JP2008170140A - Heat exchanger for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve a layout property and manufacturability by reducing a size of a tank while maintaining its strength. <P>SOLUTION: A refrigerant water cooling part 3 is housed inside a cooling water tank 23 for performing heat exchange between cooling water and a refrigerant. In the refrigerant water cooling part 3, a first refrigerant tank is communicated with an inner passage when one end part of a refrigerant flat tube 33 is inserted, while a second refrigerant tank is communicated with the inner passage when the other end part of the refrigerant flat tube 33 is inserted. In each of these refrigerant tanks, an outline of a cross sectional shape of the passage inside the tank has a circular arc shape, and the width L of the passage inside the tank is set to be smaller than the width of the cross sectional longitudinal direction of the refrigerant flat tube 33. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention includes a vehicle including a first heat exchange unit that cools a first fluid that cools a first heating element, and a second heat exchange unit that cools a second fluid that cools a second heating element. It relates to a heat exchanger.

For example, Patent Document 1 discloses a first heat exchange unit that exchanges heat between cooling water that cools a vehicle drive device and air, and cooling water that is cooled by the first heat exchange unit. A heat exchanger is disclosed that includes second heat exchanging means for exchanging heat with a refrigerant discharged from a compressor of an air conditioning system of a vehicle. Here, the cooling water cooled by the first heat exchange means flows into the cooling water tank, and is supplied to the vehicle drive device side through this cooling water tank. The second heat exchanging means described above is built in a cooling water tank into which cooling water flows and is composed of a flat tube in which an internal passage for the refrigerant is formed. A refrigerant tank into which the refrigerant flows and a refrigerant tank into which the refrigerant flowing through the flat tube flows are provided.
JP 2006-162176 A

  However, according to the technique disclosed in Patent Document 1, since the high-temperature and high-pressure refrigerant flows from the compressor side, it is necessary to ensure the strength of the refrigerant tank. There is a risk of increasing the size of the refrigerant tank. In the engine room, a plurality of heat exchangers are arranged adjacent to each other, such as a condenser for cooling the air-conditioning refrigerant and a radiator for cooling the engine. Therefore, when the refrigerant tank is enlarged, there are problems that the gaps between the plurality of heat exchangers are enlarged, and the refrigerant tank is larger than the outer shape of the heat exchanger, which is disadvantageous in terms of layout. Moreover, since the enlargement of the refrigerant tank increases its heat capacity, there is a risk that brazing will deteriorate when the components are joined. Furthermore, the joining shape is complicated, and the brazing property is often worsened.

  The present invention has been made in view of such circumstances, and the object thereof is to improve the layout and the manufacturability by reducing the size of the tank while ensuring the strength of the tank. That is.

  A vehicle heat exchanger according to claim 1 of the present invention includes a first heat exchange unit that cools cooling water that cools a drive unit, and a second heat exchange unit that cools a refrigerant used in an air conditioning system. It is a heat exchanger for vehicles containing. This vehicle heat exchanger is a cooling system in which cooling water flows through cooling water heat exchanging means for exchanging heat between cooling water and air, and supplies cooling water contained therein to the drive unit side. A water tank and a refrigerant water cooling part that constitutes a part of a refrigerant passage through which air-conditioning refrigerant flows and that is built in the cooling water tank and exchanges heat between the cooling water and the refrigerant in the cooling water tank; Have Here, the refrigerant water cooling section is inserted with a plurality of flat tubes each having an internal passage for the refrigerant arranged in a stack, and one end of the flat tube is inserted. A first refrigerant tank that supplies refrigerant from the air conditioning system to each of the flat tubes via a passage in the tank that extends in the stacking direction of the flat tubes, and the other of the flat tubes. Is inserted into the internal passage and is supplied to the second heat exchange unit through the tank passages extending in the stacking direction of the flat tubes. And a second refrigerant tank. In this case, in the first refrigerant tank and the second refrigerant tank, the outline of the sectional shape of the passage in the tank has an arc shape, and the width of the passage in the tank is smaller than the width in the longitudinal direction of the cross section of the flat tube. Is set.

  Moreover, in the vehicle heat exchanger according to claim 2 of the present invention, each of the flat tubes is joined to the first refrigerant tank by brazing in a state where one end portion is abutted against the tank inner surface. And the other end is joined to the second refrigerant tank by brazing in a state of abutting against the inner surface of the tank.

  In the vehicle heat exchanger according to claim 3 of the present invention, the first refrigerant tank is joined to the upper part of the cooling water tank on the refrigerant inflow side by brazing, and the second refrigerant tank is It is joined by brazing to the lower part of the cooling water tank on the refrigerant outflow side.

  Further, in the vehicle heat exchanger according to claim 4 of the present invention, the refrigerant water cooling section is between the refrigerant discharged from the compressor in the air conditioning system and the cooling water cooled in the first heat exchange unit. Perform heat exchange at.

  In the vehicle heat exchanger according to claim 5 of the present invention, the cooling water tank is joined to the refrigerant tank of the second heat exchange unit into which the refrigerant flows through the refrigerant water cooling section by brazing.

  Further, in the vehicle heat exchanger according to claim 6 of the present invention, the refrigerant water cooling section is configured such that the width of the refrigerant heat exchange means in the stacking direction of the flat tubes is set to be equal to or less than the width of the cooling water heat exchange means. Yes.

  The vehicle heat exchanger according to claim 7 of the present invention cools the first heat exchange unit that cools the first fluid that cools the first heating element, and the second fluid that cools the second heating element. It is a heat exchanger for vehicles containing the 2nd heat exchange unit which carries out. The vehicle heat exchanger constitutes a part of a first heat exchange unit, a first fluid tank into which a first fluid flows, and a part of a second fluid passage through which a second fluid flows, A second fluid cooling section built in the first fluid tank and exchanging heat between the first fluid and the second fluid in the first fluid tank. A plurality of flat tubes each having an internal passage for the second fluid are communicated with the internal passage by inserting one end of the flat fluid into the second fluid heat exchanging means configured in a stacked manner. The second fluid tank on the upstream side for supplying the second fluid to each of the flat tubes and the other end of the flat tube are inserted via a passage in the tank extending in the stacking direction of the flat tubes. It communicates with the internal passage, and in the stacking direction of flat tubes A second fluid tank on the downstream side that supplies the second fluid that has flowed through each of the flat tubes to the second heat exchange unit side via the extending tank passage. Here, in the second fluid tank on the upstream side and the second fluid tank on the downstream side, the outline of the sectional shape of the passage in the tank has an arc shape, and the width of the passage in the tank is in the longitudinal direction of the section of the flat tube. It is set smaller than the width.

  Further, in the vehicle heat exchanger according to claim 8 of the present invention, the first fluid tank is supplied with cooling water through the first fluid heat exchanging means for exchanging heat between the first fluid and the air. In addition, the cooling water accommodated in the interior is supplied to the first heating element side, and the second fluid cooling unit exchanges the second fluid that has been heat-exchanged with the first fluid into the second heat exchange. Supply to the unit side.

  The vehicle heat exchanger according to claim 9 of the present invention cools the first heat exchange unit that cools the first fluid that cools the first heating element, and the second fluid that cools the second heating element. It is a heat exchanger for vehicles containing the 2nd heat exchange unit which carries out. The vehicle heat exchanger includes a first fluid tank into which a first fluid flows and a part of a second fluid passage through which a second fluid flows, and is connected to the first fluid tank. A second fluid cooling unit that exchanges heat between the first fluid and the second fluid supplied from the tank; The second fluid cooling section is composed of a plurality of plate-like plates that are stacked such that the inflow direction of the first fluid from the first fluid tank and the plate surface are orthogonal to each other, and a pair of adjacent plates are adjacent to each other. The clearance between the plates is formed as a fluid passage, and the first passage through which the second fluid flows and the second passage through which the first fluid flows are alternately set.

