HEAT EXCHANGER

TECHNICAL FIELD

The present disclosure relates to a heat exchanger.

BACKGROUND ART

Conventionally, there is known a heat exchanger including a duct formed in a tubular shape and a plurality of flow path members stacked inside the duct, and performing heat exchange between a first fluid flowing through a first flow path formed inside the duct, and a second fluid flowing through a second flow path formed inside the plurality of flow paths.

SUMMARY OF THE INVENTION

In an aspect of the present disclosure, a heat exchanger that performs heat exchange between a first fluid and a second fluid, the heat exchanger including a first duct plate, a second duct plate, a plurality of flow path members, a frame member, an insertion protrusion, and a contact protrusion. The second duct plate is disposed to face the first duct plate. The second duct plate defines, together with the first duct plate, a first flow path for the first fluid to flow therethrough. The plurality of flow path members are stacked within the first flow path in a direction along which the first duct plate and the second duct plate face each other. Each of the plurality of flow path members defines a second flow path for the second fluid to flow therethrough. The frame member is disposed at an opening of the first flow path defined by the first duct plate and the second duct plate. The insertion protrusion protrudes toward the frame member from at least one of the first duct plate and the second duct plate and is inserted into an insertion hole defined in the frame member. The contact protrusion protrudes toward the frame member from the at least one of the first duct plate and the second duct plate. The contact protrusion is fixed to, and in contact with, the frame member.

In another aspect, a heat exchanger that performs heat exchange between a first fluid and a second fluid, the heat exchanger includes a first duct plate, a second duct plate, a plurality of flow path members, a frame member, an insertion protrusion, and a contact protrusion. The second duct plate is disposed to face the first duct plate. The second duct plate defines, together with the first duct plate, a first flow path for the first fluid to flow therethrough. The plurality of flow path members are stacked within the first flow path in a direction along which the first duct plate and the second duct plate face each other. Each of the plurality of flow path members defines a second flow path for the second fluid to flow therethrough. The frame member is disposed at an opening of the first flow path defined by the first duct plate and the second duct plate. The flange portion extends from the first duct plate in a direction along an opening face of the frame member. The flange portion is fixed to, and in contact with, the frame member. The insertion protrusion protrudes toward the frame member from the first duct plate and the second duct plate and is inserted into an insertion hole defined in the frame member. The contact protrusion protrudes toward the frame member from the second duct plate and is fixed to, and in contact with, the frame member.

BRIEF DESCRIPTION OF DRAWINGS

The above and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings.

FIG. 1 is a side view of a heat exchanger according to a first embodiment.

FIG. 2 is a view taken in a direction of arrow II of FIG. 1.

FIG. 3 is a view taken in a direction of arrow III of FIG. 1.

FIG. 4 is a cross-sectional view taken along line IV-IV of each of FIGS. 1 and 2.

FIG. 5 is an exploded view of a duct and a caulking plate of the heat exchanger according to the first embodiment.

FIG. 6 is an enlarged view of portion VI of FIG. 5.

FIG. 7 is a partially enlarged view of a second duct plate, an insertion protrusion, and a contact protrusion.

FIG. 8 is a partial cross-sectional view of the second duct plate, the insertion protrusion, and a caulking plate.

FIG. 9 is a partial cross-sectional view of the second duct plate, a contact protrusion, and the caulking plate.

FIG. 10 is a cross-sectional view taken along line X-X of each of FIGS. 8 and 9.

FIG. 11 is a partial cross-sectional view of a heat exchanger according to a second embodiment.

FIG. 12 is a partial cross-sectional view of a heat exchanger according to a third embodiment.

FIG. 13 is a partially enlarged view of a second duct plate, an insertion protrusion, and a contact protrusion of a heat exchanger according to a fourth embodiment.

FIG. 14 is a partial cross-sectional view of the second duct plate, the contact protrusion, and a caulking plate.

FIG. 15 is a partial cross-sectional view of a heat exchanger according to a fifth embodiment.

FIG. 16 is a view taken along a direction of arrow XVI of FIG. 15.

FIG. 17 is a partial cross-sectional view of a heat exchanger according to a sixth embodiment.

FIG. 18 is an exploded view of a duct and a caulking plate of the heat exchanger according to the sixth embodiment.

FIG. 19 is an enlarged view of portion XIX of FIG. 18.

FIG. 20 is a partially enlarged view of a first duct plate, an insertion protrusion, and a contact protrusion.

FIG. 21 is a partial cross-sectional view of the first duct plate, the insertion protrusion, and a caulking plate.

FIG. 22 is a partial cross-sectional view of the first duct plate, the contact protrusion, and the caulking plate.

FIG. 23 is a cross-sectional view taken along line XXIII-XXIII of each of FIGS. 21 and 22.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present disclosure will be described below with reference to accompanying drawings. Each of the embodiments below will be described by denoting the same or equivalent portions with the same reference numerals.

