KR101389465B1 - Latent heat exchanger for boiler increasing the heat efficiency - Google Patents

Abstract

The present invention relates to a latent heat exchanger for a boiler increasing heat efficiency that provides increased heat exchange chances through the lamination and fusion of multiple curved and perforated plates and the formation of a circulating fluid moving path in an internal space into a complex structure so that the maximum possible quantity of the latent heat contained in the exhaust gas of the boiler and disappearing into the atmosphere is recovered and heat exchange efficiency is maximized. An exhaust gas passage (140), where exhaust gas through-holes A and B (112, 122) of unit plate members (100U) adjacent according to the stacked order thereof are formed inside to cross each other, is configured as a complex passage, and the exhaust gas is subjected to mixing/separating processes while passing through the exhaust gas passage (140) formed into a zigzag pattern so that the heat of the exhaust gas itself is exchanged with that of water through a latent heat exchanger (100) for maximized heat efficiency.

Description

Latent Heat Exchanger for Boiler Increasing The Heat Efficiency

The present invention relates to a latent heat exchanger for a boiler, and more particularly, to stack and partially fuse a plurality of bent perforated plates to maximize the heat exchange efficiency by recovering the latent heat contained in the exhaust gas of the boiler and extinguished to the atmosphere. The present invention relates to a latent heat exchanger for a boiler having a high thermal efficiency to provide a more heat exchange opportunity by forming a moving passage of a circulating fluid formed in a complicated structure.

In general, domestic boilers, which are mainly used for heating and hot water supply, are classified into general boilers and condensing boilers according to the recovery method of combustion heat for heating the heating water.

The condensing boiler is composed of a sensible heat exchanger for directly exchanging heat by the combustion heat of the combustion unit, and a latent heat exchanger for recovering latent heat contained in exhaust gas discharged after combustion.

Exhaust gas, such as boilers, contains carbon dioxide (CO ₂ ) and water (H ₂ O) as the components generated by burning fossil fuels. Among them, water is vaporized at high temperature of the exhaust gas and is discharged as steam. When the temperature decreases, it condenses and changes the state from the gas state to the liquid state. At this time, it emits a lot of latent heat energy (energy released when water vapor changes state into water).

All the heat absorbed or released by a substance during the change of its state (solid <-> liquid <-> gas) is called latent heat, and the heat absorbed or released as its temperature rises or falls without changing its state is called sensible heat. do.

The latent heat of water contains a large amount of energy in the exhaust gas because 540 calories of heat are released as latent heat when 1 g of water vapor condenses and changes to 100 ° C. water.

The sensible heat exchanger receives the combustion heat of the burner directly and exchanges heat with the circulating fluid by conduction to supply heating water or use it as hot water.

On the other hand, the latent heat exchanger absorbs the energy contained in the exhaust gas discharged while passing through the sensible heat exchanger because the temperature of the exhaust gas is still high. After heating (preheating), the preheated water is supplied to the sensible heat exchanger to increase the thermal efficiency.

That is, the latent heat exchanger secondly absorbs the combustion heat of the burner and passes through the sensible heat exchanger that exchanges heat with the circulating fluid.

As a latent heat exchanger having such a function, Korean Patent Registration No. 10-1156249 (Invention name: Plate junction type heat exchanger) is a plate plate in which a circulating fluid moves inside to increase thermal efficiency by increasing the contact area with combustion gases. The heat exchanger of the structure which laminated | stacked many was disclosed.

Korean Patent Registration No. 10-1156249 is a sensible heat exchanger 10 is coupled to the combustion chamber cover 11 and the combustion chamber housing 13 and the plate plate 20 are laminated as shown in Figs. It is disclosed that the configured latent heat exchanger (30).

The sensible heat exchange unit 10, the burner unit 12 is mounted to the center of the body, the combustion chamber housing 13 and the combustion chamber cover 11 is hermetically coupled to the upper end of the space, the circulation fluid is accommodated therebetween The phosphorus storage unit 14 is formed, and the latent heat exchange unit 30 is positioned at the exhaust side of the sensible heat exchange unit 10.

The latent heat exchange unit 30 is formed by stacking a plurality of plate plates 20, and the plate plates 20 are integrally bonded to the body of the upper plate and the lower plate 22 to complete one plate plate 20. The body is formed to be symmetrical with each other to have a space through which the circulating fluid flows and a hole through which the combustion gas passes.

