WO2023013517A1 - Heat exchanger and air conditioning device - Google Patents

Abstract

This heat exchanger comprises: a heat dissipation unit (20) that dissipates heat from a first refrigerant into a first airflow; and an evaporator (22) that is disposed above the heat dissipation unit in the vertical direction and causes a second refrigerant to absorb heat from a second airflow and evaporate. Condensate produced in the evaporator flows to the heat dissipation unit to cool the first refrigerant. The half region on the inlet side of a first refrigerant flow path in the heat dissipation unit is designated as a first region (250), the half region on the outlet side is designated as a second region (251), the half region on the first region side of a second airflow path in the evaporator is designated as a third region (240), the half region (241) on the second region side is designated as a fourth region, and the airflow rate of the second airflow flowing in the third region is greater than the airflow rate of the second airflow flowing in the fourth region.

Description

heat exchangers and air conditioners Cross-references to related applications

This application is based on Japanese Patent Application No. 2021-127618 filed on August 3, 2021, the contents of which are incorporated herein by reference.

The present disclosure relates to heat exchangers and air conditioners.

Conventionally, in air conditioners, it has been proposed that an evaporating section is arranged above a heat radiating section, and a water guide passage is provided to guide condensed water generated in the evaporating section to the heat radiating section (see Patent Document 1, for example). In this device, the condensed water is applied to the heat radiating portion to evaporate the condensed water in the heat radiating portion, thereby depriving the refrigerant of the heat of vaporization, thereby increasing the cooling efficiency of cooling the refrigerant in the heat radiating portion.

WO2018/235765

Patent Document 1 does not describe how the condensed water generated in the evaporator is applied to the heat radiating section in the air conditioner.

According to the study of the inventor, for example, if the condensed water is allowed to flow down to the upper tank of the heat radiating section, the condensed water may flow downwind along the upper tank of the heat radiating section.

Therefore, the condensed water is not vaporized in the heat radiating part and flows directly to the leeward side of the heat radiating part. Therefore, there is a high possibility that a sufficient cooling effect of the refrigerant cannot be obtained in the heat radiating portion.

The present disclosure aims to provide a heat exchanger having an evaporating section and a heat radiating section, in which condensed water generated in the evaporating section is used to improve the cooling effect of the refrigerant in the heat radiating section, and an air conditioner. aim.

According to one aspect of the present disclosure, the heat exchanger includes a first refrigerant flow path through which the first refrigerant that has flowed into the first refrigerant inlet flows toward the first refrigerant outlet, and around the first refrigerant flow path a heat radiating portion that forms a first air flow path through which the first air flow passes, and that radiates the heat of the first refrigerant to the first air flow;
a second refrigerant flow path arranged vertically above the heat radiating portion for circulating the second refrigerant that has flowed into the second refrigerant inlet toward the second refrigerant outlet; an evaporator that forms a second air flow path through which two air flows pass, and causes the second refrigerant to absorb heat from the second air flow to evaporate the second refrigerant;
Condensed water generated in the evaporating portion as heat is absorbed by the second refrigerant flows to the heat radiating portion to cool the first refrigerant,
A half region of the first coolant flow path of the heat radiating portion on the first coolant inlet side is defined as a first region, and a half region of the first coolant flow channel of the heat radiating portion on the first coolant outlet side is defined as a second region, In the case where the half area of the second air flow path of the evaporating section on the first area side is the third area, and the half area of the second air flow path of the evaporating section on the second area side is the fourth area ,
The air volume of the second airflow flowing in the third region is greater than the air volume of the second airflow flowing in the fourth region.

Therefore, the amount of condensed water generated in the third area is greater than the amount of condensed water generated in the fourth area. Therefore, the amount of condensed water flowing from the third area to the first area is greater than the amount of condensed water flowing from the fourth area to the second area.

Here, a coolant with a higher temperature flows in the first region than in the second region. Therefore, compared to the case where the amount of condensed water flowing from the third area to the first area is smaller than the amount of condensed water flowing from the fourth area to the second area, the refrigerant and the condensed water in the first area Heat exchange between can be efficiently performed.

As described above, a heat exchanger is provided in which the condensed water generated in the evaporating section is used to improve the cooling effect of the refrigerant in the heat radiating section.

According to another aspect, an air conditioner includes a blower for blowing an airflow;
A first refrigerant flow path through which the first refrigerant flowing into the first refrigerant inlet flows toward the first refrigerant outlet, and a first air flow path through which the air flow passes around the first refrigerant flow path are formed. , a heat dissipation part for dissipating the heat of the first refrigerant to the air flow;
a second refrigerant flow path arranged vertically above the heat radiating portion for circulating the second refrigerant that has flowed into the second refrigerant inlet toward the second refrigerant outlet; and air around the second refrigerant flow path. an evaporator that forms a second air flow path through which the flow passes, and causes the second refrigerant to absorb heat from the air flow and evaporate the second refrigerant;
Condensed water generated in the evaporating portion as the second refrigerant absorbs heat flows to the heat radiating portion to cool the first refrigerant,
A half region of the first coolant flow path of the heat radiating portion on the first coolant inlet side is defined as a first region, and a half region of the first coolant flow channel of the heat radiating portion on the first coolant outlet side is defined as a second region, When the half area of the second air flow path of the evaporating section on the first area side is the third area, and the half area of the second air flow path of the evaporating section on the second area side is the fourth area, ,
The air volume of the airflow flowing in the third region is greater than the air volume of the airflow flowing in the fourth region.

Therefore, as in the first aspect, the amount of condensed water flowing from the third area to the first area is smaller than the amount of condensed water flowing from the fourth area to the second area. , heat exchange between the refrigerant and the condensed water can be efficiently performed in the first region.

As described above, a heat exchanger is provided in which the condensed water generated in the evaporating section is used to improve the cooling effect of the refrigerant in the heat radiating section.

It should be noted that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence relationship between the component etc. and the specific component etc. described in the embodiment described later.

1 is a cross-sectional view showing an internal configuration of a vehicle air conditioner having a heat exchanger according to the first embodiment, and is a cross-sectional view of the vehicle air conditioner cut along a plane parallel to the stacking direction and the width direction of the heat exchanger; FIG. . FIG. 2 is a refrigerant circuit diagram showing the refrigeration cycle circuit having the heat exchanger of the first embodiment, and is a block diagram for assisting the description of the condenser section and the evaporator section that constitute the heat exchanger. FIG. 2 is a cross-sectional view showing the internal configuration of the heat exchanger in the first embodiment, and is a cross-sectional view of the heat exchanger cut along a plane parallel to the stacking direction and the vertical direction. It is a top view from one side of the lamination direction of the heat exchanger in 1st Embodiment, and is a figure for assisting description of a one side plate part. FIG. 4 is a plan view from the other side in the stacking direction of the heat exchanger in the first embodiment, and is a diagram for assisting the description of the other side plate portion. FIG. 4 is a sectional view taken along line VI-VI of the heat exchanger in the first embodiment of FIG. 3; FIG. 4 is a VII-VII cross-sectional view of the heat exchanger in the first embodiment of FIG. 3; FIG. 4 is a cross-sectional view of the heat exchanger taken along line VIII-VIII in the first embodiment of FIG. 3; FIG. 4 is a sectional view taken along line IX-IX of the heat exchanger in the first embodiment of FIG. 3; FIG. 4 is a cross-sectional view taken along line XX of the heat exchanger in the first embodiment of FIG. 3; FIG. 4 is a cross-sectional view taken along line XI-XI of the heat exchanger in the first embodiment of FIG. 3; FIG. 4 is a plan view of the heat exchanger in the first embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining an air flow flowing into the evaporating section and condensed water flowing from the evaporating section to the condensing section. FIG. 6 is a cross-sectional view showing the internal configuration of a vehicle air conditioner having a heat exchanger according to a second embodiment, and is a cross-sectional view of the vehicle air conditioner cut along a plane parallel to the stacking direction and the width direction of the heat exchanger. . FIG. 11 is a cross-sectional view showing the internal configuration of a heat exchanger in the third embodiment, and is a cross-sectional view of the heat exchanger cut along a plane parallel to the stacking direction and the vertical direction. FIG. 10 is a plan view of the heat exchanger in the third embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining an air flow flowing into the evaporating section and condensed water flowing from the evaporating section to the condensing section. FIG. 11 is a cross-sectional view showing the internal configuration of a heat exchanger in a fourth embodiment, and is a cross-sectional view of the heat exchanger cut along a plane parallel to the stacking direction and the vertical direction. FIG. 11 is a plan view of the heat exchanger in the fourth embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining an air flow flowing into the evaporating section and condensed water flowing from the evaporating section to the condensing section. FIG. 11 is a cross-sectional view showing the internal configuration of a heat exchanger in a fifth embodiment, and is a cross-sectional view of the heat exchanger cut along a plane parallel to the stacking direction and the vertical direction. FIG. 11 is a plan view of the heat exchanger in the fifth embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining an air flow flowing into the evaporating section and condensed water flowing from the evaporating section to the condensing section. FIG. 20 is a plan view of the heat exchanger in the sixth embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining an air flow flowing into the evaporating section and condensed water flowing from the evaporating section to the condensing section. FIG. 20 is a plan view of the heat exchanger in the seventh embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining an air flow flowing into the evaporating section and condensed water flowing from the evaporating section to the condensing section. FIG. 20 is a plan view of the heat exchanger in the eighth embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining the airflow flowing into the evaporating section and the condensed water flowing from the evaporating section to the condensing section. FIG. 20 is a plan view of the heat exchanger in the ninth embodiment from the other side in the heat exchanger width direction, and is a diagram for explaining the airflow flowing into the evaporating section and the condensed water flowing from the evaporating section to the condensing section. FIG. 10 is a cross-sectional view showing the internal configuration of the heat exchanger in the tenth embodiment, and is a cross-sectional view of the heat exchanger cut along a plane parallel to the stacking direction and the vertical direction, showing one side plate and the other side plate It is a figure for assisting description of.

The embodiment will be described below based on the drawings. In addition, in each of the following embodiments, the same or equivalent portions are denoted by the same reference numerals in the drawings for the sake of simplification of explanation.

