JP5002798B2 - Heat exchanger - Google Patents

Description

This invention relates to heat exchangers, and more particularly relates to heat exchangers suitable for use as a car air conditioner evaporator is a refrigeration cycle, for example mounted on an automobile.

  In this specification and claims, the downstream side (direction indicated by arrow X in FIG. 1) of the air flowing through the ventilation gap between adjacent heat exchange tubes is referred to as the front, and the opposite side is referred to as the rear. The top and bottom and the left and right in FIG. In this specification, the term “aluminum” includes aluminum alloys in addition to pure aluminum.

  Conventionally, as an evaporator for a car air conditioner, a refrigerant inlet / outlet header tank having a refrigerant inlet header portion and a refrigerant outlet header portion that are arranged side by side in the front-rear direction, and a refrigerant that passes through the refrigerant inlet header portion and the refrigerant outlet header portion. The refrigerant inlet header portion is formed of a hollow inlet header portion main body having at least one end opened and a cap that is joined to the opening end portion of the inlet header portion main body to close the opening of the inlet header portion main body, The refrigerant outlet header portion is a hollow outlet header portion main body having at least the same end as the opening of the inlet header portion main body, and a cap that is joined to the opening end portion of the outlet header portion main body to close the opening of the outlet header portion main body. A header tank for refrigerant entry / exit is formed by the inlet header body, the outlet header body and the cap, A through hole is formed in each of the caps joined to the same end of the outlet header body and the outlet header body, and the through hole of the cap of the refrigerant inlet header portion of the two through holes serves as a refrigerant inlet. The through-hole of the cap of the outlet header portion is used as a refrigerant outlet, and both caps having the refrigerant inlet and the refrigerant outlet are integrated through a connecting portion to form an end member, and the refrigerant inlet hole and the refrigerant outlet leading to the refrigerant inlet are formed. A joint plate with a refrigerant outflow hole leading to it is joined to the end member so as to straddle the refrigerant inlet header part and the refrigerant outlet header part, and pipes are inserted around the refrigerant inflow hole and the refrigerant outflow hole on the outer surface in the left-right direction of the joint plate A cylindrical part is formed, a refrigerant inlet pipe is inserted into a pipe inserting cylindrical part around the refrigerant inflow hole, and a refrigerant outlet pipe is inserted around the refrigerant outflow hole. Which are respectively inserted into the cylindrical portion is joined to the tube insertion tubular portion is known (see Patent Document 1).

  By the way, it may be necessary to detachably connect the refrigerant inlet pipe and the refrigerant outlet pipe to the evaporator for the convenience of the casing design based on the positional relationship between the evaporator and the expansion valve in consideration of the layout of the car air conditioner.

However, in the evaporator described in Patent Document 1, the refrigerant inlet tube is inserted into the tube insertion tubular portion around the refrigerant inflow hole, and the refrigerant outlet tube is inserted into the tube insertion tubular portion around the refrigerant outflow hole. Since it is joined to the tubular portion for pipe insertion, the refrigerant inlet pipe and the refrigerant outlet pipe cannot be made detachable.
JP 2005-164226 A

  An object of the present invention is to solve the above problems and provide a heat exchanger capable of detachably connecting a refrigerant inlet pipe and a refrigerant outlet pipe and a manufacturing method thereof.

  In order to achieve the above object, the present invention comprises the following aspects.

1) a refrigerant inlet / outlet header tank having a refrigerant inlet header portion and a refrigerant outlet header portion extending in the left / right direction arranged side by side in the front / rear direction, and a refrigerant circulation path through the refrigerant inlet header portion and the refrigerant outlet header portion; refrigerant inlet header section, it consists cap for closing the opening of the inlet header section body is brazed to at least one end open end of the hollow inlet header section body and the inlet header section body which is open, the refrigerant outlet header section consists of a cap for closing the opening of at least the opening and the same end of the inlet header section body is brazed to the open end of the hollow outlet header section main body and the outlet header section body which opens the outlet header section body, the inlet The header tank body, the outlet header section body, and the cap form a refrigerant inlet / outlet header tank, and the inlet header section body and the outlet header section Body each through hole is formed in the brazed cap same end of a through hole of the refrigerant inlet header section of the cap of the two through holes is made as the refrigerant inlet, through the cap of the refrigerant outlet header section A hole serves as a refrigerant outlet, and both caps having a refrigerant inlet and a refrigerant outlet are integrated through a connecting portion to form an end member, and a circular refrigerant inflow hole leading to the refrigerant inlet and a circular refrigerant outflow leading to the refrigerant outlet joint plate having a hole, in the heat exchanger that is brazed to the end member so as to extend to the refrigerant inlet header and a refrigerant outlet header section,
The joint plate, joint member for connecting detachably the refrigerant inlet and the refrigerant outlet tube is brazed, the joint member, with one end communicating with the refrigerant inflow hole of the joint plate, the refrigerant inlet pipe in the other end a refrigerant inflow passage of circular cross section which is inserted, with one end communicating with the refrigerant outlet hole of the joint plate, and a refrigerant outflow channel of circular cross section in which the refrigerant outlet pipe is inserted is formed in the other end, the left-right direction outer When viewed from the above, the refrigerant inflow passage of the joint member, the refrigerant inflow hole of the joint plate, and the refrigerant inlet of the end member have a common inflow side opening, and the center in the front-rear direction and the vertical direction is the inflow When viewed from the outside in the left-right direction, the refrigerant outlet passage of the joint member, the refrigerant outlet hole of the joint plate, and the refrigerant outlet of the end member are located in the side opening portion. Together we have the outlet-side opening portion through the center of the front and rear direction and the vertical direction is positioned on the outlet side opening portion,
Around the refrigerant inflow hole and the refrigerant outflow hole of the joint plate, a cylindrical part is formed that protrudes outward in the left-right direction and is inserted into the refrigerant inflow path and the refrigerant outflow path of the joint member. A pipe expanding part is formed at the tip, and an annular engagement part that engages the pipe expanding part at the tip of the tubular part of the joint plate projects inward over the entire circumference on the inner peripheral surfaces of the refrigerant inflow path and the refrigerant outflow path The joint member is formed in a joint plate in a state where both cylindrical portions of the joint plate are inserted into the refrigerant inflow passage and the refrigerant outflow passage of the joint member and the expanded pipe portion is engaged with the annular engagement portion. A heat exchanger that is brazed .

  2) The area of the inflow side opening portion is ½ or more of the flow path cross-sectional area of the refrigerant inlet pipe connected to the joint member, and the area of the outflow side opening portion is the refrigerant outlet connected to the joint member The heat exchanger as described in 1) above, which is ½ or more of the flow path cross-sectional area of the pipe.

  3) The end member is provided with a downward projecting piece projecting downward from the outer shape of the refrigerant inlet / outlet header tank, a notch is formed in the lower edge portion of the downward projecting piece, and the end of the joint plate is passed through the notch. A protruding portion that protrudes inward in the left-right direction of the member is formed, and engages with at least one of the front and rear sides of the notch in the surface facing the inner side in the left-right direction of the protruding piece of the end member at the distal end portion of the protruding portion The heat exchanger according to 1) or 2), wherein an engaging claw is formed.

  4) Each of the caps of the inlet header part and the outlet header part of the end member is provided with a downward projecting piece, and a notch is formed in each downward projecting part, and the projecting part and the engaging part are respectively formed at the front and rear end parts of the joint plate. The heat exchanger as described in 3) above, wherein nails are formed.

5) in a circular cylindrical portion of Joy cement plate heat exchanger according to any one of the above 1) to 4) in which a plurality of slits from the tip are formed at intervals in the circumferential direction.

