KR20150065499A - A gas boiler intake pipe and exhaust pipe with a built-in radiater for prevention of icicle - Google Patents

Abstract

The present invention relates to a gas boiler intake and exhaust pipe and, more specifically, relates to a gas boiler intake and exhaust pipe to prevent an icicle containing a radiator from preventing an icicle or removing a generated icicle by transmitting heat of a surface of an exhaust pipe heated by latent heat discharged during an operation of a gas boiler, via the radiator to the surface of an intake pipe enveloping the exhaust pipe and improving a combustion efficiency of the gas boiler by exchanging heat with air going through the intake pipe. According to the present invention, the gas boiler intake and exhaust pipe comprises: an exhaust pipe (12) connected to the main body of the gas boiler having an outlet (12a) and an exhaust pipe end cap (12b) formed on an end to discharge combustion gas to the outside; an intake pipe (11) having the same central axis with the exhaust pipe (12), having a plurality of intake holes (11a) formed on the predetermined positions of an outer circumference surface having an intake pipe end cap (11b) formed on an end to supply air necessary for combustion to the main body of the gas boiler from the outside while enveloping a certain length; and an intake connector (13) formed at the predetermined position of the intake pipe (11) to supply air to the main body of the gas boiler. To transmit part of the heat of the surface of the exhaust pipe (12) heated by latent heat discharged during the operation of the gas boiler to the surface of the intake pipe (11); the radiator (110) is inserted between the exhaust pipe (12) and the intake pipe (11).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an anti-icing gas boiler and an exhaust pipe,

The present invention relates to an air supply and exhaust pipe for a gas boiler, and more particularly, to an air supply and exhaust pipe for a gas boiler, The present invention relates to an anticorrosive gas boiler feed pipe for removing icicles which has already been generated, and also has a heat dissipating body for enhancing combustion efficiency of a gas boiler by exchanging heat with air passing through a feed pipe.

The gas boiler used in the present invention is widely used in general households. The gas boiler is furnished with a combustion chamber therein, and heat generated by combustion of the gaseous fuel is heated and circulated, or the cold water supplied through the water pipe is heated to supply hot water to be. At this time, an air supply action to the inside of the combustion chamber must be performed so that the combustion of the gaseous fuel is smoothly performed, and at the same time, the exhausted action of discharging the burned off gas to the outside should be performed.

Although there are various ways of supplying and exhausting gas boilers, it is a method for preventing the danger that accidents may occur due to the outflow of waste gas into the room. In this way, the supply fan for supplying the outside air and the waste gas generated in the combustion are discharged to the outside (FF) equipped with an exhaust fan is most widely used. Accordingly, a double-structured air supply / exhaust pipe having a double-structured air supply pipe positioned at the same center axis as the outside of the exhaust pipe is commonly used. A certain portion of the air supply / exhaust pipe is installed to be exposed to the outside through a wall 200 or a window, It is common to simultaneously perform exhausting.

As shown in FIG. 2, the conventional gas and air supply / exhaust pipe for gas boiler protects the exhaust port 12a and the exhaust port 12a at the end portion in order to discharge the waste gas from the gas boiler body to the outside, And a feed hole 11a is formed at a predetermined position on the outer circumferential surface so as to supply air necessary for combustion while enclosing a certain length at the same center axis as the exhaust pipe 12, (11) formed at the end portion of a feed end cap (11b) for preventing the mixing of waste gas formed and discharged from the feed end (11b) And a connector 13.

However, such existing boiler air-supplying and exhausting pipes may generate icicles at the lower end of the air supply hole 11a of the air supply pipe 11 due to condensation water generated by combustion of the gas boiler according to the environment, The falling water may fall on a part of the air supply pipe 11 and an icicle may be generated in the periphery, which may cause an accident caused by icicle drop.

The present invention solves the problem of icicle generation as described above. Even if the surface temperature of the exhaust pipe (12) increases due to the latent heat discharged when the gas boiler is operated, the external cold air is simultaneously supplied to the exhaust pipe An environment in which the heat of the exhaust pipe 12 can hardly be transferred to the air supply pipe 11 due to the passing structure is overcome by using the heat discharging body 100 as a thermal conductor to prevent icicles from being generated around the exhaust pipe of the gas boiler, The main objective is to reduce the incidence of icicle drop by removing the icicle that has already been generated at the time of operation.

In addition, the present invention provides an effect of expanding the area where heat is exchanged by the air passing through the air supply pipe (11) and the exhaust pipe (12) at a high temperature by the heat discharging body (100) It has an effect of increasing the heat exchange rate and increasing the combustion efficiency of the gas boiler.

According to an aspect of the present invention, there is provided an anticorrosive gas boiler feed / exhaust pipe having a heat discharging body therein, the exhaust pipe having an exhaust port and an exhaust pipe end cap connected to a main body of the gas boiler for discharging the combustion gas to the outside, A plurality of air supply holes formed at predetermined positions on an outer circumferential surface of the main body of the gas boiler to supply air required for combustion from the outside to the main body of the gas boiler with a center axis having the same central axis as the exhaust pipe, And an air supply connection port formed at a predetermined position of the gas engine to supply air to the gas boiler body, wherein a part of the surface heat of the exhaust pipe, which is increased by the latent heat discharged during the operation of the gas boiler, A radiator is formed at a predetermined position between the exhaust pipe and the turbocharger for delivery in,

The heat dissipating body contacts and surrounds the outside of the exhaust pipe and contacts the inner surface of the heat dissipating power supply organs, which is a component of the heat dissipating member, to transmit heat.