There is a conventional heat exchanger (a first conventional heat exchanger) that is an intercooler mounted on a vehicle to perform heat exchange between supercharged air as a first fluid compressed by a supercharger and cooling water as a second fluid. This heat exchanger includes a caulking plate as a frame member that is fixed by brazing to an opening of a duct formed in a tubular shape. An air intake tank is fixed by caulking to the caulking plate. The air intake tank is connected to an intake pipe for introducing intake air into an internal combustion engine.

Such a heat exchanger includes a groove that is recessed in a direction orthogonal to an opening face of the caulking plate, and that is provided in a face of the caulking plate, opposite to the air intake tank. The duct and the caulking plate are fixed by brazing while an end portion of the duct is inserted into the groove.

Meanwhile, another type of a conventional heat exchanger (a second conventional heat exchanger) also includes a groove provided in a caulking plate, into which an end portion of a duct is inserted. In addition, the heat exchanger is configured such that the duct and the caulking plate are fixed by brazing while an insertion protrusion extending from the end portion of the duct is inserted into an insertion hole provided in a bottom of the groove of the caulking plate.

As a result of detailed studies performed by the present inventors and others, the following problems have been found in the conventional heat exchangers. That is, the first conventional heat exchanger described above is configured such that a bottom of the groove provided in the caulking plate is not in contact with an opening end portion of the duct to form a gap therebetween. In other words, the heat exchanger is configured such that the duct and the caulking plate are allowed to be relatively moved in the direction orthogonal to the opening face of the caulking plate.

The second conventional heat exchanger described above also has a problem in structure such that it is difficult to accurately determine the amount of insertion of the insertion protrusion extending from the end portion of the duct into the insertion hole of the caulking plate. Thus, the duct and the caulking plate are allowed to be relatively moved in the direction orthogonal to the opening face of the caulking plate. As a result, each of the first and second heat exchangers has a variation in a positional relationship between the duct and the caulking plate, so that mountability to a vehicle may be deteriorated.

First Embodiment

The first embodiment will be described with reference to the drawings. A heat exchanger of the present embodiment is a water-cooled intercooler mounted on a vehicle, for example. The intercooler is mounted on an air intake system of an internal combustion engine (not illustrated) to perform heat exchange between supercharged air as a first fluid compressed by a supercharger and cooling water as a second fluid. The intercooler adjusts the supercharged air to a target temperature to improve filling efficiency of air intake of the internal combustion engine.

The configuration of the intercooler will be described.

As illustrated in FIGS. 1 to 4, an intercooler 1 is a so-called drone cup type heat exchanger in which a plurality of cooling plates 20, a plurality of outer fins 26, and the like are stacked inside a substantially square tubular duct 10.

Components of the intercooler 1 are each made of a clad material obtained by rolling and bonding a brazing material on a surface of aluminum, for example. The components are bonded to each other by brazing by being heated while a surface of the clad material is coated with flux.

The duct 10 is formed in a substantially square tubular shape in which a first duct plate 11 and a second duct plate 12 disposed facing the first duct plate 11 are bonded to each other, and an air flow path 13 as a first flow path is formed inside the duct 10. Specifically, the first duct plate 11 mainly includes a rectangular top plate 111 and two side plates 112 extending substantially perpendicularly from respective sides of the top plate 111. The second duct plate 12 mainly includes a rectangular bottom plate 121 and two side plates 122 extending substantially perpendicularly from respective sides of the bottom plate 121. The first duct plate 11 and the second duct plate 12 are bonded to each other while each of the side plates 122 of the second duct plate 12 partially overlaps with the inside of the corresponding one of the side plates 112 of the first duct plate 11.

The air flow path 13 formed inside the duct 10 has one opening and the other opening in an air flow direction each of which is provided with a caulking plate 30 as a frame member. The caulking plate 30 is formed in a rectangular frame shape. As illustrated in FIG. 4, an intake tank 41 is caulked and fixed to the caulking plate 30 with packings 40 interposed therebetween. In FIG. 4, the packings 40 and the intake tank 41, being caulked and fixed to the caulking plate 30, are indicated by broken lines. The caulking plate 30 includes holding grooves 31 for holding the packings 40 and ends of the intake tank 41. The caulking plate 30 also includes outer peripheral walls 32 positioned on both outer peripheral sides of the rectangular frame shape, facing walls 33 facing the packing 40 and the intake tank 41, and inner peripheral walls 34 positioned on the inner peripheral sides of the rectangular frame shape. In addition, the caulking plate 30 includes the holding groove 31 defined by the outer peripheral wall 32, the facing wall 33, and the inner peripheral wall 34. The outer peripheral wall 32 of the caulking plate 30 is bent to the inner peripheral side while the packing 40 and the end of the intake tank 41 are inserted inside the holding groove 31 of the caulking plate 30, and then the intake tank 41 is caulked and fixed to the caulking plate 30.