(First embodiment)
First, a vehicle air conditioner 1 having a heat exchanger 10 according to the first embodiment will be described with reference to FIGS. 1, 2, 3, and the like.

A vehicle air conditioner 1 of the present embodiment includes a heat exchanger 10, a centrifugal blower 4, and an air conditioning duct 5, as shown in FIG. The centrifugal blower 4 includes a centrifugal fan 4a and a scroll casing 4b.

The centrifugal fan 4a is arranged inside the scroll casing 4b. The centrifugal fan 4a rotates about the axis O in one side in the rotation direction Ka by an electric motor (not shown), sucks air from one side in the axial direction, and rotates from the radially inner side to the radially outer side about the axis O by centrifugal force. Blow out to The axis O is a virtual line extending in a direction perpendicular to the plane of FIG. 1 .

The scroll casing 4b collects the airflow blown out from the centrifugal fan 4a and blows it out from the blowout port 4c.

The air conditioning duct 5 of the present embodiment changes the direction of the airflow blown out from the blowout port 4c of the scroll casing 4b and guides the changed direction of the airflow to the heat exchanger 10 as the airflows Tr1 and Tr2. Therefore, the airflows Tr1 and Tr2 from the centrifugal fan 4a flow through the plurality of ventilation flow paths 22a of the evaporating section 22 of the heat exchanger 10 and the plurality of ventilation flow paths 20a of the condensing section 20 in the heat exchanger width direction Dw. from the other side (that is, one side in the predetermined direction).

The airflow Tr1 is the airflow that flows in the half area of the heat exchanger 10 on the other side in the stacking direction Ds among the airflows blown out from the blowout port 4c. The airflow Tr2 flows in the half area of the heat exchanger 10 on one side in the stacking direction Ds among the airflows blown out from the blowout port 4c.

The air-conditioning duct 5 changes the direction of a part of the airflow blown out from the outlet 4c to a direction inclined at an angle θ with respect to the airflow Tr1, and converts the direction-changed airflow into the airflow Tr2 in the heat exchanger 10. lead to one side in the stacking direction Ds.

Therefore, in order to generate the airflow Tr1 in the air-conditioning duct 5, it is necessary to apply a larger force to the airflow from the outlet 4c in a direction that hinders the centrifugal force, compared to the case of generating the airflow Tr2. There is Thereby, the pressure loss of the airflow Tr2 becomes larger than the pressure loss of the airflow Tr1. Along with this, the air volume of the airflow Tr1 becomes larger than the air volume of the airflow Tr2.

On one side of the heat exchanger 10 in the stacking direction Ds, a one-side area 241 of the evaporating section 22 and a one-side area 251 of the condensing section 20 (that is, the second area) are arranged. On the other side of the heat exchanger 10 in the stacking direction Ds, the other side area 240 of the evaporating section 22 and the other side area 250 of the condensing section 20 (that is, the first area) are arranged.

Therefore, the air volume of the airflow Tr1 flowing in the other side region 240 of the evaporating section 22 and the other side region 250 of the condensing section 20 is equal to that of the airflow Tr2 flowing in the one side region 241 of the evaporating section 22 and the one side region 251 of the condensing section 20. air volume is greater than that of That is, the air volume of the airflow Tr1 flowing in the other side region 240 (ie, the third region) of the evaporating section 22 is greater than the air volume of the airflow Tr2 flowing in the one side region 241 (ie, the fourth region) of the evaporating section 22. Air-conditioning ducts 5 are configured to be relatively large in number.

As shown in FIG. 2, the heat exchanger 10 of this embodiment constitutes part of a refrigeration cycle circuit 12 in which refrigerant circulates. The refrigerating cycle circuit 12 includes the heat exchanger 10 as well as the compressor 14 , the throttle section 321 e and the gas-liquid separator 40 . The compressor 14 sucks the refrigerant from the gas-liquid separator 40, compresses the refrigerant, and discharges it.

The condenser section 20 of the heat exchanger 10 releases heat from the refrigerant discharged from the compressor 14 to the air flow. The refrigerant radiated by the condensation section 20 of the heat exchanger 10 is decompressed by the throttle section 321e. The depressurized refrigerant is sucked from the airflow in the evaporator section 22 of the heat exchanger 10 to evaporate the refrigerant.

The heat exchanger 10 exchanges heat between the air flowing into the air-conditioned space to be cooled or heated and the refrigerant. For example, when the air-conditioned space is cooled, the heat exchanger 10 cools the air flowing to the air-conditioned space with a refrigerant. When the air-conditioned space is heated, the heat exchanger 10 heats the air flowing to the air-conditioned space with the refrigerant.

As shown in FIG. 3, the heat exchanger 10 of the present embodiment is constructed by brazing together a plurality of structural members made of metal such as aluminum alloy. In FIG. 3, the respective cross sections of the condenser fins 203 and the evaporator fins 223 are indicated by thick lines instead of hatching.

The heat exchanger 10 of this embodiment includes a condenser section 20 as a heat radiation section, an evaporator section 22, one side plate sections 30A and 30C, the other side plate sections 30B and 30D, and a tubular inlet pipe 34. , and a tubular outlet tube 35 . Heat exchanger 10 comprises a tubular inlet tube 36 and a tubular outlet tube 37 .

As shown in FIGS. 3, 4, and 5, one side plate portions 30A and 30C and the other side plate portions 30B and 30D have a predetermined lamination direction Ds as a thickness direction and a vertical direction Dg as a longitudinal direction. It has a plate-like shape.

Here, the stacking direction Ds is a direction intersecting the vertical direction Dg, strictly speaking, a direction orthogonal to the vertical direction Dg. In this embodiment, the direction orthogonal to both the stacking direction Ds and the vertical direction Dg is called the heat exchanger width direction Dw.

The one-side side plate portions 30A and 30C are arranged at one end of the heat exchanger 10 in the stacking direction Ds. The one side plate portion 30A is arranged above the one side plate portion 30C in the vertical direction Dg (that is, vertically above).

The other side plate portions 30B and 30D are arranged at the end of the heat exchanger 10 on the other side in the stacking direction Ds. The other side plate portion 30B is arranged above the other side plate portion 30D in the vertical direction Dg.

The evaporation section 22 is arranged between the one side plate section 30A and the other side plate section 30B in the stacking direction Ds. The condensation portion 20 is arranged between the one side plate portion 30C and the other side plate portion 30D in the stacking direction Ds.

That is, the one side plate portion 30A and the other side plate portion 30B sandwich the evaporation portion 22 between the one side plate portion 30A and the other side plate portion 30B. The one side plate portion 30C and the other side plate portion 30D sandwich the condensation portion 20 between the one side plate portion 30C and the other side plate portion 30D.

The condensation section 20 has a layered structure in which a plurality of condensation-forming sections 201 are stacked in the stacking direction Ds, with the stacking direction Ds as the thickness direction and the vertical direction Dg as the longitudinal direction. That is, the condensation section 20 has a plurality of condensation-forming portions 201, and the plurality of condensation-forming portions 201 are stacked in the stacking direction Ds and joined to each other.

As shown in FIG. 3, each of the plurality of condensing components 201 includes one side condensing tank space 201a, the other side condensing tank space 201b, and a condensing channel 201c (that is, the first refrigerant channel). An internal space is formed. The one-side condensation tank space 201a, the other-side condensation tank space 201b, and the condensation flow path 201c are spaces through which the refrigerant flows.

The one-side condensation tank space 201a is connected to one end of the condensation channel 201c, and the other-side condensation tank space 201b is connected to the other end of the condensation channel 201c. The condensation flow path 201c extends, for example, along a wavy path that reciprocates a plurality of times in the vertical direction Dg. In this embodiment, the condensation flow path 201c extends along a wavy path that reciprocates twice in the vertical direction Dg.

The other side condensation tank space 201b is arranged above the one side condensation tank space 201a in the vertical direction Dg. The condensation flow path 201c is arranged above the one-side condensation tank space 201a in the vertical direction Dg. The condensation flow path 201c is arranged below the other side condensation tank space 201b in the vertical direction Dg.

Here, as shown in FIG. 3, at least one-side condensation tank spaces 201a or the other-side condensation tank spaces 201b communicate with each other between the condensation structure portions 201 adjacent to each other.

The refrigerant compressed and discharged by the compressor 14 flows into the condenser section 20 through the inlet pipe 34, and flows into the condensation flow path 201c of each condensation structure section 201 as indicated by the chain-line arrows. The condensation section 20 causes heat exchange between the air around the condensation section 20 and the refrigerant flowing in the condensation flow path 201c, thereby releasing heat from the refrigerant to the air flow and condensing the refrigerant.

In addition, in the condensation unit 20, each of the dashed line arrows in FIG. 3 indicates the refrigerant flow in the plurality of one-side condensation tank spaces 201a that are adjacent to each other in the stacking direction Ds and connected to each other. Chain line arrows in FIG. 3 respectively indicate refrigerant flows in a plurality of other-side condensing tank spaces 201b that are adjacently connected to each other in the stacking direction Ds. The dashed-line arrows in FIG. 3 respectively indicate the refrigerant flow in the condensing flow path 201c.

The evaporating section 22 has a laminated structure in which a plurality of evaporating constituent sections 221 are laminated in the laminating direction Ds, with the thickness direction being the laminating direction Ds and the longitudinal direction being the vertical direction Dg. That is, the evaporator 22 has a plurality of evaporator components 221, which are stacked in the stacking direction Ds and joined to each other.

As shown in FIG. 3, each of the plurality of evaporating components 221 is composed of one-side evaporating tank space 221a, the other-side evaporating tank space 221b, and an evaporating channel 221c (that is, a second refrigerant channel). An internal space is formed.

That is, the evaporator 22 is provided with a plurality of one-side evaporation tank spaces 221a, a plurality of other-side evaporation tank spaces 221b, and a plurality of evaporation flow paths 221c. The one-side evaporation tank space 221a, the other-side evaporation tank space 221b, and the evaporation flow path 221c are spaces through which the refrigerant flows.