  In the vehicle heat exchanger according to claim 10 of the present invention, the first fluid tank constitutes a part of the first heat exchange unit, and performs heat exchange between the first fluid and air. The first fluid flows through the first fluid heat exchanging means to be performed, and each of the second passages constitutes a passage through which the first fluid from the first fluid tank flows to the first heating element side. The first passage constitutes a passage through which the second fluid flows to the second heat exchange unit side.

  Further, in the vehicle heat exchanger according to claim 11 of the present invention, the first fluid tank has a housing shape in which a surface facing the cooling water inflow surface from the first fluid heat exchange means is opened. And the peripheral edge of the opening and the peripheral edge of the second fluid cooling part are joined by brazing.

  In the vehicle heat exchanger according to claim 12 of the present invention, the second fluid cooling section flows in a direction in which the first fluid and the second fluid face each other.

  Moreover, the vehicle heat exchanger concerning Claim 13 of this invention WHEREIN: As for the 2nd fluid cooling part, the inner fin is installed in the 1st channel | path.

  In the vehicle heat exchanger according to claim 14 of the present invention, the first fluid is cooling water for cooling the electronic component (1) for controlling the electric motor for the vehicle, and the second fluid is the air conditioning system. It is a refrigerant used for

  According to the vehicle heat exchanger according to claim 1 of the present invention, the strength against the internal pressure is improved in the first and second refrigerant tanks, and accordingly, the plates constituting the tank can be made thinner. . Therefore, the vertical dimension of the first and second tanks can be reduced. In addition, the first and second refrigerant tanks have a small difference in heat capacity with peripheral components, and can improve brazing performance. Therefore, it is possible to reduce the size of the tank while securing the strength of the tank, improving the layout and improving the manufacturability.

  According to the vehicle heat exchanger according to claim 2 of the present invention, the strength of the connection portion between the flat tube and the first and second refrigerant tanks is further improved.

  According to the vehicle heat exchanger according to claim 3 of the present invention, the flow of the cooling water in the cooling water tank is guided to the refrigerant heat exchanging means side located between the first and second refrigerant tanks. The disadvantage that the cooling water bypasses the refrigerant heat exchanging means can be suppressed.

  According to the vehicle heat exchanger according to claim 4 of the present invention, the cooling of the refrigerant by the cooling water has a large temperature difference between the fluids, uses only an efficient part, and uses the second heat exchange unit in combination. Therefore, the enlargement of the first heat exchange unit and the coolant cooling unit can be suppressed.

  According to the vehicle heat exchanger according to claim 5 of the present invention, the coupling between the first heat exchange unit and the second heat exchange unit can be easily strengthened, and a coupling bracket or the like is not required. Therefore, the configuration can be simplified.

  According to the vehicle heat exchanger according to claim 6 of the present invention, it is possible to suppress that the thickness of the downstream cooling water tank in the first heat exchange unit is larger than that of the upstream cooling water tank. It is possible to improve the performance.

  According to the vehicle heat exchanger according to claim 7 of the present invention, the strength against the internal pressure is improved in the upstream and downstream second fluid tanks, and accordingly, the plate constituting the tank can be thinned. It becomes. Therefore, the vertical dimension of the upstream and downstream second fluid tanks can be reduced. Further, the second fluid tanks on the upstream side and the downstream side have a smaller heat capacity difference from the peripheral parts, and the brazing performance can be improved. Therefore, it is possible to reduce the size of the tank while securing the strength of the tank, improving the layout and improving the manufacturability.

  According to the vehicle heat exchanger of claim 8 of the present invention, the temperature difference between the first fluid and the second fluid is large, and only the efficient part is used, and the second heat exchange unit is used in combination. Thus, an increase in the size of the system configuration can be suppressed.

  According to the vehicle heat exchanger according to claim 9 of the present invention, the second refrigerant cooling section has a laminated structure of plates, so that the individual plates can be easily assembled. Therefore, it becomes easy to manage the clearance of the brazed portion, and the brazing performance is improved. For this reason, the second refrigerant cooling unit can be easily downsized, so that it is possible to prevent the entire system from becoming large.

  According to the vehicle heat exchanger according to claim 10 of the present invention, the second fluid cooling unit uses only an efficient part with a large temperature difference between the first fluid and the second fluid, As the whole system, since the second heat exchange unit is used in combination, an increase in the size of the system configuration can be suppressed.

  According to the vehicle heat exchanger of the eleventh aspect of the present invention, the first fluid tank and the second fluid cooling section can be integrated and configured, so that space saving can be achieved.

  According to the vehicle heat exchanger of claim 12 of the present invention, it is possible to improve the heat exchange efficiency between the first fluid and the second fluid.

  According to the vehicle heat exchanger of the thirteenth aspect of the present invention, it is possible to further improve the heat exchange efficiency between the first fluid and the second fluid.

  According to the vehicle heat exchanger of the fourteenth aspect of the present invention, the second fluid cooling unit can effectively cool the refrigerant by water cooling, and the temperature difference between the cooling water and the refrigerant is large, so that the efficiency is high. Only the good part is used, and since the second system is used together with the second heat exchange unit, it is possible to suppress an increase in the size of the system configuration.

(First embodiment)
FIG. 1 is a block diagram conceptually showing a vehicle heat exchanger according to an embodiment of the present invention. In the present embodiment, the vehicle heat exchanger is applied to a hybrid vehicle that can travel with one or both of the driving force of the engine and the driving force of the electric motor.

  The vehicle heat exchanger according to this embodiment includes a sub-radiator 2 (first radiator) that cools cooling water that cools a drive unit (in this embodiment, an electric drive unit including an electric motor and electronic components for control). 1 heat exchange unit), a refrigerant water cooling unit 3 that primarily cools the refrigerant for the air conditioning system in the passenger compartment, and a condenser (second heat) that secondarily cools the refrigerant cooled in the refrigerant water cooling unit 3 The exchange unit 4 is mainly configured. As shown in FIG. 2, the sub-radiator 2 is disposed on the front side of the engine cooling radiator 5, that is, on the upstream side of the cooling air, and the capacitor 4 is disposed vertically below the sub-radiator 2. . The refrigerant water cooling unit 3 is built in the sub-radiator 2, and details thereof will be described later.

  Referring to FIG. 1 again, a passage is formed between the electric drive unit 1 and the sub-radiator 2 so that the cooling water circulates, and a circulation pump 6 for circulating the cooling water is provided in this passage. ing. By driving the circulation pump 6, the cooling water (C 1 in) from the electric drive unit 1 is supplied to the sub-radiator 2, and heat is exchanged with air in the sub-radiator 2. Cooling water (C1out) from the sub-radiator 2 is supplied to the electric drive unit 1.

  On the other hand, in the air conditioning system, the high-temperature and high-pressure gas refrigerant (C2in) compressed by the compressor is supplied to the refrigerant water cooling unit 3 and then supplied to the condenser 4. When heat exchange is performed in the refrigerant water cooling unit 3 and the condenser 4, the gas refrigerant becomes a high-pressure liquid refrigerant or a gas-liquid mixed refrigerant. The refrigerant (C2out) from the condenser 4 is gas-liquid separated in the liquid tank, and then adiabatic expansion is performed by the expansion means to form a low-temperature low-pressure liquid refrigerant or gas-liquid mixed refrigerant, and heat is exchanged with the air in the passenger compartment by the evaporator. After making the low-pressure gas refrigerant, it is returned to the compressor.