6) The short-circuit prevention space having upper and lower ends opened at a portion between the refrigerant inflow path and the refrigerant outflow path on the inner surface in the left-right direction of the joint member, according to any one of 1) to 5) above. Heat exchanger.

7) The annular protrusions that protrude toward the joint plate are formed at intervals around the openings of the refrigerant inflow passage and the refrigerant outflow passage on the inner surface in the left-right direction of the joint member. The heat exchanger according to 6) above, wherein a portion between the portions is a space for preventing a short circuit.

8) The refrigerant circulation path is spaced apart from the refrigerant inlet / outlet header tank, and is opposed to the first intermediate header part and the refrigerant outlet header part facing the refrigerant inlet header part and communicated with the first intermediate header tank A refrigerant turn header tank having a second intermediate header portion, and a heat exchange core portion formed between the header tanks, the heat exchange core portion being spaced apart in the length direction of the header tanks. It consists of a heat exchange pipe group consisting of a plurality of heat exchange pipes arranged at both ends connected to both header tanks, and fins arranged between adjacent heat exchange pipes. The heat exchange pipe groups are arranged side by side in the ventilation direction, and at least one heat exchange pipe group is provided in each of the refrigerant inlet header part and the first intermediate header part, and the refrigerant outlet header part and the second intermediate header part. Contact A heat exchanger according to any one of the above 1) to 7), which is.

According to the above-mentioned heat exchanger 1), the joint plate, joint member for connecting detachably the refrigerant inlet and the refrigerant outlet tube is brazed, the joint member, the refrigerant inlet hole of the end joint plate A refrigerant inflow passage in which the refrigerant inlet pipe is inserted into the other end, and a refrigerant outflow passage in which one end communicates with the refrigerant outflow hole of the joint plate and the refrigerant outlet pipe is inserted in the other end. Therefore, the end of the refrigerant inlet pipe is inserted into the refrigerant inflow path of the joint member, the end of the refrigerant outlet pipe is inserted into the refrigerant outflow path of the joint member, and the pipe fixing member is attached to the joint member by screwing means or the like. By fixing, the refrigerant inlet pipe and the refrigerant outlet pipe can be detachably connected. Further, when viewed from the outside in the left-right direction, the refrigerant inflow passage of the joint member, the refrigerant inflow hole of the joint plate, and the refrigerant inlet of the end member have a common inflow side opening portion, and these front-rear direction and vertical direction Is located in the inflow side opening portion, and when viewed from the left and right direction, the outflow side opening portion in which the refrigerant outflow path of the joint member, the refrigerant outflow hole of the joint plate, and the refrigerant outlet of the end member are common And the center in the front-rear direction and the up-down direction is located in the outflow side opening, so that the refrigerant flows into the refrigerant inlet header portion of the heat exchanger and from the refrigerant outlet header portion. Resistance to the flow of the refrigerant when the refrigerant flows out can be reduced. Therefore, the flow of the refrigerant becomes smooth, and an increase in pressure loss and generation of abnormal noise can be suppressed.

According to the heat exchanger of 1) above, the joint member can be temporarily fixed to the joint plate at the time of manufacturing the heat exchanger. In particular, in the case of having the configurations 3) and 4), the end member, the joint plate, and the joint member can be temporarily fixed at the time of manufacturing the heat exchanger, so that the handling becomes easy .

According to the heat exchanger of 1) above, it is possible to firmly fix the joint member and the joint plate temporarily at the time of manufacturing the heat exchanger .

  According to the heat exchanger of 2) above, the area of the inflow side opening portion is ½ or more of the flow path cross-sectional area of the refrigerant inlet pipe connected to the joint member, and the area of the outflow side opening portion is Since the flow passage cross-sectional area of the refrigerant outlet pipe connected to the joint member is ½ or more, the refrigerant flow rate when the refrigerant flows into the refrigerant inlet header portion of the heat exchanger and when the refrigerant flows out of the refrigerant outlet header portion. The resistance to flow can be effectively reduced. Therefore, the flow of the refrigerant becomes smoother, and the increase in pressure loss and the generation of abnormal noise can be effectively suppressed.

  According to the heat exchanger of 3) above, the joint plate can be temporarily fixed to the end member when the heat exchanger is manufactured.

According to the heat exchanger of the above 4), temporary fixing to the end member of the joint plate can be effectively performed at the time of manufacturing the heat exchanger.

According to the heat exchanger of the above 5) , the tubular portion of the joint plate can be relatively easily expanded when the heat exchanger is manufactured.

According to the heat exchanger of 6) , it is possible to prevent a short circuit of the refrigerant between the refrigerant inflow hole and the refrigerant outflow hole of the joint plate even when brazing failure occurs.

According to the above-mentioned heat exchanger 7), a short-circuit prevention for the space between the refrigerant inflow passage and the refrigerant outflow channel in the lateral direction inner surface of the joint member can be formed relatively easily.

  Embodiments of the present invention will be described below with reference to the drawings. In the embodiment described below, the heat exchanger according to the present invention is applied to an evaporator of a car air conditioner using a chlorofluorocarbon refrigerant.

  1 and 2 show the overall configuration of the evaporator, and FIGS. 3 to 15 show the configuration of the main part of the evaporator.

  As shown in FIGS. 1 to 3, the evaporator (1) is disposed between an aluminum refrigerant inlet / outlet header tank (2) and an aluminum refrigerant turn header tank (3) that are spaced apart in the vertical direction. Is provided with a heat exchange core section (4).

  The refrigerant inlet / outlet tank (2) includes a refrigerant inlet header portion (5) located on the front side (downstream side in the ventilation direction), a refrigerant outlet header portion (6) located on the rear side (upstream side in the ventilation direction), It has a connecting portion (7) for connecting and integrating the header portions (5) and (6) with each other (see FIG. 3).

  The refrigerant turn header tank (3) is located on the front side and faces the first intermediate header part (11) facing the refrigerant inlet header part (5) and on the rear side and faces the refrigerant outlet header part (6) A second intermediate header portion (12) and a connecting portion (13) for connecting and integrating the header portions (11) and (12) to each other, the header portions (11) and (12) being connected to the connecting portion. A drainage basin (14) is formed by (13) (see FIG. 3).

  The heat exchange core section (4) is composed of a plurality of heat exchange pipe groups (16) composed of a plurality of heat exchange pipes (15) arranged in parallel at intervals in the left-right direction. Are arranged in two rows, the ventilation gap between adjacent heat exchange tubes (15) of each heat exchange tube group (16), and the heat exchange tubes (15) at the left and right ends of each heat exchange tube group (16). Corrugated fins (17) are arranged on the outside and brazed to the heat exchange pipe (15), and aluminum side plates (18) are arranged on the outside of the corrugated fins (17) on both the left and right ends, respectively. It is configured by brazing to 17). The upper and lower ends of the heat exchange pipe (15) of the front heat exchange pipe group (16) are connected to the refrigerant inlet header section (5) and the first intermediate header section (11). The upper and lower ends of the heat exchange pipe (15) of the rear heat exchange pipe group (16) are connected to the refrigerant outlet header part (6) and the second intermediate header part (12). Here, the refrigerant inlet header portion (5) and the second intermediate header portion (12) are header portions on the side where the refrigerant flows into the heat exchange pipe (15). The refrigerant inlet header portion (5) and the refrigerant outlet header portion are formed by the first intermediate header portion (11), the second intermediate header portion (12), and the heat exchange pipe (15) of the front and rear heat exchange pipe groups (16). A refrigerant circulation path is formed through (6). In addition, it is preferable that the width | variety of the front-back direction of a heat exchange core part (4) is 45 mm or less.