As described above, the intake tank 41 is provided at each of the one opening and the other opening of the air flow path 13 formed inside the duct 10. When the intercooler 1 is mounted on a vehicle, those intake tanks 41 are each connected to an intermediate portion of an intake pipe (not illustrated) that allows a super charger (not illustrated) to communicate with the internal combustion engine. Thus, supercharged air compressed by the super charger passes through the intake pipe, and flows in the air flow path 13 formed inside the duct 10 from one of the intake tanks 41 to be supplied to the internal combustion engine from the other of the intake tanks 41 through the intake pipe.

In the duct 10, cooling plates 20 as a plurality of flow path members, a plurality of spacer plates 25, a plurality of outer fins 26, and the like are stacked. In the following description, a direction in which the plurality of cooling plates 20 is stacked is referred to as a stacking direction W. As illustrated in FIG. 4, the top plate 111 of the first duct plate 11 is disposed on one side in the stacking direction W. The bottom plate 121 of the second duct plate 12 is disposed on the other side in the stacking direction W.

Each of the plurality of cooling plates 20 includes a first plate 21 and a second plate 22 that are each pressed into a predetermined shape. Each of the cooling plates 20 may be formed by bending a single plate, which is pressed into a predetermined shape, at the center of the plate and stacking the bent portions. Between the first plate 21 and the second plate 22, a cooling water flow path 23 as a second flow path is formed.

As illustrated in FIG. 1, the spacer plate 25 in a plate-like shape is provided between the cooling plates 20. The spacer plate 25 includes a hole (not illustrated) passing through in the stacking direction W. The cooling plate 20 also includes a hole (not illustrated) passing through in the stacking direction W at a position corresponding to the hole of the spacer plate 25. The hole of the spacer plate 25 and the hole of the cooling plate 20 communicate with each other to form two communicating passages (not illustrated).

As illustrated in FIGS. 1 to 3, the first duct plate 11 includes an inlet pipe 42 for supplying cooling water to the cooling water flow path 23 formed in the cooling plate 20, and an outlet pipe 43 for draining the cooling water from the cooling water flow path 23. The cooling water supplied from the inlet pipe 42 passes through one of the communicating passages, and flows through the cooling water flow paths 23 formed in the respective cooling plates 20 to flow out from the outlet pipe 43 through the other of the communicating passages.

Between the cooling plates 20, the outer fin 26 is provided at a position excluding the spacer plate 25. The outer fin 26 promotes heat exchange between the supercharged air and the cooling water.

The above-described configuration allows the intercooler 1 to perform heat exchange between the supercharged air flowing through the air flow path 13 in the duct 10 and the cooling water flowing through the cooling water flow path 23 in the plurality of cooling plates 20 to adjust the supercharged air to a desired temperature.

Next, a method of connecting the duct 10 and the caulking plate 30 in the configuration of the intercooler 1 described above will be described in detail.

As illustrated in FIG. 4, the first duct plate 11 is provided at its end with a flange portion 36 extending in a direction along an opening face 35 of the caulking plate 30. The flange portion 36 is provided on each of the top plate 111 and the side plate 112 of the first duct plate 11. The flange portion 36 is fixed to, and in contact with, the facing wall 33 of the caulking plate 30. Before brazing is performed in the manufacturing process of the intercooler 1, the flange portion 36 and the facing wall 33 of the caulking plate 30 are relatively movable along the opening face 35. When the brazing is performed in the manufacturing process, a bonded portion between the flange portion 36 and the facing wall 33 of the caulking plate 30 serves as a sealing face that prevents the supercharged air from leaking from the air flow path 13. The intercooler 1 is provided with the flange portion 36 at the end of the first duct plate 11, so that the following effects are achieved during the brazing in the manufacturing process when many steps of the cooling plate 20 (e.g., in the case of ten or more steps) are provided. That is, the intercooler 1 is configured such that even when the plurality of cooling plates 20 changes in dimensions in the stacking direction W due to melting of the brazing material provided on each of the cooling plates 20 or the like, the first duct plate 11 and the caulking plate 30 are displaceable in the stacking direction W by following the dimensional change. Thus, the intercooler 1 can prevent brazing defects of the plurality of cooling plates 20, the duct 10, and the like from occurring.

Meanwhile, the second duct plate 12 is fixed at its end to the inner peripheral wall 34 of the caulking plate 30. Before brazing is performed in the manufacturing process of the intercooler 1, the end of the second duct plate 12 and the inner peripheral wall 34 of the caulking plate 30 can be relatively moved in a direction intersecting the opening face 35. When the brazing is performed in the manufacturing process, a bonded portion between the end of the second duct plate 12 and the inner peripheral wall 34 of the caulking plate 30 serves as a sealing face that prevents the supercharged air from leaking from the air flow path 13.