  FIG. 3 is a front view schematically showing the structure of the sub-radiator 2. The sub-radiator 2 is mainly composed of a core portion (cooling water heat exchanging means) composed of the radiation fins 20 and the cooling water flat tubes 21, a reinforcement 22, and a cooling water tank 23.

  The radiating fin 20 is a thin plate-like member having a width substantially the same as the width of a cooling water flat tube 21 described later, and is corrugated so that its front-view shape has a waveform as shown in FIG. . Moreover, the flat tube 21 for cooling water is an elongate plate-shaped member formed so that the cross-sectional shape may have a flat shape, for example, is formed from aluminum alloy. The cooling water flat tube 21 has a plurality of passages extending through the inside thereof along the longitudinal direction, and the cooling water flows through the individual passages. The core portion is configured by alternately laminating the radiating fins 20 and the cooling water flat tubes 21 by sandwiching the cooling water flat tubes 21 from both sides by a pair of radiating fins 20. Reinforces 22 are respectively installed on the outer sides of the radiating fins 20 positioned on the outermost side (upper and lower sides), and the core portion is in a state in which an appropriate amount of load is applied in the stacking direction by the pair of reinforcements 22. It is pinched. Each of the flat tubes 21 for cooling water constituting the core portion has one end inserted into the cooling water tank 23 on the upstream side and the other end inserted into the cooling water tank 23 on the downstream side. Thereby, the internal space of each cooling water tank 23 and the internal passage of the flat tube 21 for cooling water communicate.

  Although not shown in the figure, the basic configuration of the capacitor 4 is the same as that of the sub-radiator 2 and includes a core portion composed of heat radiation fins and a refrigerant flat tube, a reinforcement, and a refrigerant tank. Has been.

  FIG. 4 is a front view schematically showing the configuration of the refrigerant water cooling unit 3, and FIG. 5 is a side view schematically showing the configuration of the refrigerant water cooling unit 3. FIG. 6 is an exploded perspective view schematically showing the configuration of the upper side of the coolant cooling unit 3. The refrigerant water cooling unit 3 constitutes a part of the refrigerant passage between the compressor and the condenser 4 in the air conditioning system. This refrigerant water cooling unit 3 is built in the cooling water tank 23 on the downstream side of the sub-radiator 2, and performs heat exchange between the cooling water in the cooling water tank 23 and the refrigerant of the air conditioning system. As a premise of flowing into the condenser 4, the refrigerant is primarily cooled.

  Specifically, the refrigerant water cooling unit 3 includes an inflow side tank (first refrigerant tank), an outflow side tank (second refrigerant tank), and a core unit that exchanges heat between the refrigerant and the cooling water ( Refrigerant heat exchange means). An opening is provided in the upper portion of the cooling water tank 23 on the sub-radiator 2 side, and a cylindrical connector 25 connected to a refrigerant passage leading to the compressor side is fitted in this opening. The inflow side tank is disposed in the upper part of the cooling water tank 23, and a connector 25 protruding into the cooling water tank 23 is fitted therein. On the other hand, an opening is also provided in the lower part of the cooling water tank 23, and a cylindrical connector 25 connected to an upstream side refrigerant tank in the condenser 4 is fitted in this opening. The outflow side tank is disposed at the lower part of the cooling water tank 23 and is fitted with a connector 25 protruding into the cooling water tank 23. The core portion is provided between the inflow side tank and the outflow side tank.

  The inflow side tank is composed of a pair of tank plates 30 and 31 and a pair of patch ends 32, and supplies refrigerant from the compressor side to the core part side through a tank passage formed inside. . This inflow side tank is joined to the upper part of the cooling water tank 23 on the refrigerant inflow side by brazing.

  The first tank plate 30 is a flat plate having a substantially rectangular shape, and is disposed on the lower surface of the second tank plate 31 described later. The first tank plate 30 is formed with a slit-like opening 30 a extending in the flow direction of the cooling water in the cooling water tank 23. A plurality of the openings 30a are formed at a predetermined interval in a direction perpendicular to the flow direction of the cooling water. The shape of each opening 30a corresponds to the outer shape of the refrigerant flat tube 33 of the core portion described later. In the present embodiment, the width of the core portion in the direction orthogonal to the flow direction of the cooling water (that is, the overall width of the plurality of refrigerant flat tubes 33 arranged in a stacked manner) is the core portion of the sub-radiator 2. The number of the refrigerant flat tubes 33 is set to be equal to or less than the width (specifically, the width in the longitudinal direction of the cross section of the cooling water flat tube 21), and is formed in the first tank plate 30. The number of the openings 30a corresponds to the number of the refrigerant flat tubes 33.

  The second tank plate 31 is a plate-like member having a substantially rectangular shape corresponding to the outer peripheral shape of the first tank plate 30. The second tank plate 31 has a bent portion that is curved in a convex shape toward the connector 25 side in a central region thereof in a direction perpendicular to the flow direction of the cooling water. By this bent portion, the second tank plate 31 has a cross-sectional outline having an arc shape and a space extending in a direction orthogonal to the flow direction of the cooling water. This space functions as an in-tank passage for supplying the refrigerant to the core portion. The width (width in the flow direction of cooling water) L of the passage in the tank is set smaller than the width (width in the longitudinal direction of the cross section) of the refrigerant flat tube 33 described later.

  In addition, an opening is formed at a substantially central position at the top of the bent portion of the second tank plate 31, and the top is joined to the inner surface (upper inner surface) of the cooling water tank 23 so that the opening and the connector are connected. 25 is fitted. Further, an L-shaped engaging claw extending downward is provided at the edge of the second tank plate 31, and this engaging claw is provided on the lower surface side of the second tank plate 31. The first tank plate 30 disposed in close contact is held.

  The pair of patch ends 32 is disposed at the end of the opening region between the first tank plate 30 and the second tank plate 31 formed by the bent portion of the second tank plate 31, and passes through the tank passage. Occlude.

  The outflow side tank is composed of a pair of tank plates 30, 31 and a pair of patch ends 32, and the refrigerant from the core portion side is supplied to the upstream side of the condenser 4 through a tank passage formed inside. To a refrigerant tank (not shown). Note that the configuration of the outflow side tank is the same as that of the inflow side tank, and is provided in the cooling water tank 23 with the inflow side tank upside down. This outflow side tank is joined to the lower part of the cooling water tank 23 on the refrigerant outflow side by brazing.

  The core part is configured by a plurality of refrigerant flat tubes 33. Each of the refrigerant flat tubes 33 includes a flat holder 34 that extends in the vertical direction and has a hollow inside, and an inner fin 35 that is accommodated inside the holder 34. The refrigerant passage is configured in the above. The total length of the inner fin 35 is shorter than that of the holder 34. For this reason, both ends of the holder 34 are projected from both ends of the inner fin 35. Here, the projecting length of both end portions of the holder 34 projecting from both ends of the inner fin 35 is set to be equal to or less than the plate thickness of the second tank plate 31.

  One end of each of the refrigerant flat tubes 33 is inserted into the opening 30a of the first tank plate 30 in the inflow side tank, and abuts against the lower surface (tank inner surface) of the second tank plate 31. In a state of being joined, it is joined by brazing. The other end of each refrigerant flat tube 33 is inserted into the opening 30a of the first tank plate 30 in the inflow side tank, and the lower surface of the second tank plate 31 (the tank inner surface). It is joined by brazing in a state of being abutted against. Thereby, each flat tube 33 for refrigerant | coolants is laminated | stacked in the direction orthogonal to the flow direction of a cooling water in the state where the cross-sectional longitudinal direction is arrange | positioned in parallel with the flow direction of a cooling water.