The one-side evaporation tank space 221a is connected to one end of the evaporation channel 221c, and the other-side evaporation tank space 221b is connected to the other end of the evaporation channel 221c. The evaporation channel 221c extends, for example, along a wavy path that reciprocates a plurality of times in the vertical direction Dg.

In this embodiment, the evaporation flow path 221c extends along a wavy path that makes two round trips in the vertical direction Dg.

The other side evaporation tank space 221b is arranged above the one side evaporation tank space 221a in the vertical direction Dg.

The evaporation passage 221c is arranged below the other side evaporation tank space 221b in the vertical direction Dg. The evaporation flow path 221c is arranged above the one-side evaporation tank space 221a in the vertical direction Dg.

As shown in FIG. 3, at least the one-side evaporation tank spaces 221a or the other-side evaporation tank spaces 221b communicate with each other between the evaporating components 221 adjacent to each other.

The evaporating section 22 and the condensing section 20 are arranged side by side in the order of the evaporating section 22 and the condensing section 20 in the vertical direction Dg. The condensation section 20 is arranged below the evaporation section 22 in the vertical direction Dg.

The refrigerant that has flowed out of the condensation section 20 flows into the evaporation section 22 through the inlet pipe 36 after being decompressed by a later-described throttle section 321e (that is, a decompression section). The refrigerant that has flowed into the evaporating section 22 flows into the evaporating passages 221 c of the evaporating constituent sections 221 . The evaporating section 22 exchanges heat between the air around the evaporating section 22 and the refrigerant flowing through the evaporation passage 221c, thereby allowing the refrigerant to absorb heat and evaporate the refrigerant.

In addition, in the evaporating section 22 of FIG. 3, each of the dashed arrows indicates the refrigerant flow in a plurality of one-side evaporating tank spaces 221a that are adjacent to each other and connected in the stacking direction Ds. Chain line arrows respectively indicate refrigerant flows in a plurality of other-side evaporation tank spaces 221b that are adjacent to each other in the stacking direction Ds and connected to each other. Chain line arrows respectively indicate refrigerant flows in the evaporation passages 221c.

The evaporation part 22 is fixed to the one side plate part 30A. The inlet pipe 36 is joined to the one side plate portion 30A by brazing while the inlet pipe 36 is inserted into the through hole of the one side plate portion 30A. Thereby, the inlet pipe 36 is connected to the evaporator 22 so as to communicate with the other side evaporation tank space 221b of the evaporator 22 . The inlet pipe 36 constitutes a second refrigerant inlet that allows the refrigerant to flow into the evaporator 22 .

The evaporation section 22 is fixed to the other side plate section 30B. The outlet pipe 37 is joined to the other side plate portion 30B by brazing while the outlet pipe 37 is inserted into the through hole of the other side plate portion 30B. As a result, the outlet pipe 37 is connected to the evaporator 22 so as to communicate with the other side evaporation tank space 221b of the evaporator 22 . The outlet pipe 37 constitutes a second refrigerant outlet through which the refrigerant is discharged from the evaporator 22 .

The condenser section 20 is fixed to the one side plate section 30C. The outlet pipe 35 is joined to the one side plate portion 30C by brazing while the outlet pipe 35 is inserted into the through hole of the one side plate portion 30C. As a result, the outlet pipe 35 is connected to the condensation section 20 so as to communicate with the one-side condensation tank space 201a of the condensation section 20 . The outlet pipe 35 constitutes a first refrigerant outlet through which the refrigerant is discharged from the condensing section 20 .

The condenser section 20 is fixed to the other side plate section 30D. The inlet pipe 34 is joined to the other side plate portion 30D by brazing while the inlet pipe 34 is inserted into the through hole of the other side plate portion 30D. As a result, the inlet pipe 34 is connected to the condenser section 20 so as to communicate with the one-side condensation tank space 201a of the condenser section 20 . The inlet pipe 34 constitutes a first coolant inlet that allows coolant to flow into the condensation section 20 .

Next, the configuration of the condensation section 20 of this embodiment will be described in detail. As shown in FIGS. 6 to 11, each of the plurality of condensation structure portions 201 has a pair of plate-shaped condensation plate portions 201d and 201h. In each of the plurality of condensation structure portions 201, the pair of condensation plate portions 201d and 201h are stacked in the stacking direction Ds.

Each of the plurality of condensing structure portions 201 is joined together such that a pair of condensation plate portions 201d and 201h form a condensation flow path 201c and condensation tank spaces 201a and 201b between the pair of condensation plate portions 201d and 201h. It is composed by

Specifically, the pair of condensation plate portions 201d and 201h is composed of one side condensation plate portion 201d and the other side condensation plate portion 201h arranged on the other side of the one side condensation plate portion 201d in the stacking direction Ds. is.

As shown in FIG. 6, the one-side condensation plate portion 201d, which is one of the pair of condensation plate portions 201d and 201h, includes a first condensation tank forming portion 201e recessed to one side in the stacking direction Ds and a second condensation tank forming portion 201e. It has a formation portion 201f and a condensation passage formation portion 201g.

As shown in FIG. 8, the other side condensation plate portion 201h, which is the other of the pair of condensation plate portions 201d and 201h, includes a first condensation tank forming portion 201i recessed to the other side in the stacking direction Ds and a second condensation tank forming portion 201i. It has a formation portion 201j and a condensation passage formation portion 201k.

One side condensation tank space 201a is formed between both first condensation tank formation portions 201e and 201i, and the other side condensation tank space 201b is formed between both second condensation tank formation portions 201f and 201j. ing. Also, the condensation flow path 201c is formed between both the condensation flow path forming portions 201g and 201k.

In the one-side condensation plate portion 201d, the width of the first condensation tank forming portion 201e and the width of the second condensation tank forming portion 201f are the same in the stacking direction Ds, and are larger than the width of the condensation flow path forming portion 201g. It's becoming

Similarly, in the other side condensation plate portion 201h, the width of the first condensation tank forming portion 201i and the width of the second condensation tank forming portion 201j are the same in the stacking direction Ds, and the width of the condensation flow path forming portion 201k is the same. is larger than the width of

Therefore, in the condensation section 20, the first condensation tank formation portions 201e and 201i are joined together, and the second condensation tank formation portions 201f and 201j are also joined together between the condensation structure portions 201 adjacent to each other in the condensation portion 20. ing.

On the other hand, between the condensing structure portions 201 adjacent to each other, between the condensing flow path forming portions 201g and 201k, a ventilation flow path 20a through which an air flow (that is, a first air flow) passes is formed. .

As a result, the condensation section 20 is provided with a plurality of ventilation channels 20a (that is, the first air channels). Therefore, the condensation section 20 is provided with a plurality of pairs of condensation flow path forming sections 201g and 201k.

In this embodiment, as shown in FIG. 3, the one-side condensation tank space 201a is arranged below the condensation flow path 201c in the vertical direction Dg, and the other-side condensation tank space 201b is located below the condensation flow path 201c. It is arranged on the upper side in the vertical direction Dg.

A plurality of ventilation channels 20a are formed side by side in the stacking direction Ds, and each of the plurality of ventilation channels 20a is a corrugated fin brazed to the outside of the condensation channel forming portions 201g and 201k. Condenser fins 203 are arranged. Condensing section fins 203 promote heat exchange between the air passing through ventilation flow path 20 a and the refrigerant in condensing section 20 .

The plurality of pairs of condensation flow path forming portions 201g, 201k and the plurality of condensation portion fins 203 constitute a condensation portion heat exchange core 230 that exchanges heat between the air flow and the refrigerant in the condensation portion 20.

Further, as shown in FIG. 6, a first communication hole 201m penetrating in the stacking direction Ds is formed in the first condensation tank forming portion 201e of the one-side condensation plate portion 201d. A second communication hole 201n penetrating in the stacking direction Ds is formed in the second condensation tank forming portion 201f.

Similarly, as shown in FIG. 8, a first communication hole 201o penetrating in the stacking direction Ds is formed in the first condensation tank forming portion 201i of the other condensation plate portion 201h. A second communication hole 201p penetrating in the stacking direction Ds is formed in the second condensation tank forming portion 201j.

The one-side condensation tank spaces 201a of the condensation structure portions 201 adjacent to each other communicate with each other by arranging the first communication holes 201m and 201o so as to overlap each other. The other-side condensing tank spaces 201b of the condensing components 201 adjacent to each other communicate with each other by arranging the second communication holes 201n and 201p to overlap each other.

However, some of the plurality of condensation structure portions 201 are not provided with any of the first communication holes 201m and 201o and the second communication holes 201n and 201p. As a result, a plurality of condensation component groups 204a to 204d each having one or more condensation components 201 are configured.

In the present embodiment, the plurality of condensation component groups 204a to 204d include a first condensation component group 204a, a second condensation component group 204b, a third condensation component group 204c, and a fourth condensation component group 204d. It is configured.

In the condensation unit 20, the first condensation component group 204a, the second condensation component group 204b, the third condensation component group 204c, and the fourth condensation component group 204d are arranged from one side in the stacking direction Ds to the other in the order of description. They are arranged side by side.

In the refrigerant flow of the condensation section 20, the first condensation component group 204a, the second condensation component group 204b, the third condensation component group 204c, and the fourth condensation component group 204d are arranged from the downstream side to the upstream side in the order listed. connected in series to the side.

Among the plurality of condensation component groups 204a to 204d, in the condensation component group having the plurality of condensation components 201, the plurality of condensation flow paths 201c are connected in parallel in the refrigerant flow.

In order to realize such a refrigerant flow path, as shown in the C4 part of FIG. is not provided with the first communication hole 201m. For example, FIG. 9 shows a one-side condensation plate portion 201d provided with the second communication hole 201n but not provided with the first communication hole 201m.

As shown in the C5 part of FIG. 3, the second communication hole 201n is not provided in the one-side condensation plate portion 201d located at one end in the stacking direction Ds of the third condensation component group 204c. For example, FIG. 7 shows a one-side condensation plate portion 201d provided with a first communication hole 201m but not provided with a second communication hole 201n.