The anti-icing gas boiler supply / exhaust pipe with the heat discharging body according to the present invention can be installed in a straight line in the direction of the end portion of the supply / discharge engine with the start point of the charge / discharge engine facing the gas boiler body and the charge / And the heat dissipation fins come into contact with the inner surface of the air supply pipe between the air supply holes and the air supply holes where the air supply holes are not formed.

In a preferred embodiment of the present invention, the heat dissipator is characterized in that a water dripping groove for smooth water dripping is formed at a terminating end of the heat dissipating member in contact with the heat dissipating fins and the air supply end cap.

As described above, the anti-icing gas boiler-equipped exhaust pipe incorporating the heat radiator of the present invention has the effect of reducing the risk of causing an accident in the supply and exhaust pipe of the boiler in the winter cold wave and causing safety accidents.

In addition, according to the anti-icing gas boiler feed pipe of the present invention, the temperature of the air sucked into the gas boiler is increased, which contributes to the combustion efficiency of the boiler.

1 is a side perspective view of an anti-icing gas boiler-and-gas exhaust pipe incorporating a heat-
2 is a side view of a gas boiler /
3 is a side perspective view of the heat discharging body 100,
4 is a sectional view taken along the line AA in Fig. 2,
5 is a sectional view taken along line BB of Fig. 2,
6 is a side view of the heat discharging body 100,
FIG. 7 is a cross-sectional view taken along the line B'-B 'of FIG. 6 and the line B'"-B"
8 is a sectional view taken along the line CC of Fig. 6,
9 is a sectional view taken along line DD of Fig.

According to an aspect of the present invention, there is provided an anticorrosive gas boiler feed / exhaust pipe having a heat discharging body therein, the exhaust pipe having an exhaust port and an exhaust pipe end cap connected to a main body of the gas boiler for discharging the combustion gas to the outside, A plurality of air supply holes formed at predetermined positions on an outer circumferential surface of the main body of the gas boiler to supply air required for combustion from the outside to the main body of the gas boiler with a center axis having the same central axis as the exhaust pipe, And an air supply connection port formed at a predetermined position of the gas engine to supply air to the gas boiler body, wherein a part of the surface heat of the exhaust pipe, which is increased by the latent heat discharged during the operation of the gas boiler, It is noted that a heat dissipator is interposed between the exhaust pipe and the air supply pipe for delivery It shall be.

In the anti-icing gas boiler feed line of the present invention, the above-mentioned heat discharging body contacts and surrounds the outside of the exhaust pipe, and contacts the inner surface of the heat discharging power supplying / .

In the anti-icing gas boiler feed pipe having the heat discharging body according to the present invention, the heat dissipating fins are arranged such that the point of view of the feed pipe directed to the gas boiler body and the end portion of the feed pipe end- And the heat dissipation fins are brought into contact with the inner surface of the air supply pipe between the air supply holes and the air supply holes, in which the air supply holes are not formed.

In the anti-icing gas boiler feed pipe having the heat discharging body of the present invention, the heat discharging body has a water dripping groove formed at the end portion of the heat discharging body to which the heat discharging body and the exhaust pipe end cap are abutted, .

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

FIG. 1 is a side perspective view illustrating an anti-icing gas boiler-and-gas exhaust pipe incorporating a heat sink according to an embodiment of the present invention, FIG. 2 is a side view for explaining the external shape, name, and configuration of a conventional gas boiler- And FIG. 3 is a side perspective view for explaining a heat discharging body 100 located inside the air supply duct 11. FIG. 4 is a sectional view taken along the line AA in FIG. 2, 6 is a side view of the heat discharging body 100, and Fig. 7 is a sectional view taken along the line B-B in Fig. 6, and Fig. 6 is a sectional cross-sectional view for comparing a "-B" line cross-section and a B "-B" line cross-section where a water dropout groove 111 is formed. FIG. 8 is a cross- Sectional view.

The present invention relates to an exhaust gas purifying apparatus having an exhaust pipe 12 connected to a gas boiler body and having an exhaust port 12a and an exhaust pipe end cap 12b at an end thereof for discharging the combustion gas to the outside, A plurality of air supply holes 11a formed at predetermined positions on an outer circumferential surface of the main body of the gas boiler for supplying air required for combustion from the outside, and a gas supply end cap 11b formed at an end of the gas supply end cap 11b, And an air supply connection port (13) formed at a predetermined position of the air supply pipe (11) so as to supply air to the gas boiler body, characterized in that the air supply pipe (12) increases in response to the latent heat discharged from the gas boiler The heat discharging body 100 is sandwiched between the exhaust pipe 12 and the air supply pipe 11 so as to transmit part of the surface heat to the surface of the air supply pipe 11.