  Each of the refrigerant flat tubes 33 (specifically, the holder 34) is formed with a bead 34a having a side surface partially protruding outward, and the adjacent refrigerant flat tubes 33 are connected to each other by the beads 34a. Joined by brazing in a butted state. Further, a bead 23a is formed on the inner peripheral surface of the cooling water tank 23 so that the inner peripheral surface is partially protruded inward, and the flattened tube 33 for refrigerant located on the outermost side is formed by itself. The bead 34a and the bead 23a on the cooling water tank 23 side are joined to each other by brazing. For this reason, at the time of brazing, if a load is applied from the outside of the cooling water tank 23, the holder 34 and the inner fins 35 can be joined in a closely contacted state.

  FIG. 7 is an exploded perspective view illustrating an assembled state of the sub radiator 2. In the assembly of the sub-radiator 2, the radiation fins 20 and the cooling water flat tubes 21 are alternately laminated, the reinforcement 22 is installed outside the outermost fins, and an appropriate amount of load is applied in the lamination direction. The cooling water flat tube 21 and the end of the reinforcement 22 are inserted into the upstream cooling water tank 23 and the downstream cooling water tank 23, respectively. The cooling water tank 23 on the downstream side has a detachable side surface 24 on the insertion side of the cooling water flat tube 21, and an inflow side tank, a core portion, and an outflow side tank are assembled therein. A coolant cooling unit 3 is incorporated. Further, in the cooling water tank 23, a connector 25 for connecting a refrigerant passage is inserted into openings provided in the upper and lower portions of the cooling water tank 23, and the side surface 24 on the insertion side of the cooling water flat tube 21 is further inserted. An opening is formed in a side surface facing the, and an outlet pipe 26 to which a cooling water passage leading to the electric drive unit 1 side is connected is fitted in this opening.

  The sub-radiator 2 in which the individual parts are assembled and the refrigerant water cooling part is built in is integrally heated via a brazing material provided in advance at the joint between these various parts by heating in a heating furnace. Brazing is performed. In addition, the refrigerant | coolant water cooling part 3 has a large heat capacity compared with another site | part, and integral brazing may become difficult. In this case, it is possible to perform brazing after assembling the coolant cooling unit 3 and a part of the cooling water tank 23 on the upstream side separately, and then assembling the sub radiator body and brazing. Good.

  In the vehicle heat exchanger having such a configuration, the cooling water that has cooled the electric drive unit 1 flows from an inlet provided in the cooling water tank 23 on the upstream side of the sub-radiator 2, and then each cooling water Flows through the flat tube 21 and flows into the cooling water tank 23 on the downstream side. In the process of flowing through the cooling water flat tubes 21, the cooling water is transferred from the cooling water flat tubes 21 to the radiating fins 20 and from the radiating fins 20 to the cooling air to perform heat exchange. The cooling water is cooled. The cooling water whose temperature has decreased flows between the individual refrigerant flat tubes 33 in the refrigerant water cooling section 3 in the cooling water tank 23 on the downstream side, and then flows out from the outlet pipe 26.

  Further, the refrigerant in the air conditioning system flows into the inflow side tank of the refrigerant water cooling unit 3 in the state of the high-temperature and high-pressure gas discharged from the compressor, and is dispersed from the flow side tank to each of the refrigerant flat tubes 33. In the process in which the refrigerant flows through the refrigerant passage of the refrigerant flat tube 33, the heat of the refrigerant is transferred from the refrigerant flat tube 33 to the cooling water, and the degree of superheat is reduced or in a partially saturated region. To the outflow side tank. Then, it flows from the outflow side tank to the refrigerant tank upstream of the condenser 4 via the connector 25.

  Normally, water cooling has higher heat transfer efficiency than air cooling, and downsizing is possible, but when the refrigerant is completely condensed with cooling water, the temperature difference between the refrigerant condensing temperature and the cooling water is small. Therefore, in order to cover all the cooling of the refrigerant by water cooling, the core part of the sub-radiator 2 and the refrigerant water cooling part 3 may be increased in size. However, in the present embodiment, the cooling of the refrigerant by water cooling has a large temperature difference between the fluids, and only the efficient part is used, and the condenser 4 is used in combination to suppress the sub radiator 2 and the refrigerant water cooling unit 3 from being enlarged. is doing.

  As described above, according to the present embodiment, in the refrigerant water cooling unit 3, the width L of the in-tank passage is made larger than the width of the refrigerant flat tube 33 from the viewpoint of reducing the bent portion in the central region of the second tank plate 31. A small value is set. Thereby, in the inflow and outflow side tanks, the strength against the internal pressure is improved, and the tank plates 30 and 31 can be made thinner accordingly. Therefore, the vertical dimension of the inflow side tank and the outflow side tank can be reduced. Therefore, it is possible to reduce the size of the tank while securing the strength of the tank, improving the layout and improving the manufacturability. In addition, when the vertical dimensions of the inflow side tank and the outflow side tank are reduced, the refrigerant flat tube 33 can be set longer, so that the efficiency of heat exchange can be improved.

  Further, the end of the refrigerant flat tube 33 is inserted into the opening 30 a of the first tank plate 30 and then joined to the lower surface of the second tank plate 31. Therefore, the strength of the connecting portion between the refrigerant flat tube 33 and the inflow side tank or the outflow side tank is further improved. In addition, since the inner fin 35 is set slightly shorter than the holder 34, the refrigerant passage can be secured even if the tip of the holder 34 abuts against the second tank plate 31. The inner fin 35 is shorter than the holder 34, and a portion where the inner fin 35 is not joined is generated at the tip of the holder 34. However, since the distance of the portion is equal to or less than the plate thickness of the first tank plate 30, it is reinforced by the plate thickness of the first tank plate 30 and the strength reduction can be suppressed.

  For example, as a configuration in which the coolant water cooling unit is built in the cooling water tank on the downstream side of the sub-radiator, a method of causing the coolant to flow into and out of the coolant water cooling unit 3 from the side surface corresponding to the upstream side of the cooling air can be considered. However, according to this method, the gap between the upper and lower sides of the core portion including the refrigerant flat tube and the cooling water tank becomes large, and the amount of cooling water that bypasses the refrigerant flat tube 33 by the gap. There is a disadvantage that will increase. In addition, since the refrigerant inflow / outflow direction is the forward direction, the refrigerant passage pipe jumps forward, resulting in an obstacle in layout.

  However, in the present embodiment, the inner wall of the cooling water tank 23 of the sub radiator 2 and the inflow side tank and the outflow side tank of the refrigerant water cooling unit 3 are joined by brazing. In addition, these tanks extend in a direction perpendicular to the flow direction of the cooling water and guide the flow of the cooling water to the core portion side, so that the disadvantage that the cooling water bypasses the core portion is suppressed. be able to. Further, in the inflow side tank and the outflow side tank, a bent portion is formed in the second tank plate 31, thereby constituting a passage in the tank for the refrigerant, so that the strength against the internal pressure of the tank is improved in shape. . Therefore, the thickness of the second tank plate 31 can be reduced. Further, when the thickness of the second tank plate 31 is reduced, the refrigerant water cooling unit 3 can be reduced in weight, and the heat capacity difference with the peripheral part such as the cooling water tank 23 of the sub radiator 2 is reduced, thereby improving the brazing performance. be able to. In addition, since the refrigerant can flow in and out of the cooling water tank 23, the refrigerant can be smoothly guided to the condenser 4 located below the sub-radiator 2, and the layout is advantageous. The appearance can also be made smart.

  Further, if the cooling water tank 23 on the downstream side of the sub-radiator 2 and the refrigerant tank on the upstream side of the condenser 4 are coupled by brazing, the coupling between the sub-radiator 2 and the condenser 4 can be easily strengthened and coupled. Therefore, the configuration can be simplified. Furthermore, it is also possible to share a patch end that closes each tank between the cooling water tank 23 of the sub-radiator 2 and the refrigerant tank upstream of the condenser 4.