  The heat exchange pipe (15) is made of a bare material formed of an aluminum extruded profile, and has a flat shape having a plurality of refrigerant passages arranged in the width direction and arranged in the width direction in the front-rear direction. The corrugated fin (17) is formed in a wave shape using an aluminum brazing sheet having a brazing filler metal layer on both sides, and is composed of a wave top portion, a wave bottom portion and a horizontal connection portion connecting the wave top portion and the wave bottom portion, A plurality of louvers are formed in the connecting portion side by side in the front-rear direction. The corrugated fin (17) is shared by the front and rear heat exchange pipes (15) constituting the front and rear heat exchange pipe groups (16), and the width in the front-rear direction is equal to the front edge of the front heat exchange pipe (15). The distance from the rear edge of the rear heat exchange pipe (15) is substantially equal. The wave crest and wave bottom of the corrugated fin (17) are brazed to the front and rear heat exchange tubes. The front side edge of the corrugated fin (17) projects slightly forward from the front side edge of the front heat exchange pipe (15). In addition, instead of sharing one corrugated fin between the front and rear heat exchange tube groups (16), corrugated fins are respectively arranged between adjacent heat exchange tubes (15) of both heat exchange tube groups (16). It may be.

  As the heat exchange pipe (15), instead of the one made of an aluminum extruded shape, one in which a plurality of refrigerant passages are formed by inserting inner fins into an aluminum electric sewing pipe may be used. . Also, two flat wall forming parts formed by rolling an aluminum brazing sheet having a brazing filler metal layer on both sides and connected via connecting parts, and the opposite side of the connecting part in each flat wall forming part A side wall forming portion integrally formed in a protruding shape from the side edges of the flat wall forming portion, and a plurality of partition wall forming portions integrally formed in a protruding shape from the two flat wall forming portions at a predetermined interval in the width direction of the flat wall forming portion. It is also possible to use a plate having a partition wall formed by bending a plate with a hairpin shape at the connecting portion, butting the side wall forming portions with each other and brazing each other. In this case, a corrugated fin made of a bare material is used.

  As shown in FIGS. 2 to 5, the refrigerant inlet / outlet tank (2) is formed by pressing an aluminum brazing sheet having a brazing filler metal layer on both sides and all the heat exchange pipes (15) are connected. A plate-shaped first member (21), a second member (22) made of a bare material formed from an extruded aluminum material and covering the upper side of the first member (21), and a brazing material layer on both sides Right and left end member (24) formed by pressing aluminum aluminum brazing sheet and left and right end members (23) and (24) made of aluminum brazed to both left and right ends of both members (21) and (22) A joint plate (25) made of an aluminum brazing sheet that is long in the front-rear direction is brazed to the outer surface of the joint plate (25) so as to straddle the refrigerant inlet header (5) and the refrigerant outlet header (6). Refrigerant inlet pipe (130) to be described later Also, a block joint member (30) made of an aluminum bare material capable of detachably connecting the refrigerant outlet pipe (131) is brazed.

  The first member (21) includes a first bulging first header forming portion (26) that forms a lower portion of the refrigerant inlet header portion (5) and a lower bulging that forms a lower portion of the refrigerant outlet header portion (6). A second header forming part (27) having a shape, a rear edge of the first header forming part (26) and a front edge of the second header forming part (27), and a lower part of the connecting part (13) And a connecting wall (28) forming The first header forming part (26) includes a horizontally flat bottom wall (29) and front and rear side walls (31) and (32) integrally formed on both front and rear side edges of the bottom wall (29). The front side wall (31) is connected to the front edge of the bottom wall (29) and inclined upward (31a), and the vertical part extends upwardly connected to the upper edge of the inclined part (31a). (31b). The rear side wall (32) continues to the rear edge of the bottom wall (29) and is inclined rearward toward the upper side. The upper end of the front side wall (31) is located above the upper end of the rear side wall (32). The second header forming portion (27) is symmetrical to the first header forming portion (26), and has a horizontally flat bottom wall (33), a rear edge and a front side of the bottom wall (33). It consists of a rear side wall (34) and a front side wall (35) integrally formed on the edge. The rear side wall (34) is connected to the rear edge of the bottom wall (33) and inclined backward (34a) upward, and the vertical part (34b) connected to the upper edge of the inclined part (34a). It becomes more. The front side wall (35) is connected to the front edge of the bottom wall (33) and is inclined forward in the upward direction. The upper end of the rear side wall (34) is located above the upper end of the front side wall (35). The upper edge of the rear side wall (32) of the first header forming part (26) and the upper edge of the front side wall (35) of the second header forming part (27) are integrally connected by the connecting wall (28).

  A plurality of pipe insertion holes (36) that are long in the front-rear direction in both header forming portions (26), (27) of the first member (21) are spaced in the left-right direction and are at the same position in the left-right direction. Is formed. The pipe insertion hole (36) of the first header forming part (26) is formed from the inclined part (31a) of the front side wall (31) to the rear side wall (32), and the pipe insertion hole ( 36) is formed from the inclined portion (34a) of the rear side wall (34) to the front side wall (35). The upper end portions of the heat exchange pipes (15) of both the front and rear heat exchange pipe groups (16) of the heat exchange core part (4) are inserted into the pipe insertion holes (36) of both header forming parts (26), (27), The first member (21) is brazed to the first member (21) using the brazing material layer of the first member (21), so that the upper end of the heat exchange pipe (15) of the front heat exchange pipe group (16) is connected to the refrigerant inlet. The upper end of the heat exchange pipe (15) of the rear heat exchange pipe group (16) is connected to the header part (5) in communication with the refrigerant outlet header part (6). In the connecting wall (28) of the first member (21), a plurality of drainage through holes (37) elongated in the left-right direction are formed at intervals in the left-right direction. In addition, a plurality of fixing through holes (38) are formed in the connecting wall (28) of the first member (21) at intervals in the left-right direction so as to be shifted from the drain through holes (37). Has been. Here, drainage through holes (37) and fixing through holes (38) are alternately formed.

  The second member (22) includes an upper bulging first header forming part (41) that forms the upper part of the refrigerant inlet header part (5), and an upper bulging that forms the upper part of the refrigerant outlet header part (6). A second header forming portion (42) having a shape, a rear edge portion of the first header forming portion (41) and a front edge portion of the second header forming portion (42), and the first member (21) The connecting wall (43) is brazed to the connecting wall (28) to form the upper part of the connecting portion (7). The cross-sectional shapes of the first header forming portion (41) and the second header forming portion (42) are each substantially U-shaped in cross section that opens downward and has a center portion in the front-rear direction protruding upward. The first header forming portion (41) is a horizontal connecting the lower ends of the front and rear walls (41a) together and partitioning the refrigerant inlet header portion (5) into two upper and lower spaces (5a) and (5b). A first shunt control wall 41b. The second header forming portion (42) integrally connects the lower end portions of the front and rear walls (42a) at the same height as the first diversion control wall (41b) and passes through the inside of the refrigerant outlet header portion (6). It has a horizontal second flow control wall (42b) that is divided into two upper and lower spaces (6a) and (6b).

  A cutout (44) is formed in the first diversion control wall (41b) of the first member (22) from the left end. Further, in the first diversion control wall (41b), a diversion adjusting hole (45) is formed in a penetrating manner in a portion near the notch (44) and a portion near the right end. A plurality of oblong coolant passage holes (46A) and (46B) which are long in the left-right direction are formed in the left-right direction in the portion excluding the left and right end portions in the rear portion of the second diversion control wall (42b) of the first member (22) Are formed in a penetrating manner with a gap therebetween. The length of the oval refrigerant through hole (46A) in the center is shorter than the length of the other oval refrigerant through hole (46B), and is located between the adjacent heat exchange tubes (15).

