KR101878203B1 - Combustion apparatus of condensing type - Google Patents

Abstract

An object of the present invention is to provide a condensing-type combustion apparatus capable of preventing corrosion of the condensate receiver due to condensate generated in the latent heat heat exchanger. The present invention for realizing this is characterized in that it comprises a burner 120, a sensible heat exchanging part 130 for absorbing the heat of combustion generated in the burner 120, a latent heat exchanger 130 for storing the latent heat of the steam contained in the heat exchanged exhaust gas in the sensible heat exchanging part 130 A condensate receiver 160 made of a synthetic resin material for receiving the condensed water dropped from the latent heat heat exchanger 140 and discharging the condensed water to the outside; A partition 151 of metallic material for flowing an upward flow of exhaust gas to one side of the latent heat heat exchanger 140 when a part of the upper region of the sensible heat exchanger 130 is intercepted and disposed below the condenser receiver 160, Further comprising:

Description

[0001] Combustion apparatus of condensing type [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condensing-type combustion apparatus, and more particularly, to a condensing-type combustion apparatus capable of preventing corrosion by condensed water.

The condensing type combustion device is composed of a sensible heat exchange part absorbing the sensible heat of the exhaust gas generated in the combustion chamber and a latent heat heat exchanger part absorbing the latent heat in the heat exchanged exhaust gas in the sensible heat exchange part in order to increase thermal efficiency, .

As such a conventional condensing boiler, Korean Patent Laid-Open No. 10-2009-0067760, entitled "Heat exchanger of upflow combustion condensing boiler" is disclosed.

The conventional condensing boiler includes a sensible heat exchanging unit for absorbing combustion sensible heat generated in an upwardly burning burner, a latent heat heat exchanging unit for absorbing latent heat of steam contained in exhaust gas heat-exchanged in the sensible heat exchanging unit, And a condensate receiver for draining the condensate generated in the condenser. The exhaust gas passing through the latent heat heat exchanging unit and the falling direction of the condensed water generated by the latent heat heat exchanger are vertically downward, So that the latent heat recovery efficiency can be maximized.

However, in the conventional condensing boiler, corrosion may occur in the condensate receiver due to the condensate generated in the latent heat heat exchanger. In order to prevent such corrosion, the condensate receiver should be made of stainless steel which is resistant to corrosion.

Further, the condensed water generated in the latent heat heat exchanger leaks into the frame for fixing and supporting the latent heat heat exchanger, thereby causing corrosion of the frame.

It is an object of the present invention to provide a condensing type combustion device capable of preventing corrosion of a condensate receiver due to condensed water generated in a latent heat heat exchanger.

It is another object of the present invention to provide a condensing-type combustion apparatus capable of preventing leakage of condensed water at a portion where a latent heat heat exchanging unit and a sensible heat exchanging unit are connected.

It is another object of the present invention to provide a condensing-type combustion device capable of preventing leakage of exhaust gas passing through a latent heat heat exchanger.

In order to achieve the above object, a condensing type combustion apparatus of the present invention includes a burner 120, a sensible heat exchanging unit 130 for absorbing combustion heat generated in the burner 120, and a heat exchange unit 130 for heat exchange in the sensible heat exchanging unit 130 And a latent heat heat exchanger (140) for absorbing the latent heat of the steam contained in the exhaust gas after completion of the condensate heat exchanger (140). The condenser boiler includes a condensate receiver (160); A partition 151 of metallic material for flowing an upward flow of exhaust gas to one side of the latent heat heat exchanger 140 when a part of the upper region of the sensible heat exchanger 130 is intercepted and disposed below the condenser receiver 160, .

