to the present invention.
FIG. 5 is a sectional view showing the installation structure of a heating guide for preventing discoloration of the front and rear surfaces of the sensible heat exchanger according to the present invention,
6 is a perspective view of a sensible heat exchanger of a condensing boiler to which the present invention is applied,
Fig. 7 is a front view of Fig. 6,
FIG. 8 is a cross-sectional view taken along the line CC in FIG. 7, (b) is a cross-sectional perspective view,
9 is a perspective view of the heating guide viewed from different directions;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, a condensing boiler 1 to which the present invention is applied includes a blower 10 for supplying air to be supplied to the burner 10, a burner for igniting a mixture of the combustion gas and the air supplied from the blower 10 A sensible heat exchanger 40 for absorbing the sensible heat of the combustion gas generated in the combustion chamber 30 to heat the heat medium, a heat exchanger 40 for exchanging heat with the sensible heat exchanger 40 A condensate receiver 60 for collecting the condensed water generated in the latent heat heat exchanger 50 and discharging the condensed water to the outside, And an exhaust duct 70 through which gas is exhausted.

The front and rear surfaces of the combustion chamber 30 and the sensible heat exchanger 40 are provided with a combustion chamber 30 and a sensible heat panel 41 forming an outer wall of the sensible heat exchanger 40.

The front and rear surfaces of the combustion chamber 30 are provided with a plurality of water pipes 42 disposed on the outside of the sensible heat panel 41 and spaced vertically. The heating medium flowing along the water pipe 42 performs a combustion chamber cooling function for absorbing combustion heat generated in the combustion chamber 30 and preheated to prevent overheating of the combustion chamber 30. [

The sensible heat exchanger 40 includes a tube 43 through which the heating medium having passed through the water pipe 42 flows and a plurality of heat conductive fins 43, (44).

The heat medium flows through the heat medium inlet 40a (see FIG. 7), absorbs latent heat while passing through a heat medium flow passage (not shown) provided in the latent heat heat exchanger 50, And the heated heating medium is discharged through the heating medium outlet 40b and can be used for heating or hot water supply.

The sensible heat exchanger 40 and the latent heat heat exchanger 50 are made of separate modules and are formed of a sensible heat connection part 410 formed at the lower end of the sensible heat exchanger 40 and a latent heat connection part 410 formed at the upper end of the latent heat heat exchanger 50, The connecting portion 510 is joined by fastening means such as a bolt and a nut.

A packing 80 is provided between the sensible heat connection part 410 and the latent heat connection part 510 to prevent the combustion gas from leaking to the outside through a gap between the sensible heat connection part 410 and the latent heat connection part 510.

A sensible heat flange portion 411 contacting the upper surface of the packing 80 is attached to the sensible heat insulator 410. The sensible heat insulator 410 may be formed of a synthetic resin, And a latent heat flange portion 511 having a seating groove 510a on which the packing 80 is seated is formed in the latent heat connection portion 510. [

In the present invention, the combustion heat shielding means 100 (100-1, 100-2, 100-3) for blocking the combustion heat of the combustion gas from being directly transmitted to the packing 80 is provided.

The combustion heat interrupting means 100 is configured such that the combustion gas of a high temperature (about 300 캜) passing through the sensible heat exchanger 40 flows into the gap between the sensible heat flange portion 411 and the latent heat flange portion 511, It is possible to prevent the packing 80 from being burned due to hardening and carbonization.

2, the combustion heat interrupting means 100-1 is disposed at an inner end of the latent heat flange portion 511 so as to be located inside the inner end of the sensible heat flange portion 411, And an extended combustion heat inflow preventing protrusion 512. [

3, the combustion heat interrupting means 100-2 is disposed at an inner side of the latent heat flange 511 so as to be in contact with the bottom of the inner end of the sensible heat flange 411, And a combustion heat inflow prevention protrusion 513 extended from the combustion heat inflow prevention protrusion 513.

When the combustion heat inflow preventing protrusion 513 is configured to be in surface contact with the bottom surface of the inner end of the sensible heat flange 411, it is possible to effectively prevent the combustion gas from flowing into the packing 80 side.

4, the combustion heat shielding means 100-3 may be formed so as to contact the upper surface of the inner end of the latent heat flange portion 511 at the inner end of the sensible heat flange portion 411 And a bent combustion heat inflow preventing protrusion 412.

When the combustion heat inflow preventing protrusion 412 is configured to be in surface contact with the upper surface of the inner end of the latent heat flange 511, it is possible to effectively block the inflow of the combustion gas into the packing 80 side.

Referring to FIGS. 1 and 5 to 9, in the present invention, combustion gas flows into the space between the water pipe 42 positioned at the lowermost position and the tube 43 disposed adjacent thereto, As a means for solving the problem of deteriorating the durability and deteriorating the appearance due to the generation of the discoloration portion 41a which may be caused when the sensible heat panel 41 is overheated as shown in the drawing, And a heating guide (90) for guiding the flow of the combustion gas passed through the tube (42) to flow toward the tube (43).