  Further, in the refrigerant water cooling unit 3, the plurality of refrigerant flat tubes 33 constituting the refrigerant passage have a width in the entire stacking direction that is equal to or smaller than the width of the cooling water flat tube 21 in the sub radiator 2 (width in the longitudinal direction of the cross section). By doing so, it is possible to suppress the thickness of the cooling water tank 23 on the downstream side of the sub-radiator 2 from becoming larger than that of the cooling water tank 23 on the upstream side, thereby improving the layout.

(Second Embodiment)
FIG. 8 is a front view schematically showing the configuration of the refrigerant water cooling unit 3 in the second embodiment, and FIG. 9 is a side view schematically showing the configuration of the refrigerant water cooling unit 3 according to the second embodiment. It is. The refrigerant water cooling unit 3 according to the first embodiment is different from that according to the first embodiment in the shapes of the inflow side and outflow side tanks. In addition, about the same structure as 1st Embodiment, a referential mark is quoted and the overlapping description is abbreviate | omitted.

  Specifically, the refrigerant water cooling unit 3 according to the second embodiment includes an inflow side in which refrigerant from the compressor side flows in and an outflow in which refrigerant flows out to an upstream side refrigerant tank (not shown) in the condenser 4. It is comprised by the side tank and the core part (heat exchanger means for refrigerant | coolants) which performs heat exchange between a refrigerant | coolant and cooling water. An opening is provided in the upper part of the cooling water tank 23, and a cylindrical connector 25 connected to a refrigerant passage leading to the compressor side is fitted in this opening. The inflow side tank is disposed in the upper part of the cooling water tank 23 and is fitted with the connector 25. On the other hand, an opening is also provided in the lower part of the cooling water tank 23, and a cylindrical connector 25 connected to an upstream side refrigerant tank in the condenser 4 is fitted in this opening. The outflow side tank is disposed below the cooling water tank 23 and is fitted with the connector 25. Moreover, the core part is arrange | positioned between the inflow side tank and the outflow side tank.

  The inflow side tank is composed of a pair of tank plates 40, 41 and a pair of patch ends (not shown), and the refrigerant from the compressor side is supplied to the core portion through a tank passage formed inside. Supply to the side. This inflow side tank is joined to the upper part of the cooling water tank 23 on the refrigerant inflow side by brazing.

  The first tank plate 40 is a flat plate having a substantially rectangular shape. The first tank plate 40 is formed with an opening at substantially the center thereof, and the upper surface side of the first tank plate 40 is joined to the inner surface (upper inner surface) of the cooling water tank. Will fit. An L-shaped engaging claw extending downward is provided at the edge of the first tank plate 40, and the engaging claw is in close contact with the lower surface side of the first tank plate 40. The second tank plate 41 arranged in a state is held.

  The second tank plate 41 is a plate-like member having a substantially rectangular shape corresponding to the outer periphery shape of the first tank plate 40. The second tank plate 41 has a bent portion that is curved in a convex shape toward the side facing the connector 25 in a central region thereof in a direction perpendicular to the flow direction of the cooling water. Due to this bent portion, the second tank plate 41 has a space in which the outline of the cross-sectional shape has an arc shape and extends in a direction perpendicular to the flow direction of the cooling water. This space functions as an in-tank passage for supplying the refrigerant to the core portion. The width (width in the flow direction of cooling water) L of the passage in the tank is set to be smaller than the width (width in the longitudinal direction of the cross section) of the refrigerant flat tube 43 described later. Further, the second tank plate 31 is formed with a rectangular opening, and this opening corresponds to the outer peripheral shape of the core part described later. In the present embodiment, the width of the core portion in the direction orthogonal to the flow direction of the cooling water (that is, the overall width of the plurality of flat refrigerant tubes 43 arranged in a stacked manner) is the core portion of the sub-radiator 2. The number of the refrigerant flat tubes 43 is set to be equal to or less than the width (specifically, the width in the longitudinal direction of the cross section of the cooling water flat tube 21), and is formed in the first tank plate 30. The width of the opening is formed to a width corresponding to the number of the refrigerant flat tubes 43.

  The pair of patch ends are arranged at the end of the opening region between the first tank plate 40 and the second tank plate 41, which is formed by the bent portion of the second tank plate 41. Block.

  The outflow side tank is composed of a pair of tank plates 40 and 41 and a pair of patch ends (not shown), and the refrigerant from the core portion side is condensated through a tank passage formed inside. 4 is supplied to an upstream side refrigerant tank (not shown). Note that the configuration of the outflow side tank is the same as that of the inflow side tank, and is provided in the cooling water tank 23 with the inflow side tank upside down. This outflow side tank is joined to the lower part of the cooling water tank 23 on the refrigerant outflow side by brazing.

  The core portion is configured by a plurality of refrigerant flat tubes 43. Each of the refrigerant flat tubes 43 includes a flat holder 45 that extends in the vertical direction and has a hollow interior, and an inner fin (not shown) accommodated in the holder 45. A refrigerant passage is formed inside. The total length of the inner fin is shorter than that of the holder 45. For this reason, both ends of the holder 45 are shaped to protrude from both ends of the inner fin. Here, the projecting length of both end portions of the holder 45 projecting from both ends of the inner fin is set to be equal to or less than the thickness of the second tank plate 41.

  The individual flat tubes 43 for refrigerant are arranged in a stacked manner in a direction orthogonal to the flow direction of the cooling water in a state where the longitudinal direction of the cross section corresponds to the flow direction of the cooling water. Each of the refrigerant flat tubes 43 (specifically, the holder 45) is formed with a bead 45a in which a part of the side surface region partially protrudes outward. The beads 45a are joined by brazing in a state where the beads 45a are in contact with each other. Further, a bead 23a is formed on the inner peripheral surface of the cooling water tank 23 so that a part of the inner peripheral surface protrudes inward, and the refrigerant flat tube 43 located on the outermost side is formed by itself. The bead 45a and the bead 23a on the cooling water tank 23 side are joined to the cooling water tank 23 by brazing. That is, at the time of brazing, if a load is applied from the outside of the cooling water tank 23, the holder 45 and the inner fin can be joined in close contact.

  Further, the both end portions of each refrigerant flat tube 43 have a shape in which the central region is cut into a substantially semicircular shape corresponding to the shape of the passage in the tank. Both end portions of each refrigerant flat tube 43 having such a shape are expanded, and adjacent refrigerant flat tubes 43 are directly joined to each other.

  One end of the core portion composed of the plurality of refrigerant flat tubes 43 is inserted into the opening of the second tank plate 41 in the inflow side tank, and is formed on the lower surface (tank inner surface) of the first tank plate 40. In the butted state, they are joined by brazing. In addition, each refrigerant flat tube 43 has its other end inserted into the opening of the second tank plate 41 in the inflow side tank and abuts against the lower surface (tank inner surface) of the first tank plate 40. Are joined together by brazing.

  As described above, according to the present embodiment, the same effects as those of the first embodiment can be achieved, and further effects as described below can be achieved. Specifically, the second tank plate 41 is not provided with a plurality of openings corresponding to the individual refrigerant flat tubes 43, but is expanded by expanding both ends of the refrigerant flat tubes 43. The flat tube 43 for use is made into the shape joined directly. Thereby, it is not necessary to process the hole corresponding to the number of the refrigerant | coolant flat tubes 43 in the 2nd tank plate 41, and it can simplify to the shape on a square frame. Moreover, since the area of the refrigerant | coolant flat tube 43 can be increased by abutting each flat tube 43 for refrigerant | coolants to the flat tank-shaped 1st tank plate 40, the heat exchange area | region should be set widely. Can do. Furthermore, the pressure loss at the time of entering / exiting the tube can be reduced by expanding the end of the refrigerant flat tube 43.