In this case, an exhaust gas communication part 153 for communicating the sensible heat exchanging part 130 and the latent heat heat exchanging part 140 is formed at one side of the diaphragm 151; A first blocking wall 154 extending upward from one end of the partition 151 is provided to partition between the space above the condensate receiver 160 and the exhaust gas communication part 153; A first packing 101 is provided at one end of the condenser receiver 160 to seal the space between the condenser receiver 160 and the first blocking wall 154 to prevent the condensed water from entering the upper surface of the partition plate 151 Lt; / RTI >

A connection frame 150 is coupled between the upper end of the edge of the sensible heat exchanging part 130 and the lower end of the edge of the latent heat heat exchanging part 140; The connection frame 150 includes a frame body 152 surrounding a space between the sensible heat exchanging part 130 and the latent heat heat exchanging part 140 and a frame body 152 surrounding a part of the inner lower part of the frame body 152 And the diaphragm 151; The exhaust gas communication part 153 may be an open area of an inner lower part of the frame body 152 and may include other areas except the area where the partition 151 is located.

The condensate receiver 160 includes a bottom portion 161 that is inclined and side portions 162a, 162b, and 162c that extend upward from the periphery of the bottom portion 161 and side portions 162a, 162b, And a condensed water discharge port (163) formed in a side body (162a) formed at an inclined lower end of the bottom portion (161) of the bottom portion (162c) for discharging the condensed water dropped to the bottom portion (161) The condenser receiver 160 may be installed to be accommodated in an upper space of the diaphragm 151 as an inner space of the frame body 152.

A connection frame 150 is coupled between the upper edge of the sensible heat exchanger 130 and the lower edge of the latent heat heat exchanger 140; The connection frame 150 includes a frame body 152 surrounding a space between the sensible heat exchanging unit 130 and the latent heat heat exchanging unit 140, (151); A second packing 102 may be interposed between the upper end of the frame body 152 and the lower end edge of the latent heat heat exchanging part 140.

The condensate receiver 160 includes a sloping bottom portion 161 and side bodies 162a and 162b extending upwardly from the periphery of the bottom portion 161; A concave packing insertion groove 164 is formed in the upper portion of the side bodies 162a and 162b; The second packing 102 includes a packing body 102a interposed between the upper end of the frame body 152 and the lower surface of the latent heat heat exchanging part 140 and a lower body 102a extending downward from the inner end of the packing body 102a And a packing inner body 102b inserted into the packing insertion groove 164.

At least one protrusion 165 protruding downward is formed on the bottom surface of the condensate receiver 160 and a lower end of the protrusion 165 is supported on the upper surface of the partition plate 151.

And a heat insulating material may be attached to the lower end of the protrusion 165.

The latent heat heat exchanger 140 includes first to third regions 143a, 143b, and 143c adjacent to each other in the horizontal direction; And an exhaust gas guide 170 covering an upper portion of the first region 143a and the second region 143b; The exhaust gas flowing into the first region 143a through the sensible heat exchanging portion 130 is guided downward by the exhaust gas guide 170 and passes through the second region 143b, Is guided upward in the second region 143b, passes through the third region 143c, and is discharged to the outside through the exhaust portion 180; The upper surface of the third packing 103 is brought into contact with the guide engaging portion 171 located at the third region 143c side as one end of the exhaust gas guide 170, The upper surface of the heat exchange pipe 141 of the latent heat heat exchanger 140 may be brought into contact with the lower surface of the second region 143b so that the exhaust gas from the second region 143b is prevented from leaking to the exhaust portion 180.

According to the present invention, since a condensed water receiver made of a synthetic resin is provided on a metal diaphragm, corrosion due to condensed water can be prevented without using an expensive stainless material.

In addition, by providing the first packing between the condensate receiver and the blocking wall, it is possible to prevent the condensed water from leaking to the diaphragm below the condensate receiver.

In addition, since the second packing is provided in the connection frame for connecting the sensible heat exchanging part and the latent heat heat exchanging part, the condensed water can be prevented from leaking to the outside, and the condensed water can be prevented from leaking to the diaphragm below the condensed water receiver.

Also, the third packing is provided between the exhaust gas guide covering the upper part of the latent heat heat exchanger and the exhaust part, so that the exhaust gas passing through the latent heat heat exchanger can be prevented from leaking to the exhaust port without passing through the latent heat heat exchanger.