9, the heating guide 90 includes a curved surface portion 91 having a shape that wraps around the inner surface of the water pipe 42, and a tube portion 43 at a lower end of the curved surface portion 91 And a guide portion 92 extending obliquely in the direction in which the guide portion 92 extends.

According to the configuration of the heating guide 90, as shown by arrows in the flow direction of the combustion gas in FIG. 8, the combustion gas flowing downward along the front and rear surfaces of the combustion chamber 30 is located at the lowermost side The curved surface portion 91 of the heating guide 90 and the guide portion 92 are moved in the direction of the flow toward the tube 43 by the curved surface portion 91 and the guide portion 92 of the heating guide 90, It is possible to prevent contact of the combustion gas with a portion susceptible to heat at high temperature, so that the durability of the sensible heat panel 41 can be improved.

As described above, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention as defined in the appended claims. And such modifications are within the scope of the present invention.

1: condensing boiler 10: blower
20: burner 30: combustion chamber
40: sensible heat exchanger 41: sensible heat panel
41a: discoloration part 42: water pipe
43: tube 44: heating pin
410: sensible heat connection part 411: sensible heat flange part
412: Combustion heat inflow prevention protrusion 50: Latent heat heat exchanger
510: latent heat coupling portion 510a:
511: latent heat flange portion 512,513: combustion heat inflow preventing projection
60: condensate receiver 70: exhaust duct
80: packing 90: heating guide
91: curved portion 92: guide portion
100: Combustion heat blocking means

Claims (8)

A sensible heat exchanger (40) for absorbing combustion sensible heat generated in the combustion chamber (30);
A latent heat heat exchanger (50) for absorbing the latent heat of steam contained in the heat-exchanged combustion gas in the sensible heat exchanger (40);
A packing 80 provided between the sensible heat coupling part 410 and the latent heat coupling part 510 to which the sensible heat exchanger 40 and the latent heat heat exchanger 50 are connected to prevent leakage of the combustion gas; And
A combustion heat blocking means (100) for blocking the heat of the combustion gas from being directly transferred to the packing (80);
To prevent the heat exchanger parts from burning out. The method according to claim 1,
The sensible heat connection part 410 is formed with a sensible heat flange part 411 contacting the upper surface of the packing 80,
The latent heat connection part 510 is formed with a latent heat flange part 511 on which the packing 80 is seated,
The combustion heat shielding means 100 includes a combustion heat inflow prevention protrusion 512 extending from the inner end of the latent heat flange portion 511 to the inside of the inner end of the sensible heat flange portion 411, Prevent burn-out structure of heat exchanger parts. The method according to claim 1,
The sensible heat connection part 410 is formed with a sensible heat flange part 411 contacting the upper surface of the packing 80,
The latent heat connection part 510 is formed with a latent heat flange part 511 on which the packing 80 is seated,
The combustion heat shielding means 100 is provided with a combustion heat inflow prevention protrusion 513 extending from the inner end of the latent heat flange portion 511 so as to contact the bottom surface of the inner end of the sensible heat flange portion 411 Prevent burn-out structure of heat exchanger parts. The method of claim 3,
Wherein the combustion heat inflow prevention protrusion (513) is in surface contact with the bottom surface of the inner end of the sensible heat flange (411). The method according to claim 1,
The sensible heat connection part 410 is formed with a sensible heat flange part 411 contacting the upper surface of the packing 80,
The latent heat connection part 510 is formed with a latent heat flange part 511 on which the packing 80 is seated,
The combustion heat cutoff means 100 includes a combustion heat introduction preventing protrusion 412 which is bent at an inner end of the sensible heat flange 411 so as to come into contact with the upper surface of the inner end of the latent heat flange 511, Prevent burn-out structure of heat exchanger parts. 6. The method of claim 5,
Wherein the combustion heat inflow preventing protrusion (412) is in surface contact with the upper surface of the inner end of the latent heat flange (511). The method according to claim 1,
The front and rear surfaces of the combustion chamber 30 and the sensible heat exchanger 40 are provided with a sensible heat panel 41 forming an outer wall,
The front and rear surfaces of the combustion chamber 30 are provided with a plurality of water pipes 42 disposed on the outside of the sensible heat panel 41 and spaced vertically,
The sensible heat exchanger (40) is provided with a plurality of tubes (43) through which heat medium flows,
The combustion gas flows toward the tube 43 on the inner surface of the sensible heat pipe panel 41 located between the water pipe 42 and the tube 43 adjacent to the water pipe 42 And a heating guide (90) for guiding the heat of the heat exchanger. 8. The method of claim 7,
The heating guide 90 includes a curved surface portion 91 formed to surround the inner surface of the water pipe 42 and a curved surface portion 91 extending from the lower end of the curved surface portion 91 in an inclined manner toward the tube 43 And a guide portion (92).

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