KR102538973B1 - Heat Exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger, and more particularly, to a heat exchanger in which a first header tank and a second header tank are arranged in two rows in the width direction and a heat exchange medium is introduced and discharged in the width direction, wherein the heat exchange medium is disposed in the first header A heat exchanger capable of improving heat exchange performance by uniformly distributing a heat exchange medium in the heat exchanger by increasing the number of paths through which a tank and a second header tank flow.

Description

Heat Exchanger {Heat Exchanger}

The present invention relates to a heat exchanger, and more particularly, to a heat exchanger in which a first header tank and a second header tank are arranged in two rows in the width direction and a heat exchange medium is introduced and discharged in the width direction, wherein the heat exchange medium is disposed in the first header A heat exchanger capable of improving heat exchange performance by uniformly distributing a heat exchange medium in the heat exchanger by increasing the number of paths through which a tank and a second header tank flow.

1 shows that an inlet 11 through which the heat exchange medium is introduced and an outlet 12 through which the heat exchange medium is discharged are formed in the width direction of the first header tank 13 so that the heat exchange medium is introduced and discharged in the width direction, and the first header tank 13 ) and the second header tank 14 are conventional heat exchangers 10 arranged in two rows.

At this time, in the conventional heat exchanger 10, a path in which the heat exchange medium flows through the tube 15 between the first header tank 13 and the second header tank 14 through a partition wall for uniform distribution of the heat exchange medium. will increase the number.

In the conventional heat exchanger 10, the heat exchange medium is introduced and discharged in the width direction (side surface) of the first header tank 10, so it is generally formed to have four paths according to the limitations thereof.

That is, since the conventional heat exchanger 10 has four paths, there is a problem in that the heat exchange medium is not evenly distributed when the flow rate of the heat exchange medium is low due to the low load because the number of paths is small. Accordingly, the performance of the heat exchanger is improved. There is a problem with deterioration.

Republic of Korea Patent Registration No. 10-1385230 (2014.04.08.)

The present invention has been made to solve the above problems, and an object of the present invention is a heat exchange in which a first header tank and a second header tank are arranged in two rows in the width direction and a heat exchange medium is introduced and discharged in the width direction. To provide a heat exchanger capable of improving heat exchange performance by uniformly distributing the heat exchange medium in the heat exchanger by increasing the number of paths through which the heat exchange medium flows through the first header tank and the second header tank.

The heat exchanger according to the present invention includes a first header tank 200 and a second header tank 300 which have a certain length in the longitudinal direction and are divided into two rows, a front row and a back row, in a width direction perpendicular to the longitudinal direction; And a tube 400 connecting the front row of the first header tank 200 and the second header tank 300 and the rear row of the first header tank 200 and the second header tank 300 to each other, , In the heat exchanger in which the heat exchange medium is introduced into and discharged from the front heat of the first header tank 200 in the width direction, the heat exchange medium between the first header tank 200 and the second header tank 300 When the flow path is referred to as a path, the heat exchange medium flows into the front and rear rows in the width direction at one side of the longitudinal direction of the first header tank 200 in the back row, and heat is exchanged between the front row and back row of the second header tank 300. It has four passes, including one pass through which the medium flows, and the heat exchanger flows from the front row of the second header tank 300 to the front row of the first header tank 200 to discharge the heat exchange medium. It is characterized by having two passes including a pass.

In addition, the first header tank 200 is formed in the longitudinal direction to divide the front row and the rear row, and the first front row one side space 201A and the first rear row other side space 201D are formed to communicate with each other. The first compartment 210 including the penetrating part 211 and the second penetrating part 212 formed by penetrating so that the first front row other side space 201C and the first rear row other side space 201F communicate with each other The second header tank 300 is formed in the longitudinal direction to divide the front row and the rear row, and the second front row one side space 301A and the second back row one side space 301C are formed to communicate with each other. It is characterized in that it further includes a second compartment 310 including a three-through portion 311.