Further, by forming protrusions on the bottom surface of the condensate receiver and forming an air layer between the partition and the diaphragm, high temperature heat can be prevented from being transferred to the condensate receiver.

1 is a cross-sectional view of a condensing-type combustion apparatus according to the present invention
2 is an exploded perspective view of a combustion apparatus of the condensing system according to the present invention.
3 is a cross-sectional view showing a part of a combustion apparatus of the condensing system according to the present invention

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

The condensing type combustion apparatus 1 of the present invention includes a burner 120, a sensible heat exchanging unit 130 that absorbs the heat of combustion generated in the burner 120, and a sensible heat exchanging unit 130 that is connected to the heat exchanged exhaust gas in the sensible heat exchanging unit 130 A condensate receiver 160 made of a synthetic resin material for receiving the condensed water dropped from the latent heat heat exchanger 140 and discharging the condensed water to the outside, And a diaphragm 151 disposed at a lower portion of the upper portion of the sensible heat exchanging portion 130 to block exhaust gas flowing upward from the upper portion of the sensible heat exchanging portion 130 to one side of the latent heat heat exchanging portion 140.

The condensing type combustion apparatus 1 includes both a boiler for heating and a water heater for supplying hot water.

A blower 110 for supplying a mixture of air and fuel gas to the burner 120 is provided at a lower portion of the burner 120.

A combustion chamber 125, which is a space where combustion is generated by the flame generated in the burner 120, is provided in the upper portion of the burner 120.

The sensible heat exchanging part 130 is installed in the upper part of the combustion chamber 125. The sensible heat exchanging unit 130 may include a plurality of heat exchange pipes 131 each having a circular or elliptical cross section. The heat exchange pipes 131 are installed horizontally from one side to the other side of FIG. 3, and a plurality of heat exchange pipes 131 are arranged side by side at a predetermined distance in the direction of the paper surface. A plurality of heat transfer fins 132 are coupled to the outer circumferential surface of the heat exchange pipe 131 at a constant interval to form a Fin-Tube system.

The upper part of the sensible heat exchanging part 130 is blocked by the diaphragm 151 and the exhaust gas communicating part 130 is provided at one side of the diaphragm 151 so as to allow the exhaust gas passing through the sensible heat exchanging part 130 to flow. 153 are formed. Due to the diaphragm 151, the flow path space above the sensible heat exchanging part 130 is narrowed toward the upward direction, so that the flow of the exhaust gas is biased to one side.

The latent heat heat exchanger (140) is installed on the upper part of the sensible heat exchanger (130). The latent heat heat exchanger 140 may include a plurality of heat exchange pipes 141 each having a circular or elliptical cross section. The heat exchange pipes 141 are installed horizontally from one side to the other side of FIG. 3, and a plurality of heat exchange pipes 141 are arranged side by side at a predetermined distance in the direction of the paper surface. A plurality of heat transfer fins 142a, 142b, and 142c are coupled to the outer circumferential surface of the heat exchange pipe 141 at a constant interval to form a fin-tube system.

The latent heat heat exchanging part 140 is divided into three areas 143a, 143b and 143c which are adjacent to each other in the horizontal direction by the first blocking wall 154 and the second blocking wall 144, respectively. The first region 143a is an area formed in the upper portion of the exhaust gas communication portion 153 and is a region provided with the first heat conductive fin 142a. The second region 143b is a region formed on the side of the first region 143a with the first blocking wall 154 interposed therebetween, and is a region provided with the second heat conductive fin 142b. The third region 143c is an area formed on the side of the second region 143b with the second blocking wall 144 therebetween, and is a region provided with the third heat conductive fin 142c. The second blocking wall 144 may be one of the heat conductive fins.

The first region 143a and the second region 143b are blocked by the exhaust gas guide 170 to block the upward flow of the exhaust gas and induce the downward flow.

A connection frame 150 is provided between the upper edge of the sensible heat exchanger 130 and the lower edge of the latent heat heat exchanger 140.