As shown in part C6 in FIG. 3, the first communication hole 201m is not provided in the one-side condensation plate portion 201d located at the end of the fourth condensation component portion group 204d on the other side in the stacking direction Ds. For example, FIG. 10 shows a one-side condensation plate portion 201d provided with the second communication hole 201n but not provided with the first communication hole 201m.

Further, as shown in FIG. 3, the condensation structure portion 201 on one side in the stacking direction Ds of the first condensation structure portion group 204a is composed only of the other side condensation plate portion 201h of the pair of condensation plate portions 201d and 201h. It is

Furthermore, the condensation structure portion 201 on the other side in the stacking direction Ds of the fourth condensation structure portion group 204d is composed only of the one side condensation plate portion 201d of the pair of condensation plate portions 201d and 201h.

Next, the configuration of the evaporating section 22 of this embodiment will be described in detail. As shown in FIGS. 3 to 11, the configuration of the evaporating section 22 is basically the same as the configuration of the condensing section 20 described above.

That is, as shown in FIGS. 3 to 11, each of the plurality of evaporating components 221 has a pair of plate-like evaporating plate portions 221d and 221h. In each of the plurality of evaporating component portions 221, the pair of evaporating plate portions 221d and 221h are stacked in the stacking direction Ds. Each of the plurality of evaporating structure portions 221 is joined together so that a pair of evaporating plate portions 221d and 221h form an evaporating channel 221c and an evaporating tank space 221a and 221b between the pair of evaporating plate portions 221d and 221h. It is composed by

Specifically, the pair of evaporation plate portions 221d and 221h includes one evaporation plate portion 221d and the other evaporation plate portion 221h arranged on the other side of the one evaporation plate portion 221d in the stacking direction Ds. is.

As shown in FIG. 6, one side evaporating plate portion 221d, which is one of the pair of evaporating plate portions 221d and 221h, has a first evaporating tank forming portion 221e recessed to one side in the stacking direction Ds and a second evaporating tank forming portion 221e. It has a formation portion 221f and an evaporation passage formation portion 221g.

As shown in FIG. 8, the other side evaporating plate portion 221h, which is the other of the pair of evaporating plate portions 221d and 221h, includes a first evaporating tank forming portion 221i recessed to the other side in the stacking direction Ds and a second evaporating tank forming portion 221i. It has a formation portion 221j and an evaporation passage formation portion 221k.

The one-side evaporation tank space 221a is formed between both of the first evaporation tank forming portions 221e and 221i, and the other side evaporation tank space 221b is formed between both of the second evaporation tank forming portions 221f and 221j. ing. Also, the evaporation channel 221c is formed between both the evaporation channel forming portions 221g and 221k.

In the one-side evaporating plate portion 221d, the width of the first evaporating tank forming portion 221e and the width of the second evaporating tank forming portion 221f are the same in the stacking direction Ds, and are larger than the width of the evaporating channel forming portion 221g. It's becoming

In addition, the width of the evaporation tank forming portions 221e and 221f in the stacking direction Ds is the same as the width of the condensation tank forming portions 201e and 201f of the one-side condensation plate portion 201d.

Similarly, in the other evaporating plate portion 221h, the width of the first evaporating tank forming portion 221i and the width of the second evaporating tank forming portion 221j are set to be the same in the stacking direction Ds. It is larger than the width of the evaporation channel forming portion 221k.

In addition, the width of the evaporation tank forming portions 221i and 221j in the stacking direction Ds is the same as the width of the condensation tank forming portions 201i and 201j of the other side condensation plate portion 201h. Therefore, in the evaporating section 22, the first evaporating tank forming portions 221e and 221i are joined together, and the second evaporating tank forming portions 221f and 221j are also joined together between the evaporating constituent portions 221 adjacent to each other. there is

On the other hand, the ventilation flow path 22a through which the air passes is formed between the evaporation flow path forming portions 221g and 221k among the evaporation forming portions 221 adjacent to each other.

As a result, the evaporator 22 is provided with a plurality of ventilation channels 22a (that is, second air channels).

A plurality of ventilation channels 22a are formed side by side in the stacking direction Ds. Evaporation section fins 223, which are corrugated fins brazed to the outside of the evaporation flow path forming sections 221g and 221k, are arranged in the plurality of ventilation flow paths 22a (that is, second air flow paths). .

The evaporator fins 223 promote heat exchange between the airflow (that is, the second airflow) passing through the ventilation flow path 22a and the refrigerant in the evaporator 22.

The one-side evaporation tank space 221a is arranged below the evaporation channel 221c in the vertical direction Dg, and the other-side evaporation tank space 221b is arranged above the evaporation channel 221c in the vertical direction Dg.

The plurality of pairs of evaporation flow path forming portions 221g and 221k and the plurality of evaporator fins 223 form an evaporator heat exchange core 260 that exchanges heat between the air flow and the refrigerant in the evaporator 22.

As shown in FIG. 6, in the one-side evaporating plate portion 221d, the first evaporating tank forming portion 221e is formed with a first communication hole 221m penetrating in the stacking direction Ds, and the second evaporating tank forming portion 221f is formed with a first communicating hole 221m. A second communication hole 221n penetrating in the direction Ds is formed.

Similarly, as shown in FIG. 8, a first communication hole 221o penetrating in the stacking direction Ds is formed in the first evaporation tank forming portion 221i of the other evaporation plate portion 221h. A second communication hole 221p penetrating in the stacking direction Ds is formed in the second evaporation tank forming portion 221j.

The one-side evaporation tank spaces 221a of the evaporation components 221 adjacent to each other communicate with each other by arranging the first communication holes 221m and 221o so as to overlap each other. The other-side evaporation tank spaces 221b of the evaporation components 221 adjacent to each other communicate with each other by arranging the second communication holes 221n and 221p so as to overlap each other.

However, some of the plurality of evaporating components 221 are not provided with any of the first communication holes 221m and 221o and the second communication holes 221n and 221p. Thus, a plurality of evaporative component groups 224a to 224d each having one or two or more evaporative component parts 221 are configured.

In this embodiment, the plurality of evaporative component groups 224a to 224d include a first evaporative component group 224a, a second evaporative component group 224b, a third evaporative component group 224c, and a fourth evaporative component group 224d. It is configured.

In the evaporator 22, the first evaporative component group 224a, the second evaporative component group 224b, the third evaporative component group 224c, and the fourth evaporative component group 224d are arranged in order from the other side in the stacking direction Ds. They are arranged side by side. Then, in the refrigerant flow of the evaporator 22, the first evaporative component group 224a, the second evaporative component group 224b, the third evaporative component group 224c, and the fourth evaporative component group 224d are arranged downstream in that order. are connected in series from upstream to upstream.

In addition, among the plurality of evaporation component groups 224a to 224c, in the evaporation component group having the plurality of evaporation component portions 221, the plurality of evaporation flow paths 221c are connected in parallel in the refrigerant flow.

In order to realize such a refrigerant circulation path, as shown in E4 part of FIG. is not provided with the second communication hole 221p. For example, FIG. 11 shows the other side evaporating plate portion 221h provided with the first communication hole 221o but not provided with the second communication hole 221p.

As shown in part E5 in FIG. 3, the first communication hole 221m is not provided in the one-side evaporator plate portion 221d positioned at one end in the stacking direction Ds of the second evaporator component group 224b. For example, FIG. 7 shows a one-side evaporating plate portion 221d provided with the second communication hole 221n but not provided with the first communication hole 221m.

As shown in part E6 in FIG. 3, the second communication hole 221n is not provided in the one-side evaporator plate portion 221d positioned at one end in the stacking direction Ds of the third evaporator component group 224c. For example, FIG. 9 shows a one-side evaporating plate portion 221d provided with a first communication hole 221m but not provided with a second communication hole 221n.

Further, as shown in FIG. 3, the evaporation component 221 on one side in the stacking direction Ds of the fourth evaporation component group 224d is composed only of the other evaporation plate portion 221h of the pair of evaporation plate portions 221d and 221h. It is

Furthermore, the evaporator component 221 on the other side in the stacking direction Ds of the first evaporator component group 224a is composed only of the one-side evaporator plate 221d of the pair of evaporator plates 221d and 221h.

Next, the refrigerant flow in the heat exchanger 10 and the refrigeration cycle circuit 12 of this embodiment will be described. The dashed arrows shown in FIG. 3 indicate the refrigerant flow in the heat exchanger 10 .

First, as shown in FIG. 3, the refrigerant discharged from the compressor 14 passes through the inlet pipe 34 to a plurality of one-side condensing tank spaces 201a of the fourth condensing component group 204d of the condensing section 20. It flows into the upstream space. The refrigerant that has flowed into the upstream space of the fourth condensing component group 204d is distributed to the plurality of condensing flow paths 201c while flowing to one side in the stacking direction Ds in the upstream space.

Here, from the other side in the heat exchanger width direction Dw (that is, one side in the predetermined direction), the air flows TR1 and TR2 flow around the condensation structure portion 201 (that is, the plurality of ventilation flow paths 20a) and flow through the one side in the heat exchanger width direction Dw. flow to

The refrigerant (that is, the high-pressure refrigerant) flowing through the plurality of condensing flow paths 201c exchanges heat with the air flow around the condensing component 201 (that is, the air flow within the plurality of ventilation flow paths 20a) while flowing in parallel with each other. and dissipate heat into the air stream.

　Refrigerant flows from the plurality of condensation passages 201c into the downstream space where the plurality of other-side condensation tank spaces 201b are connected. Further, the refrigerant flows from the downstream space of the fourth condensation component group 204d into the upstream space of the third condensation component group 204c where the plurality of other side condensation tank spaces 201b are connected.

The refrigerant that has flowed into the upstream space of the third condensing component group 204c is distributed to the plurality of condensing flow paths 201c while flowing to one side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of condensation passages 201c exchanges heat with the air flow around the condensation structure portion 201 (that is, the air flow in the plurality of ventilation passages 20a), and radiates heat to the air flow. .

　Refrigerant flows from the plurality of condensation flow paths 201c into the downstream space where the plurality of one-side condensation tank spaces 201a are connected. Further, the refrigerant flows from the downstream space of the third condensation component group 204c into the upstream space of the second condensation component group 204b where the plurality of one-side condensation tank spaces 201a are connected.