That is, the plate plate 20 has an outer connection passage 23 connected to the supply hole 15 at the outer portion of the body, the combustion gas moving hole 24 to which the combustion gas of the combustion chamber housing 13 is moved, The inner movement passage 25 and the combustion gas exhaust hole 26 in the center of the body connected to the outer connection passage 23 are sequentially formed.

Therefore, the latent heat exchange unit 30 is formed so that the outer connecting passage 23, the combustion gas moving hole 24, the combustion gas exhaust hole 26 is in communication with the upper portion.

At this time, the inner movement passage 25 of the plate plate 20 is formed along the combustion gas exhaust hole 26 in a spiral direction at the inner supply port 25a and connected to the outer drain port 25b. Both the supply port 25a and the drain port 25b of the plate plate 20 are configured to communicate with each other.

The latent heat exchange unit 30 configured as described above is welded so that the outer portions of the plate plates 20 to be stacked overlap each other, and the lower plate 22 stacked with the top plate 21 of the combustion gas moving hole 24 is formed. By bending to overlap each other to close the outer connecting passage 23, the circulating fluid can be moved upward.

Moreover, the space | interval holding protrusion 22a which protrudes to the outer surface of any one of the upper board 21 and the lower board 22 of the plate plate 20 is provided, and the combustion gas movement path 24a is formed, The combustion gas introduced into the gas movement hole 24 is moved along the combustion gas movement path 24a to the central combustion gas exhaust hole 26.

In addition, the upper blocking cap 40 is joined to the uppermost end of the latent heat exchange unit 30 to shield the combustion gas movement hole 24, thereby causing the combustion gas to move to the central combustion gas exhaust hole 26, and to block the upper portion of the latent heat exchanger 30. The combustion gas is discharged through the combustion gas exhaust pipe 41 provided at the center of the cap 40.

In addition, the plate plate 20 positioned at the lowermost end of the latent heat exchange unit 30 forms a partition wall between the internal movement passages 25 and a condensate discharge pipe communicating with the combustion gas exhaust hole 26 at the center thereof. 51) was formed.

The combustion gas of the burner part 12 is moved to the outside by being blocked by the partition wall and the lower blocking cap 50 of the latent heat exchanger 30, and then moved upward along the combustion gas moving hole 24.

However, this conventional technology has the advantage of forming a miniaturized heat exchanger by integrally forming the sensible heat exchanger and the latent heat exchanger, but the exhaust gas flow path of the latent heat exchanger is short, so that the heat exchange opportunity is reduced, so that sufficient thermal efficiency cannot be expected. have.

That is, as shown in the movement path of the exhaust gas, as shown in FIG. 2, the exhaust gas moves at once through the combustion gas movement holes 24 and is dispersed at a time in all the layers of the laminated plate plate 20. It is a structure like a parallel circuit which is collected and discharged back to the central combustion gas exhaust hole 26 through each plate.

Therefore, the path passing between each plate plate 20 is very short there was a problem that the heat exchange efficiency is lowered.

In addition, the upper plate 21 of the combustion gas moving hole 24 and the lower plate 22 to be stacked are bent to overlap each other to seal the outer connection passage 23, the manufacturing process is a very difficult operation, it is completely sealed If not, there is another problem caused by leaks.

In order to solve the above problems, the present invention stacks a plurality of plates, but separates the exhaust passage and the circulating water passage by welding two plate upper / lower joining surfaces of different forms on each layer to be integrated with each other. In addition, the path of the latent heat exchanger through which the exhaust gas moves is formed in a zigzag path to extend as much as possible, and the exhaust gas is repeatedly mixed / separated several times in the movement path to form a vortex in each part so that a complete heat exchange is achieved. It is an object of the present invention to provide a latent heat exchanger for a boiler having a high heat efficiency to provide a heat exchange opportunity.

In the present invention for achieving the above object and the combustion chamber of the boiler; A sensible heat exchanger installed adjacent to the combustion chamber and heating hot water by direct heat exchange with combustion heat; In the latent heat exchanger of the condensing boiler which is installed on the exhaust side of the sensible heat exchanger, the latent heat exchanger of the condensing boiler is installed on the exhaust side to absorb and heat the latent heat of the exhaust gas is exhausted, A housing provided; A unit plate member installed in the housing and stacked in plural so as to form an exhaust gas passage in a zigzag of multiple stages in order to increase the latent heat absorption rate of the exhaust gas; An inlet pipe provided at an upper side of the stacked unit plate member and supplying water to a latent heat exchanger; An outlet pipe provided at the other side of the stacked unit plate members and discharging water heated by a latent heat exchanger; It is provided on the lower side of the laminated unit plate member, characterized in that it comprises a condensate discharge member for discharging the condensate generated during the heat exchange process.