The connection frame 150 includes a frame body 152 surrounding the space between the sensible heat exchanging unit 130 and the latent heat heat exchanging unit 140 and a diaphragm 151 for blocking a part of the inside of the frame body 152 And a first blocking wall 154 extending upward from one end of the diaphragm 151.

The upper end of the frame body 152 has a rectangular cross section, and an upper end flange 155a is formed along the periphery of the frame body 152. A lower end flange 155b is formed at the lower end along the periphery of the lower end flange 155b have. The edge of the sensible heat exchanging part 130 is coupled to a lower portion of the lower flange 155b by a fastening member (not shown), and an edge of the latent heat exchanging part 140 is fastened to an upper part of the upper flange 155b, (Not shown). A through hole 156 is formed in the frame body 152 to which the inclined lower end of the diaphragm 151 is coupled so that the condensed water outlet 163 of the condensed water receiver 160 to be described later is inserted.

The diaphragm 151 is rectangular and is inclined to one side. The diaphragm 151 is integrally coupled to the inside of the frame body 152 with three other edges except for one side edge adjacent to the exhaust gas communication part 153.

The first blocking wall 154 extends upward from the inclined upper end of the partition 151 and the upper end of the first blocking wall 154 contacts the lower portion of the latent heat exchanging part 140. Accordingly, the first blocking wall 154 isolates the space between the exhaust gas communication portion 153 and the space through which the exhaust gas has passed through the second region 143b of the latent heat heat exchanger 140 from each other.

The first blocking wall 154 divides an inner region of the frame body 152 into two regions. That is, the exhaust gas communication unit 153 is divided into a region formed on the upper portion of the partition 151 and a region formed by the exhaust gas communication unit 153.

The condensate receiver 160 is seated in an area formed on the upper part of the partition 151, and is made of a synthetic resin material, so that corrosion due to condensed water does not occur.

The condensate receiver 160 is installed to be accommodated in an inner space of the frame body 152 which is the upper part of the partition plate 151.

The condensed water receiver 160 includes a bottom portion 161 inclined as a shape corresponding to the partition 151, side bodies 162a, 162b, and 162c extending upward from the periphery of the bottom portion 161, A condensed water discharge port 163 formed in a side body 162a formed at an inclined lower end of the bottom part 161 of the side bodies 162a, 162b and 162c for discharging condensed water dropped to the bottom part 161, . The condensed water generated in the latent heat heat exchanger (140) drops to the bottom (161) and is discharged through the condensed water outlet (163).

The upper surfaces of the side bodies 162a and 162b formed at the inclined bottom and both side portions of the side bodies 162a, 162b and 162c are provided with packing insertion grooves 164 Is formed.

The first packing 101 is coupled to the side body 162c extending upward from the inclined upper end of the bottom portion 161 of the side bodies 162a, 162b, 162c.

A groove 101a is formed in the bottom surface of the first packing 101 so as to be concave along the longitudinal direction of the first packing 101. An upper end of the side body 162c is inserted into the groove 101a of the first packing 101 . When the first packing 101 is coupled to the side body 162c, the side of the first blocking wall 154 and the first packing 101 are brought into close contact with each other. The condensed water generated in the latent heat heat exchanger 140 can be prevented from flowing into the upper surface of the diaphragm 151 through the gap between the side body 162c and the first blocking wall 154, Corrosion of the connection frame 150 can be prevented.

A plurality of projections 165 protruding downward are formed on the bottom surface of the bottom portion 161. The lower end of the protrusion 165 is supported on the upper surface of the partition plate 151. An air layer is formed between the bottom portion 161 and the diaphragm 151 so that the heat of the combustion chamber 125 can be minimally transferred to the condensate receiver 160 through the diaphragm 151. [

Further, a heat insulating material may be attached to the lower end of the protrusion 165. Accordingly, heat can be prevented from being transmitted to the condensate receiver 160 through the protrusion 165.

A second packing 102 is interposed between the upper end of the frame body 152 and the lower end edge of the latent heat heat exchanger 140.

The second packing 102 includes a packing body 102a having a rectangular band shape and a packing inner body 102b extending downward from an inner end of the packing body 102a.

