KR101434978B1 - Gas boiler which prevents overheat of a burner flange - Google Patents

Abstract

The present invention relates to a gas boiler, comprising: a burner which burns premixed gas and has a burner flange formed along the circumferential direction; A gas supply chamber which is seated at the top of the burner to supply the premixed gas to the burner and which is formed with a chamber flange cooperating with the burner flange and in surface contact with the burner flange; And a sealing member provided between the burner and the gas supply chamber to prevent the premixed gas supplied to the burner from leaking from the gas supply chamber to the burner in the gas supply chamber.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a gas boiler for preventing overheating of a burner flange,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas boiler, and more particularly, to a gas boiler having a structure capable of preventing superheat of a burner by supplying a premixed gas from a gas supply chamber and burning it.

Boilers that are mainly used for heating and hot water supply in general households can be divided into oil boilers and gas boilers, depending on the fuel used. Gas boilers use liquefied petroleum gas (LPG) as a raw material, but most of them use LNG, which is a clean fuel that can minimize air pollution, because it contains almost no sulfur except diesel or kerosene. The oil boiler and the gas boiler heat the fluid by using the heat generated by oxidation of the oil and the gas and circulate the heated fluid so that the heat exchange is performed, thereby increasing the room temperature and using hot water at the same time.

In recent years, a condensing boiler in which a burner is provided on the upper surface or side surface of a heat exchanger to make a combustion gas flow downward and a condensing heat exchanger to lower an exhaust gas temperature of the heat exchanger to a dew point temperature or less is widely used.

However, when the burner is burned in the gas boiler, there is a problem that the flame of the burner generated by the combustion is shortened in the case of low calorific value, and if the flame of the burner becomes short, the flame may cause a problem of overheating the surface of the burner . In particular, in the case of a top-down type condensing boiler, since the flame of the burner is almost attached to the surface of the burner, there is a problem that the surface of the burner (in particular, the flange of the burner) In such a high-temperature environment, there is a problem that the width of selecting the sealing member material becomes narrow.

Korea Patent No. 10-0242970

The present invention relates to a gas boiler including a packing for preventing heat from being exchanged with premixed gas to prevent overheating of the burner, preventing gas from leaking while making a close contact between the burner and the gas supply chamber, And to provide the above-mentioned objects.

The present invention relates to a burner for burning premixed gas, comprising: a burner having a burner flange formed along a circumferential direction; A gas supply chamber which is seated at the top of the burner to supply the premixed gas to the burner and which is formed with a chamber flange cooperating with the burner flange and in surface contact with the burner flange; And a sealing member provided between the burner and the gas supply chamber to prevent the premixed gas supplied to the burner from leaking from the gas supply chamber to the burner do.

The gas boiler according to the present invention has the following effects.

First, the burner flange of the burner and the chamber flange of the gas supply chamber coalesce and come into contact with each other, so that the heat of the burner itself is released into the chamber flange of the gas supply chamber during operation, so that the overheat of the burner .

Secondly, it is possible to prevent premixed gas supplied to the burner from the gas supply chamber from leaking between the burner and the gas supply chamber by the sealing member provided between the burner and the gas supply chamber.

Third, protrusions formed obliquely projecting from the body of the sealing member can be laid toward the body when the burner and the gas supply chamber are coupled, so that the contact between the burner flange and the chamber flange is more stable, Overheating of the burner can be prevented through heat exchange. Therefore, the effect of widening the selection of the material of the sealing member can be obtained.

Fourth, a radiating fin is provided between the burner and the gas supply chamber to further prevent the burner from being overheated by the radiating fin cooled by the low-temperature premixed gas supplied from the gas supply chamber.

1 is a perspective view showing an overall structure of a gas boiler according to an embodiment of the present invention.
2 and 3 are partially enlarged cross-sectional views of a cross section of a gas boiler according to the embodiment of FIG.
4 is a sectional view of the sealing member shown in Figs. 2 and 3. Fig.
5 and 6 are partially enlarged cross-sectional views showing a cross-sectional view of a gas boiler according to another embodiment of the present invention.
7 is a perspective view of the radiating fin shown in Figs. 5 and 6. Fig.
8 is a perspective view of a modification of the radiating fin shown in Fig.

1 to 4 show a gas boiler according to an embodiment of the present invention.

Referring to FIGS. 1 to 4, the gas boiler includes a burner 110, a gas supply chamber 130, and a sealing member 150. 1, the gas boiler according to an embodiment of the present invention has a shape and a structure as shown in FIG. 1, and the gas boiler according to an embodiment of the present invention can accurately determine the burner 110 and the gas supply chamber 130 Location can be grasped. The burner 110 serves to burn and pre-mix the pre-mixed gas. The burner 110 is supplied with the pre-mixed gas from the gas supply chamber 130, which will be described later, in which air and gas are preliminarily mixed at a mixing ratio in an optimum combustion state. This premixed gas can be completely burned, and it can have an effect of achieving complete combustion with a high combustion efficiency and a small air ratio. The burner 110 is generally a metal fiber burner. An example of the metal fiber burner is disclosed in Japanese Patent Application Laid-Open No. 2002-0069530.