  In the connecting wall (43) of the second member (22), drainage through holes (47) that are long in the left-right direction are formed at positions corresponding to the drainage through holes (37) of the first member (21). A plurality of protrusions (48) fitted into the fixing through holes (38) are formed at positions corresponding to the fixing through holes (38) of the first member (21) on the lower surface of the wall (43). In the first member (21) and the second member (22), the protrusion (48) is inserted into the fixing through hole (38) and caulked so that both the members (21) and (22) are temporarily fixed. In the state, using the brazing material layer of the first member (21), the front side walls (31) and (41a) of the first header forming portions (26) and (41) of both members (21) and (22) 2 The rear side walls (34) and (42a) of the header forming portions (27) and (42) and the connecting walls (28) and (43) are brazed.

  A hollow inlet header main body (50) opened at both ends by the first header forming portion (26) of the first member (21) and the first header forming portion (41) of the second member (22). A hollow outlet header main body (both ends open) by the second header forming portion (27) of the first member (21) and the second header forming portion (42) of the second member (22). 51) is formed.

  The left end member (23) includes a front cap (23a) for closing the left end opening of the inlet header body (50) and a rear cap (23b) for closing the left end opening of the outlet header body (51). 23c). The front cap (23a) of the left end member (23) is integrally formed with a right protrusion (52) that is fitted into the inlet header body (50), and the rear cap (23b) is also provided with an outlet header. An upper right protrusion (53) fitted into the space (6a) above the second diversion control wall (42b) of the main body (51), and a lower side than the second diversion control wall (42b) A lower right protrusion (54) fitted into the space (6b) is formed integrally with a space in the vertical direction. In addition, at the connecting portion between the front and rear side edges and the upper and lower edges of the left end member (23), there are engaging claws (55) that protrude to the right and engage with both members (21) and (22). It is integrally formed. The left end member (23) is brazed to both members (21) and (22) using its own brazing material layer. And the left end opening of the notch (44) of the first diversion control wall (41b) is closed by the front cap (23a) of the left end member (23), and thereby the upper and lower spaces (5a) of the inlet header portion (5). A communication hole (56) for communicating (5b) with each other at the left end is formed. Here, the communication hole (56) is formed by closing the left end opening of the notch (44) by the front cap (23a) of the left end member (23), but instead of this, a notch is formed. Instead, a communication hole may be provided by forming a through hole in the left end portion of the first diversion control wall (41b).

  The right end member (24) includes a front cap (24a) for closing the right end opening of the inlet header body (50) and a rear cap (24b) for closing the right end opening of the outlet header body (51). 24c). The front cap (24a) of the right end member (24) has an upper left protrusion (57) that is fitted into the space (5a) above the first flow control wall (41b) of the inlet header body (50). ) And a lower left projecting portion (58) fitted into the space (5b) below the first diversion control wall (41b) are integrally formed with a vertical gap, and the rear cap (24b) includes an upper left protrusion (59) fitted into the space (6a) above the second flow dividing control wall (42b) of the outlet header body (51), and a second flow dividing control wall. A lower left protrusion (61) fitted into the space (6b) below (42b) is integrally formed with a space in the vertical direction. A refrigerant inlet (62) is formed in the protruding end wall of the upper left protrusion (57) of the front cap (24a) of the right end member (24), and the upper left protrusion (59) of the rear cap (24b) is also formed. A refrigerant outlet (63) is formed in the protruding end wall. Both members project to the left on the connecting part between the front and rear side edges and the upper edge of the right end member (24), the front part of the front cap (24a) and the rear part of the lower edge of the rear cap (24b). (21) An engaging claw (64) that engages with (22) is integrally formed.

  As shown in FIGS. 6-8, the bottom wall in the first header forming portion (26) of the first member (21) of the refrigerant inlet / outlet header tank (2) is attached to the front cap (24a) of the right end member (24). The lower protruding piece (65) protruding downward from the front end portion of (29) and the inclined portion (31a) of the front side wall (31) is integrally formed, and the refrigerant cap header 24 ( 2) A downward projecting piece projecting downward from the rear end portion of the bottom wall (33) and the inclined portion (34a) of the rear side wall (34) in the second header forming portion (27) of the first member (21). 66) are integrally formed. Cutouts (67) are formed in the lower edges of the downward projecting pieces (65) and (66) of the caps (24a) and (24b), respectively. Each notch (67) is located at the front and rear ends of the right end member (24), that is, on the front side of the engaging claw (64) of the front cap (24a) and on the rear side of the engaging claw (64) of the rear cap (24b). positioned. Further, an engaging male portion (68) protruding upward is integrally formed at the center portion in the front-rear direction at the upper end of the connecting portion (24c) of the right end member (24). The right end member (24) is brazed to both members (21) and (22) using its own brazing material layer.

  As shown in FIGS. 7 to 10, the joint plate (25) communicates with the circular penetrating refrigerant inflow hole (71) leading to the refrigerant inlet (62) of the right end member (24) and the refrigerant outlet (63). A circular through-flow refrigerant outflow hole (72) is provided. Short cylindrical part (69) (70) projecting to the right (outward in the left-right direction) in the part around the refrigerant inflow hole (71) and refrigerant outflow hole (72) on the right side of the joint plate (25) Are integrally formed. In each short cylindrical portion (69) (70), a plurality of slits (79) (80) are formed at intervals in the circumferential direction from the tip thereof. In addition, pipe expansion parts (69a) (70a) are formed at the tip of each short cylindrical part (69) (70). As shown in FIG. 9, when the evaporator (1) is manufactured, in the state before the joint plate (25) and the joint member (30) are combined, the short cylindrical portion (69) (70) The expanded portion (69a) (70a) is not formed. The short cylindrical portions in which the expanded portions (69a) and (70a) are not formed are indicated by (69A) and (70A).

  A portion of the joint plate (25) between the refrigerant inflow hole (71) and the refrigerant outflow hole (72) is formed with a slit (73) for preventing a short circuit extending in the vertical direction, and the slit (73) Substantially trapezoidal through-holes (74) and (75) are formed to be connected to the upper and lower ends. The width of the slit (73) in the front-rear direction is preferably 1 mm or less. In addition, it extends to the left and right ends of the lower edge of the joint plate (25) to the left (inward in the left-right direction), and the notches (67) in both downward projecting pieces (65) (66) of the right end member (24) A projecting portion (76) projecting to the left of both caps (24a) and (24b) through the inside is integrally formed, extending to the front end of the projecting portion (76) on both front and rear sides and of the right end member (24). Engaging claws (77) that engage with both front and rear sides of the notches (67) on the surfaces facing the inner side in the left-right direction of both downward projecting pieces (65, 66) are formed. Note that the protrusion (76) engages only with either one of the front and rear of the notch (67) on the surface facing the inner side in the left-right direction of the lower protrusion pieces (65) (66) of the right end member (24). An engaging claw may be formed. Thereby, the movement of the joint plate (25) in the upward, front-rear direction, and left-right direction is prevented. As shown in FIG. 9, in manufacturing the evaporator (1), the protrusion (76) protrudes obliquely downward to the left before the right end member (24) and the joint plate (25) are combined. Yes. A protruding portion protruding diagonally to the left is indicated by (76A). Note that, in the state before the right end member (24) and the joint plate (25) are combined, the protruding portion may protrude vertically downward.

