JP2011252661A - Heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat exchanger which can properly drain a heat absorbing tube with a simple constitution without interfering with miniaturization even when the heat absorbing tube is thinned.SOLUTION: In the heat exchanger 5 in which the heat absorbing tube 51 is disposed in a case 50 applied as a pathway of combustion exhaust, both pipe ends 511, 512 of the heat absorbing tube 51 are positioned with prescribed height difference, both pipe ends 511, 512 are respectively connected with two headers 54, 55 disposed on a side plate 52 of the case 50, and the water distributed into the heat absorbing tube 51 through one of the headers 54 from external piping 63 is heated by heat exchange with the combustion exhaust, a lower end of a pipe end opening 51A at a low position side of the heat absorbing tube 51 is set above a lower end of an opening 54A for connecting the external piping, of the header 54.

Description

  The present invention relates to a heat exchanger that heats and heats water flowing into a heat absorption pipe via an inflow header and an outflow header by combustion exhaust.

  A latent heat recovery type heat exchanger mounted on a high thermal efficiency water heater has a plurality of heat absorption pipes arranged in a case serving as a passage for combustion exhaust, and both pipe ends of the heat absorption pipes are arranged with a predetermined height difference. The pipe ends of these endothermic tubes are separately connected to two headers provided on the side plate of the case, and water is sent from the external piping to each endothermic tube through this one header to condense the water vapor in the combustion exhaust, It is comprised so that the hot water which collect | recovered the latent heat may be taken out from the header of (for example, refer patent document 1).

  In such a heat exchanger, in order to achieve further miniaturization and higher thermal efficiency, the heat absorption tube is made thinner. That is, by reducing the size of the heat absorption tube, more heat absorption tubes are arranged in the limited space of the case, and the heat transfer area of the entire heat absorption tube is widened.

  However, as a result of reducing the size of the endothermic tube, when draining water from the endothermic tube to prevent freezing in the endothermic tube in winter, a water film is stretched on the end of the endothermic tube due to the surface tension of the water. There was a problem that water remained in the downstream portion in the flowing water direction in the heat absorption pipe. Therefore, when the endothermic tube is made thin, it is desirable that the endothermic tube be drained smoothly.

  By the way, as a conventional heat exchanger, an extended tube that bends downward from the side of the case is connected to one end of the heat absorption tube, and a header is provided at the lower end of the extended tube, and the heat absorption tube is passed through this header. (For example, refer to Patent Document 2).

  As shown in FIG. 10, the heat exchanger 9 has both pipe ends of a plurality of heat absorption tubes 91 accommodated in the case 90 inserted into the side plates 92 of the case 90, and the heat absorption tubes 91 exposed to the side plates 92 are exposed. In this configuration, an extended pipe body 93 that bends downward is connected to one pipe end, and a header 94 is attached to the lower end of the extended pipe body 93.

  According to this, even when the endothermic tube 91 is narrowed, the formation of a water film at the distal end portion of the extended tube 93 is prevented by the water head pressure in the extended tube 93. It is assumed that the heat absorption pipe 91 is drained.

  However, in this case, since the extended pipe 93 and the header 94 are provided in a state of projecting from the case 90, downsizing of the heat exchanger 9 is hindered. Moreover, since it is necessary to provide the extended pipe 93 for each of the plurality of heat absorbing pipes 91, there is a problem that the number of parts increases and the number of assembly steps increases.

JP 2007-163096 A

JP 2007-333343 A

  The present invention has been made in view of the above circumstances, and even when the endothermic tube is made thin, heat exchange in which the endothermic tube is appropriately drained with a simple configuration without hindering downsizing. It is an object to provide a vessel.

The heat exchanger according to the present invention is
An endothermic tube is arranged in the case serving as a passage for combustion exhaust, both pipe ends of the endothermic tube are arranged with a predetermined height difference, and both the pipe ends are connected to two headers provided on the side plate of the case. In the heat exchanger that heats and heats the water sent from the external piping to the heat absorption pipe through one header into the heat absorption pipe,
The lower end of the pipe end opening on the lower position side of the heat absorption pipe is set above the lower end of the opening for connecting the external pipe of the header.