As illustrated in FIGS. 5 to 7, the second duct plate 12 is provided at its end with insertion protrusions 14 and contact protrusions 15 that protrude from the second duct plate 12 toward the caulking plate 30. The second duct plate 12, the insertion protrusions 14 and the contact protrusions 15 are integrally formed of the same base material. The contact protrusions 15 are provided on both sides of each insertion protrusion 14. Each of the contact protrusion 15 extends from the second duct plate 12 so as to be tilted toward one side in a thickness direction of the second duct plate 12. Specifically, the contact protrusion 15 extends from the second duct plate 12 so as to be tilted circumferentially inward of the caulking plate 30. As shown in FIG. 8, the contact protrusion 15 has an end surface having a normal line that intersects the thickness direction of the contact protrusion 14.

Meanwhile, the caulking plate 30 is provided with stopper walls (or stopper plane walls) 37 extending from the inner peripheral wall 34 toward the inside of the rectangular frame shape. Each of the stopper wall 37 is provided at a position corresponding to the contact protrusions 15 of the second duct plate 12. The stopper wall 37 has a normal line extending along the thickness direction of the caulking plate 30. The stopper wall 37 is provided with an insertion hole 38 passing through in its thickness direction. That is, the stopper wall 37 is provided around the insertion hole 38 in the caulking plate 30. The insertion hole 38 is provided at a position of the stopper wall 37 corresponding to the insertion protrusion 14 of the second duct plate 12. The insertion hole 38 provided in the stopper wall 37 is a through hole allowing the insertion protrusion 14 to pass through the through hole.

FIGS. 8 to 10 each illustrate a state where the insertion protrusion 14 extending from the second duct plate 12 is inserted into the insertion hole 38 of the caulking plate 30, and the stopper wall 37 of the caulking plate 30 and the contact protrusion 15 are in contact with each other. More specifically, the end surface of the contact protrusion 15 is brought into contact with the stopper wall 37 of the caulking plate 30 when the contact protrusion 15 is fixed to the caulking plate 30.

Inserting the insertion protrusion 14 extending from the second duct plate 12 into the insertion hole 38 of the caulking plate 30 enables the caulking plate 30 and the second duct plate 12 to be positioned in a direction parallel to the opening face 35 of the caulking plate 30.

Bringing the stopper wall 37 of the caulking plate 30 and the contact protrusions 15 extending from the second duct plate 12 into contact with each other enables the amount of insertion of the insertion protrusion 14 into the insertion hole 38 of the caulking plate 30 to be accurately determined.

As described above, when the flange portion 36 provided on the first duct plate 11 is brought into contact with the facing wall 33 of the caulking plate 30, the caulking plate 30 and the first duct plate 11 are positioned in a direction intersecting the opening face 35 of the caulking plate 30. When the contact protrusions 15 extending from the second duct plate 12 are brought into contact with the stopper wall 37 of the caulking plate 30, the caulking plate 30 and the second duct plate 12 are positioned in the direction intersecting the opening face 35 of the caulking plate 30. Thus, this configuration enables the intercooler 1 to prevent a variation in angle formed between the duct 10 and the caulking plate 30.

As illustrated in FIG. 9, a connection portion 39 between the inner peripheral wall 34 and the stopper wall 37 in the caulking plate 30 may be curved by bending. Accordingly, the contact protrusions 15 extend from the second duct plate 12 so as to be tilted toward one side in the thickness direction of the second duct plate 12. Specifically, the contact protrusions 15 extend from the second duct plate 12 so as to be tilted circumferentially inward of the caulking plate 30. Accordingly, the contact protrusions 15 are prevented from being brought into contact with the connection portion 39 formed as a curved face. Thus, positioning accuracy between the second duct plate 12 and the caulking plate 30 is increased.

FIG. 10 illustrates a state where the insertion protrusion 14 is split and caulked after the insertion protrusion 14 of the second duct plate 12 is inserted into the insertion hole 38 of the caulking plate 30. Caulking by splitting refers to a way in which a load is applied to a part 16 in a portion exposed from the insertion hole 38, in the insertion protrusion 14, with a jig or the like, which is not illustrated, to deform a shape of a tip portion of the insertion protrusion 14, thereby preventing the insertion protrusion 14 from coming off from the insertion hole 38.

As described above, while the caulking plate 30 and the duct 10 are positioned, the duct 10, the cooling plates 20, the caulking plate 30, the flange portion 36, the insertion protrusions 14, the contact protrusions 15, the inlet pipe 42, the outlet pipe 43, and the like are installed in a heating furnace (not illustrated). Then, each component is fixed by brazing in the heating furnace. Accordingly, the intercooler 1 is manufactured.

The intercooler 1 of the present embodiment described above achieves the following effects.

(1) In the present embodiment, the flange portion 36 extending from the first duct plate 11 along the opening face 35 is fixed to, and in contact with, the caulking plate 30. The insertion protrusions 14 protruding from the second duct plate 12 are inserted into the insertion holes 38 of the caulking plate 30 and fixed while the contact protrusions 15 are in contact with the stopper walls 37 of the caulking plate 30.