The refrigerant that has flowed into the upstream space of the second condensing component group 204b is distributed to the plurality of condensing flow paths 201c while flowing to one side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of condensation passages 201c exchanges heat with the air flow around the condensation structure portion 201 (that is, the air flow in the plurality of ventilation passages 20a), and radiates heat to the air flow. .

　Refrigerant flows from the plurality of condensation passages 201c into the downstream space where the plurality of other-side condensation tank spaces 201b are connected. Further, the refrigerant flows from the downstream space of the second condensation component group 204b into the upstream space of the first condensation component group 204a where the plurality of other side condensation tank spaces 201b are connected.

The refrigerant that has flowed into the upstream space of the first condensing component group 204a is distributed to the plurality of condensing flow paths 201c while flowing to one side in the stacking direction Ds in the upstream space. The refrigerant flowing through the plurality of condensing flow paths 201c flows in parallel with each other while exchanging heat with the air flow around the condensing component 201 (that is, the plurality of ventilation flow paths 20a), and radiates heat to the air flow.

　Refrigerant flows from the plurality of condensation flow paths 201c into the downstream space where the plurality of one-side condensation tank spaces 201a are connected. The refrigerant that has flowed into the downstream space of the first condensing component group 204a flows from the outlet pipe 35 to the constricted portion 321e.

The refrigerant flowing through this throttle portion 321e is decompressed by the throttle portion 321e. This depressurized refrigerant flows into the evaporator 22 through the inlet pipe 36 . The refrigerant flowing into the evaporator 22 first flows into the upstream space of the fourth evaporator component group 224d where the plurality of other-side evaporation tank spaces 221b are connected.

The refrigerant that has flowed into the upstream space of the fourth evaporating component group 224d is distributed to the plurality of evaporating flow paths 221c while flowing to the other side in the stacking direction Ds in the upstream space.

Here, airflows Tr1 and Tr2 flow from the other side in the heat exchanger width direction Dw through the surroundings of the evaporation component 221 (that is, the plurality of ventilation flow paths 22a) to the other side in the heat exchanger width direction Dw.

Therefore, the refrigerant flowing through the plurality of evaporation passages 221c is caused to exchange heat with the air flow around the evaporation component 221 (that is, the air flow in the plurality of ventilation passages 22a) while flowing in parallel with each other. absorb heat from

Then, the refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of one-side evaporation tank spaces 221a are connected. Further, the refrigerant flows from the downstream space of the fourth evaporating component group 224d into the upstream space of the third evaporating component group 224c where the plurality of one-side evaporation tank spaces 221a are connected.

The refrigerant that has flowed into the upstream space of the third evaporating component group 224c is distributed to the plurality of evaporating flow paths 221c while flowing to the other side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of evaporation flow paths 221c exchanges heat with the air flow around the evaporation component 221 (that is, the air flow within the plurality of ventilation flow paths 22a) and absorbs heat from the air.

Refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of other-side evaporation tank spaces 221b are connected. Further, the refrigerant flows from the downstream space of the third evaporating component group 224c into the upstream space of the second evaporating component group 224b where the plurality of other evaporation tank spaces 221b are connected.

The refrigerant that has flowed into the upstream space of the second evaporating component group 224b is distributed to the plurality of evaporating flow paths 221c while flowing to the other side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of evaporation channels 221c is heat-exchanged with the airflow around the evaporation component 221 (that is, the airflow in the plurality of ventilation channels 22a), and absorbs heat from the airflow. .

Then, the refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of one-side evaporation tank spaces 221a are connected. Further, the refrigerant flows from the downstream space of the second evaporating component group 224b into the upstream space of the first evaporating component group 224a where the plurality of one-side evaporation tank spaces 221a are connected.

The refrigerant that has flowed into the upstream space of the first evaporating component group 224a is distributed to the plurality of evaporating channels 221c while flowing to the other side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of evaporation flow paths 221c exchanges heat with the air flow around the evaporation component 221 (that is, the air flow within the plurality of ventilation flow paths 22a) and absorbs heat from the air.

Refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of other-side evaporation tank spaces 221b are connected. The refrigerant that has flowed into the downstream space of the first evaporating component group 224 a flows from the outlet pipe 37 to the gas-liquid separator 40 outside the heat exchanger 10 .

The gas-liquid separator 40 separates the refrigerant into a gas-phase refrigerant and a liquid-phase refrigerant, and the separated gas-phase refrigerant is sucked into the compressor 14 from the gas-liquid separator 40 . As described above, the refrigerant flows through the heat exchanger 10 and the refrigeration cycle circuit 12 of the present embodiment.

In the present embodiment, in the evaporating section 22, as described above, the refrigerant flowing through the plurality of evaporation flow paths 221c absorbs heat from the air flow around the evaporation structure section 221 (that is, the air flow within the plurality of ventilation flow paths 22a). . For this reason, condensed water is generated on the surface exposed to the ventilation flow path 22a side and on the evaporator fins 223 of each of the plurality of evaporator components 221 in the plurality of ventilation flow paths 22a.

The condensed water W1 and W2 generated in this manner drips into the plurality of ventilation flow paths 20a of the condensation section 20.

That is, the condensed water is splashed on the surfaces exposed to the plurality of ventilation flow paths 20 a and the condensation section fins 203 in the plurality of condensation structure sections 201 . The refrigerant flowing through the plurality of condensation passages 201c radiates heat to the condensed water and vaporizes the condensed water. Therefore, the condensed water takes heat of vaporization from the refrigerant flowing through the plurality of condensing channels 201c.

Here, of the plurality of condensation flow paths 201 c of the condensation section 20 , a region that occupies half the volume on the inlet pipe 34 side (that is, the half region on the first refrigerant inlet side) is defined as the other side region 250 . A one-side region 251 occupies half the volume of the plurality of condensation flow paths 201 c of the condensation section 20 on the outlet pipe 35 side (that is, the half region on the first refrigerant outlet side).

Among the plurality of ventilation flow paths 22a of the evaporating section 22, a region that occupies half the volume on the other side region 250 side (that is, the half region on the first region side) is called the other side region 240 (that is, the third region). do. Among the plurality of ventilation passages 22a of the evaporator 22, a region occupying half the volume on the side of the one side region 251 (that is, half the region on the side of the second region) is called a one side region 241 (that is, the fourth region). do.

Here, the other side region 250 and the one side region 251 are arranged in the stacking direction Ds. The other side area 240 and the one side area 241 are arranged in the stacking direction Ds.

Furthermore, the other side area 250 of the condensation section 20 is located directly below the other side area 240 of the evaporation section 22 . The one-side region 251 of the condenser section 20 is positioned directly below the one-side region 241 of the evaporator section 22 .

In the present embodiment, as described above, the air volume of the airflow Tr1 flowing in the other side of the heat exchanger 10 in the stacking direction Ds is larger than the air volume of the airflow Tr2 flowing in the one side of the heat exchanger 10 in the stacking direction Ds. many.

Therefore, the air volume of the airflow Tr1 flowing in the other side region 240 of the evaporating section 22 is greater than the air volume of the airflow Tr2 flowing in the one side region 241. As a result, the amount of heat absorbed by the refrigerant from the air in the other side region 240 is greater than that in the one side region 241 .

The amount of condensed water W1 generated in the other side area 240 is greater than the amount of condensed water W2 generated in the one side area 241. Therefore, the amount of condensed water W1 flowing from the other side area 240 to the other side area 250 is greater than the amount of condensed water W2 flowing from the one side area 241 to the one side area 251 .

Here, gas refrigerant with superheat may flow through the inlet pipe 34 side of the plurality of condensation flow paths 201c of the condensation section 20. In this case, gas refrigerant having a temperature higher than the saturation temperature (that is, the refrigerant condensation temperature) flows to the inlet pipe 34 side of the plurality of condensation passages 201c.

In addition, subcooled refrigerant may flow through the outlet pipe 35 side of the plurality of condensation passages 201c of the condensation section 20 .

Furthermore, since pressure loss occurs due to the flow of the gas-liquid two-phase refrigerant in the plurality of condensation passages 201c of the condensation section 20, the temperature of the refrigerant on the inlet pipe 34 side is higher than that on the outlet pipe due to the pressure loss. It becomes higher than the temperature of the coolant on the 35 side.

As described above, the temperature of the refrigerant flowing on the inlet pipe 34 side of the plurality of condensing flow paths 201c is higher than the temperature of the refrigerant flowing on the outlet pipe 35 side of the plurality of condensing flow paths 201c.

Therefore, when the condensed water W1 and W2 does not drop from the evaporating section 22 to the condensing section 20, the surface temperature of the condensing section 20 on the inlet pipe 34 side is higher than the surface temperature of the condensing section 20 on the outlet pipe 35 side. get higher Therefore, the temperature difference between the refrigerant and the condensed water is greater in the surface temperature of the condenser section 20 on the inlet pipe 34 side than in the surface temperature of the condenser section 20 on the outlet pipe 35 side.

At this time, as described above, the amount of condensed water W1 flowing in the other side area 250 is greater than the amount of condensed water W2 flowing in the one side area 251. Therefore, in the present embodiment, the amount of condensed water W1 flowing in the other side region 250 is less than the amount of condensed water W2 flowing in the one side region 251, so that heat exchange between the refrigerant and the condensed water is facilitated. It can be implemented efficiently. Therefore, in this embodiment, the cooling effect of the refrigerant in the condensation section 20 can be improved.

According to the embodiment described above, the heat exchanger 10 includes the condensation section 20 that releases heat from the refrigerant to the airflow, and the evaporator section 22 that causes the refrigerant to absorb heat from the airflow and evaporate the refrigerant.

The condensation part 20 forms a condensation passage 201c through which the refrigerant that has flowed into the inlet pipe 34 flows toward the outlet pipe 35, and a plurality of ventilation passages 20a through which the air flow passes around the condensation passage 201c. .

The evaporator 22 forms an evaporation passage 221c through which the refrigerant flowing into the inlet pipe 36 flows toward the outlet pipe 37, and a plurality of ventilation passages 22a through which the air flow passes around the evaporation passage 221c. .