In addition, the first header tank 200 includes a 1-1 front row partition wall 221-1 dividing the first front row side space 201A and the first front row center space 201B, and the first front row center space 201B. The first front row partition 221 including the first and second front row partitions 221-2 partitioning the space 201B and the other side space 201C of the first front row, and the first front row one side space 201D and the first front row partition 221 A 1-1 rear row partition 222-1 partitioning the first rear row central space 201E, and a 1-2 rear row partition partitioning the first rear row central space 201E and the other first rear row space 201F It is characterized in that it includes a first header tank partition wall portion 220 further including a first rear row partition wall 222 including (222-2).

In addition, the second header tank 300 includes a second heat transfer partition wall including a 2-1 heat transfer partition wall 321-1 dividing the space on one side of the second heat transfer row 301A and the space on the other side of the second heat transfer row 301B. 321, and a second rear row partition 322 including a 2-1 rear row partition 322-1 partitioning the second rear row one side space 301C and the second rear row other side space 301D. It is characterized in that it further comprises a second header tank bulkhead portion 320.

In addition, the second header tank 300 is characterized in that a throttle 323 is provided in the space 301B on the other side of the second electric row.

In addition, in the heat exchanger 1000, the first heat exchanger central space 201B is adjacent to the first heat transfer side space 201A on the other side in the longitudinal direction, and the heat exchange medium is discharged in the width direction in the 1-1 heat transfer central space ( 201B-1) and the central space 201B-2 of the first-second row adjacent to the other side space 201C of the first row, and the other side space 301B of the second row passes through the tube 400. The other side space (301B-1) of the 2-1 row connected to the 1-1 row central space (201B-1) and the 1-2 row central space (201B-2) through is partitioned into the 1-2 front row central space 201B-2 and the 2-1st front row other side space 301B-2 connected to the 1st front row other side space 201C, so that the front row has two more passes. characterized by

In addition, the first front row partition 221 divides the first front row central space 210B into the 1-1st front row central space 201B-1 and the 1-2nd front row central space 201B-2. It further includes a 1-3 heat transfer partition 221-3, and the second heat transfer partition 321 divides the second heat transfer row other side space 301B into the 2-1 heat transfer row other side space 301B-1 and the second heat transfer partition 301B. It is characterized in that it further includes a 2-2 heat transfer partition wall 321-2 partitioning into the other heat transfer space 301B-2.

The heat exchanger according to the present invention has the advantage of uniformly distributing the heat exchange medium in the heat exchanger by increasing the number of paths through which the heat exchange medium flows between the first header tank and the second header tank.

In addition, the heat exchanger according to the present invention has the advantage of improving heat exchange performance through uniform distribution of the heat exchange medium.

In addition, the heat exchanger according to the present invention has the advantage of increasing the number of paths through which the heat exchange medium flows through the first header tank and the second header tank through a simple configuration.

1 is a view conceptually showing a conventional two-row heat exchanger
2 is a perspective view of a heat exchanger according to a first embodiment of the present invention;
3 is a view conceptually showing the flow of the heat exchange medium in the heat exchanger according to the first embodiment of the present invention.
4 is a conceptual view of a heat exchanger according to a first embodiment of the present invention;
5 is a view conceptually showing the flow of a heat exchange medium in a heat exchanger according to a second embodiment of the present invention.
6 is a view conceptually showing a heat exchanger according to a second embodiment of the present invention
7 is a view conceptually showing the flow of a heat exchange medium in a heat exchanger according to a third embodiment of the present invention.
8 is a view conceptually showing a heat exchanger according to a second embodiment of the present invention

Hereinafter, a heat exchanger according to the present invention as described above will be described in detail with reference to the accompanying drawings.

<First Embodiment>

2 is a perspective view of a heat exchanger according to the first embodiment of the present invention, FIG. 3 is a view conceptually showing the flow of a heat exchange medium in the heat exchanger according to the first embodiment of the present invention, and FIG. It is a view conceptually showing the heat exchanger according to the first embodiment of the invention.