  The upper part of the upper through hole (74) and the lower part of the lower through hole (75) of the joint plate (25) are U-shaped so as to protrude to the left (right end member (24) side). The upper U-shaped bent portion is bent, and an engaging female portion (78) through which the engaging male portion (68) of the right end member (24) is inserted from below is formed. Then, the engagement male portion (68) of the right end member (24) is inserted from below into the engagement female portion (78) of the joint plate (25) and is engaged with the engagement female portion (78). This prevents the joint plate (25) from moving in the left-right direction and the front-rear direction. Further, the engaging female portion (78) is engaged with the front and rear side portions of the engaging male portion (68) in the connecting portion (24c) of the right end member (24), thereby lowering the joint plate (25). Movement to is blocked. In this way, the joint plate (25) is engaged with the right end member (24) so as to be prevented from moving in the left-right direction, the up-down direction, and the front-rear direction, and the right end member (24) and its own brazing member The right end member (24) is brazed using the material layer.

  As shown in FIGS. 5, 7, 8, and 10, one end (left end) of the joint member (30) leads to the refrigerant inflow hole (71) of the joint plate (25) and the other end (right end) The refrigerant inlet pipe (130) into which the refrigerant inlet pipe (130) is inserted into the circular cross section of the refrigerant inflow path (86) and one end (left end) leading to the refrigerant outflow hole (72) of the joint plate (25) and the other end (right end) A refrigerant outflow passage (87) having a circular cross section is formed in which the refrigerant outlet pipe (131) is inserted. When viewed from the right side (outside in the left-right direction), the refrigerant inlet path (86) of the joint member (30), the refrigerant inlet hole (71) of the joint plate (25), and the refrigerant inlet (62) of the right end member (24) are common. And the center of the refrigerant inflow path (86), the refrigerant inflow hole (71) and the refrigerant inlet (62) in the front-rear direction and the vertical direction is the inflow-side opening part (88). (See FIG. 7). When viewed from the right side (outside in the left-right direction), the refrigerant outlet path (87) of the joint member (30), the refrigerant outlet hole (72) of the joint plate (25), and the refrigerant outlet (63) of the right end member (24) Have a common outflow side opening portion (89), and the center of the refrigerant outflow path (87), the refrigerant outflow hole (72) and the refrigerant outlet (63) in the front-rear direction and in the vertical direction is the outflow side opening. It is located in part (89) (see also FIG. 7). The area of the inflow side opening portion (88) is ½ or more of the flow path cross-sectional area of the refrigerant inlet pipe (130) connected to the joint member (30), and the area of the outflow side opening portion (89) is It is preferable that the flow passage cross-sectional area of the refrigerant outlet pipe (131) connected to the joint member (30) is ½ or more.

  Annular protrusions (91) and (92) are integrally formed over the entire periphery of the portion around the opening of the refrigerant inflow passage (86) and the refrigerant outflow passage (87) on the left side surface of the joint member (30). . Both annular protrusions (91) and (92) are spaced apart from each other, and a short-circuit prevention space (93) with both upper and lower ends opened is formed between both annular protrusions (91) and (92). ing. Portions surrounded by the annular protrusions (91) and (92) are also part of the refrigerant inflow passage (86) and the refrigerant outflow passage (87). On the inner peripheral surfaces of the annular protrusions (91) and (92) of the joint member (30), that is, on the inner peripheral surfaces of the left ends of the refrigerant inflow passage (86) and the refrigerant outflow passage (87), annular protrusions (94) (95 ) (Engagement part) is integrally formed over the entire circumference, and is formed at the tip of the short cylindrical part (69) (70) of the joint plate (25) on these annular protrusions (94) (95) The expanded pipe portions (69a) and (70a) thus engaged are engaged. Furthermore, on the right side surface of the joint member (30), screw holes (96) are formed at both upper and lower ends of the portion between the refrigerant inflow passage (86) and the refrigerant outflow passage (87).

  As shown in FIGS. 2, 3, 11 and 12, the refrigerant turn header tank (3) is formed of an aluminum brazing sheet having a brazing filler metal layer on both sides and all the heat exchange tubes (15) are connected. A plate-shaped first member (81), a second member (82) made of a bare material formed from an extruded aluminum material and covering the lower side of the first member (81), and a brazing material layer on both sides Aluminum left and right end members (83) and (84) formed of an aluminum brazing sheet having both ends and brazed to both left and right ends of both members (81) and (82), and a first intermediate on the outer surface of the right end member (84) It consists of a communicating member (85) made of aluminum bare material that is brazed so as to straddle the header portion (11) and the second intermediate header portion (12), and the first through the communicating member (85). The intermediate header portion (11) and the second intermediate header portion (12) communicate with each other at the right end.

  The first member (81) has the same shape as the first member (21) of the refrigerant inlet / outlet header tank (2), and both the members (21) (81) are arranged upside down. In the first member (81) of the refrigerant turn header tank (3), the same parts as those of the first member (21) of the refrigerant inlet / outlet tank (2) are denoted by the same reference numerals and description thereof is omitted. Both side surfaces are moved upward by the rear side wall (32) of the first header forming part (26) of the first member (81), the front side wall (35) of the second header forming part (27) and the connecting wall (28). A drainage basin (14) inclined outward in the front-rear direction is formed. The connecting portion (13) side end portion of the tube insertion hole (36) formed in both header forming portions (26) and (27) of the first member (81), that is, the tube insertion hole of the first header forming portion (26). The rear end portion of (36) and the front end portion of the pipe insertion hole (36) of the second header forming portion (27) are located on the side surface of the drainage basin (14). The front end of the pipe insertion hole (36) of the first header forming part (26) is connected to the inclined part (31a) of the front side wall (31) and the pipe insertion hole (36) of the second header forming part (87). The rear end portions are respectively located on the inclined portions (34a) of the rear side wall (34). From the intermediate part of the inclined part (31a) of the front side wall (31) of the outer surface of the first header forming part (26) to the lower end of the vertical part (31b) and the outer side of the rear side wall (34) of the second header forming part (27) From the middle part of the inclined part (34a) to the lower end of the vertical part (34b), a drainage groove that continues to the outer end part in the front-rear direction of the pipe insertion hole (36) and gradually goes downward as it moves away from the pipe insertion hole (36). (97) is formed. The lower end portions of the heat exchange pipes (15) of the front and rear heat exchange pipe groups (16) of the heat exchange core part (4) are inserted into the pipe insertion holes (36) of both header forming parts (26), (27), The first member (81) is brazed to the first member (81) using the brazing material layer of the first member (81), so that the lower end of the heat exchange pipe (15) of the front heat exchange pipe group (16) is the first part. The lower end portion of the heat exchange pipe (15) of the rear heat exchange pipe group (16) is connected to the intermediate header section (11) in communication with the second intermediate header section (12).

  The second member (82) is substantially the same shape as the second member (22) of the refrigerant inlet / outlet header tank (2), and is formed of the same extruded profile. Both members (82) (22) are It is arranged upside down. The difference between the second member (82) of the refrigerant turn header tank (3) and the second member (22) of the refrigerant inlet / outlet header tank (2) is that the first diversion control wall (41) is entirely cut off. In addition to the oblong refrigerant passage holes (46A) and (46B), a plurality of circular refrigerant passage holes (98) are spaced apart in the left-right direction at the rear portion of the second diversion control wall (42). The gap between adjacent circular refrigerant passage holes (98) gradually increases as the distance from the right end portion increases. The intervals between adjacent circular refrigerant passage holes (98) may all be equal. In the first member (81) of the refrigerant turn header tank (3), the same parts as those of the first member (21) of the refrigerant inlet / outlet tank (2) are denoted by the same reference numerals and description thereof is omitted. The second intermediate header portion (12) is partitioned into two upper and lower spaces (12a) and (12b) by the second diversion control wall (42b).