  According to the above configuration, when the heat absorption pipe is drained, even if a water film is held in the pipe end opening due to the surface tension of the water, the water that has reached the pipe end opening is separated from the lower end of the pipe end opening. Due to the difference in height from the lower end of the opening for connecting the external pipe of the header, the pipe is smoothly discharged from the opening of the pipe end. Therefore, even when the diameter of the endothermic tube is reduced, the water does not remain in the downstream portion of the endothermic tube in the direction of water flow, and the endothermic tube is surely drained.

In the above heat exchanger,
A plurality of the endothermic tubes are stacked one above the other in a front-down state, and arranged such that the pipe end openings on the low position side are arranged in a staggered manner,
The pipe end opening on the lower position side of the heat sink tube at the lowest position may be arranged behind the pipe end opening on the lower position side of the heat absorption pipe in the second stage from the bottom.

  The size of the header is set according to the arrangement configuration of each pipe end opening of the endothermic pipe and the opening for connecting the external pipe of the header. According to the above configuration, the lower end of the endothermic pipe is located on the lower position side. By arranging the pipe end opening behind the pipe end opening on the lower position of the heat sink tube, which is the second stage from the bottom, the pipe end of the heat sink tube at the lowest position can be obtained without setting the header unnecessarily large. The lower end of the opening can be set above the lower end of the opening for connecting an external pipe of the header. Therefore, the heat absorption pipe is surely drained without impairing the downsizing and high thermal efficiency of the heat exchanger.

  In the header connected to the pipe end opening on the lower position side of the heat absorption pipe, a water draining plate for forming a water draining passage reaching the pipe end opening is arranged opposite to the pipe end opening. It is desirable that

  In this case, when the heat absorption pipe is drained, even if a water film is held at the pipe end opening due to the surface tension of the water, the water that has reached the pipe end opening is the water formed by the drain plate. It is discharged from the pipe end opening along the extraction channel. Therefore, even when the diameter of the endothermic tube is reduced, the water does not remain in the downstream portion of the endothermic tube in the direction of water flow, and the endothermic tube is surely drained. Moreover, since it is the simple structure which provided the water draining board in the header, size reduction of a heat exchanger is not inhibited.

The drainage channel is constituted by a concave groove formed in the drainage plate extending in the vertical direction,
The concave groove preferably has a groove width narrower than the diameter of the pipe end opening and communicates with the pipe end opening.

  In this case, even when a water film due to the surface tension of water is formed at the pipe end opening when draining the heat absorption pipe, the water reaching the pipe end opening travels through the concave groove as the water drainage channel. Discharged from the pipe end opening. Therefore, even when the diameter of the endothermic tube is reduced, the water does not remain in the downstream portion of the endothermic tube in the direction of water flow, and the endothermic tube is surely drained.

Further, the drainage channel is constituted by a gap between the pipe end opening and the drainage plate,
The gap may be set to be equal to or less than the amount of swelling of the water film formed at the pipe end opening due to the surface tension of water.

  In this case, even if a water film due to the surface tension of water is formed at the pipe end opening when draining the heat absorption pipe, the water reaching the pipe end opening travels through the gap as the water drainage channel. It is discharged from the pipe end opening. Therefore, even when the diameter of the endothermic tube is reduced, the water does not remain in the downstream portion of the endothermic tube in the direction of water flow, and the endothermic tube is surely drained.

  It is desirable that the water drain plate is composed of a water permeable member.

  In this case, since water can smoothly pass through the drain plate, it does not hinder the water flow to the heat exchanger even when a normal hot water discharge operation is performed.