Accordingly, when the insertion protrusions 14 are inserted into the insertion holes 38, positional displacement between the second duct plate 12 and the caulking plate 30 in the direction parallel to the opening face 35 of the caulking plate 30 is further prevented. In addition, when the flange portion 36 is brought into contact with the caulking plate 30 and the contact protrusions 15 are brought into contact with the stopper walls 37, a variation in angle formed between the duct 10 and the caulking plate 30 is prevented. Thus, the intercooler 1 can improve positioning accuracy between the duct 10 and the caulking plate 30.

In the present embodiment, the flange portion 36 extends in the direction along the opening face 35 of the caulking plate 30. Thus, the intercooler 1 has an advantageous effect during brazing in the manufacturing process. That is, the intercooler 1 is configured such that even when the plurality of cooling plates 20 changes in dimensions in the stacking direction W due to melting of the brazing material provided on each of the cooling plates 20 or the like, the first duct plate 11 and the caulking plate 30 are displaceable in the stacking direction W by following the dimensional change. Thus, the intercooler 1 can prevent brazing defects of the plurality of cooling plates 20, the duct 10, and the like from occurring. This is effective when many steps of the cooling plate 20 (e.g., in the case of ten or more steps) are provided.

(2) In the present embodiment, the insertion hole 38 is a through hole allowing the insertion protrusion 14 to pass through the through hole.

Accordingly, positional displacement between the second duct plate 12 and the caulking plate 30 in the direction parallel to the opening face 35 of the caulking plate 30 can be prevented. In addition, it can be visually recognized from the outer side of the caulking plate 30 that the insertion protrusion 14 is securely inserted into the insertion hole 38.

(3) In the present embodiment, the insertion protrusion 14 is split and caulked while being inserted into the insertion hole 38.

Accordingly, the insertion protrusion 14 is prevented from coming off from the insertion hole 38, so that a state where the contact protrusions 15 and the stopper wall 37 are in contact with each other can be maintained. Thus, a variation in angle formed between the duct 10 and the caulking plate 30 can be prevented.

(4) In the present embodiment, the contact protrusions 15 are in contact with the stopper wall 37 provided around the insertion hole 38 in the caulking plate 30.

Accordingly, the stopper wall 37 provided around the insertion hole 38 in the caulking plate 30 is used as a portion with which the contact protrusions 15 are brought into contact, so that the caulking plate 30 can be simplified in structure.

(5) In the present embodiment, the contact protrusions 15 are provided on both sides of the insertion protrusion 14.

Accordingly, a load applied to the caulking plate 30 is absorbed by the contact protrusions 15 when the insertion protrusion 14 is split and caulked, so that deformation and the like of the caulking plate 30 can be suppressed.

(6) In the present embodiment, the contact protrusions 15 extend from the second duct plate 12 so as to be tilted circumferentially inward of the caulking plate 30 toward one side in the thickness direction of the second duct plate 12.

Accordingly, the contact protrusions 15 and the stopper wall 37 are brought into contact with each other at places away from the connection point 39 between the inner peripheral wall 34 and the stopper wall 37. Thus, even when the connection portion 39 between the inner peripheral wall 34 of the caulking plate 30 and the stopper wall 37 is curved by bending, the contact protrusions 15 are prevented from being brought into contact with the connection portion 39 formed as a curved face. As a result, the intercooler 1 can prevent a variation in angle formed between the duct 10 and the caulking plate 30 and improve the positioning accuracy between the duct 10 and the caulking plate 30.

(7) In the present embodiment, the first duct plate 11, the second duct plate 12, the plurality of flow path members, the caulking plate 30, the flange portion 36, the insertion protrusion 14, the contact protrusions 15, and the like are fixed by brazing.

Accordingly, the intercooler 1 can improve the positioning accuracy between the duct 10 and the caulking plate 30, and prevent supercharged air from leaking from the connection portion 39 between the duct 10 and the caulking plate 30.

Second Embodiment

A second embodiment will be described. The second embodiment is different from the first embodiment in a part of a method of connecting the duct 10 and the caulking plate 30, and is similar to the first embodiment in other portions. Thus, only portions different from those of the first embodiment will be described.

As illustrated in FIG. 11, in the second embodiment, an insertion hole 381 provided in a stopper wall 37 of a caulking plate 30 is a hole with a dead end formed in a middle of the caulking plate 30 in a thickness direction of the caulking plate 30. An insertion protrusion 14 of a second duct plate 12 is inserted into the insertion hole 381. Even this structure enables preventing positional displacement between the second duct plate 12 and the caulking plate 30 in a direction parallel to an opening face 35 of the caulking plate 30 using fitting between the insertion protrusion 14 and the insertion hole 381. Thus, the second embodiment can also achieve operation effects similar to those of the first embodiment.

