KR101563579B1 - Double tewel of boiler - Google Patents

Abstract

The present invention relates to a double flue of a boiler, wherein the double flue of the boiler according to the invention comprises a tubular outer body enclosing a space between a first end and a second end and a space between the first end and the second end Wherein the first end is open and connected to the boiler combustion chamber so as to communicate with the combustion chamber intake port of the boiler, and a distal end portion of the outer body, which includes a portion of the predetermined length from the second end, And a tubular inner body enclosing a space between the opened primary end and the closed secondary end and the space between the primary end and the secondary end, the outer peripheral surface of the inner body being spaced from the inner peripheral surface of the outer body by a distance And the first end of the pipe passes through the inner space of the air supply pipe, and the first end of the pipe is surrounded by the combustion chamber intake port of the boiler And an end portion of the inner body, which includes a portion of a predetermined length from the second end, is longer than the air supply pipe so as to be located outside the air supply pipe, And an exhaust pipe having a plurality of exhaust holes formed in a distal end portion of the inner body located outside the inner body, and the outer region portion of the inner body of the second end is configured to be closed.

Description

DOUBLE TEWEL OF BOILER < RTI ID = 0.0 >

The present invention relates to a flue of a boiler, and more particularly, to a dual flue of a boiler which is excellent in combustion efficiency and has fuel saving effect and structurally robust.

The double flue of the conventional boiler shown in FIG. 1 has only a part of the front part of the double flue, the air inlet is formed at the outer peripheral face of the end edge of the outer flue, the air inlet is formed at the end of the double flue, And includes a building finish ring at the end.

The inner flue, which has an inner diameter of 75 psi, is a straight pipe used exclusively for exhaust, and the outer flue, which has an inner diameter of 100 pie, is set as a simple intake path from the outside of the building and forms the air passage required by the aluminum bellows Supply air to the inside of the boiler, and a single-pipe elbow with an inner diameter of 75 pie is to be used as a heat-resistant silicone O-ring.

When connecting the parts together, the intersection is closed with O-ring inside and the outside with heat-resistant silicone to prevent waste gas leakage.

However, in the conventional double flame as described above, the combustion efficiency is good when fresh air is introduced. However, since the inlet of the waste gas at the end of the internal combustion engine is too close to the intake port of the external combustion engine, the waste gas is introduced again to incomplete combustion, have.

In addition, the inner duct exhaust pipe is an intuitive structure which does not help to preheat the intake air, and the silicon o-ring mounted is ruptured to prevent leakage of the exhaust gas at the intersection when the straight pipe is joined with the elbow part. It can be leaked into the building, leading to safety accidents, and the aluminum bellows is damaged, so that its function is easily lost and the waste heat source is discharged to the atmosphere.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art, and it is an object of the present invention to prevent backward flow and good inflow from an all-weather environment and to connect parts together using a sealing type without using a silicone O- The purpose of the present invention is to provide a double year boiler which can supply intake air to a boiler room without using a hard aluminum bellows and make the air heated by an exhaust heat source to double the efficiency in the combustion chamber when the boiler is operated have.

To achieve these and other advantages and in accordance with the purpose of the present invention, a dual phase boiler comprises a tubular outer body enclosing a space between a first end and a second end and a space between the first end and the second end Wherein the first end is connected to the boiler combustion chamber so as to communicate with the combustion chamber intake port of the boiler and the end portion including the portion of the outer main body having a predetermined length from the second end is provided with an air supply pipe And a tubular inner body enclosing a space between the primary end and the closed end and a space between the primary end and the secondary end, the outer periphery of the inner body being spaced from the inner periphery of the outer body And the first end passes through the inner space of the air supply pipe, and the first end is connected to the combustion chamber inlet And a distal end portion of the inner body, which has a predetermined length from the second end, is longer than the air supply pipe so as to be positioned outside the air supply pipe, And an exhaust pipe in which a plurality of exhaust holes are formed in the distal end portion of the inner body located outside, and the outer region portion of the inner body of the second end is configured to be closed.

In addition, it is preferable that at least a part of the inner body of the exhaust pipe located inside the air supply pipe is formed in a corrugated pipe structure.