The bottom surface of the packing body 102a contacts the upper surface of the upper flange 155a of the frame body 152 and the upper surface of the packing body 102a contacts the bottom surface of the latent heat exchanger 140. [ Due to such a configuration, it is possible to prevent the condensed water from leaking to the outside through the space between the connection frame 150 and the latent heat heat exchanging part 140.

The lower end of the packing inner body 102b is inserted into the packing insertion groove 164 of the side bodies 162a and 162b. The condensed water generated in the latent heat heat exchanger 140 is guided to the upper surface of the bottom portion 161 of the condensate receiver 160 by the packing inner body 102b and the condensed water generated by the side body 162a and the frame body 152 And is prevented from flowing into the gap. Therefore, the condensed water can be prevented from flowing into the upper surface of the diaphragm 151 through the gap between the side body 162a and the frame body 152, thereby preventing corrosion of the connection frame 150 including the diaphragm 151 .

An exhaust part 180 is provided on the exhaust gas guide 170. The exhaust unit 180 includes an exhaust cover 181 covering the upper portion of the exhaust gas guide 170 and the upper portion of the third region 143c and a valve cover 181 coupled to the exhaust cover 181 to exhaust the exhaust gas to the outside And an exhaust port 182 for exhausting the exhaust gas.

At one end of the exhaust gas guide 170, a downwardly protruding guide engaging portion 171 is formed. A third packing 103 is coupled to the guide engaging part 171 to prevent the exhaust gas from the second area 143b from leaking to the inner space of the exhaust part 180.

A groove 103a is formed on the upper surface of the third packing 103 along the longitudinal direction thereof and a guide engaging portion 171 is inserted into the groove 103a.

A plurality of pipe contact portions 103b are formed at the lower end of the third packing 103 to contact the outer circumferential surface of the heat exchange pipe 141. The pipe contacting portion 103b has a shape in which a part of a lower end portion of the third packing 103 is cut. The heat exchanging pipe 141 is inserted into the incised portion and the outer circumferential surface of the upper portion of the heat exchange pipe 141 and the body of the third packing 103 inside the pipe contacting portion 103b are closely contacted to prevent leakage of the exhaust gas .

The first packing 101, the second packing 102, and the third packing 103 described above can be applied to any material that can maintain airtightness such as rubber or silicone.

A path through which the exhaust gas flows in the condensing boiler constructed as above will be described.

The exhaust gas in the combustion chamber 125 produced by the burning of the burner 120 is upwardly flowed and the exhaust gas of the upward flow is guided by the partition plate 151 and the first blocking wall 154, And flows to the exhaust gas communication part 153 provided at one side of the first blocking wall 154.

The exhaust gas having passed through the exhaust gas communication portion 153 flows into the first region 143a. The exhaust gas in the first region 143a is heat-exchanged between the heat exchange pipe 141 of the latent heat heat exchanger 140 and the first heat conductive fin 142a.

The exhaust gas that has passed through the first region 143a is prevented from flowing upward by the exhaust gas guide 170 and the flow is induced laterally by the space above the first blocking wall 154, 143b. In this case, since the airtightness is maintained by the third packing 103 in the guide engaging portion 171 of the exhaust gas guide 170, the exhaust gas in the second region 143b is discharged directly to the outside of the third region 143c It is possible to prevent leakage to the base 180 side.

The exhaust gas in the second region 143b is flowed downward to perform heat exchange in the heat exchange pipe 141 and the second heat conductive fin 142b. The exhaust gas that has passed through the second region 143b is flowed laterally by the space below the second blocking wall 144 and flows into the third region 143c. The exhaust gas in the third region 143c is flowed upward and heat exchange is performed in the heat exchange pipe 141 and the third heat conductive fin 142c. In this case, the condensed water generated in the second area 143b and the third area 143c falls to the top of the condensate receiver 160. [ A part of the generated condensed water is prevented from being introduced into the upper part of the diaphragm 151 by the first packing 101 and a part of the other condensed water is leaked into the connection frame 150 by the second packing 102 Is prevented.