1 and 3, 4 and 5, the heat discharging body 100 surrounds the outer surface of the exhaust pipe 12, and the heat discharging body 100 The heat radiating fins 110 which are constituent parts of the exhaust pipe 12 are contacted to transfer the heat of the surface of the exhaust pipe 12 to the surface of the air supply pipe 11.

4 and 5, the heat radiating fins 110 of the heat discharging body 100 are arranged such that the view point of the air intake port 11 toward the gas boiler body and the air inlet end cap 11b, The heat dissipating flesh 110 is formed so as to contact the inner surface of the air supply duct 11 between the air supply holes 11a and the air supply holes 11a on the straight line in the direction of the end of the air supply duct 11, 6, which is a portion where the radiating fins 110 of FIG. 6 are present, and a portion where the radiating fins 110 do not exist It can be seen that the air holes 11a and the heat dissipating fins 110 are not in contact with each other due to the comparison of the DD line cross section.

7, 8, and 9, the heat discharging body 100 may be configured such that external water flowing through the upper feed holes 11a flows downward easily and is discharged to the lower feed holes 11a The water dripping groove 111 is formed and is explained by the difference between the B'-B 'line end face without the water drainage recess 111 of FIG. 7 and the B "-B" line end face where the water drainage recess 111 is formed The position and shape of the water dropping groove 111 can be seen due to the difference between the CC line end face of the radiator fuselage 110 of FIG. 9 and the DD line end face of the heat radiation fins 110, The size and shape of the grooves 111 can be modified into various shapes, which will be included in the basic idea of the present invention.

On the other hand, the heat discharging body 100 may be made of various materials having high thermal conductivity, but it is advantageous in terms of economy and efficiency to use an aluminum alloy.

Accordingly, when the combustion gas having a high temperature is discharged to the exhaust pipe 12, heat is transferred to a certain portion of the air supply pipe 11 through the heat discharging body 100, thereby preventing icicle formation or removing the already formed icicle At this time, the position of the radiating fins 110 is installed so as not to block the air supply holes 11a, so that the flow of the air sucked from the outside of the boiler- 11a, even if it flows into the boiler-and-air exhaust pipe, in the case of the construction example in which the installation regulation of the boiler air supply pipe is set to be downward by about 5 degrees in the outward direction, water is not accumulated by the heat discharging body 100, The lower feed hole 11a is formed through the water dropout groove 111 in the portion of the line B "-B" where the water dropout groove 111 is formed through the portion of the B'-B 'line where the grooves 111 are not formed .

In addition, the external air sucked through the air supply holes 11a is in contact with the heat discharging body 100 to perform constant heat exchange, thereby contributing to improvement of the combustion efficiency.

That is, the heat discharging body 100 has two purposes of transmitting the heat of the surface of the exhaust pipe 12 due to the latent heat being discharged to the surface of the air supply tube 11 and of exchanging heat with the air sucked from the outside.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the basic idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art will be able to modify the basic idea of the present invention in various forms. Accordingly, it is intended that the present invention cover modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

11: a power source 11a: a power source 11b: a power source end cap
12: exhaust pipe 12a: exhaust port 12b: exhaust pipe end cap
13: Supply connector
100: heat sink 110: heat sink 111: water dropping groove
200: wall

Claims (3)

An exhaust pipe 12 having an exhaust pipe 12a and an exhaust pipe end cap 12b connected to the main body of the gas boiler so as to discharge the combustion gas to the outside and an exhaust pipe 12b surrounding the exhaust pipe 12a, (11) having a plurality of feed holes (11a) formed at predetermined positions on an outer circumferential surface thereof and a feed end cap (11b) formed at an end thereof to supply air required for combustion from the outside to the main body of the gas boiler, (13) for supplying air to a gas boiler body at a predetermined position of the boiler body (11)
The heat radiator 100 is installed at a predetermined position between the exhaust pipe 12 and the air supply pipe 11 so as to transfer part of the surface heat of the exhaust pipe 12 to the surface of the air supply pipe 11, As a result,
The heat discharging body 100 contacts and surrounds the outside of the exhaust pipe 12 so that the heat discharging body 110 constituting a part of the heat discharging body 100 contacts the inner surface of the air supplying tube 11 to transmit heat Characterized in that the icemaker has a built-in heat sink (100). The method according to claim 1,
The heat dissipating fins 110 are installed in a space between the viewpoint of the air intake port 11 and the air intake port 11 formed with the air intake end cap 11b toward the gas boiler body so as not to block the air supply holes 11a. The heat discharging body 110 is formed in such a manner that the heat discharging body 110 is in contact with the inner surface of the air supply duct 11 between the air feeding holes 11a and the air feeding holes 11a, ) Anti-icing gas boiler exhaust pipe with built-in. 3. The method according to claim 1 or 2,
The heat dissipator 100 includes a water dissipation recess 111 for smooth water dissipation and a heat dissipation member 110 formed at a longitudinal end of the heat dissipation member 100 contacting the heat dissipation member 110 and the air supply end cap 11b 100) built-in anti-icing gas boiler exhaust pipe.

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