Third Embodiment

A third embodiment will be described. The third embodiment is also different from the first embodiment in a part of a method of connecting the duct 10 and the caulking plate 30, and is similar to the first embodiment in other portions. Thus, only portions different from those of the first embodiment will be described.

FIG. 12 illustrates a state where an insertion protrusion 14 is split and caulked after the insertion protrusion 14 of a second duct plate 12 is inserted into an insertion hole 38 of the caulking plate 30. In the third embodiment, the insertion protrusion 14 of the second duct plate 12 is provided with a cut-out portion 17. Providing the cut-out portion 17 in the insertion protrusion 14 as described above enables reduction in load for splitting and caulking the insertion protrusion 14 to reliably split and caulk the insertion protrusion 14. Thus, the third embodiment can also achieve operation effects similar to those of the first embodiment.

Fourth Embodiment

A fourth embodiment will be described. The fourth embodiment is also different from the first embodiment in a part of a method of connecting the duct 10 and the caulking plate 30, and is similar to the first embodiment in other portions. Thus, only portions different from those of the first embodiment will be described.

As illustrated in FIG. 13, in the fourth embodiment, contact protrusions 15 provided on a second duct plate 12 are formed on a plane continuous with the second duct plate 12 without being tilted toward one side in a thickness directions. That is, the second duct plate 12, the insertion protrusion 14, and the contact protrusions 15 are all formed on the continuous plane.

As illustrated in FIG. 14, in the fourth embodiment, a connection portion 391 between an inner peripheral wall 34 and a stopper wall 37 is formed at a substantially right angle by bending in the caulking plate 30. Accordingly, positioning accuracy between the second duct plate 12 and the caulking plate 30 is increased also in the fourth embodiment. Thus, the fourth embodiment can also achieve operation effects similar to those of the first embodiment.

Fifth Embodiment

A fifth embodiment will be described. The fifth embodiment is also different from the first embodiment in a part of a method of connecting the duct 10 and the caulking plate 30, and is similar to the first embodiment in other portions. Thus, only portions different from those of the first embodiment will be described.

As illustrated in FIGS. 15 and 16, in the fifth embodiment, an insertion protrusion 14 has a polygonal shape, and an inner wall of an insertion hole 38 has a curved shape. Specifically, the insertion protrusion 14 has a rectangular shape, and the inner wall of the insertion hole 38 has an elongated shape. In the fifth embodiment, corner portions 141 of the insertion protrusion 14 are formed to have an outer dimension larger than an inner dimension of the insertion hole 38. Accordingly, the corner portions 141 of the insertion protrusion 14 can be pressed into the insertion hole 38 along the inner wall thereof. As a result, the insertion protrusion 14 can be fixed in the insertion hole 38 without splitting and caulking the insertion protrusion 14. When brazing is performed in this state, the heat exchanger can improve positioning accuracy between the duct 10 and the caulking plate 30. Thus, the fifth embodiment can also achieve operation effects similar to those of the first embodiment.

Sixth Embodiment

A sixth embodiment will be described. The sixth embodiment is different from the first embodiment in a part of a method of connecting the duct 10 and the caulking plate 30, and is similar to the first embodiment in other portions. Thus, only portions different from those of the first embodiment will be described.

As illustrated in FIGS. 17 to 20, in the sixth embodiment, no flange portion is provided at an end of a first duct plate 11. Instead, in the sixth embodiment, each of the end of the first duct plate 11 and an end of a second duct plate 12 is provided with an insertion protrusion 14 and contact protrusions 15.

The first duct plate 11, the insertion protrusion 14, and the contact protrusions 15 are integrally formed of the same base material. The second duct plate 12, the insertion protrusion 14, and the contact protrusions 15 are also integrally formed of the same base material. The insertion protrusion 14 and the contact protrusions 15 each have specific structure similar to that described in the first embodiment.

Meanwhile, the caulking plate 30 includes stopper walls 37 provided at positions corresponding to the contact protrusion 15 of the first duct plate 11 and the contact protrusion 15 of the second duct plate 12. The stopper wall 37 is provided with an insertion hole 38 passing through in its thickness direction. The insertion holes 38 are provided at positions corresponding to the insertion protrusion 14 of the first duct plate 11 and the insertion protrusion 14 of the second duct plate 12.

FIGS. 21 to 23 each illustrate a state where the insertion protrusion 14 extending from the first duct plate 11 is inserted into the insertion hole 38 of the caulking plate 30, and the contact protrusions 15 extending from the first duct plate 11 are in contact with the stopper wall 37 of the caulking plate 30.

Inserting the insertion protrusions 14 extending from the first duct plate 11 or the second duct plate 12 into the insertion holes 38 of the caulking plate 30 enables the caulking plate 30 and the duct 10 to be positioned in a direction parallel to an opening face 35 of the caulking plate 30.