Meanwhile, the burner 110 as described above may be variously formed without limiting its shape, and a burner flange 111 is formed on the side surface of the burner 110 along the circumferential direction.

The gas supply chamber 130 serves to supply the premixed gas to be burned by the burner 110 to the burner 110, as described above. The gas supply chamber 130 is seated and coupled to the upper portion of the burner 110. A chamber flange 131 is formed in the gas supply chamber 130 so as to cooperate with the burner flange 111 when the gas supply chamber 130 is seated at the top of the burner 110, The flange 111 and the chamber flange 131 are brought into surface contact by coalescence.

The burner 110 and the gas supply chamber 130 are generally formed of a metal material and the burner flange 111 and the chamber flange 131 are formed in the gas supply chamber 130, It is possible to prevent the premixed gas supplied to the fuel cell 110 from leaking. However, since the combination of the burner flange 111 and the chamber flange 131 does not completely prevent the leaking of the premixed gas, the burner 110 and the gas supply chamber 130 may be separated from each other, It is necessary to provide a structure capable of preventing gas leakage.

Accordingly, a sealing member is provided between the burner 110 and the gas supply chamber 130. However, due to the installation of the sealing member, the burner and the gas supply chamber may not be formed and may be slightly opened. Accordingly, the sealing member 150 according to the present invention solves this problem, so that the burner flange 111 of the burner 110 and the chamber flange 131 of the gas supply chamber 130 are completely combined and combined, So that the surface contact between the flange 111 and the chamber flange 131 can be made. The position where the sealing member 150 is installed is more specifically disposed between the burner flange 111 and the chamber flange 131 when the burner flange 111 and the chamber flange 131 are combined . Therefore, a groove 133 is formed in the chamber flange 131 so that the sealing member 150 can be installed.

The sealing member 150 includes a body 151 and a protrusion 153 formed on the body 151. The body 151 is formed to have a thickness smaller than the height of the groove 133 so as to be inserted into the groove 133. The body 151 may be formed in a column shape having a circular or rectangular cross section, or may be formed in various shapes.

The body 151 is formed with a plurality of protrusions 153 projecting from the body 151. The projection 153 is formed in the chamber flange 151 of the gas supply chamber 130 when the sealing member 150 is installed between the burner 110 and the gas supply chamber 130. And the other part is formed to be inclined toward the burner flange 111 of the burner 110. The other part of the burner 110 is inclined toward the inner surface of the groove 133,

4, the protrusions 153 formed on the inner surfaces of the grooves 133 of the plurality of protrusions 153 are inclined upwards from the body 151, and the burner flanges 111 The protrusion 153 is formed to be inclined downward from the body 151. That is, the plurality of projections 153 are formed in a direction toward the gas supply chamber 130 and the inside of the burner 110.

When the sealing member 150 is installed between the burner 110 and the gas supply chamber 130, the plurality of protrusions 153 may be formed between the burner 110 and the gas supply chamber 130 As shown in FIG. The sealing member 150 is formed to be larger than the height of the groove 133 formed in the gas supply chamber 130 by the plurality of projections 153. However, since the sealing member 150 is formed of a rubber material having ductility, the protrusion 153 can move smoothly and be installed between the burner 110 and the gas supply chamber 130. 3, when the sealing member 150 is installed in the groove 133, the plurality of protrusions 153 of the sealing member 150 move in the direction of arrows toward the body 151 And is installed in the groove 133.

The burner flange 111 of the burner 110 and the chamber flange 131 of the gas supply chamber 130 can be perfectly coupled to each other even if the sealing member 150 is installed, The flange 111 and the chamber flange 131 may be in surface contact with each other. Due to the surface contact between the burner flange 111 and the chamber flange 131, the burner has a short burner flame at the time of burning at a low load of heat, so that the burner flange 111 and the chamber flange 131) of the burner (110) is prevented from being overheated.

The premixed gas supplied to the burner 110 from the gas supply chamber 130 may leak between the burner 110 and the gas supply chamber 130. However, 150 is installed between the burner 110 and the gas supply chamber 130, leakage of the gas by the sealing member 150 can be prevented. Particularly, since the plurality of protrusions 153 formed on the sealing member 150 are installed so as to face the gas supply chamber 130 and the burner 110, the plurality of protrusions 153 are formed in the premixed It is possible to prevent the gas from escaping once more.

5 to 8 show a gas boiler according to another embodiment of the present invention. The same reference numerals as those of the above-described embodiment denote the same members, and the following description will focus on the differences from the above-described embodiments.