In the present invention, the unit plate member is bent upward with respect to the bottom edge and the upper bending plate having a top bonding surface; A downward bending plate formed in pairs corresponding to the upward bending plate and having a bottom bonding surface bent downward with respect to a bottom edge to be fused to the upper bonding surface; It is characterized in that it is formed between the upwardly bent plate and the downwardly bent plate and comprises a circulating water passage of a multi-stage structure in communication with each other.

In the present invention, the upwardly bent plate and the downwardly bent plate is formed in the same shape and size of the corner portion, respectively, the circumferential portion A, the circumference portion B and; A plurality of exhaust gas through holes A and exhaust gas through holes B respectively drilled at the same positions so that the holes coincide with each other; A circulation water passage A and a circulation water passage B are respectively provided to interconnect the circulation water passages formed in the multi-stage structure by the unit plate members to be stacked, and the lowermost upward bending plate is closed so that the circulation water passage A is sealed. Characterized in that configured.

In the present invention, the unit plate member is characterized in that the exhaust gas through-holes of the unit plate member adjacent to each other are arranged to be offset from each other in the stacking order.

In the present invention, the plurality of stacked unit plate members are installed at an oblique angle to one side.

In the present invention, a combustion chamber including a burner and a sensible heat exchanger which is installed adjacent to the combustion chamber and heats hot water by direct heat exchange by combustion heat; In a latent heat exchanger of a condensing boiler installed on the exhaust side of the boiler and absorbing and exchanging latent heat of the exhaust gas exhausted, the latent heat exchanger is provided between an inlet part through which the exhaust gas passing through the sensible heat exchanger is introduced and an exhaust part being exhausted. And a plurality of unit plate members having perforated exhaust gas through holes A and exhaust gas through holes B are stacked to form exhaust gas passages in multiple stages of zigzag to absorb latent heat of the exhaust gases. The circumferential part A, the circumferential part B is integrally welded.

The present invention as described above can obtain the following effects.

First: The exhaust gas movement path is a complicated structure, and the mixing / separation process is performed repeatedly each time each layer passes through the exhaust gas passage, so that the amount of heat contained in the exhaust gas is sufficiently transferred to the latent heat exchanger. Agitating effect can be obtained.

Secondly, by increasing the residence time of the exhaust gas in the boiler to ensure complete combustion, there is an effect to prevent air pollution.

Third: Solder problems such as leakage by completely welding the joints of the plate members of each layer of the plate plate to be united with each other. Also, it is possible to design by adjusting the degree of lamination of the plate or the area of the plate. There is an effect that can be provided.

Fourth: the inlet pipe and the outlet pipe can be easily changed and installed at the upper end or the lower end of the latent heat exchanger, thereby producing various types of heat exchangers.

Fifth: When the unit plate member is installed at an angle to one side, the condensed water can be easily treated to obtain higher thermal efficiency.

1 is an exploded perspective view of a conventional plate-bonded heat exchanger.
Figure 2 is a cross-sectional view of the operation state of a conventional plate-bonded heat exchanger.
Figure 3 is a schematic diagram showing the internal configuration of the boiler to which the embodiment of the present invention is applied.
4 is a perspective view of a heat exchanger according to an embodiment of the present invention.
5 is a cross-sectional view of FIG.
a) is a sectional view taken along the line AA 'of FIG.
b) is a sectional view taken along the line B-B 'of FIG.
6 is a cross-sectional view showing the structure of a unit plate member 100U of the embodiment of the present invention,
a) is a state in which the up bending plate and the down bending plate are fusion-bonded,
b) is a state of separating the up and down bending plate.
Figure 7 is a bottom perspective view of the separated state showing the structure of the unit plate member of the embodiment of the present invention,
a) is a state in which the up bending plate and the down bending plate are fusion-bonded,
b) is a cross-sectional view of a).
Figure 8 is a cross-sectional view showing an operating state of the heat exchanger embodiment of the present invention.

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

Figure 3 is a schematic configuration diagram showing an internal configuration of a boiler to which the embodiment of the present invention is applied, Figure 4 is a perspective view of a heat exchanger according to an embodiment of the present invention, Figure 5 is a cross-sectional view of Figure 4, a) is A-A of Figure 4 Is a cross-sectional view taken along a line 'B' in FIG. 4.