The exhaust gas having passed through the third region 143c is discharged to the outside through the inner space of the exhaust cover 181 and the exhaust port 182.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And this also belongs to the present invention.

101: first packing 102: second packing
102a: packing body 102b: packing inner body
110: blower 120: burner
125: combustion chamber 130: sensible heat exchanger
140: latent heat heat exchanger 131, 141: heat exchange pipe
132, 142a, 142b, 142c: heat conductive pins 143a:
143b: second region 143c: third region
150: connection frame 151: diaphragm
152: frame body 153: exhaust gas communication part
154: first blocking wall 155a: upper flange
155b: lower flange 156: through hole
160: condensate receiver 161: bottom part
162a, 162b, 162c: side body 163: condensate outlet
164: packing insertion groove 170: exhaust gas guide
180: exhaust part 181: exhaust part cover
182: Exhaust

Claims (9)

A latent heat exchanger 140 for absorbing the latent heat of the steam contained in the heat-exchanged exhaust gas in the sensible heat exchanger 130; The combustion apparatus of a condensing system according to claim 1,
A condensate receiver 160 made of a synthetic resin material for receiving the condensed water dropped from the latent heat heat exchanger 140 and discharging the condensed water to the outside;
A partition 151 of metallic material for flowing an upward flow of exhaust gas to one side of the latent heat heat exchanger 140 when a part of the upper region of the sensible heat exchanger 130 is intercepted and disposed below the condenser receiver 160, ;
Further comprising:
The condensate receiver 160 includes a bottom portion 161 that is inclined and side portions 162a, 162b, and 162c that extend upward from the periphery of the bottom portion 161 and side portions 162a, 162b, And a condensed water discharge port 163 formed in a side body 162a formed at an inclined lower end of the bottom portion 161 of the discharge port 162c for discharging the condensed water dropped to the bottom portion 161,
A connection frame 150 is coupled between the upper end of the edge of the sensible heat exchanging part 130 and the lower end of the edge of the latent heat heat exchanging part 140; The connection frame 150 includes a frame body 152 surrounding the space between the sensible heat exchanging part 130 and the latent heat heat exchanging part 140; Wherein the condenser receiver (160) is installed to be accommodated in an upper space of the partition plate (151) as an inner space of the frame body (152) The method according to claim 1,
An exhaust gas communication part 153 communicating between the sensible heat exchanging part 130 and the latent heat heat exchanging part 140 is formed at one side of the diaphragm 151;
A first blocking wall 154 extending upward from one end of the partition 151 is provided to partition between the space above the condensate receiver 160 and the exhaust gas communication part 153;
A first packing 101 is provided at one end of the condenser receiver 160 to seal the space between the condenser receiver 160 and the first blocking wall 154 to prevent the condensed water from entering the upper surface of the partition plate 151 And a condensing type combustion device A latent heat exchanger 140 for absorbing the latent heat of the steam contained in the heat-exchanged exhaust gas in the sensible heat exchanger 130; The combustion apparatus of a condensing system according to claim 1,
A condensate receiver 160 made of a synthetic resin material for receiving the condensed water dropped from the latent heat heat exchanger 140 and discharging the condensed water to the outside;
A partition 151 of metallic material for flowing an upward flow of exhaust gas to one side of the latent heat heat exchanger 140 when a part of the upper region of the sensible heat exchanger 130 is intercepted and disposed below the condenser receiver 160, ;
Further comprising:
The condensate receiver 160 includes a bottom portion 161 that is inclined and side portions 162a, 162b, and 162c that extend upward from the periphery of the bottom portion 161 and side portions 162a, 162b, And a condensed water discharge port 163 formed in a side body 162a formed at an inclined lower end of the bottom portion 161 of the discharge port 162c for discharging the condensed water dropped to the bottom portion 161,
A connection frame 150 is coupled between the upper end of the edge of the sensible heat exchanging part 130 and the lower end of the edge of the latent heat heat exchanging part 140;
The connection frame 150 includes a frame body 152 surrounding a space between the sensible heat exchanging part 130 and the latent heat heat exchanging part 140 and a frame body 152 surrounding a part of the inner lower part of the frame body 152 And the diaphragm 151;