  As described above, according to the present invention, even if the endothermic tube is narrowed, the endothermic tube is surely drained. Water remains, and it does not cause problems such as freezing and damaging the heat sink. Thereby, while further miniaturization and high thermal efficiency of a heat exchanger are implement | achieved, the heat exchanger which can drain the heat absorption pipe | tube appropriately with a simple structure can be provided.

The schematic block diagram of the water heater incorporating the heat exchanger which concerns on embodiment of this invention. The cross-sectional view of the heat exchanger which concerns on embodiment of this invention. The figure which shows the inflow header periphery of the heat exchanger which concerns on embodiment of this invention. The exploded view around the inflow header of the heat exchanger which concerns on embodiment of this invention. The cross-sectional view around the inflow header of the heat exchanger according to the embodiment of the present invention. The longitudinal cross-sectional view of the inflow header periphery of the heat exchanger which concerns on embodiment of this invention. The figure which shows the front (A), right side (B), and bottom face (C) of the drain plate of the heat exchanger which concerns on embodiment of this invention. The cross-sectional view around the inflow header of the heat exchanger according to another embodiment of the present invention. The longitudinal cross-sectional view of the inflow header periphery of the heat exchanger which concerns on other embodiment of this invention. Explanatory drawing of the conventional heat exchanger.

  Next, embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic vertical cross-sectional view of a latent heat recovery type water heater 1 provided with a sub heat exchanger 5 according to an embodiment of the present invention. Supply fan 2 for sending combustion air to the gas, gas burner 3, main heat exchanger 4 for recovering sensible heat in the combustion exhaust of the gas burner 3, and auxiliary heat exchanger 5 for recovering latent heat in the combustion exhaust. And are incorporated.

  The gas burner 3 is accommodated in a rectangular box-shaped combustion casing 30 whose upper end is open, and an air supply fan 2 is connected to the bottom of the combustion casing 30. Further, the upper end of the combustion housing 30 is connected to the lower end of a trunk portion 40 described later of the main heat exchanger 4.

  The main heat exchanger 4 accommodates a plurality of heat-absorbing fins (not shown) and a heat-absorbing tube 41 penetrating through the heat-absorbing fins in a rectangular tubular body 40 that is open at the top and bottom. Is connected to the bottom of the auxiliary heat exchanger 5. Further, one end of the heat absorption pipe 41 of the main heat exchanger 4 is connected to a hot water supply destination P such as a currant or a shower via a hot water outlet pipe 61, and the other end is connected to the sub heat exchanger 5 via a connection pipe 62. Yes.

  The auxiliary heat exchanger 5 includes a plurality of (here, eight) heat absorption tubes 51 accommodated in a rectangular box-shaped case 50. A transverse passage 500 extending in the front-rear direction is formed in the case 50, and the heat absorption pipe 51 is incorporated in the transverse passage 500. In addition, an exhaust introduction port 501 that connects the lateral passage 500 and the internal space of the body portion 40 is formed at the rear bottom portion of the case 50, and a space outside the lateral passage 500 and the exterior case 10 is formed above the case 50. The exhaust port 502 is established.

  Therefore, when the hot water supply destination P is opened and the combustion of the gas burner 3 is started, the combustion exhaust of the gas burner 3 passes through the trunk portion 40 of the main heat exchanger 4 and then passes through the side passage from the exhaust inlet 501. 500, and is discharged from the exhaust port 502 to the outside of the exterior case 10 through the gap between the heat absorption tubes 51. On the other hand, the water supplied from the water supply to the auxiliary heat exchanger 5 through the water supply pipe 63 described later is heat-exchanged and heated by the latent heat in the combustion exhaust when passing through each heat absorption pipe 51, and then passes through the connection pipe 62. Guided to the main heat exchanger 4. The water guided to the main heat exchanger 4 is heat-exchanged by sensible heat in the combustion exhaust when passing through the heat absorption pipe 41 and supplied to the hot water supply destination P through the hot water supply pipe 61.