As shown in FIG. 3, the condensing boiler is installed adjacent to the combustion chamber 300 and the combustion chamber 300 provided inside the boiler 1, and a sensible heat exchanger 200 for heating hot water by direct heat exchange by combustion heat. Wow; It is provided on the exhaust side of a boiler, and is provided with the latent heat exchanger 100 which absorbs the latent heat of exhaust gas exhausted, and heat-exchanges.

The latent heat exchanger 100, which is a main part of the present invention, is installed between the inlet 410 through which the exhaust gas is introduced into the housing 400 and the exhaust unit 420 through which the latent heat is introduced, and to increase the latent heat absorption rate of the exhaust gas. A plurality of unit plate members (100U) are laminated so that directions are reversed for each layer so as to form the exhaust gas passage 140 by a multi-step zigzag.

That is, since the exhaust gas through holes 112 and 122 of the unit plate members 100U adjacent to each other are arranged to be offset from each other according to the stacking order of the plurality of unit plate members 100U, the exhaust gas passage 140 formed therein is complicated. Configured to be a path.

An inlet pipe 150 is provided at one side of the top end of the stacked unit plate member 100U, and an outlet pipe 160 is provided at the other side to supply water to be heated and to discharge water heated by latent heat. The water discharged to be introduced into the sensible heat exchanger 200 or to be used as hot water.

The position of the water inlet pipe 150 and the water outlet pipe 160 is also possible to change the position of each other, if necessary, the water inlet pipe 150 may be installed on the upper side and the water outlet pipe 160 may be installed on the lower side, on the contrary The outlet pipe 160 may be installed on the upper side, and the inlet pipe 150 may be installed on the lower side.

The circumferential portion A 113 and the circumferential portion B 123 of the stacked unit plate members 100U are fused and integrated as a whole to leak the exhaust gas and water flowing through the interior while moving through the spaces separated from each other. It should not be.

The lower side of the housing 400 is provided with a condensate discharge member 170 in the lower side of the laminated unit plate member 100U to collect and discharge the condensate generated during operation of the latent heat exchanger 100 of the present invention.

The condensate discharge member 170 includes a condensate hopper 171 for collecting and discharging condensate and a condensate discharge tube 180 for discharging condensate collected by the condensate hopper 171 to the outside.

The unit plate member 100U, which is the main part of the embodiment of the present invention, will be described in detail.

6 is a cross-sectional view showing the structure of the unit plate member of the embodiment of the present invention, a) is a state in which the up bending plate and the down bending plate is fusion-bonded, b) is a state in which the up bending plate and the down bending plate is separated, Figure 7 is a bottom perspective view of the separated state showing the structure of the unit plate member of the embodiment of the present invention, Figure 7a) is a state in which the up and down bending plate is fusion-bonded, Figure 7b) is a cross-sectional view of Figure 7a).

The unit plate member (100U) is bent upward with respect to the bottom edge and the upward bending plate 110 having an upper bonding surface 111; Paired to correspond to the upward bending plate 110, the downward bending plate 120 having a bottom bonding surface 121 is bent downward relative to the bottom edge and fused with the upper bonding surface 111 integrally. It is made by fusion.

That is, while the down bending plate 120 is installed on the up bending plate 110, the upper bonding surface 111 of the up bending plate 110 and the bottom bonding surface 121 of the down bending plate 120 mutually They are fused together by welding so as to be integrated.

Therefore, a circulation water passage 130 is formed between the upwardly bending plate 110 and the downwardly bending plate 120 by a space formed at a predetermined interval without being fused to each other.

In addition, the upward bending plate 110 and the downward bending plate 120 is fusion-sealed by the circumferential portion A 113 and the circumferential portion B 123, the corner portion is formed in the same shape and standard, respectively, the inner circulation passage Water flowing through the 130 is prevented from leaking to the outside.

The circumferential portion A 113 and the circumferential portion B 123 of the upwardly bending plate 110 and the downwardly bending plate 120 are formed in the same shape and size so that they are closely adhered to each other when overlapped with each other. It is to facilitate the integration between the parts by welding.

When the upward bending plate 110 and the downward bending plate 120 are bonded to each other, a plurality of exhaust gas through holes A formed at the same position in the center of the plurality of upper joining surfaces 111 and bottom bonding surfaces 121, respectively. (112) and B (122) abutted so that the holes coincided with each other so that the exhaust pipe passage was communicated.