Bringing the contact protrusions 15 extending from the first duct plate 11 or the second duct plate 12 into contact with the stopper walls 37 of the caulking plate 30 enables the amount of insertion of the insertion protrusion 14 into the insertion hole 38 of the caulking plate 30 to be accurately determined. As a result, the duct 10 and the caulking plate 30 are positioned in a direction intersecting the opening face 35 of the caulking plate 30. Thus, this configuration enables the intercooler 1 to prevent a variation in angle formed between the duct 10 and the caulking plate 30.

In the sixth embodiment described above, the insertion protrusion 14 protruding from the first duct plate 11 or the second duct plate 12 is inserted into the insertion hole 38 of the caulking plate 30 and fixed while the contact protrusion 15 is in contact with the stopper wall 37 of the caulking plate 30.

Accordingly, when the insertion protrusion 14 is inserted into the insertion hole 38, positional displacement between the duct 10 and the caulking plate 30 in the direction parallel to the opening face 35 of the caulking plate 30 is further prevented. In addition, when the contact protrusions 15 extending from the first duct plate 11 or the second duct plate 12 are brought into contact with the stopper wall 37, a variation in angle formed between the duct 10 and the caulking plate 30 is prevented. Thus, the intercooler 1 can improve positioning accuracy between the duct 10 and the caulking plate 30. That is, the sixth embodiment can also achieve operation effects similar to those of the first embodiment.

Another Embodiment

The present disclosure is not limited to the embodiments described above, and can be modified as appropriate. In addition, the embodiments described above are not independent of one another, and can be appropriately combined except a case where a combination is apparently impossible. In each of the above embodiments, it is needless to say that elements constituting the embodiments are not necessarily indispensable except a case of being specified to be particularly indispensable and a case where it is considered to be obviously indispensable in principle. When the number of components, a numeric value, an amount, and a numeric value of a range or the like, are described in each of the embodiments described above, the values each are not limited to a specific number except a case of being specified to be particularly indispensable, a case of being apparently limited to a specific number in principle, and the like. Likewise, when a shape, a positional relationship, and the like, of a component and the like are described in each of the embodiments described above, the present invention is not limited to the shape, the positional relationship, and the like except a case of being particularly specified, a case of being limited to a specific shape, a positional relationship, or the like in principle, and the like.

(1) In each of the above embodiments, the water-cooled intercooler 1 is described as an example of the heat exchanger. In contrast, in another embodiment, the heat exchanger may be an exhaust gas recirculation (EGR) cooler or an exhaust heat recovery device, for example.

(2) In each of the above embodiments, the insertion protrusion 14 has a polygonal shape, and the insertion hole 38 has an elongated shape. In contrast, in another embodiment, the shapes of the insertion protrusion 14 and the insertion hole 38 are not limited. For example, the insertion protrusion may have a cylindrical columnar shape or a tapered shape, and the insertion hole 38 may have a polygonal shape, a circular shape, or an elliptical shape.

SUMMARY

According to a first aspect illustrated in part or all of the above-described embodiments, the heat exchanger performs heat exchange between the first fluid and the second fluid, and includes the first duct plate, the second duct plate, the plurality of flow path members, the frame member, the flange portion, the insertion protrusion, and the contact protrusion. The first duct plate and the second duct plate are disposed facing each other to define the first flow path through which the first fluid flows. The plurality of flow path members each have the second flow path through which the second fluid flows, and are stacked in a direction in which the first duct plate and the second duct plate face each other, in the first flow path. The frame member is provided at the opening of the first flow path formed by the first duct plate and the second duct plate. The insertion protrusion protruding toward the frame member from at least one of the first duct plate and the second duct plate is inserted into the insertion hole provided in the frame member. The contact protrusion protruding toward the frame member from the at least one of the first duct plate and the second duct plate is fixed to, and in contact with, the frame member. The contact protrusion has a surface having a normal line that intersects a thickness direction of the contact protrusion. The frame member includes a stopper plane wall having a normal line along a thickness direction of the frame member. The surface of the contact protrusion is in contact with the stopper plane wall when the contact protrusion is fixed to the frame member.

Accordingly, when the insertion protrusion extending from the at least one of the first duct plate and the second duct plate is inserted into the insertion hole, positional displacement between the at least one of the first and second duct plates, and the frame member, in a direction parallel to an opening face of the frame member is prevented. In addition, when the contact protrusion extending from the at least one of the first duct plate and the second duct plate is brought into contact with the frame member, a variation in angle formed between the duct composed of the first duct plate and the second duct plate, and the frame member, is prevented. Thus, the heat exchanger can improve the positioning accuracy between the duct and the frame member.