  As shown in FIG. 2, the endothermic tube 51 is a single corrugated pipe formed of a highly corrosion-resistant metal such as stainless steel or titanium, and is bent in a plurality of locations to make it meander in a plane. The inlet side pipe end 511 and the outlet side pipe end 512 are respectively inserted and fixed in two recesses 520 formed in one side plate 52 of the case 50.

  The recess 520 on the inlet side pipe end 511 side is provided with an inflow header 54 that collectively connects the inlet side pipe ends 511 to the water supply pipe 63, and the recess 520 on the outlet side pipe end 512 side includes The outflow header 55 is provided to connect the outlet side pipe ends 512 to the connecting pipe 62 at a time.

  As shown in FIG. 1, the inflow header 54 is disposed at a lower position than the outflow header 55, and accordingly, the heat absorption pipe 51 also has an inlet side pipe end 511 at a lower position than the outlet side pipe end 512. In such a manner, it is arranged in a state of being lowered forward by a predetermined angle (for example, 5 degrees).

  Each endothermic tube 51 is incorporated in the horizontal passage 500 so as to overlap each other so that the pipe cross sections are arranged in a staggered manner when viewed in the longitudinal section, and the endothermic tube at the lowest position among them is arranged. 51 is arrange | positioned behind the heat absorption pipe | tube 51 in the 2nd step | paragraph from the bottom.

  As shown in FIG. 3, the recess 520 is formed in a vertically long rectangular shape and is disposed in a state inclined at a predetermined angle (for example, 5 degrees) toward the front side of the case 50. The inlet side pipe ends 511 of the endothermic tubes 51 are arranged in two rows and zigzag along the longitudinal direction of the recesses 520, and the inlet side pipe ends 511 of the endothermic end tubes 51 at the bottom are the lower ends. From the inlet pipe end 511 of the heat absorption pipe 51 in the second stage from the rear.

  Each opening 51 </ b> A (hereinafter referred to as “pipe end opening”) 51 </ b> A of the inlet side pipe end 511 is covered by the header body 541 of the inflow header 54 from the outside of the case 50. A joint portion 542 for connecting the water supply pipe 63 is provided at a lower portion of the outer surface of the header body 541. Each pipe end opening 51A is connected to the joint portion 542 via a closed space 540 described later in the inflow header 54. It is connected to an opening 54A (hereinafter referred to as “connection port”).

  Therefore, when the hot water supply operation to the hot water supply destination P is started, the water supplied from the water supply to the water supply pipe 63 is guided from the connection port 54A to the pipe end openings 51A through the closed space 540 described later, in parallel. Then, it is sent to the heat absorption pipe 51. On the other hand, when the water draining operation is performed, the water in the heat absorption pipe 51 is discharged from each pipe end opening 51A through the closed space 540 described later to the connection port 54A.

  As described in the background art, in the auxiliary heat exchanger 5 as well, the heat absorption pipe 51 is made thinner in order to realize further downsizing and higher thermal efficiency. Specifically, eight endothermic pipes 51 having a diameter of each pipe end opening 51A of 10 mm are overlapped as described above and accommodated in the lateral space 500. Thereby, many water passages can be arrange | positioned in the limited space, and a wide heat-transfer area is ensured.

  However, when the endothermic tube 51 is thinned, when water is drained from the endothermic tube 51, a water film is formed in the pipe end opening 51A due to the surface tension of the water, and water remains in the downstream portion of the endothermic tube 51. there's a possibility that.

  Therefore, in the sub heat exchanger 5, each endothermic pipe 51 is arranged so that the inlet side pipe end 511 of the lowest endothermic pipe 51 is behind the inlet side pipe end 511 of the second endothermic pipe 51. Were arranged one above the other. Thereby, since the lower end of the pipe end opening 51A at the lowest position is arranged above the lower end of the connection port 54A, the water in the heat absorption pipe 51 is separated from the lower end of the pipe end opening 51A and the lower end of the connection port 54A. It is smoothly discharged from the pipe end opening 51A due to the height difference.