In addition, the upward bending plate 110 and the downward bending plate 120 are provided with circulation water passages A 114 and B 124 on both sides, respectively, while the water circulation passages 130 of each layer pass through each other. This flow was made to exchange heat.

In particular, when the water inlet pipe 150 and the water outlet pipe 160 is installed in the upper portion to be sealed without the circulation water through hole A 114 of the up bending plate 110 is installed at the bottom of the water inlet pipe 150 and the water outlet pipe A smooth circulation passage 130 is formed between the 160.

In another embodiment, when the position of the water inlet pipe 150 or the water outlet pipe 160 is located at the lower end, the water circulation hole A 114 is drilled at the corresponding position, and thus the water inlet pipe 150 or the water outlet pipe 160 Weld)

At this time, the circulation water passage B 124 formed in the uppermost downward bending plate 120 is formed on only one side, and the water inlet pipe 150 or the water outlet pipe 160 is welded.

As another embodiment of the present invention, the housing 400 may be formed around the latent heat exchanger 100.

The latent heat exchanger 100 is installed between an inlet 410 through which the exhaust gas passing through the sensible heat exchanger 200 flows in and an exhaust part 420 exhausted from each other, so that the latent heat exchanger 100 can absorb latent heat of the exhaust gas. A plurality of unit plate members 100U having perforated exhaust gas through holes A 112 and B 122 are stacked to form the exhaust gas passage 140 with a zigzag of the stacked unit plate, and the periphery of the stacked unit plate members 100 U are stacked. By integrally welding the entire A 113 and B 123 portions, there is no problem in the formation of the pipeline even when the separate sealed housing 400 is removed, thereby enabling a simpler design.

In another embodiment of the present invention, it is also preferable that the plurality of stacked unit plate members 100U are installed obliquely to one side so that condensed water flows to one side.

It looks at the operating state of the embodiment of the present invention configured as described above.

As shown in FIG. 3, the flame of the burner of the combustion chamber 300 installed in the upper part is primarily subjected to heat exchange through the sensible heat exchanger 200 at the lower side, and after combustion, the exhaust gas moves to the latent heat exchanger 100 at the lower side. After the secondary heat exchange to be discharged through the exhaust pipe 190 to recover the latent heat contained in the exhaust gas.

8 is a cross-sectional view showing an operating state of a heat exchanger according to an embodiment of the present invention, and shows exhaust gas and water flowing through respective conduits while crossing each other at the boundary of each plate.

Exhaust gas passing through the sensible heat exchanger 200 is the unit plate member (100U) (downward bending plate 120 and upward bending plate 110) located on the uppermost side through the inner inlet 410 of the housing 400; A plurality of exhaust gas through holes A (112), B (122) are drilled in and flows through the internal exhaust gas passage (140) formed between the adjacent lower unit plate members (100U), and the lower unit. A plurality of exhaust gas through holes A 112 and B 122 drilled in the plate member 100U are introduced.

At this time, since the upper exhaust gas through holes A 112 and B 122 and the lower exhaust gas through holes A 112 and B 122 are positioned to be offset from each other, the exhaust gas passage 140 may be zigzag as shown in the drawing. It forms a complicated path.

Particularly, in the embodiment of the present invention, a plurality of exhaust gas through holes A 112 and B 122 are formed in each unit plate member 100U, and the exhaust gas passages 140 of each layer communicate with each other. Each time the gas passes through each layer, the mixing / separation process is continuously performed, and the gas is mixed evenly by the stirring effect to allow sufficient heat exchange with water flowing in each unit plate member 100U.

The exhaust gas is heat-exchanged through the latent heat exchanger 100 while passing through the mixing / separation process while passing through the exhaust gas passage 140 formed in a zigzag.

In particular, the water vapor contained in the exhaust gas is instantaneously cooled while contacting the latent heat exchanger to form condensed water. At this time, the latent heat energy contained in the water vapor is transferred to the water through the heat exchanger to heat the water.

As the latent heat of water, 540 cal / 1g, which is generated when water vapor is converted into water, is released as latent heat, it is possible to recover a large amount of latent heat energy contained in the exhaust gas.

At this time, condensed water is generated in the exhaust gas passage 140 of the heat exchanger to flow down, and the condensed water flowing down is collected by the condensed water hopper 171 to be discharged through the condensed water discharge pipe 180.