  The first member (81) and the second member (82) are brazed in the same manner as the first member (21) and the second member (22) of the refrigerant inlet / outlet header tank (2).

  Then, a hollow first intermediate header portion body (both ends opened) by the first header forming portion (26) of the first member (81) and the first header forming portion (41) of the second member (82). 107), and a hollow second intermediate portion having both ends opened by the second header forming portion (27) of the first member (81) and the second header forming portion (42) of the second member (82). A header body (108) is formed.

  The left end member (83) includes a front cap (83a) for closing the left end opening of the first intermediate header body (107), and a rear cap (83b) for closing the left end opening of the second intermediate header body (108). Is integrated through a connecting portion (83c), and a right protruding portion (152) that is fitted into the first intermediate header body (107) is integrally formed on the front cap (83a). Similarly, the rear cap (83b) has an upper right protrusion (154) fitted into the space (12a) above the flow dividing control wall (102b) of the second intermediate header body (108), A lower right projecting portion (153) fitted into the space (12b) below the flow dividing control wall (102b) is integrally formed with a space in the vertical direction. Further, at the connecting portion between the front and rear side edges and the upper and lower edges of the left end member (83), there are engaging claws (155) that protrude to the right and engage with both members (81) and (82). It is integrally formed. The left end member (83) is brazed to both members (81) and (82) using its own brazing material layer.

  The right end member (84) includes a front cap (84a) that closes the right end opening of the first intermediate header portion main body (107), and a rear cap (84b) that closes the right end opening of the second intermediate header portion main body (108). Is integrated through a connecting portion (84c), and a left protruding portion (114) that is fitted into the first intermediate header body (107) is formed integrally with the front cap (84a). Similarly, the rear cap (84b) has an upper left protrusion (115) fitted into the space (12a) above the flow dividing control wall (42b) of the second intermediate header body (108), A lower left protrusion (116) that is fitted into the space (12b) below the flow dividing control wall (42b) is integrally formed with a space in the vertical direction. Also, at the connecting portion between the front and rear side edges and the upper and lower edges of the right end member (84), there are engaging claws (117) that protrude to the left and engage with both members (81) and (82). It is integrally formed. In addition, at the front and rear ends of the upper edge of the right end member (84), there are engaging claws (118) that protrude to the right and are bent downward and engaged with the upper edge of the communication member (85). Engagement formed integrally with the lower edge of the lower end of the right end member (84), protruding rightward and bent upward and engaged with the lower edge of the communication member (85) The claw (118) is integrally formed. In FIG. 10, the engaging claw (118) is shown in a straight state on the right before being bent. A refrigerant outlet (119) is formed on the protruding end wall of the left protruding portion (114) of the front cap (84a) of the right end member (84) to allow the refrigerant to flow out from the first intermediate header portion (11). The refrigerant flows into the protruding end wall of the lower left protruding portion (116) of the cap (84b) into the space (12b) below the flow dividing control wall (42b) of the second intermediate header portion (12). A refrigerant inlet (121) is formed. In addition, the lower left protruding portion (116) of the rear cap (84b) is inclined upward or inwardly toward the inner side of the second intermediate header (12) at the lower portion of the peripheral edge of the refrigerant inlet (121). The curved guide portion (122) is integrally formed. The right end member (84) is brazed to both members (81) and (82) using its own brazing material layer.

  The communicating member (85) is formed by pressing an aluminum bare material, and is a plate having the same shape and size as the right end member (84) when viewed from the right, and its peripheral edge is at the right end. The outer surface of the member (84) is brazed using the brazing material layer of the right end member (84). The communication member (85) is formed with an outward bulging portion (123) so as to pass through the refrigerant outlet (119) and the refrigerant inlet (121) of the right end member (84). Further, a notch (124) into which the engaging claw (118) of the right end member (84) is fitted is formed at both the front and rear end portions of the upper edge of the communication member (85) and the center portion of the lower edge in the front and rear direction. Yes.

  Hereinafter, referring to FIG. 13 to FIG. 16 for a method of combining the right end member (24), the joint plate (25), and the joint member (30) of the refrigerant inlet / outlet header tank (2) when the evaporator (1) is manufactured. To explain.

  First, as shown in FIG. 13, a right end member (24), a joint plate (25), and a joint member (30) are prepared. At this stage, the joint plate (25) has a straight short cylindrical portion (69A) (70A) and a protruding portion (76A) inclined diagonally to the left.

  Then, as shown in FIG. 14 (a), straight short cylindrical portions (69A) (70A) around the refrigerant inflow hole (71) and the refrigerant outflow hole (72) in the joint plate (25) are respectively connected to the joints. The member (30) is inserted into the refrigerant inflow path (86) and the refrigerant outflow path (87). Next, the tip of the short cylindrical portion (69A) (70A) is expanded to form the expanded portion (69a) (70a), and the expanded portion (69a) (70a) is connected to the refrigerant inflow path (30) of the joint member (30). 86) and the annular projections (94) and (95) on the inner peripheral surface of the refrigerant outflow passage (87), thereby temporarily fixing the joint plate (25) and the joint member (30) (FIG. 14B). )reference).

  Next, as shown in FIG. 15 (a), the joint plate (25) temporarily fixed to the joint member (30) is set in a vertical state, and the engaging male part (68) of the right end member (24) is left-slanted. Pass through the through hole (74) on the joint plate (25) from below. When the engaging male part (68) of the right end member (24) is passed through the through hole (74) on the joint plate (25), the relative positional relationship between them is as shown in FIG. 15 (a). For example, the right end member (24) may be in a vertical state.

  Next, the right end member (24) is rotated counterclockwise in FIG. 15 (a) to be in a vertical state, and the front and rear protrusions (76A) protruding diagonally to the left of the joint plate (25) are connected to the right end member (76A). The front cap (24a) and the rear cap (24b) of 24) are fitted into the notches (67) of the downward projecting pieces (65) and (66) (see FIG. 15 (b)). As a result, the engaging male part (68) of the right end member (24) is engaged with the engaging female part (78) in a state of being inserted from below into the engaging female part (78) of the joint plate (25). Then, the engaging female portion (78) of the joint plate (25) is engaged with the front and rear side portions of the engaging male portion (68) at the upper end of the connecting portion (24c) of the right end member (24).

  Thereafter, the protrusion (76A) is bent in the clockwise direction in FIG. 15 (b) to be in a horizontal state to form a protrusion (76) extending in the left-right direction, and the left end of the protrusion (76) is connected to both caps (24a ) (24b) projecting to the left of the downward projecting pieces (65) and (66), and the engaging claw (77) on the inner side in the left-right direction of the projecting pieces (65) and (66) of the right end member (24) Engage with the front and rear sides of the notch (67) on the surface facing the. Thus, the joint plate (25) is engaged with the right end member (24) so as not to move in the left-right direction, the up-down direction, and the front-rear direction with respect to the right end member (24) (see FIGS. 15C and 16). . Thus, the right end member (24), the joint plate (25), and the joint member (30) are temporarily fixed.