When the premixed gas is burned in the burner, the flame is shortened in the case of a low load calorific value, which may cause a problem that the surface of the burner is overheated. The gas boiler further includes a radiating fin 170 to solve this problem. The radiating fins 170 are installed between the burner 110 and the gas supply chamber 130 as shown in FIGS. More specifically, one end of the radiating fin 170 is fixed to the burner flange 111 and the other end is extended toward the inside of the gas supply chamber 130. The other end of the radiating fin 170 extending toward the inside of the gas supply chamber 130 is in contact with the premixed gas supplied from the gas supply chamber 130. Since the premixed gas is at a low temperature, The heat dissipation fin 170 cooled by the premixed gas is heat exchanged through one end of the heat dissipation fin 170 fixed to the burner flange 111 of the burner 110 to cool the burner 110 have.

7, a first plate 171 fixed to the burner flange 111 and extending in a direction toward the inside of the burner 110, When the heat radiating fins 170 are installed between the burner 110 and the gas supply chamber 130, the heat radiating fins 170 are bent upwardly in the direction toward the gas supply chamber 130, And a second plate (172).

The second plate 172 in contact with the premixed gas is bent plural times while alternating between the convex portion 172a and the concave portion 172b to increase the contact area with the premixed gas. Referring to FIG. 7, the convex portion 172a and the concave portion 172b have the same shape as the thread.

8 shows a modification of the heat dissipating fin 170 '. Referring to FIG. 8, the radiating fin 170 'includes a first plate 171' and a second plate 172 'like the radiating fin 170 described above, but is formed on the second plate 172' The shape of the convex portion 172a 'and the shape of the concave portion 172b' are formed differently. The convex portion 172a and the concave portion 172b of the radiating fin 170 as shown in FIG. 7 are formed to be sharp in the form of a thread as described above, but the convex portion 172a and the concave portion 172b of the radiating fin 170 ' The convex portion 172a 'and the concave portion 172b' are formed in a curved shape.

Meanwhile, the second plates 172 and 172 'are not limited to the shapes shown in FIGS. 7 and 8, and may be formed in various shapes to increase the contact area with the pre-mixed gas.

Since the heat dissipation fins 170 and 170 'can easily be cooled by being in contact with the premixed gas and the heat dissipation fins 170 and 170' can be heat-exchanged with the fixed burner 110, It is preferable to be formed of a good metal material or a thermally conductive plastic material.

When the radiating fins 170 and 170 'are installed between the burner 110 and the gas supply chamber 130 as described above, the radiating fins 170 and 170' And cooling the burner 110 through heat exchange between the heat dissipation fin 170 and the burner 110. The heat dissipation fin 170 can be cooled by contacting the pre- Particularly, in the case of a low load, when the burner 110 burns the premixed gas, the flame is shortened to overheat the surface of the burner 110, Can be prevented.

When the surface of the burner 110 is overheated, the selection width of the material of the sealing member 150 installed to prevent leakage of the premixed gas between the burner 110 and the gas supply chamber 130 Become narrower. Particularly, when the surface of the burner 110 is overheated, it is necessary to provide a sealing member using a material having enhanced heat resistance. In addition to narrowing the selection range of the sealing member, a material or a cost This can lead to a problem of burden. Therefore, when the heat dissipation fin 170 is provided between the burner 110 and the gas supply chamber 130, the surface of the burner 110 can be prevented from being overheated through heat exchange, The selection range of the material used for the sealing member 150 installed between the supply chambers 130 can be widened and the cost can be reduced.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110: burner 111: burner flange
130: gas supply chamber 131: chamber flange
133: Home
150: sealing member 151: body
153: projection 170: radiating fin

Claims (6)

A burner for burning premixed gas and having a burner flange formed along the circumferential direction;
A gas supply chamber which is seated at the top of the burner to supply the premixed gas to the burner and which is formed with a chamber flange cooperating with the burner flange and in surface contact with the burner flange;
A sealing member installed between the burner and the gas supply chamber to prevent the premixed gas supplied from the gas supply chamber to the burner from leaking between the gas supply chamber and the burner;
And a radiating fin which is provided between the gas supply chamber and the burner and has one end fixed to the burner flange and the other end extending toward the gas supply chamber to heat exchange with the premixed gas to cool the burner,
Wherein the sealing member comprises:
Body; And
A plurality of protrusions protruding from the body toward the gas supply chamber and a remaining portion protruding toward the burner,
Wherein the plurality of projections
A part of which is protruded upwardly toward the gas supply chamber and the remaining part of which protrudes downwardly toward the burner,
Wherein the sealing member is disposed between the gas supply chamber and the burner such that a direction in which the protrusions extend is opposite to a direction in which the premixed gas leaks, and when the burner and the gas supply chamber are engaged, A gas boiler in which a plurality of projections are pressed in a direction toward the body. The method according to claim 1,
Wherein the gas supply chamber is formed with a groove in which the sealing member is installed in the chamber flange. delete delete The method according to claim 1,
The heat-
A first plate extending from the burner flange toward the inside of the burner; And
And a second plate extending from a front end of the first plate, the second plate being inclined upward toward the gas supply chamber. The method of claim 5,
Wherein the heat dissipation fin is formed by bending the concave portion and the protrusion portion of the second plate alternately a plurality of times so that the contact area with the pre-mixed gas is increased.

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