According to a second aspect, the heat exchanger performs heat exchange between the first fluid and the second fluid, and includes the first duct plate, the second duct plate, the plurality of flow path members, the frame member, the flange portion, the insertion protrusion, and the contact protrusion. The first duct plate and the second duct plate are disposed to face each other to define the first flow path through which the first fluid flows. The plurality of flow path members each have the second flow path through which the second fluid flows, and are stacked in a direction in which the first duct plate and the second duct plate face each other, in the first flow path. The frame member is provided at the opening of the first flow path formed by the first duct plate and the second duct plate. The flange portion extends from the first duct plate in the direction along the opening face of the frame member, and is fixed to, and in contact with, the frame member. The insertion protrusion protrudes from the second duct plate toward the frame member, and is inserted into the insertion hole provided in the frame member. The contact protrusion protrudes from the second duct plate toward the frame member, and is fixed to, and in contact with, the frame member. The contact protrusion has a surface having a normal line that intersects a thickness direction of the contact protrusion. The frame member includes a stopper plane wall having a normal line along a thickness direction of the frame member. The surface of the contact protrusion is in contact with the stopper plane wall when the contact protrusion is fixed to the frame member.

Accordingly, when the insertion protrusion extending from the second duct plate is inserted into the insertion hole, positional displacement between the second duct plate and the frame member, in a direction parallel to the opening face of the frame member is prevented. In addition, when the flange portion extending from the first duct plate is brought into contact with the frame member and the contact protrusion extending from the second duct plate is brought into contact with the frame member, a variation in angle formed between the duct composed of the first duct plate and the second duct plate, and the frame member, is prevented. Thus, the heat exchanger can improve the positioning accuracy between the duct and the frame member.

The heat exchanger also includes the flange portion that extends in the direction along the opening face of the frame member. Thus, the heat exchanger is configured such that even when the plurality of flow path members, and the like are changed in dimension in the stacking direction due to melting of brazing material provided in each component during brazing in a manufacturing process, the first duct plate and the frame member can be displaced in the stacking direction by following the dimensional change. As a result, the heat exchanger can prevent brazing failure from occurring in each component.

According to a third aspect, the insertion hole is a through hole allowing the insertion protrusion to pass through the through hole.

Accordingly, the second duct plate and the frame member can be prevented from being displaced in the direction parallel to the opening face.

According to a fourth aspect, the insertion hole is the hole with a dead end formed in a middle of the frame member in the thickness direction of the frame member.

Even this structure enables the second duct plate and the frame member to be prevented from being displaced in the direction parallel to the opening face.

According to a fifth aspect, the insertion protrusion has a polygonal shape, the inner wall of the insertion hole is curved, and the corner of the insertion protrusion and the inner wall of the insertion hole are fixedly connected to each other.

Accordingly, the insertion protrusion can be prevented from coming off from the insertion hole by pressing the corner portion of the insertion protrusion having a polygonal shape into the insertion hole along the inner wall thereof. Thus, a state where the contact protrusion and the frame member are in contact with each other can be maintained, so that positioning accuracy between the duct and the frame member can be improved.

According to a sixth aspect, the insertion protrusion is split and caulked while being inserted into the insertion hole.

Accordingly, the insertion protrusion is prevented from coming off from the insertion hole. Thus, a state where the contact protrusion and the frame member are in contact with each other can be maintained, so that positioning accuracy between the duct and the frame member can be improved.

According to a seventh aspect, the contact protrusion is brought into contact with the stopper wall provided around the insertion hole in the frame member.

Accordingly, when the stopper wall provided around the insertion hole in the frame member is used as a portion with which the contact protrusion is brought into contact, the structure of the frame member can be simplified.

According to the eighth aspect, the contact protrusion is two contact protrusions provided on both sides of the insertion protrusion.

Accordingly, the contact protrusions absorb a load applied to the frame member when the insertion protrusion is split and caulked, so that deformation or the like of the frame member can be suppressed.

According to a ninth aspect, the second duct plate, the insertion protrusion, and the contact protrusion are integrally formed of a single base material. The contact protrusion extends from the second duct plate so as to be tilted toward one side in the thickness direction of the second duct plate.

Accordingly, when the connection portion between a wall face connected to the end of the second duct plate and a wall face with which the contact protrusion is brought into contact in the frame member is formed as a curved face, the contact protrusion is prevented from being brought into contact with the curved face of the connection portion. Thus, the heat exchanger can improve the positioning accuracy between the duct and the frame member.

According to a tenth aspect, the contact protrusion extends from the second duct plate so as to be tilted circumferentially inward of the frame member toward one side in the thickness direction.

According to an eleventh aspect, the first duct plate, the second duct plate, the plurality of flow path members, the frame member, the flange portion, the insertion protrusion, and the contact protrusion are fixed by brazing.

Accordingly, the heat exchanger can improve the positioning accuracy between the duct and the frame member, and can prevent a fluid from leaking from the connection portion between the duct and the frame member.

	Number	Date	Country
Parent	PCT/JP2017/047109	Dec 2017	US
Child	16524522		US

HEAT EXCHANGER

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