  In manufacturing the evaporator (1), the right end member (24), the joint plate (25) and the joint member (30) are temporarily fixed to the right end member (24), and then the front cap (24a) of the right end member (24) is attached. The upper and lower left protrusions (57) and (58) are connected to the first header forming part (26) of the members (21) and (22) forming the refrigerant inlet / outlet tank (2) above the inlet header part (5). (41) and the upper and lower left projecting portions (59), (61) of the rear cap (24b) are fitted into the two members (21, 22). ) Is inserted into the space on both the upper and lower sides of the second diversion control wall (42b) between the second header forming portions (27) and (42), and the upper engaging claw (64) of the right end member (24) is Engage with both header forming portions (41) and (42) of one member (22) and lower engaging claws (64) on both header forming portions (26) and (27) of the first member (21). By engaging, the right end member (24), joint plate (25) and joint member (30) are both parts. Temporarily secured to the materials (21) and (22).

  Instead, the right end member (24) is temporarily fixed to the two members (21) and (22) that form the refrigerant inlet / outlet tank (2) first, and then the right end member (24) by the method described above. Alternatively, the temporary fixing bodies of the joint plate (25) and the joint member (30) may be combined.

  The evaporator (1) constitutes a refrigeration cycle that uses a chlorofluorocarbon refrigerant together with a compressor and a condenser as a refrigerant cooler, and is mounted on a vehicle such as an automobile as a car air conditioner.

  As shown in FIGS. 17 and 18, the detachable connection of the refrigerant inlet pipe (130) and the refrigerant outlet pipe (131) to the joint member (30) of the evaporator (1) described above is performed as follows. Is called.

  First, a pipe fixing member (140) to which the refrigerant inlet pipe (130) and the refrigerant outlet pipe (131) are fixed is prepared. The leading ends of the refrigerant inlet pipe (130) and the refrigerant outlet pipe (131) are slightly larger in diameter than the other parts, respectively, and annular grooves are respectively formed on the outer peripheral surfaces of these large diameter parts (130a) (131a). (134) (135) are formed over the entire circumference. An O-ring (136) is mounted in each annular groove (134) (135). The pipe fixing member (140) has two pipe insertion holes through which the small diameter parts (130b) (131b) excluding the large diameter parts (130a) (131a) of the refrigerant inlet pipe (130) and the refrigerant outlet pipe (131) are passed. (141) (142) and both pipe insertion holes (141) (having through holes (143) formed at both upper and lower ends of the portion between 142 and through which the male screw component (144) passes. Pipe fixing member Large diameter portions (141b) and (142b) are formed at the right end portions of both pipe insertion holes (141) and (142) in (140) via step portions (141a) and (142a), respectively. (130) and the refrigerant outlet pipe (131) are respectively passed through both pipe insertion holes (141) and (142) of the pipe fixing member (140) and expanded, and an annular bead is attached to the small diameter part (130b) (131b). (145) and (146) are formed and press-fitted into the large diameter portions (141b) and (142b), thereby being fixed to the tube fixing member (140).

  Then, the large diameter portion (130a) of the refrigerant inlet pipe (130) fixed to the pipe fixing member (140) and the large diameter portion (131a) of the refrigerant outlet pipe (131) are respectively supplied to the refrigerant in the joint member (30). Insert into the right end of the passage (86) and the refrigerant outflow passage (87). Thereafter, the male screw part (144) passed through the through hole (143) of the pipe fixing member (140) is screwed into the screw hole (96) of the joint member (30). Thus, the refrigerant inlet pipe (130) and the refrigerant outlet pipe (131) are detachably connected to the joint member (30) of the evaporator (1).

  In the evaporator (1) described above, the gas-liquid mixed phase two-phase refrigerant that has passed through the compressor, the condenser, and the expansion valve flows from the refrigerant inlet pipe (130) to the refrigerant inflow path (86) of the joint member (30), the joint plate The upper space of the refrigerant inlet header portion (5) of the refrigerant inlet / outlet header tank (2) through the refrigerant inlet hole (71) of (25) and the refrigerant inlet (62) of the front cap (24a) of the right end member (24) Enter (5a). The refrigerant that has entered the upper space (5a) of the refrigerant inlet header (5) flows to the left, enters the lower space (5b) through the communication hole (56), and passes through the flow dividing adjustment hole (45). Enter the lower space (5b).

  The refrigerant entering the lower space (5b) is divided and flows into the refrigerant passage of the heat exchange pipe (15) of the front heat exchange pipe group (16). The refrigerant flowing into the refrigerant passage of the heat exchange pipe (15) flows downward in the refrigerant passage and enters the first intermediate header portion (11) of the refrigerant turn header tank (3). The refrigerant that has entered the first intermediate header portion (11) flows to the right, the refrigerant outlet (119) of the front cap (84a) of the right end member (84), and the outward bulge portion of the communication member (85) ( 123) and the refrigerant inlet (121) of the rear cap (84b) through the communication passage in the rear cap (84b) to turn so as to change the flow direction and enter the lower space (12b) of the second intermediate header (12). .

  The refrigerant that has entered the lower space (12b) flows to the left, passes through the refrigerant passage hole (98), and enters the upper space (12a). The refrigerant entering the upper space (12a) is divided and flows into the refrigerant passage of the heat exchange pipe (15) of the rear heat exchange pipe (16).

  The refrigerant flowing into the refrigerant passage of the heat exchange pipe (15) changes the flow direction, flows upward in the refrigerant passage, enters the lower space (6b) of the refrigerant outlet header (6), and performs the second shunt control. It enters the upper space (6a) through the oblong coolant passage holes (46A) and (46B) in the wall (42b).

  Next, the refrigerant that has entered the upper space (6a) of the refrigerant outlet header section (6) passes through the refrigerant outlet (63) of the rear cap (24b) of the right end member (24) and the refrigerant outlet hole of the joint plate (25) ( 72) and the refrigerant outlet passage (87) of the joint member (30), and then flows out to the refrigerant outlet pipe (131).

  Then, while the refrigerant flows through the refrigerant passage of the front heat exchange pipe (15) and the refrigerant passage of the rear heat exchange pipe (15), air and heat passing through the ventilation gap of the heat exchange core section (4). After replacement, the refrigerant flows out as a gas phase.

In the above embodiment, the heat exchanger according to the present invention is applied to an evaporator of a car air conditioner using a chlorofluorocarbon refrigerant, but is not limited to this, a compressor, a gas cooler as a refrigerant cooler, In a vehicle having a car air conditioner having an intermediate heat exchanger, an expansion valve and an evaporator and using a supercritical refrigerant such as a CO ₂ refrigerant, for example, an automobile, it may be applied to an evaporator of a car air conditioner.

1 is a partially cutaway perspective view showing an overall configuration of an evaporator according to the present invention. It is the vertical sectional view which omitted the middle part at the time of seeing the evaporator shown in Drawing 1 from back. It is the AA line expanded sectional view of Drawing 2 which omitted some. It is a disassembled perspective view of the part of the header tank for refrigerant | coolant in / out of the evaporator shown in FIG. FIG. 3 is a sectional view taken along line B-B in FIG. 2. FIG. 6 is an enlarged sectional view taken along the line CC of FIG. 5. FIG. 6 is an enlarged sectional view taken along line D-D in FIG. 5. FIG. 9 is a cross-sectional view taken along line EE in FIG. 7. It is a perspective view of the joint plate before combining with the right end member. It is the elements on larger scale of FIG. It is a disassembled perspective view of the header tank for refrigerant | coolant turns of the evaporator shown in FIG. It is the FF sectional view taken on the line of FIG. It is a perspective view which shows the right end member, joint plate, and coupling member which are used when combining components in manufacturing an evaporator. It is a vertical sectional view which shows the method of combining a joint plate and a coupling member in manufacturing an evaporator. It is a vertical sectional view which shows the method of combining the right end member and the temporary fixing body of a joint plate and a joint member in manufacturing an evaporator. It is a partially cutaway perspective view which shows the state which combined the right end member, the joint plate, and the coupling member in manufacturing an evaporator. It is a disassembled perspective view which shows the method of connecting a refrigerant | coolant inlet pipe and a refrigerant | coolant outlet pipe | tube to the coupling member of an evaporator. It is a partial expanded horizontal sectional view which shows the state which connected the refrigerant | coolant inlet pipe and the refrigerant | coolant outlet pipe to the coupling member of the evaporator.