And an inner ring which is in close contact with an outer peripheral surface of the inner body and a connecting member which connects the outer ring and the inner ring, And a support portion configured to allow the supply air to pass through the space.

Each of the air supply pipe and the exhaust pipe may include a horizontal pipe extending in a horizontal direction, an elbow for connecting the horizontal pipe and the boiler, and a plurality of supports installed at a portion where the horizontal pipe and the elbow are connected Wherein one of the ends of the horizontal tube and the elbow is inserted into and connected to the other end of the elongated tube, and the end portion of the horizontal tube of the supply tube and the distal end portion of the elbow of the supply tube intersect, Is inserted into the fitting groove formed around the outer ring of the supporting portion provided inside the distal end portion located on the outer side and is engaged while being sealed by the engagement, and the distal end of the vertical pipe of the air supply pipe and the elbow The end portion of the overlapping portion, which is located on the inner side of the overlapping portion, It is fitted into the insertion grooves formed in the periphery of the outer ring of the position support portion provided at a distal end, inside of which the other hand it is preferred that the combination yirumyeonseo sealing by engaging.

An outer fixing ring which is in close contact with an outer ring of the support portion and which is in close contact with an inner peripheral surface of the air supply pipe and is adjacent to an outer ring of the support portion in the longitudinal direction of the air supply pipe, And an inner fixing ring which is in close contact with the inner ring of the support portion and is fixed in close contact with the inner ring of the support portion and the longitudinal direction of the exhaust pipe.

Further, it is preferable that the exhaust hole has a rectangular shape.

In addition, it is preferable that a reinforcing member protruding inward is integrally formed between the adjacent exhaust holes in the inner circumferential surface of the exhaust pipe.

As described above, according to the double year of the boiler according to the present invention, the incomplete combustion due to the reverse wind is prevented by the structure of the end of the year, and the exhaust heat is maximized by using the corrugated tube and the rectangular elbow is double- The required air is primarily used to heat the intake air by applying the heat of waste heat between the inner and outer ducts, and the connecting points between the parts are completely sealed by the aluminum die casting parts and are firmly fixed by the triple intersection with the stainless steel flue, It has the advantage that the appearance is neat and the silicone o-ring is not necessary to prevent the waste gas leakage.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a side view of a dual year boiler according to the prior art;
2 is a side view showing a double year of the boiler according to the present invention.
3 is a sectional side view showing a double flue of the boiler according to the present invention.
4 is a perspective view of a double flue of a boiler according to the present invention.
5 is a perspective view showing a supporting part and a fixing ring of a double flue of a boiler according to the present invention.
6 and 7 are partially enlarged views showing a double year of the boiler according to the present invention;
8A and 8B are perspective views showing a boiler connection cap of a double year boiler according to the present invention.
FIG. 9 is a perspective view showing the invention applied in Korean Patent Application No. 10-2013-0073703.
10 is a side view showing a state in which a double year of the boiler according to the present invention is combined with the invention disclosed in Korean Patent Application No. 10-2013-0073703.

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

FIG. 2 is a side view showing a double flue of the boiler according to the present invention, and FIG. 3 is a sectional side view showing a double flue of the boiler according to the present invention.

The double flue of the boiler according to the present invention comprises an air supply pipe 100, an exhaust pipe 200, supports 300a, 300b and 300c, an outer fixing ring 400 and an inner fixing ring 500.

The air supply pipe 100 is the outermost pipe and the exhaust pipe 200 is a stainless steel pipe extending long along the center of the inner space of the air supply pipe 100, The supply pipe 100 is connected to the boiler combustion chamber intake port 600 and the exhaust pipe 200 is connected to the boiler combustion chamber exhaust port 610 surrounded by the boiler combustion chamber intake port 600, The space between the inner exhaust pipes 200 becomes a passage through which the outside air of the boiler flows and the inner space of the exhaust pipe 200 becomes a passage through which the exhaust gas discharged from the boiler combustion chamber passes.