The evaporating section 22 is arranged above the condensing section 20 in the vertical direction Dg. Condensed water generated in the evaporating section 22 as the refrigerant absorbs heat flows to the condensing section 20 to cool the refrigerant.

In the evaporating section 22, the air volume of the airflow Tr1 flowing through the other side region 240 is larger than the air volume of the airflow Tr2 flowing through the one side region 241. Therefore, the amount of condensed water W1 flowing from the other side area 240 to the other side area 250 is greater than the amount of condensed water W2 flowing from the one side area 241 to the one side area 251 .

Therefore, in the present embodiment, the amount of condensed water W1 flowing in the other side region 250 is less than the amount of condensed water W2 flowing in the one side region 251, so that heat exchange between the refrigerant and the condensed water is facilitated. It can be implemented efficiently. Therefore, in this embodiment, the cooling effect of the refrigerant in the condensation section 20 can be improved.

In this embodiment configured in this manner, the following effects (a), (b), and (c) can be obtained.

(a) In this embodiment, in the evaporating section 22, the inlet pipe 36 is arranged on the one side area 241 side in the stacking direction Ds among the plurality of evaporating flow paths 221c. The outlet pipe 37 is arranged on the other side region 240 side in the stacking direction Ds among the plurality of evaporation channels 221c.

Here, pressure loss occurs due to the refrigerant flowing through the plurality of evaporation channels 221c of the evaporation section 22 . Therefore, the temperature of the refrigerant flowing on the outlet pipe 37 side of the plurality of evaporation passages 221c of the evaporating section 22 is lower than the temperature of the refrigerant flowing on the inlet pipe 36 side of the plurality of evaporation passages 221c. Therefore, the water temperature of the condensed water W1 generated in the other side region 240 of the evaporator 22 is lower than the water temperature of the condensed water W2 generated in the one side region 241 of the evaporator 22 .

Therefore, the water temperature of the condensed water W1 flowing from the other side area 240 to the other side area 250 is lower than the water temperature of the condensed water W2 flowing from the one side area 241 to the one side area 251.

Therefore, heat exchange between the refrigerant and the condensed water can be efficiently performed in the other side region 250 of the condensation section 20 . Therefore, the cooling effect of the refrigerant in the condensation section 20 can be further improved.

(b) In the present embodiment, as described above, the amount of condensed water W1 flowing from the other side area 240 to the other side area 250 is greater than the amount of condensed water W2 flowing from the one side area 241 to the one side area 251. . Therefore, since the condensed water is sufficiently supplied to the other side region 250 , the situation in which heat exchange between the refrigerant and the condensed water is performed only in a part of the other side region 250 hardly occurs.
(c) In the present embodiment, airflows Tr1 and Tr2 from the centrifugal fan 4a flow through the plurality of ventilation flow paths 22a of the evaporating section 22 of the heat exchanger 10 and the plurality of ventilation flow paths 20a of the condensing section 20. It flows in from the other side in the exchanger width direction Dw (that is, one side in the predetermined direction).
For this reason, compared to the case where the air flow flowing into the plurality of ventilation flow paths 22a of the evaporating section 22 and the air flow flowing into the plurality of ventilation flow paths 20a of the condensing section 20 have a counterflow relationship, air conditioning The size of the duct 5 can be reduced, and the configuration of the air conditioning duct 5 can be simplified.

(Second embodiment)
In the above-described first embodiment, the air conditioning duct 5 changes the direction of the airflow blown out from the outlet 4c to a direction inclined at an angle θ with respect to the airflow Tr1, and the changed direction of the airflow is used as the airflow Tr2. An example in which the heat exchanger 10 is guided to one side in the stacking direction Ds has been described.

However, the air-conditioning duct 5 narrows the air flow path of the airflow Tr2 flowing from the air outlet 4c to the other side of the heat exchanger 10 in the stacking direction Ds, and the airflow Tr2 flows from the air outlet 4c to the other side of the heat exchanger 10 in the stacking direction Ds. A description will be given of the second embodiment that expands the air flow path of the airflow Tr1 that flows through.

FIG. 13 shows a schematic diagram showing the internal configuration of the vehicle air conditioner 1 of this embodiment.

The vehicle air conditioner 1 of this embodiment and the vehicle air conditioner 1 of the first embodiment differ in the shape of the air conditioning duct 5, and are otherwise identical in configuration.

The air-conditioning duct 5 forms an air flow path 5a that guides part of the airflow Tr01 blown out from the outlet 4c to the heat exchanger 10 as the airflow Tr1 to the other side in the stacking direction Ds. The air-conditioning duct 5 forms an air flow path 5b that guides the remaining airflow Tr2 other than the airflow Tr1 of the airflow Tr01 blown out from the outlet 4c to the heat exchanger 10 to one side in the stacking direction Ds. The air conditioning duct 5 is formed so that the air flow path 5a is wider than the air flow path 5b.

Therefore, the flow rate of air flowing from the air outlet 4c to the other side in the stacking direction Ds from the heat exchanger 10 is greater than the flow rate of air flowing from the air outlet 4c to the heat exchanger 10 to the one side in the stacking direction Ds. . Therefore, in the evaporator 22, the air volume flowing through the other side region 240 is greater than the air volume flowing through the one side region 241, as in the first embodiment.

(Third Embodiment)
In the first embodiment described above, the inlet pipe 36 is provided on one side of the evaporator 22 in the stacking direction Ds, and the outlet pipe 37 is provided on the other side of the evaporator 22 in the stacking direction Ds. However, regarding the third embodiment in which the inlet pipe 36 is provided on the other side of the evaporating section 22 in the stacking direction Ds, and the outlet pipe 37 is provided on one side of the evaporating section 22 in the stacking direction Ds, see FIGS. will be described with reference to

FIG. 14 is a cross-sectional view of the heat exchanger 10 of this embodiment. FIG. 15 is a drawing of the heat exchanger 10 of the present embodiment viewed from the other side in the heat exchanger width direction Dw. The heat exchanger 10 of this embodiment and the heat exchanger 10 of the above-described first embodiment only differ in the structure of the evaporating section 22, and the rest of the structure is the same. Therefore, the evaporating section 22 of the heat exchanger 10 of this embodiment will be described.

As shown in FIG. 14, the inlet pipe 36 is inserted into the through hole of the other side plate portion 30B and joined to the other side plate portion 30B by brazing. The outlet pipe 37 is joined to the one side plate portion 30A by brazing while being inserted into the through hole of the one side plate portion 30A.

The evaporating section 22 includes a plurality of evaporating component groups 224a to 224c in FIG. 14 instead of the plurality of evaporating component groups 224a to 224d in FIG. In this embodiment, a first evaporative component group 224a, a second evaporative component group 224b, and a third evaporative component group 224c are configured as the plurality of evaporative component groups 224a to 224c.

In the evaporator 22, the first evaporative component group 224a, the second evaporative component group 224b, and the third evaporative component group 224c are arranged in order from the other side to the one side in the stacking direction Ds. there is

In the refrigerant flow of the evaporator 22, the first evaporative component group 224a, the second evaporative component group 224b, and the third evaporative component group 224c are connected in series from the upstream side to the downstream side in the order listed. .

Among the plurality of evaporation component groups 224a to 224c, in the evaporation component group having the plurality of evaporation component portions 221, the plurality of evaporation flow paths 221c are connected in parallel in the refrigerant flow.

In order to realize such a refrigerant flow path, as shown in E4 part of FIG. is provided with the first communication hole 221o but is not provided with the second communication hole 221p.

As shown in part E5 in FIG. 14, the second evaporating plate portion 221h located at the center in the stacking direction Ds of the second evaporating component group 224b is provided with a second communicating hole 221p. The communicating hole 221o is not provided.

As shown in part E6 in FIG. 14, the other-side evaporator plate portion 221h positioned at the other end in the stacking direction Ds of the third evaporator component group 224c is provided with the first communication hole 221o. The second communication hole 221p is not provided.

As shown in FIG. 14, the evaporation component 221 on one side in the stacking direction Ds of the third evaporation component group 224c is constituted only by the other evaporation plate portion 221h of the pair of evaporation plate portions 221d and 221h. there is

Furthermore, the evaporator component 221 on the other side in the stacking direction Ds of the first evaporator component group 224a is composed only of the one-side evaporator plate 221d of the pair of evaporator plates 221d and 221h.

Next, the refrigerant flow in the heat exchanger 10 and the refrigeration cycle circuit 12 of this embodiment will be described. 14 indicate the refrigerant flow in the heat exchanger 10. As shown in FIG.

First, when the refrigerant discharged from the compressor 14 flows into the condenser section 20 through the inlet pipe 34, in the condenser section 20, as in the first embodiment, the air flows from the refrigerant into the plurality of ventilation channels 20a. to dissipate heat. The refrigerant that has released heat to the airflow flows from the outlet pipe 35 of the condensation section 20 to the throttle section 321e.

The refrigerant flowing through this throttle portion 321e is decompressed by the throttle portion 321e. This depressurized refrigerant flows into the evaporator 22 through the inlet pipe 36 . The refrigerant flowing into the evaporator 22 first flows into the upstream space of the first evaporator component group 224a where the plurality of other-side evaporation tank spaces 221b are connected.

The refrigerant that has flowed into the upstream space of the first evaporating component group 224a is distributed to the plurality of evaporating channels 221c while flowing to one side in the stacking direction Ds in the upstream space.

Here, air flows Tr1 and Tr2 flow from the other side in the width direction Dw of the heat exchanger through the surroundings of the evaporation component 221 (that is, the plurality of ventilation flow paths 22a) to the one side in the width direction Dw of the heat exchanger.

Therefore, the refrigerant flowing through the plurality of evaporation passages 221c is caused to exchange heat with the air flow around the evaporation component 221 (that is, the air flow in the plurality of ventilation passages 22a) while flowing in parallel with each other. absorb heat from

Then, the refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of one-side evaporation tank spaces 221a are connected. Further, the refrigerant flows from the downstream space of the first evaporating component group 224a into the upstream space of the second evaporating component group 224b where the plurality of one-side evaporation tank spaces 221a are connected.