  As shown in FIGS. 4 to 6, the header main body 541 of the inflow header 54 is formed in a shallow vessel shape having a peripheral wall 543 around the entire inner surface where the joint portion 542 is not disposed. The entire recess 520 is covered from the outside. The peripheral wall 543 is fixed in close contact with the entire inner periphery of the recess 520 and defines a closed space 540 between the header body 541 and the recess 520.

  As shown in FIG. 4, the joint portion 552 of the outflow header 55 that connects the connection pipe 62 is provided on the outer surface upper portion of the header body 551, and is set at a position higher than the joint portion 542 of the inflow header 54. ing.

  As shown in FIGS. 5 to 7, the closed space 540 accommodates a drain plate 56 made of punching metal. As shown in FIGS. 5 and 6, the water drain plate 56 is provided to face each pipe end opening 51 </ b> A of the heat absorption pipe 51, and when draining the heat absorption pipe 51, each pipe end opening is provided. A drain passage for water reaching 51A is formed. Specifically, two concave grooves 561 extending in the vertical direction are formed on the surface of the drainage plate 56 facing the pipe end openings 51A, and the concave grooves 561 are arranged in two rows. It faces the end opening 51A continuously.

  The recessed groove 561 is formed to have a narrower width than the diameter of the pipe end opening 51A (for example, the diameter of the pipe end opening 51A is 10 mm and the groove width of the recessed groove 561 is approximately 1 mm), while the water draining plate 56 is formed. A large number of punch holes 56A provided in are formed in a smaller diameter than the pipe end opening 51A.

  The drain plate 56 is provided with a rib crest 562 that forms a concave groove 561, which contributes to securing the strength of the drain plate 56. Further, bent portions 563 that bend at an obtuse angle toward the rib crest 562 are provided on both side ends of the drainage plate 56. Further, the outer shape of the drainage plate 56 is formed in a size substantially along the inner periphery of the recess 520.

  The rib crest 562 is formed at a height at which the top portion 56 </ b> T abuts on the inner side of the header main body 541. Further, the bent portion 563 is formed so that the tip thereof is in contact with the upper end of the peripheral wall 543 of the header main body 541, and the surface on the opening side of the concave groove 561 of the drain plate 56 is formed on the periphery of the pipe end opening 51A. It is held in contact.

  Then, when draining the heat absorption pipe 51 of the auxiliary heat exchanger 5, when the drain plugs (not shown) provided in the water supply pipe 63 and the hot water discharge pipe 61 are opened, first, the inlet side and the outlet side of the heat absorption pipe 51 Accordingly, the water in the heat absorption pipe 51 is guided to the pipe end opening 51A side on the inlet side, and is smoothly discharged to the connection port 54A side through the plurality of punch holes 56A formed in the drain plate 56. The

  Thereafter, when the water in the endothermic pipe 51 is discharged to the downstream portion in the flowing direction, the water head pressure due to the height difference is reduced, so that a water film is formed in the pipe end opening 51A due to the surface tension of the water. In this embodiment, the water that has reached the pipe end opening 51 </ b> A enters the concave groove 561 of the water draining plate 56 and further flows down along the concave groove 561 in this embodiment. . This drainage principle is considered as follows.

  The water that has reached the pipe end opening 51A penetrates into the concave groove 561 by capillarity in the concave groove 561, and the water that has penetrated into the concave groove 561 combines its own weight with the capillary phenomenon in the concave groove 561. It is thought that it flows down along the concave groove 561. And since the water which reached the pipe end opening 51A in this way is made to flow sequentially through the concave groove 561, even if the water head pressure due to the above-mentioned height difference is reduced, the water in the heat absorption pipe 51 remains at the pipe end. The water is not discharged to the connection port 54A side without forming a water film at the opening 51A. Therefore, even if the diameter of the endothermic tube 51 is reduced by reducing the diameter, water does not remain in the downstream portion of the endothermic tube 51 in the flowing water direction, so that the endothermic tube 51 is reliably drained.