The supply pipe 100 includes an outer body in the form of a circular pipe and a first end 120 which is an open end of the outer body and a second end 130 which is closed at an outer portion surrounding the exhaust pipe 200 And the exhaust pipe 200 includes an inner body 210 in the form of a circular pipe and a secondary end 230 which is a closed end and a primary end 220 which is an open end of the internal body 210 do.

The space between the outer body 110 and the inner body 210 becomes the passage of the introduced air and the inner space of the inner body 210 becomes the passage of the exhaust gas. The primary end 120 connected to the inlet port 600 and opened is connected to the boiler combustion chamber exhaust port 610.

2, the exhaust pipe 200 is extended longer from the combustion chamber than the air supply pipe 100 so that the secondary end 230 is located farther from the combustion chamber than the second end 130, 200 protrude to the outside of the supply pipe 100.

A plurality of rectangular exhaust holes 211 are formed in the outer surface of the inner body 210 of the exhaust pipe 200 such that the exhaust pipes 200 are exposed to the outside of the air supply pipe 100. Since the secondary end 230 of the exhaust pipe 200 is closed and only the exhaust holes 211 formed in the vicinity of the end portion of the exhaust pipe 200 are connected to the outside atmosphere, It is possible to solve the problem that the exhaust gas is re-introduced by the backward wind as in the case of the double year due to the reverse flow.

The reason why the exhaust hole 211 is formed in a quadrangular shape is to increase the exhaust effect by making the actual area of the hole larger as compared with the case where the exhaust hole 211 is formed in a circular shape.

A plurality of air inlet holes 111 are formed at a predetermined distance from the outer end of the outer main body 110 of the air supply pipe 100 at a distal end located within a certain distance from the second end 130, do.

The air inlet hole 111 is formed by a plurality of circular air holes formed at regular intervals while circulating the air supply pipe 100 and a plurality of horizontally elongated rectangular holes circulating the air supply pipe 100 at regular intervals, It includes two kinds of formed ones.

A reinforcing member protruding inwardly of the pipe is formed integrally with the inner body 210 between the adjacent exhaust holes 211 and the exhaust holes 211 and the adjacent intake holes 111 and the intake holes 111, The reinforcing member 112 protruding inwardly of the pipe is integrally formed with the outer body 110 to increase the durability of the pipe body 110. The strength of the pipe strength Weakening is prevented.

3, the air supply pipe 100 includes a horizontal pipe 101 extending in a horizontal direction, an air supply pipe connection cap 103 coupled to the upper portion of the boiler combustion chamber intake port 600, a horizontal pipe 101, And an elbow 102 connected to the supply pipe connection cap 103 and bent at an angle of 90 DEG. The exhaust pipe 200 includes a horizontal pipe 201 extending in a horizontal direction, a horizontal pipe 201 extending in a horizontal direction, And an elbow 102 which connects the horizontal pipe 201 and the exhaust pipe connecting cap 203 and is bent at 90 °.

5, the supports 300a, 300b and 300c include an outer ring 310 which is in close contact with the inner peripheral surface of the outer body 110, an inner ring 320 which is in close contact with the outer peripheral surface of the inner body 210, And a connecting member 330 connecting between the outer ring 310 and the inner ring 320. The connecting members 330 are radially extended about the inner body 210 with a gap therebetween, And the intake air is passed through the space between the members 330. [

4, the support portion includes a first support portion 300a provided in close contact with the inner peripheral surface of the horizontal pipe 101 of the air supply pipe 100, a first support portion 300b provided in the elbow 102 of the air supply pipe 100 extending in the horizontal direction, A second support portion 300b which is in close contact with the inner circumferential surface of one end portion of the first support portion 300a and is spaced apart from the first support portion 300a and an inner circumferential surface of the other end portion of the elbow 102 of the supply pipe 100 extending in the vertical direction The third support portion 300c is installed to firmly support the exhaust pipe 200 while firmly supporting the elbow 102 and the horizontal pipe 101 or between the elbow 102 and the supply pipe connecting cap 103. [ .

4, in the air supply pipe 100, a portion of the elbow 102 bent to be curved has a corrugated pipe structure. In the exhaust pipe 200, a portion bent in a curve in the elbow 202, And the portion supported by the first support portion 300a forms a bell tube 212 structure.