The refrigerant that has flowed into the upstream space of the second evaporating component group 224b is distributed to the plurality of evaporating channels 221c while flowing to one side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of evaporation flow paths 221c exchanges heat with the air flow around the evaporation component 221 (that is, the air flow within the plurality of ventilation flow paths 22a) and absorbs heat from the air.

Refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of other-side evaporation tank spaces 221b are connected. Further, the refrigerant flows from the downstream space of the second evaporating component group 224b into the upstream space of the second evaporating component group 224b where the plurality of other evaporation tank spaces 221b are connected.

The refrigerant that has flowed into the upstream space of the second evaporating component group 224b is distributed to the plurality of evaporating channels 221c while flowing to one side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of evaporation channels 221c is heat-exchanged with the airflow around the evaporation component 221 (that is, the airflow in the plurality of ventilation channels 22a), and absorbs heat from the airflow. .

Then, the refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of one-side evaporation tank spaces 221a are connected.

Furthermore, the refrigerant flows from the downstream space of the second evaporating component group 224b into the upstream space of the third evaporating component group 224c where the plurality of one-side evaporation tank spaces 221a are connected.

The refrigerant that has flowed into the upstream space of the third evaporating component group 224c is distributed to the plurality of evaporating channels 221c while flowing to one side in the stacking direction Ds in the upstream space. While flowing in parallel with each other, the refrigerant flowing through the plurality of evaporation flow paths 221c exchanges heat with the air flow around the evaporation component 221 (that is, the air flow within the plurality of ventilation flow paths 22a) and absorbs heat from the air. The refrigerant flows from the plurality of evaporation passages 221c into the downstream space where the plurality of other-side evaporation tank spaces 221b are connected. The refrigerant that has flowed into the downstream space of the third evaporating component group 224 c flows from the outlet pipe 37 to the gas-liquid separator 40 outside the heat exchanger 10 .

The gas-liquid separator 40 separates the refrigerant into a gas-phase refrigerant and a liquid-phase refrigerant, and the separated gas-phase refrigerant is sucked into the compressor 14 from the gas-liquid separator 40 . As described above, the refrigerant flows through the heat exchanger 10 and the refrigeration cycle circuit 12 of the present embodiment.

Therefore, similarly to the first embodiment, condensed water is generated on the surface exposed to the ventilation flow path 22a side and on the evaporator fins 223 of each of the plurality of evaporator components 221 of the evaporator 22 . The condensed water W1 and W2 generated in this way drips into the plurality of ventilation channels 20a of the condensation section 20. As shown in FIG. Therefore, the refrigerant flowing through the plurality of condensation passages 201c radiates heat to the condensed water and evaporates the condensed water. Therefore, the condensed water takes heat of vaporization from the refrigerant flowing through the plurality of condensing channels 201c.

Therefore, as shown in FIG. 15, the air volume of the airflow Tr1 flowing in the other side region 240 of the evaporating section 22 is greater than the air volume of the airflow Tr2 flowing in the one side region 241. The air volume of the airflow Tr1 flowing in the other side region 250 of the condensation section 20 is greater than the air volume of the airflow Tr2 flowing in the one side region 251 .

Therefore, the amount of condensed water W1 generated in the other side area 240 of the evaporating section 22 is greater than the amount of condensed water W2 generated in the one side area 241. Therefore, the amount of condensed water W1 flowing from the other side area 240 to the other side area 250 is greater than the amount of condensed water W2 flowing from the one side area 241 to the one side area 251 .

Therefore, in the present embodiment, heat exchange between the refrigerant and the condensed water can be efficiently performed as in the first embodiment. Therefore, the cooling effect of the refrigerant in the condensation section 20 can be improved.

(Fourth Embodiment) In the first embodiment, the inlet pipe 36 is provided in the one side plate portion 30A. Instead, the inlet pipe 36 is provided in the other side plate portion 30B. The fourth embodiment will be described with reference to FIGS. 16 and 17. FIG.

FIG. 16 is a cross-sectional view of the heat exchanger 10 of this embodiment. FIG. 17 is a drawing of the heat exchanger 10 of the present embodiment viewed from the other side in the heat exchanger width direction Dw.

The heat exchanger 10 of the present embodiment and the heat exchanger 10 of the first embodiment differ only in the structure of the evaporating section 22, and the rest of the structure is the same. Therefore, the evaporating section 22 of the heat exchanger 10 of this embodiment will be described.

In this embodiment, as shown in FIGS. 16 and 17, the inlet pipe 36 is brazed to the other side plate portion 30B.

In the present embodiment, a back-side evaporator (not shown) is provided on one side of the evaporator 22 in the heat exchanger width direction Dw (that is, the back side of the paper surface of FIG. 16). In this deep-side evaporator, the refrigerant that has flowed through the inlet pipe 36 absorbs heat from the airflow and evaporates the refrigerant. As shown in FIG. 16, the refrigerant that has passed through such a deep-side evaporator flows into the two other-side evaporation tank spaces 221b in the fourth evaporator component group 224d. The refrigerant that has flowed into the two other-side evaporation tank spaces 221b flows through the evaporation section 22 in the same manner as in the first embodiment.

According to the present embodiment described above, the condensed waters W1 and W2 generated in the evaporating section 22 drop into the plurality of ventilation flow paths 20a of the condensing section 20 in the same manner as in the first embodiment. Therefore, heat is radiated from the refrigerant flowing through the plurality of condensation passages 201c to the condensed water, and the condensed water is vaporized.

Here, the air volume of the airflow Tr1 flowing in the other side region 240 of the evaporating section 22 is greater than the air volume of the airflow Tr2 flowing in the one side region 241. Therefore, in the other side region 240 of the evaporating portion 22 , the amount of heat absorbed by the refrigerant from the air flow is greater than that in the one side region 241 . Therefore, the amount of condensed water W1 generated in the other side area 240 of the evaporating section 22 is greater than the amount of condensed water W2 generated in the one side area 241 . Therefore, the amount of condensed water W1 flowing from the other side area 240 to the other side area 250 is greater than the amount of condensed water W2 flowing from the one side area 241 to the one side area 251 . Therefore, in the present embodiment, heat exchange between the refrigerant and the condensed water can be efficiently performed as in the first embodiment. Therefore, the cooling effect of the refrigerant in the condensation section 20 can be improved.

(Fifth embodiment)
In the third embodiment, an example in which the inlet pipe 36 is provided in the other side plate portion 30B has been described. Description will be made with reference to FIGS. 18 and 19. FIG.

FIG. 18 is a cross-sectional view of the heat exchanger 10 of this embodiment. FIG. 19 is a drawing of the heat exchanger 10 of the present embodiment viewed from the other side in the heat exchanger width direction Dw.

The heat exchanger 10 of the present embodiment and the heat exchanger 10 of the third embodiment differ mainly in the arrangement of the inlet pipe 36 of the evaporating section 22, and the rest of the configuration is the same. Therefore, the evaporating section 22 of the heat exchanger 10 of this embodiment will be described. In FIG. 18, the same reference numerals as in FIG. 14 denote the same items, and the description thereof will be omitted.

In this embodiment, as shown in FIGS. 18 and 19, the inlet pipe 36 is brazed to the one side plate portion 30A while the inlet pipe 36 is inserted into the through hole of the one side plate portion 30A. are spliced.

In the present embodiment, a back-side evaporator (not shown) is provided on one side of the evaporator 22 in the heat exchanger width direction Dw (that is, the back side of the paper surface of FIG. 16). In this deep-side evaporator, the refrigerant that has flowed through the inlet pipe 36 absorbs heat from the airflow and evaporates the refrigerant. As shown in FIG. 18, the refrigerant that has passed through such a deep-side evaporator flows into the two other-side evaporation tank spaces 221b in the first evaporator component group 224a. The refrigerant that has flowed into the two other-side evaporation tank spaces 221b flows through the evaporation section 22 in the same manner as in the third embodiment.

According to the present embodiment described above, the condensed waters W1 and W2 generated in the evaporating section 22 drop into the plurality of ventilation flow paths 20a of the condensing section 20 in the same manner as in the third embodiment. Therefore, heat is radiated from the refrigerant flowing through the plurality of condensation passages 201c to the condensed water, and the condensed water is vaporized.

Here, the air volume of the airflow Tr1 flowing in the other side region 240 of the evaporating section 22 is greater than the air volume of the airflow Tr2 flowing in the one side region 241. Therefore, in the other side region 240 of the evaporating portion 22 , the amount of heat absorbed by the refrigerant from the air flow is greater than that in the one side region 241 . Therefore, the amount of condensed water W1 generated in the other side area 240 of the evaporating section 22 is greater than the amount of condensed water W2 generated in the one side area 241 . Therefore, the amount of condensed water W1 flowing from the other side area 240 to the other side area 250 is greater than the amount of condensed water W2 flowing from the one side area 241 to the one side area 251 .

Therefore, in this embodiment, heat exchange between the refrigerant and the condensed water can be efficiently performed, as in the third embodiment. Therefore, the cooling effect of the refrigerant in the condensation section 20 can be improved.

(Sixth embodiment)
In the above-described first embodiment, an example in which the airflow Tr1 and the airflow Tr2 flow from the other side in the heat exchanger width direction Dw to the other side region 240 and the one side region 241 of the evaporating section 22 is described. bottom.

However, instead of this, in the present embodiment, as shown in FIG. 20, the air flow Tr1 and the air flow Tr2 are directed toward the other side region 240 and the one side region 241 of the evaporating section 22 in the heat exchanger width direction Dw. You may make it flow from one side to the other side.

In the other side region 250 and the one side region 251 of the condenser section 20 of the present embodiment, the airflow Tr1 and the airflow Tr2 flow from the other side in the heat exchanger width direction Dw to the one side in the same manner as in the first embodiment. . Therefore, the airflows Tr1 and Tr2 flowing into the evaporating section 22 and the airflows Tr1 and Tr2 flowing into the condensing section 20 are in a counterflow relationship.
The configuration of the heat exchanger 10 is the same between this embodiment and the first embodiment. According to the present embodiment described above, the same effects as those of the first embodiment can be obtained.