  As described above, according to the auxiliary heat exchanger 5 according to the above embodiment, even when the heat absorption tube 51 is made thin, the heat absorption tube 51 can be surely drained. In spite of having performed, water remains in the endothermic tube 51, and it does not cause troubles such as freezing and damaging the endothermic tube 51. As a result, the sub heat exchanger 5 can be further reduced in size and increased in thermal efficiency, and the lower end of the pipe end opening 51A is set above the lower end of the connection port 54A, or the pipe end opening in the inflow header 54 is set. It is possible to provide the auxiliary heat exchanger 5 capable of appropriately draining the heat absorption pipe 51 with a relatively simple configuration such as disposing the water draining plate 56 in 51A.

  In addition, the inlet-side pipe end 511 of the heat-absorbing pipe 51 at the lowest position is arranged behind the inlet-side pipe end 511 of the heat-absorbing pipe 51 in the second stage from the bottom, so that the inflow header 54 is set to be unnecessarily large. Even if not, the lower end of the lowermost pipe end opening 51A can be set higher than the lower end of the connection port 54A, so that the heat absorption pipe 51 can be surely drained without impairing downsizing and high thermal efficiency. A possible secondary heat exchanger 5 can be provided.

  Furthermore, since the water draining plate 56 is made of a punching metal, the water guided to the inlet side pipe end 511 side of the heat absorption pipe 51 can smoothly pass through the water draining plate 56. In this case, the flow of water to the auxiliary heat exchanger 5 is not hindered.

[Others]
As long as the sub heat exchanger 5 is not reduced in size or increased in thermal efficiency, the lowest endothermic pipe as long as the lower end of the lowermost pipe end opening 51A is set above the lower end of the connection port 54A. 51 may be disposed in front of the heat absorption pipe 51 in the second stage from the bottom.

  Moreover, in the said embodiment, although the draining board 56 was comprised with the punching metal, if it is a thing of the structure which does not become the hindrance of the water flow to the sub heat exchanger 5, it will not restrict to this, an expanded metal, a net | network, You may employ | adopt various water-permeable members, such as a mesh and a filter. Moreover, although the metal material is used suitably for the drain plate 56, you may use materials, such as a plastic and a ceramic.

  In the above-described embodiment, the configuration in which the opening-side surface of the groove 561 provided in the drain plate 56 is held in contact with the peripheral edge of the pipe end opening 51A has been described. As shown in FIG. 9, a gap 57S having a predetermined width may be provided between the drain plate 57 and the peripheral edge of the pipe end opening 51A.

  The gap 57S is set to be equal to or less than the rising amount of the water film formed in the pipe end opening 51A due to the surface tension of water (for example, the diameter of the pipe end opening 51A is 10 mm and the gap 57S is approximately 1 mm). The gap 57S forms a water drainage channel that reaches each pipe end opening 51A.

  A rib crest 572 extending in the vertical direction is formed at one central portion in the width direction of the drain plate 57, which contributes to securing the strength of the drain plate 57. Further, bent portions 573 that are bent at an obtuse angle toward the rib crest 572 side are provided at both ends of the drainage plate 57. Furthermore, the outer shape of the drain plate 57 is formed to have a size substantially along the inner periphery of the recess 520.

  The rib crest 572 is formed at a height at which the top 57T abuts on the inner side of the header body 541. Further, the bent portion 573 is formed so that the tip thereof is in contact with the upper end of the peripheral wall 543 of the header main body 541, and the gap 57S described above is provided between the drain plate 57 and the pipe end opening 51A. Is retained.