(Third embodiment)
FIG. 10 is a perspective view schematically showing a vehicle heat exchanger according to a third embodiment of the present invention. The vehicle heat exchanger of the third embodiment is different from that of the first or second embodiment in that a refrigerant water cooling unit 7 is used instead of the refrigerant water cooling unit 3. In addition, about the same structure as 1st or 2nd embodiment, the detailed description is abbreviate | omitted by referring to a referential mark, and below, it demonstrates centering around difference.

  Specifically, the vehicular heat exchanger includes a sub-radiator 2 (first radiator) that cools cooling water that cools a driving unit (in this embodiment, an electric driving unit including an electric motor and electronic components for control thereof). 1 heat exchange unit), a refrigerant water cooling section 7 that primarily cools the refrigerant for the air conditioning system in the passenger compartment, and a condenser (second heat) that secondarily cools the refrigerant cooled in the refrigerant water cooling section 7 The exchange unit 4 is mainly configured. As shown in the figure, the sub-radiator 2 is arranged on the front side of the radiator 5 for cooling the engine, that is, on the upstream side of the cooling air, and the condenser 4 is arranged vertically below the sub-radiator 2. . The refrigerant water cooling unit 7 is connected to the sub radiator 2, and the detailed structure thereof will be described later.

  A passage is formed between the electric drive unit 1 and the sub radiator 2 so that the cooling water circulates, and a circulation pump 6 for circulating the cooling water is provided in the passage. By driving the circulation pump 6, the cooling water (C 1 in) from the electric drive unit 1 is supplied to the sub-radiator 2, and heat exchange is performed between the air and the cooling water in the sub-radiator 2. Cooling water (C1out) from the sub-radiator 2 is supplied to the electric drive unit 1.

  On the other hand, in the air conditioning system, the high-temperature and high-pressure gas refrigerant (C2in) compressed by the compressor is supplied to the refrigerant water cooling unit 7 and then supplied to the capacitor 4. When heat exchange is performed in the refrigerant water cooling unit 7 and the condenser 4, the gas refrigerant becomes a high-pressure liquid refrigerant or a gas-liquid mixed refrigerant. The refrigerant (C2out) from the condenser 4 is gas-liquid separated in the liquid tank, and then adiabatic expansion is performed by the expansion means to form a low-temperature low-pressure liquid refrigerant or gas-liquid mixed refrigerant, and heat is exchanged with the air in the passenger compartment by the evaporator. After making the low-pressure gas refrigerant, it is returned to the compressor.

  FIG. 11 is a front view schematically showing the structure of the sub-radiator 2 and the coolant cooling unit 7. As in the first or second embodiment, the sub-radiator 2 includes a core part (cooling water heat exchanging means) composed of the radiation fins 20 and the cooling water flat tubes 21, the reinforcement 22, and the cooling water. The tank 23 is mainly configured. Each of the flat tubes 21 for cooling water constituting the core portion has one end inserted into the cooling water tank 23 on the upstream side and the other end inserted into the cooling water tank 23 on the downstream side. Thereby, the internal space of each cooling water tank 23 and the internal passage of the flat tube 21 for cooling water communicate.

  The refrigerant water cooling unit 7 constitutes a part of the refrigerant passage between the compressor and the condenser 4 in the air conditioning system. The refrigerant water cooling unit 7 is connected to the cooling water tank 23 on the downstream side of the sub-radiator 2, and performs heat exchange between the cooling water in the cooling water tank 23 and the refrigerant of the air conditioning system. Cool down.

  FIG. 12 is a schematic diagram showing the refrigerant water cooling unit 7 from the side, and FIG. 13 is a schematic diagram showing an AA cross section of the refrigerant water cooling unit 7 shown in FIG. The refrigerant water cooling unit 7 is configured by stacking a plurality of sets of first shell plates 76 and second shell plates 77 facing each other, and the individual shell plates 76 and 77 have a flat plate shape as a whole. is doing. The first and second shell plates 76 and 77 are formed of a member having excellent thermal conductivity, for example, a metal plate such as an aluminum alloy.

  The first shell plate 76 and the second shell plate 77 are laid out in such a manner that their plate surfaces are perpendicular to the cooling water inflow direction from the cooling water tank 23 on the downstream side of the sub radiator 2. ing. In other words, the refrigerant water cooling unit 7 is configured by a plurality of plate-like plates 76 and 77 that are stacked such that the inflow direction of the cooling water from the cooling water tank 23 and the plate surface are orthogonal to each other. The peripheral portions of the first and second shell plates 76 and 77 are bent into a substantially L shape, and the peripheral portions are joined to each other by brazing. Moreover, the set of the 1st shell plate 76 and the 2nd shell plate 77 which were mutually joined is mutually joined by brazing via the peripheral part. Here, the cooling water tank 23 on the downstream side of the condenser 4 has an opening on the surface facing the cooling water inflow surface, and the opening is located on the peripheral edge and on the cooling water tank 23 side. The peripheral portion of the first shell plate 76 is joined by brazing, so that the cooling water tank 23 and the coolant cooling unit 7 are integrated.

  In the refrigerant water cooling section 7 having such a configuration, a clearance between a pair of adjacent shell plates 76 and 77 is formed as a passage for cooling water or refrigerant, and the shell plate 76 is provided in each passage (ie, clearance). , 77, the first passage 78 through which the refrigerant flows and the second passage 79 through which the cooling water flows are alternately set. Inner fins 80 are installed in the individual first passages 78.

  The refrigerant water cooling unit 7 includes a pair of cooling water inlet / outlet portions 81 and 82 that pass through the individual shell plates 76 and 77. When the cooling water from the cooling water tank 23 flows into one cooling water inlet / outlet portion 81, the cooling water branches into the individual second passages 79 via the cooling water inlet / outlet portion 81. The refrigerant that has flowed through the second passage 79 joins at the other cooling water inlet / outlet portion 82, and flows out to the outside (driving unit side) via the cooling water inlet / outlet portion 82 (C1out). Here, the first shell plate 76 and the second shell plate 77 are respectively formed with openings 76a and 77a corresponding to the pair of cooling water inlet / outlet portions 81 and 82, respectively. The shell plate 76 is formed with a recess in which the opening 76a and the peripheral edge thereof are recessed in a concave shape toward the outside (right side in FIG. 13). The individual cooling water inlet / outlet portions 81 and 82 are adjacent to the peripheral portion of the opening 76a in the first shell plate 76 by the adjacent second shell plate 77 (second shell plate 77 located on the right side in FIG. 13). By making it contact to the side and joining the said contact location by brazing, it is comprised as a series of channel | paths.

  Similarly, a pair of refrigerant inlet / outlet portions 83 and 84 that pass through the individual shell plates 76 and 77 are formed in the refrigerant water cooling portion 7. When the refrigerant (C2in) from the compressor side flows into one of the refrigerant inlet / outlet portions 83, the refrigerant branches into the individual first passages 78 via the refrigerant inlet / outlet portions 83, and further, The refrigerant that has flowed through the first passage 78 merges at the other refrigerant inlet / outlet portion 84, and flows out to the outside (capacitor 4 side) via the refrigerant inlet / outlet portion 84 (C2out). Here, the first shell plate 76 and the second shell plate 77 are respectively formed with openings 76b and 77b corresponding to the pair of refrigerant inlet / outlet portions 83 and 84, respectively. The shell plate 77 is formed with a recess in which the opening 77b and its peripheral edge are recessed in a concave shape toward the outside (right side in FIG. 13). The individual refrigerant inlet / outlet portions 83 and 84 are adjacent to the peripheral portion of the opening 77b in the second shell plate 77 on the side of the adjacent first shell plate 76 (second shell plate 77 located on the right side in FIG. 13). It is comprised as a series of passages by making it contact, and joining the contact point by brazing.