(Seventh embodiment)
In the above-described third embodiment, an example in which the airflow Tr1 and the airflow Tr2 flow from the other side in the heat exchanger width direction Dw to the other side region 240 and the one side region 241 of the evaporating section 22 is described. bottom.

However, instead of this, in the present embodiment, as shown in FIG. 21, the air flow Tr1 and the air flow Tr2 are directed toward the other side region 240 and the one side region 241 of the evaporating section 22 in the heat exchanger width direction Dw. You may make it flow from one side to the other side.

In the other side region 250 and the one side region 251 of the condensation section 20 of the present embodiment, airflow Tr1 and airflow Tr2 flow from the other side in the heat exchanger width direction Dw to one side in the same manner as in the third embodiment. . Therefore, the airflows Tr1 and Tr2 flowing into the evaporating section 22 and the airflows Tr1 and Tr2 flowing into the condensing section 20 are in a counterflow relationship.
The configuration of the heat exchanger 10 is the same between this embodiment and the third embodiment. According to the present embodiment described above, it is possible to obtain the same effects as those of the third embodiment.

(Eighth embodiment)
In the above-described fourth embodiment, an example in which the airflow Tr1 and the airflow Tr2 flow from the other side in the heat exchanger width direction Dw to the other side region 240 and the one side region 241 of the evaporating section 22 is described. bottom.

However, instead of this, in the present embodiment, as shown in FIG. 22, the air flow Tr1 and the air flow Tr2 are directed toward the other side region 240 and the one side region 241 of the evaporating section 22 in the heat exchanger width direction Dw. You may make it flow from one side to the other side.

In the other side region 250 and the one side region 251 of the condenser section 20 of the present embodiment, the airflow Tr1 and the airflow Tr2 flow from the other side in the heat exchanger width direction Dw to the one side in the same manner as in the fourth embodiment. . Therefore, the airflows Tr1 and Tr2 flowing into the evaporating section 22 and the airflows Tr1 and Tr2 flowing into the condensing section 20 are in a counterflow relationship.
The configuration of the heat exchanger 10 is the same between this embodiment and the fourth embodiment. According to the present embodiment described above, the same effects as those of the fourth embodiment can be obtained.

(Ninth embodiment)
In the fifth embodiment, an example in which the airflow Tr1 and the airflow Tr2 flow from the other side in the heat exchanger width direction Dw to the other side region 240 and the one side region 241 of the evaporating section 22 is described. bottom.

However, instead of this, in the present embodiment, as shown in FIG. 23, the air flow Tr1 and the air flow Tr2 are directed toward the other side region 240 and the one side region 241 of the evaporating section 22 in the heat exchanger width direction Dw. flow from one side to the other.

In the other side region 250 and the one side region 251 of the condensation section 20 of the present embodiment, airflow Tr1 and airflow Tr2 flow from the other side in the heat exchanger width direction Dw to the one side in the same manner as in the fifth embodiment. . Therefore, the airflows Tr1 and Tr2 flowing into the evaporating section 22 and the airflows Tr1 and Tr2 flowing into the condensing section 20 are in a counterflow relationship.
The configuration of the heat exchanger 10 is the same between this embodiment and the fourth embodiment. According to the present embodiment described above, the same effects as those of the fifth embodiment can be obtained.

(Tenth embodiment)
In the above-described first embodiment, an example in which the evaporating section 22 and the condensing section 20 are configured independently has been described.

However, instead of this, the tenth embodiment in which the evaporating section 22 and the condensing section 20 are integrated will be described with reference to FIG. 24, the same reference numerals as in FIG. 3 denote the same components, and the description thereof will be omitted.

The configuration of the present embodiment and the first embodiment is the same except that the one side plate portions 30A and 30C and the other side plate portions 30B and 30D are different.

In this embodiment, as shown in FIG. 24, the one side plate portions 30A and 30C are integrated to form one side plate 31A. The other side plate portions 30B and 30D are integrated to form the other side plate 31B.

The one-side side plate 31A is arranged on one side in the stacking direction Ds with respect to the evaporating section 22 and the condensing section 20 (that is, one side in the predetermined direction). The other side plate 31B is arranged on the other side in the stacking direction Ds (that is, one side in the predetermined direction) with respect to the evaporating section 22 and the condensing section 20 .

The one-side side plate 31A is brazed to the evaporating section 22 and the condensing section 20 . Thereby, the evaporating section 22 and the condensing section 20 are supported by the one side plate 31A.

The other side plate 31B is brazed to the evaporator 22 and the condenser 20 . Thereby, the evaporating section 22 and the condensing section 20 are supported by the other side plate 31B.

As described above, the evaporating section 22 and the condensing section 20 are integrated by the one side plate 31A and the other side plate 31B. Therefore, the number of parts of the heat exchanger 10 can be reduced, and the physical size of the heat exchanger 10 can be reduced.

(Other embodiments)
(1) In the above-described first to tenth embodiments, an example in which the air conditioner 1 is an air conditioner for a vehicle has been described. household air conditioner) or the like.

(2) In the first to tenth embodiments, the example in which the evaporating section 22 and the condensing section 20 are configured by one refrigeration cycle circuit 12 has been described. However, instead of this, the evaporating section 22 and the condensing section 20 may be configured by independent refrigerating cycle circuits 12 .

(3) In the above-described first embodiment, an example in which the air flow blown out from one centrifugal fan 4 flows into the evaporating section 22 and the condensing section 20 has been described. However, instead of this, two centrifugal blowers may be provided that independently flow air into the evaporating section 22 and the condensing section 20 . This also applies to the first to tenth embodiments.

(4) In the above-described first embodiment, an example in which the centrifugal blower 4 is used as the blower of the vehicle air conditioner 1 has been described. However, instead of this, a blower other than the centrifugal blower may be used as the blower of the vehicle air conditioner 1 .

(5) It should be noted that the present disclosure is not limited to the above-described embodiments, and can be modified as appropriate. Moreover, the above-described embodiments are not unrelated to each other, and can be appropriately combined unless the combination is clearly impossible. Further, in each of the above-described embodiments, it goes without saying that the elements constituting the embodiment are not necessarily essential, unless it is explicitly stated that they are essential, or they are clearly considered essential in principle. stomach.

Claims (6)

1. A first refrigerant flow path (201c) for circulating the first refrigerant flowing into the first refrigerant inlet (34) toward the first refrigerant outlet (35), and a first air flow around the first refrigerant flow path. a heat radiating portion (20) that forms a first air flow path (20a) that allows the passage of the first refrigerant to dissipate heat to the first air flow;
   a second refrigerant flow path (221c) arranged vertically above the heat radiating portion for circulating the second refrigerant that has flowed into the second refrigerant inlet (36) toward the second refrigerant outlet (37); A second air flow path (22a) for passing a second air flow is formed around the second refrigerant flow path, and the second refrigerant absorbs heat from the second air flow to evaporate the second refrigerant. and an evaporator (22) for
   condensed water generated in the evaporating portion as the heat is absorbed by the second refrigerant flows to the heat radiating portion to cool the first refrigerant;
   A half area of the first coolant inlet side of the first coolant flow channel of the heat radiating part is defined as a first region (250), and a half area of the first coolant flow channel of the heat radiating part on the first coolant outlet side is defined as a first region (250). A half area is defined as a second area (251), a half area on the first area side of the second air flow path of the evaporator is defined as a third area (240), and the second air of the evaporator is defined as a third area (240). When the half region (241) of the channel on the second region side is the fourth region,
   A heat exchanger in which the air volume of the second airflow flowing through the third region is greater than the air volume of the second airflow flowing through the fourth region.
2. When the direction in which the first region (250) and the second region (251) are aligned is defined as the alignment direction (Ds),
   The second refrigerant inlet (36) is arranged on the side of the second region (251) in the alignment direction in the second refrigerant flow path of the evaporator, and the second refrigerant outlet (37) is arranged in the The heat exchanger according to claim 1, wherein the second refrigerant flow path of the evaporator is arranged on the side of the first region (250) in the alignment direction.
3. Side plates (31A, 31B) arranged on one side or the other side in a predetermined direction (Ds) with respect to the heat radiating section and the evaporating section,
   The heat exchanger according to claim 1 or 2, wherein the heat radiation section and the evaporation section are integrated by supporting the heat radiation section and the evaporation section by the side plates.
4. a blower (4) for blowing an airflow;
   a first refrigerant channel (201c) for circulating the first refrigerant that has flowed into the first refrigerant inlet (34) toward the first refrigerant outlet (35); a heat radiating part (20) that forms a first air flow path (20a) that passes through and that radiates heat from the first refrigerant to the air flow;
   a second refrigerant flow path (221c) arranged vertically above the heat radiating portion for circulating the second refrigerant that has flowed into the second refrigerant inlet (36) toward the second refrigerant outlet (37); a second air flow path (22a) through which the air flow passes around the second refrigerant flow path, and an evaporating portion that causes the second refrigerant to absorb heat from the air flow to evaporate the second refrigerant; (22) and
   condensed water generated in the evaporating portion along with the heat absorption of the second refrigerant flows to the heat radiating portion to cool the first refrigerant;
   A half area of the first coolant inlet side of the first coolant flow channel of the heat radiating part is defined as a first region (250), and a half area of the first coolant flow channel of the heat radiating part on the first coolant outlet side is defined as a first region (250). A half area is defined as a second area (251), a half area on the first area side of the second air flow path of the evaporator is defined as a third area (240), and the second air of the evaporator is defined as a third area (240). When the half region (241) of the channel on the second region side is the fourth region,
   An air conditioner in which a volume of air flowing through the third region is greater than a volume of air flowing through the fourth region.
5. The blower includes a fan (4a) that blows out the airflow, and a duct (5) that guides the airflow blown out from the fan to the first air flow path and the second air flow path,
   5. The air conditioner according to claim 4, wherein the duct is configured such that the volume of air flowing through the third region is greater than the volume of air flowing through the fourth region.
6. 6. The air conditioner according to claim 5, wherein the air flow blown out from the blower flows into the first air flow path and the second air flow path from one side in a predetermined direction (Dw). .

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