(1): Evaporator
(2): Header tank for refrigerant entry / exit
(3): Header tank for refrigerant turn
(4): Heat exchange core
(5): Refrigerant inlet header
(6): Refrigerant outlet header
(11): First intermediate header
(12): Second intermediate header
(15): Heat exchange pipe
(16): Heat exchange tube group
(17): Corrugated fin
(50): Inlet header body
(51): Outlet header body
(23): Left end member
(23a) (23b): Cap
(24): Right end member
(24a) (24b): Cap
(24c): Connection part
(25): Joint plate
(30): Fitting member
(62): Refrigerant inlet
(63): Refrigerant outlet
(65) (66): downward projecting piece
(67): Notch
(69) (69A): Short cylindrical part
(69a): Expanded part
(70) (70A): Short cylindrical part
(70a): Expansion section
(71): Refrigerant inflow hole
(72): Refrigerant outflow hole
(76) (76A): Projection
(77): Engagement claw
(79) (80): Slit
(86): Refrigerant inflow path
(87): Refrigerant outflow path
(88): Inlet side opening
(89): Outflow side opening
(91) (92): Annular protrusion
(93): Space for preventing short circuit
(94) (95): Annular projection (engagement part)
(130): Refrigerant inlet pipe
(131): Refrigerant outlet pipe

Claims (8)

A refrigerant inlet comprising a refrigerant inlet / outlet header tank having a refrigerant inlet header portion and a refrigerant outlet header portion that are arranged side by side in the front-rear direction, and a refrigerant circulation path that passes through the refrigerant inlet header portion and the refrigerant outlet header portion. header section, at least one end is brazed consists cap for closing the opening of the inlet header section body has open ends of the hollow inlet header section body and the inlet header section body which is open, the refrigerant outlet header section, at least It consists cap for closing the opening of the outlet header section body the same end and the opening of the inlet header body is brazed to the open end of the hollow outlet header section main body and the outlet header section body which is open, the inlet header section The main body, the outlet header section main body and the cap form a refrigerant inlet / outlet header tank, and the inlet header section main body and the outlet header section book Same end each through hole is formed in the brazed cap, the through hole of the a through hole of the inlet header of the cap, of the two through holes is made a refrigerant inlet, a refrigerant outlet header section of cap Is formed as a refrigerant outlet, and both caps having a refrigerant inlet and a refrigerant outlet are integrated via a connecting portion to form an end member, and a circular refrigerant inflow hole leading to the refrigerant inlet and a circular refrigerant outflow hole leading to the refrigerant outlet joint plate having found in the heat exchanger that is brazed to the end member so as to extend to the refrigerant inlet header and a refrigerant outlet header section,
The joint plate, joint member for connecting detachably the refrigerant inlet and the refrigerant outlet tube is brazed, the joint member, with one end communicating with the refrigerant inflow hole of the joint plate, the refrigerant inlet pipe in the other end a refrigerant inflow passage of circular cross section which is inserted, with one end communicating with the refrigerant outlet hole of the joint plate, and a refrigerant outflow channel of circular cross section in which the refrigerant outlet pipe is inserted is formed in the other end, the left-right direction outer When viewed from the above, the refrigerant inflow passage of the joint member, the refrigerant inflow hole of the joint plate, and the refrigerant inlet of the end member have a common inflow side opening, and the center in the front-rear direction and the vertical direction is the inflow When viewed from the outside in the left-right direction, the refrigerant outlet passage of the joint member, the refrigerant outlet hole of the joint plate, and the refrigerant outlet of the end member are located in the side opening portion. Together we have the outlet-side opening portion through the center of the front and rear direction and the vertical direction is positioned on the outlet side opening portion,
Around the refrigerant inflow hole and the refrigerant outflow hole of the joint plate, a cylindrical part is formed that protrudes outward in the left-right direction and is inserted into the refrigerant inflow path and the refrigerant outflow path of the joint member. A pipe expanding part is formed at the tip, and an annular engagement part that engages the pipe expanding part at the tip of the tubular part of the joint plate projects inward over the entire circumference on the inner peripheral surfaces of the refrigerant inflow path and the refrigerant outflow path of the joint member. The joint member is formed in a joint plate in a state where both cylindrical portions of the joint plate are inserted into the refrigerant inflow passage and the refrigerant outflow passage of the joint member and the expanded pipe portion is engaged with the annular engagement portion. A heat exchanger that is brazed . The area of the inflow side opening portion is ½ or more of the flow path cross-sectional area of the refrigerant inlet pipe connected to the joint member, and the area of the outflow side opening portion of the refrigerant outlet pipe connected to the joint member The heat exchanger according to claim 1, wherein the heat exchanger has a flow path cross-sectional area of ½ or more. The end member is provided with a downward projecting piece projecting downward from the outer shape of the refrigerant inlet / outlet header tank, a notch is formed at the lower edge of the downward projecting piece, and the end plate of the end member passes through the notch. A protrusion that protrudes inward in the left-right direction is formed, and a front end of the protrusion engages with at least one of the front and rear sides of the cutout in the surface facing the inner side in the left-right direction of the protruding piece of the end member. The heat exchanger according to claim 1 or 2, wherein a fingernail is formed. Each of the caps of the inlet header portion and the outlet header portion of the end member is provided with a downward projecting piece, a notch is formed in each downward projecting piece, and a projecting portion and an engaging claw are respectively provided at the front and rear end portions of the joint plate. The heat exchanger according to claim 3 formed. The heat exchanger according to any one of claims 1 to 4, wherein a plurality of slits are formed in the cylindrical portion of the joint plate from the tip thereof at intervals in the circumferential direction . The heat exchange according to any one of claims 1 to 5, wherein a short-circuit prevention space having upper and lower ends opened is formed in a portion between the refrigerant inflow path and the refrigerant outflow path on the inner surface in the left-right direction of the joint member. vessel. An annular protrusion projecting toward the joint plate side is formed at a distance from each other in a portion around the opening of the refrigerant inflow path and the refrigerant outflow path on the inner surface in the left-right direction of the joint member. The heat exchanger according to claim 6, wherein the portion is a space for preventing a short circuit . The refrigerant circulation path is disposed at a distance from the refrigerant inlet / outlet header tank, and is opposed to the first intermediate header part and the refrigerant outlet header part facing the refrigerant inlet header part, and communicated with the first intermediate header tank. A refrigerant turn header tank having an intermediate header portion and a heat exchange core portion formed between both header tanks are provided, and the heat exchange core portions are arranged at intervals in the length direction of both header tanks. The heat exchange pipe group is composed of a plurality of heat exchange pipes whose both ends are connected to both header tanks, and fins arranged between adjacent heat exchange pipes. The exchange pipe groups are arranged side by side in the ventilation direction, and the heat exchange pipes of at least one heat exchange pipe group are connected to the refrigerant inlet header part and the first intermediate header part, and the refrigerant outlet header part and the second intermediate header part, respectively. A heat exchanger according to any one of claims 1 to 7 are.

Images