  In the present embodiment, one cooling water inlet / outlet portion 81 for branching the cooling water to the second passage 79 is laid out below the refrigerant water cooling portion 7, and also flows through the second passage 79. The other cooling water inlet / outlet portion 82 where the cooling water merges is laid out above the refrigerant water cooling portion 7. Therefore, in the coolant cooling section 7, the coolant flows in the second passage 79 from below to above. On the other hand, the one refrigerant inlet / outlet part 83 for branching the refrigerant with respect to the first passage 78 is laid out above the refrigerant water cooling part 7, and the refrigerant flowing through the first passage 78 is The other refrigerant inlet / outlet portion 84 that joins is laid out below the refrigerant water cooling portion 7. Therefore, in the coolant cooling unit 7, the coolant flows in the first passage 78 from the upper side to the lower side. Therefore, the refrigerant and the cooling water flow into the refrigerant water cooling unit 7 so that the refrigerant and the cooling water flow in directions opposite to each other.

  Further, as shown in FIG. 12, the pair of cooling water inlet / outlet portions 81 and 82 are offset from each other in the horizontal direction on a plane orthogonal to the extending direction, and the pair of refrigerant inlet / outlet portions. 83 and 84 are also offset from each other in the horizontal direction on a plane orthogonal to the extending direction. For this reason, the refrigerant and the cooling water are in such a manner that their traveling directions intersect each other.

  In the vehicle heat exchanger having such a configuration, the cooling water that has cooled the electric drive unit 1 flows into the interior from the inlet portion provided in the cooling water tank 23 on the upstream side of the sub-radiator 2, and thereafter It flows through the cooling water flat tube 21 and flows into the cooling water tank 23 on the downstream side. In the process of flowing through the cooling water flat tubes 21, the cooling water is transferred from the cooling water flat tubes 21 to the radiating fins 20 and from the radiating fins 20 to the cooling air to perform heat exchange. The cooling water is cooled. The cooling water that has flowed to the cooling water tank 23 on the downstream side passes through the refrigerant water cooling unit 7 from there. Specifically, the cooling water branches from one cooling water inlet / outlet portion 81 to each of the second passages 79, and flows through the second passages 79 respectively, and then in the other cooling water inlet / outlet portion 82. After joining, it is supplied to the electric drive unit 1 side.

  The refrigerant in the air conditioning system flows into the refrigerant water cooling unit 7 in the state of high-temperature and high-pressure gas discharged from the compressor. Specifically, the refrigerant branches from the one refrigerant inlet / outlet portion 83 to the individual first passages 78 and flows through the first passages 78. In the process of flowing through the first passage 78 in the refrigerant water cooling section 7, the refrigerant is cooled from the inner fin 80 by the first and second shell plates 76, 77 and from the first and second shell plates 76, 77. It is transmitted to water, and the state of superheat decreases or enters a state of partial saturation. The refrigerant that has flowed through the individual first passages 78 merges at the other refrigerant inlet / outlet portion 84 and then flows into the condenser 4.

  Normally, water cooling has higher heat transfer efficiency than air cooling, and the heat exchanger can be downsized. However, when the refrigerant is completely condensed with cooling water, the temperature difference between the refrigerant condensing temperature and the cooling water. Therefore, in order to cover all the cooling of the refrigerant by water cooling, the core part of the sub-radiator 2 and the refrigerant water cooling part 3 may be increased in size. However, in the present embodiment, the cooling of the refrigerant by water cooling uses only the efficient part where the temperature between the fluids is large and uses the condenser 4 together, thereby suppressing the sub radiator 2 and the refrigerant water cooling part 7 from being enlarged. ing.

  Moreover, according to this embodiment, since the coolant cooling unit 7 has a laminated structure of the shell plates 76 and 77, the assembly of the individual plates 76 and 77 is facilitated. Therefore, it becomes easy to manage the clearance of the brazed portion, and the brazing performance is improved.

  Moreover, according to this embodiment, since the flow of the cooling water and the refrigerant is opposed to each other in the refrigerant water cooling unit 7, it is possible to improve the heat exchange efficiency. Moreover, since the cooling water is flowing upward, deterioration of the flow rate distribution can be relatively suppressed even when the flow rate of the cooling water is small. On the other hand, since the refrigerant is flowing downward as opposed to the cooling water, it is advantageous in terms of oil return. Further, since the refrigerant outlet in the refrigerant water cooling section 7, that is, the refrigerant inlet / outlet section 84 is laid out on the lower side, the distance from the capacitor 4 is reduced, and both can be connected smoothly.

  In the present embodiment, the refrigerant water cooling unit 7 has a configuration in which the inner fins 80 are disposed only on the first passage 78 side, but may be disposed on the second passage 79 side. Of course, without using the inner fins 80, the first and second shell plates 76 and 77 may be provided with irregularities (beads) to ensure a heat radiation area and strength. In this case, the number of parts can be reduced, and the assembly time can be shortened.

  In the present embodiment, the first and second shell plates 76 and 77 are alternately stacked. However, one type of plate may be alternately rotated by 180 degrees and stacked. In this case, It becomes possible to further reduce the types of parts.

  Further, the sub radiator 2 and the coolant cooling unit 7 are not necessarily integrated by brazing. For example, by brazing the two separately and then caulking the periphery with the packing in between, it is possible to achieve more appropriate brazing conditions for each, and to improve the brazing performance Can do.

  The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above embodiments, and various modifications can be made to the above embodiments without departing from the scope of the invention. For example, in each of the above-described embodiments, the refrigerant water cooling unit 3 (or the refrigerant water cooling unit 7) exchanges heat between the cooling water that cools the drive unit (electric drive unit) 1 and the refrigerant of the air conditioning system. However, the present invention is not limited to this, and heat exchange can be performed between the first fluid that cools the first heating element in the vehicle and the second fluid that cools the second heating element.

The block diagram which shows notionally the heat exchanger for vehicles concerning embodiment of this invention The perspective view which shows typically the heat exchanger for vehicles concerning embodiment of this invention Front view schematically showing the structure of the sub-radiator 2 The front view which shows typically the structure of the refrigerant | coolant water cooling part 3 concerning 1st Embodiment. The side view which shows typically the structure of the refrigerant | coolant water cooling part 3 concerning 1st Embodiment. The disassembled perspective view which shows typically the structure of the upper part side of the refrigerant | coolant water cooling part 3 concerning 1st Embodiment. The disassembled perspective view explaining the assembly state of the sub radiator 2 concerning 1st Embodiment The front view which shows typically the structure of the coolant cooling unit 3 in 2nd Embodiment. The side view which shows typically the structure of the refrigerant | coolant water cooling part 3 which concerns on 2nd Embodiment. The perspective view which shows typically the heat exchanger for vehicles concerning 3rd Embodiment. The front view which shows typically the structure of the sub radiator 2 and the coolant cooling unit 7 The schematic diagram which shows the coolant water cooling part 7 from the side surface side The schematic diagram which shows the AA cross section of the refrigerant | coolant water cooling part 7 shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Drive part 2 Sub radiator 3 Refrigerant water cooling part 4 Condenser 5 Radiator 6 Circulation pump 20 Radiation fin 21 Flat tube for cooling water 22 Reinforce 23 Cooling water tank 23a Bead 25 Connector 26 Outlet pipe 30 1st tank plate 30a Opening 31 1st 2 tank plate 32 patch end 33 flat tube for refrigerant 34 holder 34a bead 35 inner fin 40 first tank plate 41 second tank plate 43 flat tube for refrigerant 45 holder 45a bead 76 ... first shell plate 76a ... opening 76b ... Opening 77 ... Second shell plate 77a ... Opening 77b ... Opening 78 ... First passage 79 ... Second passage 80 ... Inner fin 81 ... Cooling water inlet / outlet portion 82 ... Cooling water inlet / outlet portion 83 ... Refrigerant inlet Exit 84 ... refrigerant inlet / outlet