An exhaust gas communication part 153 communicating between the sensible heat exchanging part 130 and the latent heat heat exchanging part 140 is formed at one side of the diaphragm 151;
Wherein the exhaust gas communication part (153) is an open area of an inner lower portion of the frame body (152), and the remaining area except the area where the diaphragm (151) is located is the combustion gas communicating part delete A latent heat exchanger 140 for absorbing the latent heat of the steam contained in the heat-exchanged exhaust gas in the sensible heat exchanger 130; The combustion apparatus of a condensing system according to claim 1,
A condensate receiver 160 made of a synthetic resin material for receiving the condensed water dropped from the latent heat heat exchanger 140 and discharging the condensed water to the outside;
A partition 151 of metallic material for flowing an upward flow of exhaust gas to one side of the latent heat heat exchanger 140 when a part of the upper region of the sensible heat exchanger 130 is intercepted and disposed below the condenser receiver 160, ;
Further comprising:
A connection frame 150 is coupled between the upper edge of the sensible heat exchanger 130 and the lower edge of the latent heat heat exchanger 140;
The connection frame 150 includes a frame body 152 surrounding a space between the sensible heat exchanging unit 130 and the latent heat heat exchanging unit 140, (151);
A second packing (102) is interposed between the upper end of the frame body (152) and the lower end edge of the latent heat heat exchanger (140);
The condensate receiver 160 includes a sloping bottom portion 161 and side bodies 162a and 162b extending upwardly from the periphery of the bottom portion 161;
A concave packing insertion groove 164 is formed in the upper portion of the side bodies 162a and 162b;
The second packing 102 includes a packing body 102a interposed between the upper end of the frame body 152 and the lower surface of the latent heat heat exchanging part 140 and a lower body 102a extending downward from the inner end of the packing body 102a And a packing inner body (102b) inserted into the packing insertion groove (164) A latent heat exchanger 140 for absorbing the latent heat of the steam contained in the heat-exchanged exhaust gas in the sensible heat exchanger 130; The combustion apparatus of a condensing system according to claim 1,
A condensate receiver 160 made of a synthetic resin material for receiving the condensed water dropped from the latent heat heat exchanger 140 and discharging the condensed water to the outside;
A partition 151 of metallic material for flowing an upward flow of exhaust gas to one side of the latent heat heat exchanger 140 when a part of the upper region of the sensible heat exchanger 130 is intercepted and disposed below the condenser receiver 160, ;
Further comprising:
The latent heat heat exchanger 140 includes a plurality of regions 143a, 143b, and 143c positioned adjacent to each other in the horizontal direction;
An exhaust gas guide (170) covering an upper portion of the plurality of regions (143a, 143b, 143c) is provided;
The upper surface of the third packing 103 is brought into contact with the guide engaging portion 171 located on the side of the region 143c communicating with the exhaust portion 180 through which the exhaust gas is discharged as one end of the exhaust gas guide 170 And the upper surface of the heat exchange pipe 141 of the latent heat heat exchanger 140 is brought into contact with the lower surface of the third packing 103 to form a second region 143b which is one of the plurality of regions 143a, Is prevented from leaking to the exhaust part (180). ≪ RTI ID = 0.0 > The method according to claim 1,
Wherein at least one protrusion 165 protruded downward is formed on the bottom surface of the condensate receiver 160 and the lower end of the protrusion 165 is supported on the upper surface of the partition plate 151. [ 8. The method of claim 7,
And a heat insulating material is attached to the lower end of the projection (165) The method according to claim 6,
The plurality of regions 143a, 143b, and 143c may include a first region 143a, a second region 143b, and a third region 143c;
The exhaust gas flowing into the first region 143a through the sensible heat exchanging portion 130 is guided downward by the exhaust gas guide 170 and passes through the second region 143b, Is introduced upward in the second region (143b), passes through the third region (143c), and is discharged to the outside through the exhaust portion (180)

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