The low temperature direct water obtained through the inlet pipe 150 is first heated by the latent heat exchanger 100 to increase the temperature, and the heated water is discharged through the outlet pipe 160 to the sensible heat exchanger 200. By supplying, the efficiency of the sensible heat exchanger 200 to which the preheated water is supplied is also increased, so that the boiler has a high thermal efficiency as a whole.

1: boiler 100: latent heat exchanger
100U: unit plate member 110: upward bending plate
111: upper bonding surface 112: exhaust gas through hole A
113: circumference A 114: circulation water through hole A
120: downward bending plate 121: bottom surface
122: exhaust gas through hole B 123: circumference B
124: circulation water passage B 130: circulation water passage
140: exhaust gas passage 150: inlet pipe
160: outlet pipe 170: condensate discharge member
171: condensate hopper 180: condensate discharge pipe
190: exhaust pipe 200: sensible heat exchanger
300: combustion chamber (burner) 400: housing
410: inlet 420: outlet

Claims (7)

Adjacent to the combustion chamber 300 of the condensing boiler is installed on the exhaust side of the sensible heat exchanger 200 for heating the hot water by direct heat exchange with the combustion heat, in the latent heat exchanger 100 to absorb the latent heat of the exhaust gas to heat exchange In
The latent heat exchanger 100
A housing 400 having an inlet 410 through which exhaust gas is introduced and a discharge part 420 discharged;
A unit plate member (100U) installed in the housing (400) and stacked in plural to form an exhaust gas passage (140) with zigzag in multiple stages to increase the latent heat absorption rate of the exhaust gas;
An inlet pipe 150 provided on one side of the stacked unit plate member 100U and supplying water into the latent heat exchanger 100;
An outlet pipe 160 provided at the other side of the stacked unit plate members 100U and discharging water heated by the latent heat exchanger 100;
It is provided on the lower side of the stacked unit plate member (100U), and comprises a condensate discharge member 170 for discharging the condensate generated in the heat exchange process;
The unit plate member 100U
An upward bending plate 110 having an upper bonding surface 111 bent upward with respect to the bottom edge;
A downward bending plate 120 that is paired with the upward bending plate 110 and has a bottom bonding surface 121 that is bent downward with respect to a bottom edge and fused with the upper bonding surface 111;
A latent heat exchanger for a heat efficiency having a heat efficiency, characterized in that it comprises a circulating water passage 130 of the multi-stage structure formed between the up bending plate 110 and the down bending plate 120 and communicate with each other. delete The method of claim 1,
The upward bending plate 110 and the downward bending plate 120
Each of the corner portions is formed in the same shape and standard, and overlapped with each other by the circumferential portion A 113 and the circumferential portion B 123;
A plurality of exhaust gas through holes A 112 and exhaust gas through holes B 122 respectively drilled at the same positions so that the holes coincide with each other;
Each of the circulation unit passages 130 formed in the multi-stage structure by the stacked unit plate members 100U are provided with a circulation water passage A 114 and a circulation water passage B 124, respectively. Upward bending plate 110 is a latent heat exchanger for the thermal efficiency of the boiler, characterized in that the circulation water passage hole (114) is configured to be sealed.
The method of claim 1,
The unit plate member 100U
The latent heat exchanger of the boiler with high heat efficiency, characterized in that the exhaust gas through holes (112, 122) of the unit plate member (100U) adjacent to each other in a stacking order are arranged to be offset from each other.
The method of claim 1,
The plurality of stacked unit plate members (100U) is a latent heat exchanger for the heat efficiency of the boiler, characterized in that installed inclined obliquely to one side.
Adjacent to the combustion chamber 300 of the condensing boiler is installed on the exhaust side of the sensible heat exchanger 200 for heating hot water by direct heat exchange with combustion heat, in the latent heat exchanger 100 to absorb the latent heat of the exhaust gas to be exchanged In
The latent heat exchanger 100
It is installed between the inlet part 410 through which the exhaust gas passing through the sensible heat exchanger 200 flows in and the exhaust part 420 exhausted from each other, and has a multi-stage zigzag exhaust gas passage to absorb latent heat of the exhaust gas. A plurality of unit plate members 100U having bored exhaust gas through holes A 112 and exhaust gas through holes B 122 are stacked to form 140, and the circumferential portions A 113 of the stacked unit plate members 100 U are stacked. ), The latent heat exchanger for a boiler with improved thermal efficiency, characterized in that the portion B (123) is integrally welded.
The method according to claim 6,
The plurality of stacked unit plate members (100U) is a latent heat exchanger for the heat efficiency of the boiler, characterized in that installed inclined obliquely to one side.

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