  Then, when draining water (not shown) provided in the water supply pipe 63 and the hot water discharge pipe 61 during the water draining operation in the heat absorption pipe 51 of the auxiliary heat exchanger 5, first, as in the above-described embodiment, the heat absorption pipe 51 is opened. The water inside is smoothly discharged through the plurality of punch holes 57A formed in the drain plate 57 to the connection port 54A side.

  Thereafter, when the water in the endothermic pipe 51 is discharged to the downstream portion in the flowing direction, the water that has reached the pipe end opening 51A has a gap 57S between the drain plate 57 and the pipe end opening 51A before becoming a water film. And flow down along the drainage plate 57. That is, the water that has reached the pipe end opening 51 </ b> A swells outward at the pipe end opening 51 </ b> A and contacts the drain plate 57. Then, it is induced to the gap 57S by the capillary phenomenon in the gap 57S, and it is considered that the self-weight and the capillary phenomenon in the gap 57S combine to flow down along the drain plate 57.

  Thus, the water that has reached the pipe end opening 51A is sequentially flowed through the drain plate 57, so that even if the water head pressure due to the height difference of the heat absorption pipe 51 is reduced, the water in the heat absorption pipe 51 is Before the water film is formed in the pipe end opening 51A, it does not remain and is discharged to the connection port 54A side. Thereby, the effect similar to embodiment mentioned above is exhibited.

  The present invention is not limited to the above embodiment, and various modifications can be made within the scope of the present invention, for example, a spiral or spiral shape is adopted for the heat absorption tube 51. . Moreover, the heat exchanger mentioned above may be used not only for a water heater but for various heat exchange devices.

DESCRIPTION OF SYMBOLS 1 ... Hot water heater 2 ... Air supply fan 3 ... Gas burner 4 ... Main heat exchanger 5 ... Sub heat exchanger 50 ... Case 51 ... Endothermic pipe 511 ... Inlet Side pipe end 512 ... Outlet side pipe end 51A ... Pipe end opening (low end pipe end opening)
52... Side plate 520... Recess 54. Inflow header (header disposed on the low position side)
54A ... Connection port (opening for external piping connection)
55 ... Outflow header 56 ... Drain plate 561 ... Groove 562 ... Rib crest 563 ... Bending part 56A ... Punch hole 61 ... Hot water pipe 62 ... Connection pipe 63 ... Water supply pipe

Claims (6)

An endothermic tube is arranged in the case serving as a passage for combustion exhaust, both pipe ends of the endothermic tube are arranged with a predetermined height difference, and both the pipe ends are connected to two headers provided on the side plate of the case. In the heat exchanger that heats and heats the water sent from the external piping to the heat absorption pipe through one header into the heat absorption pipe,
A heat exchanger in which the lower end of the pipe end opening on the lower position side of the heat absorption pipe is set above the lower end of the opening for connecting an external pipe of the header. The heat exchanger according to claim 1,
A plurality of the endothermic tubes are stacked one above the other in a front-down state, and arranged such that the pipe end openings on the low position side are arranged in a staggered manner,
The heat exchanger which arrange | positioned the pipe end opening of the low position side of the heat sink pipe in the lowest position behind the pipe end opening of the low position side of the heat sink pipe in the second stage from the bottom. The heat exchanger according to claim 1 or 2,
In the header connected to the pipe end opening on the lower position side of the heat absorption pipe, a water draining plate for forming a water draining passage reaching the pipe end opening is arranged opposite to the pipe end opening. A heat exchanger. The heat exchanger according to claim 3,
The drainage flow path is constituted by a concave groove formed in the drainage plate and extending in the vertical direction,
The concave groove has a groove width narrower than the diameter of the pipe end opening and communicates with the pipe end opening. The heat exchanger according to claim 3,
The drainage flow path is constituted by a gap between the pipe end opening and the drainage plate,
The gap is set to be equal to or less than a rising amount of a water film formed in a pipe end opening due to a surface tension of water. The heat exchanger according to any one of claims 3 to 5,
The water drain plate is a heat exchanger composed of a water permeable member.

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