Since most of the portion of the horizontal pipe 201 of the exhaust pipe 200 has a corrugated pipe structure, the heat radiation area is maximized, so that the preheating effect of the intake air using the waste gas is enhanced.

6, a distal end portion of a portion of the elbow 102 of the air supply pipe 100 that is connected to the horizontal tube 101 of the air supply pipe 100 is connected to a distal end portion of the horizontal tube 101 of the air supply pipe 100, The end portion of the first support portion 300a is engaged with the outer ring 310 of the first support portion 300a while a portion of the outer circumferential surface of the outer ring 310 of the first support portion 300a is pushed inward, Is inserted in the fitting groove which forms a space between the outer circumferential surface of the outer ring 310 of the air supply pipe 100 and the inner circumferential surface of the horizontal pipe 101 of the air supply pipe 100, Is inserted into the distal end portion of the elbow 102 of the supply pipe 100 so that the end portion thereof abuts against the inner ring 320 of the second support portion 300b while the distal end portion of the second support portion 300b is engaged with the inner ring 320 of the second support portion 300b, A part of the inner circumferential surface of the inner ring 320 of the support portion 300b is punched out and the inner circumferential surface of the inner ring 320 of the second support portion 300b and the inner circumferential surface of the air supply pipe 100, Horizontal pipe 101 is closed without the use of silicone O-rings by being inserted into the insertion groove to form a space between the outer circumferential surface of the well comprising the other hand, the coupling is made firmly.

One end of the inner ring 320 of the first support portion 300a is caught by the protruding portion of the corrugated tube 212 due to the corrugated pipe structure of the exhaust pipe 200 and the other end of the inner ring 320 is closely attached to the outer circumferential surface of the exhaust pipe 200 And the first supporting portion 300a is fixed to be unable to move in the horizontal direction by being caught by the inner fixing ring 500 which is fixedly installed.

The outer ring 310 of the second support portion 300b is fixed to the inner circumferential surface of the supply pipe 100 and is fixed to the inner circumferential surface of the supply pipe 100. The pair of outer retaining rings 400, The second support portion 300b is fixed so as not to move in the horizontal direction.

FIGS. 8A and 8B show the double-jointed connection caps 103 and 203 of the boiler according to the present invention, and FIG. 7 is a partially enlarged view showing a portion where the connection caps 103 and 203 are installed.

8A is an exhaust pipe connecting cap 203 for connecting the exhaust pipe 200 to the boiler combustion chamber exhaust port 610. The lower end of the exhaust pipe connection cap 203 is connected to the boiler combustion chamber exhaust port 610 And the lower end of the elbow 202 of the exhaust pipe 200 is inserted into the groove formed around the outer peripheral surface of the lower end portion of the exhaust pipe connecting cap 203 to be airtightly coupled, Is fitted into the lower end of the exhaust pipe (200).

8B is an air supply pipe connecting cap 103 for connecting the air supply pipe 100 to the boiler combustion chamber inlet port 600. The lower end of the air supply pipe connection cap 103 is connected to the boiler combustion chamber inlet port 600 The upper end of the supply pipe connecting cap 103 is connected to the outer side of the third supporting portion 300c and the upper end of the air supply pipe connecting cap 103 is connected to the outside of the third supporting portion 300c The lower end surface of the inner ring 320 of the third support portion 300c is inserted into the fitting groove formed at the lower end of the ring 310 to be hermetically sealed so that the peripheral portion of the inner body 210 And is in contact with the upper end surface of the inner fixing ring 500 fixedly installed so as to tightly and enclose it.

The operation of the double boiler according to the present invention constructed as described above will be described as follows.

The air sucked in the air intake hole 111 of the air supply pipe 100 flows into the inner body of the exhaust pipe 200 located inside the air supply pipe 100 through the air passage of the outer body 110 and the inner body 210 210 to heat up the exhaust gas while moving to the boiler combustion chamber intake port 600 through the horizontal pipe 201 and the elbow 202, thereby heating up the exhaust gas and maximizing the effect of preheating the intake gas.