Claims (14)

A vehicle heat exchanger including a first heat exchange unit (2) that cools cooling water that cools the drive unit (1), and a second heat exchange unit (4) that cools the refrigerant used in the air conditioning system. In
The cooling water flows through the cooling water heat exchange means (20, 21) for exchanging heat between the cooling water and the air, and the cooling water accommodated therein is supplied to the drive unit (1) side. A cooling water tank (23);
A refrigerant that constitutes a part of a refrigerant passage through which air-conditioning refrigerant flows and that is built in the cooling water tank (23) and exchanges heat between the cooling water in the cooling water tank (23) and the refrigerant. A water cooling part (3),
The refrigerant water cooling part (3)
A plurality of flat tubes (34, 35) each having an internal passage for refrigerant are arranged in a stack, and the refrigerant heat exchange means (33),
One end of the flat tube (34, 35) is inserted and communicated with the internal passage, and the air conditioning is performed via a tank internal passage extending in the stacking direction of the flat tube (34, 35). A first refrigerant tank (30, 31, 32) for supplying refrigerant from the system side to each of the flat tubes (34, 35);
The other end of the flat tube (34, 35) is inserted and communicated with the internal passage, and the flat tube (34, 35) passes through the tank passage extending in the stacking direction of the flat tube (34, 35). A second refrigerant tank (30, 31, 32) for supplying the refrigerant flowing through each of the tubes (34, 35) to the second heat exchange unit (4) side,
In the first refrigerant tank (30, 31, 32) and the second refrigerant tank (30, 31, 32), the outline of the cross-sectional shape of the tank passage has an arc shape, and the tank passage Is set to be smaller than the width in the longitudinal direction of the cross section of the flat tube.   Each of the flat tubes (34, 35) is joined to the first refrigerant tank (30, 31, 32) by brazing in a state where one end is abutted against the inner surface of the tank, and the other 2. The vehicle heat exchange according to claim 1, wherein an end portion of the vehicle is joined to the second refrigerant tank (30, 31, 32) by brazing in a state of being abutted against an inner surface of the tank. vessel. The first refrigerant tank (30, 31, 32) is joined to the upper part of the cooling water tank (23) on the refrigerant inflow side by brazing,
The said 2nd refrigerant | coolant tank (30,31,32) is joined to the lower part of the said cooling water tank (23) used as the refrigerant | coolant outflow side by brazing. Vehicle heat exchanger.   The refrigerant water cooling unit (3) performs heat exchange between the refrigerant discharged from the compressor in the air conditioning system and the cooling water cooled in the first heat exchange unit (2). The vehicle heat exchanger according to any one of claims 1 to 3.   The cooling water tank (23) is joined by brazing to the refrigerant tank of the second heat exchange unit (4) into which refrigerant flows through the refrigerant water cooling section (3). Item 5. The vehicle heat exchanger according to any one of Items 1 to 4.   In the refrigerant water cooling section (3), the width of the refrigerant heat exchange means (33) in the stacking direction of the flat tubes (34, 35) is less than the width of the cooling water heat exchange means (20, 21). It is set, The heat exchanger for vehicles described in any one of Claim 1 to 5 characterized by the above-mentioned. A first heat exchange unit (2) that cools the first fluid that cools the first heating element, and a second heat exchange unit (4) that cools the second fluid that cools the second heating element. Including vehicle heat exchangers,
A first fluid tank (23) that forms part of the first heat exchange unit (2) and into which the first fluid flows;
A part of the second fluid passage through which the second fluid flows, and is built in the first fluid tank (23), between the first fluid and the second fluid in the first fluid tank (23). A second fluid cooling section (3) for exchanging heat at
The second fluid cooling section (3)
A plurality of flat tubes (34, 35) each having an internal passage for the second fluid, the second fluid heat exchanging means (33) configured in a stacked manner;
One end of the flat tube (34, 35) is inserted and communicated with the internal passage, and the second through the tank internal passage extending in the stacking direction of the flat tube (34, 35). An upstream second fluid tank (30, 31, 32) for supplying fluid to each of the flat tubes (34, 35);
The other end of the flat tube (34, 35) is inserted and communicated with the internal passage, and the flat tube (34, 35) passes through the tank passage extending in the stacking direction of the flat tube (34, 35). A second fluid tank (30, 31, 32) on the downstream side for supplying the second fluid flowing through each of the tubes (34, 35) to the second heat exchange unit (4) side,
In the upstream second fluid tank (30, 31, 32) and the downstream second fluid tank (30, 31, 32), the outline of the cross-sectional shape of the passage in the tank has an arc shape, The vehicular heat exchanger is characterized in that the width of the passage in the tank is set to be smaller than the width in the longitudinal direction of the cross section of the flat tube. In the first fluid tank (23), cooling water flows through the first fluid heat exchanging means (20, 21) for exchanging heat between the first fluid and air, and is stored in the first fluid tank (23). Supplying water to the first heating element side,
The said 2nd fluid cooling part (3) supplies the 2nd fluid by which heat exchange was performed between the 1st fluids to the said 2nd heat exchange unit (4) side, It is characterized by the above-mentioned. The heat exchanger for vehicles described in 1. A first heat exchange unit (2) that cools the first fluid that cools the first heating element, and a second heat exchange unit (4) that cools the second fluid that cools the second heating element. Including vehicle heat exchangers,
A first fluid tank (23) into which the first fluid flows;
A part of the second fluid passage through which the second fluid flows and a first fluid and a second fluid connected to the first fluid tank (23) and supplied from the first fluid tank (23) A second fluid cooling section (7) for exchanging heat between the two,
The second fluid cooling section (7) includes a plurality of flat plate plates (76, 77) that are stacked such that the inflow direction of the first fluid from the first fluid tank (23) and the plate surface are orthogonal to each other. ), A clearance between a pair of adjacent plates is formed as a fluid passage, and a first passage (78) through which the second fluid flows, and a second passage through which the first fluid flows ( 79) and the vehicle heat exchanger. The first fluid tank (23) forms a part of the first heat exchange unit (2), and heat exchange means for first fluid that exchanges heat between the first fluid and air ( 20, 21) is flowing in through the first fluid,
Each of the second passages (79) constitutes a passage through which the first fluid from the first fluid tank (23) flows to the first heating element side,
The vehicular heat exchanger according to claim 9, wherein the first passage (78) constitutes a passage through which the second fluid flows to the second heat exchange unit (4) side.   The first fluid tank (23) has a housing shape in which a surface facing the cooling water inflow surface from the first fluid heat exchange means (20, 21) is opened, 11. The vehicle heat exchanger according to claim 10, wherein a peripheral edge part and a peripheral edge part of the second fluid cooling part (7) are joined by brazing.   The vehicle heat according to any one of claims 9 to 11, wherein the second fluid cooling section (7) flows in a direction in which the first fluid and the second fluid face each other. Exchanger.   The vehicle according to any one of claims 9 to 12, wherein the second fluid cooling section (7) is provided with an inner fin (80) in the first passage (78). Heat exchanger. The first fluid is cooling water that cools the electronic component (1) for controlling the vehicle electric motor,
The vehicle heat exchanger according to any one of claims 9 to 13, wherein the second fluid is a refrigerant used in an air conditioning system.

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