On the other hand, the exhaust gas discharged from the boiler is discharged from the boiler combustion chamber exhaust port 610 to the exhaust hole 210 while being exhausted to the outside atmosphere in a state in which heat is absorbed by heat exchange with the intake air, thereby contributing to prevention of global warming , The exhaust hole 211 is located farther away from the intake hole 111, so that the exhaust gas is prevented from entering the intake hole 111 again.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as set forth in the accompanying drawings. And modifications are within the scope of the appended claims.

100: Supply pipe 101: Supply pipe horizontal pipe
102: Supply pipe elbow 103: Supply pipe connection cap
110: outer body 111: intake hole
112: reinforcing member 120: first end
130: second end 200: exhaust pipe
201: exhaust pipe horizontal pipe 202: exhaust pipe elbow
203: exhaust pipe connecting cap 210: inner body
211: exhaust hole 212: corrugated tube
220: primary end 230: secondary end
300a: first support part 300b: second support part
300c: third support part 310: outer ring
320: inner ring 330: connecting member
400: outer fixing ring 500: inner fixing ring
600: Boiler combustion chamber intake port 610: Boiler combustion chamber exhaust port
1: Double tube 2: Bellows
3: Single-ended elbow

Claims (7)

And an outer body in the form of a tube surrounding a space between the first end and the second end, the first end being opened to communicate with the combustion chamber intake port of the boiler, And a plurality of air intake holes are formed in a distal end portion of the outer body, the portion including a predetermined length from the second end; And
And a tubular inner body enclosing a space between the opened first end, the closed second end, and the space between the first end and the second end, wherein the outer peripheral surface of the inner body is spaced from the inner peripheral surface of the outer body And the first end is coupled with the combustion chamber of the boiler so as to communicate with the combustion chamber exhaust port surrounded by the combustion chamber intake port of the boiler, and the first end of the inner body is connected to the combustion chamber exhaust port surrounded by the combustion chamber exhaust port And an exhaust pipe having a plurality of exhaust holes formed in a distal end portion of the inner body located outside the air supply pipe, wherein the exhaust pipe is extended from the air supply pipe so that a distal end portion thereof is located outside the air supply pipe,
The outer region portion of the inner body of the second end is configured to be closed,
An inner ring which is in close contact with an outer peripheral surface of the inner body and a connecting member which connects the outer ring and the inner ring, Further comprising a support configured to allow air supply air to pass therethrough,
Each of the supply pipe and the exhaust pipe includes a horizontal pipe extending in a horizontal direction, an elbow connecting the horizontal pipe and the boiler, and a plurality of supports installed at a portion where the horizontal pipe and the elbow are connected to each other ,
Wherein one end portion of the horizontal tube and the elbow are inserted and connected to the other end portion,
The end portion of the end portion of the horizontal pipe of the supply pipe and the end portion of the elbow of the supply pipe is located inside the end portion of the outer end portion of the outer pipe, And is coupled while being sealed by the engagement,
The end portion of the inlet pipe which is located inwardly of the fitting portion of the end portion of the vertical pipe and the end portion of the elbow of the air supply pipe is inserted into the insertion groove formed around the outer ring of the support portion provided inside the distal end portion And is engaged while being sealed by a catch. The method according to claim 1,
Wherein at least a part of an inner body of the exhaust pipe located inside the air supply pipe is formed in a corrugated pipe structure. delete delete 3. The method according to claim 1 or 2,
An outer fixing ring which is in close contact with an inner peripheral surface of the air supply pipe and which is in close contact with an outer ring of the supporting portion and an outer ring of the supporting portion in a longitudinal direction of the air supply pipe,
Further comprising an inner retaining ring which is in close contact with an outer peripheral surface of the exhaust pipe and is in close contact with the inner ring of the support portion and the inner ring of the support portion while being adjacent to the inner ring in the longitudinal direction of the exhaust pipe, . 3. The method according to claim 1 or 2,
Characterized in that the exhaust holes are rectangular in shape. 3. The method according to claim 1 or 2,
Wherein a reinforcing member protruding inward is integrally formed between the exhaust holes adjacent to each other in an inner peripheral surface of the exhaust pipe.

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