2 to 4, the heat exchanger 1000 according to the first embodiment of the present invention includes a first header tank 200 and a second header tank 300 that have a predetermined length and are spaced apart from each other. , The first header tank 200 and the second header tank 300 are connected to each other to include a tube 400 provided to allow a heat exchange medium to flow, wherein the first header tank 200 and the second header The tank 300 is a two-row heat exchanger partitioned into two rows of a front row and a back row in a width direction perpendicular to the longitudinal direction.

In addition, the heat exchanger 1000 according to the first embodiment of the present invention is a heat exchanger in which a heat exchange medium is introduced and discharged in the width direction of the first header tank 200, and for this purpose, the inlet 110 through which the heat exchange medium flows and the discharge port 120 is formed in communication with the front row of the first header tank 200 in the width direction.

At this time, in the heat exchanger 1000 according to the first embodiment of the present invention, a path in which the heat exchange medium flows through the tube 400 between the first header tank 200 and the second header tank 300 is referred to as a path. In this case, the rear row includes one pass through which the heat exchange medium flows into the front and rear rows of the second header tank 300 in the width direction on one side in the longitudinal direction of the first header tank 200, and the heat exchange medium flows into the front and rear rows of the second header tank 300. Thus, it has four passes, and the front row flows from the front row of the second header tank 300 to the front row of the first header tank 200 and has two passes, including one pass for discharging the heat exchange medium.

That is, the heat exchanger 1000 according to the first embodiment of the present invention is a heat exchanger having 6 passes including 4 passes of the rear row and 2 passes of the front row, through which the conventional two-row heat exchanger having 4 passes By increasing the number of passes compared to the heat exchanger, it is possible to have a uniform temperature distribution throughout the heat exchanger.

The heat exchanger 1000 according to the first embodiment of the present invention described above will be described in more detail.

In the heat exchanger 1000 according to the first embodiment of the present invention, the heat exchanger 1000 of the first header tank 200 extends from the first heat transfer row side space 201A into which the heat exchange medium flows in the width direction at the first side in the longitudinal direction to the other longitudinal heat exchanger. It is partitioned into a first front row central space (201B) and a first front row other side space (201C) at the farthest side in the longitudinal direction, in which the heat exchange medium is discharged in the width direction, and the rear row communicates with the first front row one side space (201A) The first rear row one side space 201D is divided into the first rear row other side space 201E at the farthest side in the longitudinal direction communicating with the first rear row central space 201E and the first front row other side space 201C adjacent to the other side in the longitudinal direction. do.

That is, the front row and the rear row of the first header tank 200 are partitioned into three zones in the longitudinal direction.

The second header tank 300 has a second front row one side space 301A in which the front row is connected to the first front row one side space 201A through a tube 400 and a first front row central space 201B through the tube 400. and the second front row other side space 301B connected to the first front row other side space 201C, the rear row communicates with the second front row one side space 301A and the first rear row one side space 201D through the tube 400 ) and the second rear row one side space 301C connected to the first rear row central space 201E and the second rear row other side space connected to the first rear row central space 201E and the first rear row other side space 201F through a tube. (301D).

That is, the front row and the back row of the second header tank 300 are divided into two zones in the longitudinal direction.

As described above, in the heat exchanger 1000 according to the first embodiment of the present invention, the front row and rear row of the first header tank 200 are divided into three zones in the longitudinal direction, and the second header tank 300 The anterior and posterior rows are longitudinally divided into two zones.

To explain the flow of the heat exchange medium in the heat exchanger according to the first embodiment of the present invention having the above-described configuration, the first heat exchanger one side space 201A, the first heat transfer one side space 201A and The heat exchange medium is introduced into the communicating first rear row side space 201D, from the first front row one side space 201A to the second front row one side space 301A, and from the first rear row one side space 201D to the second back row one side space The heat exchange medium flows through (301C), and the above-described path is referred to as the first pass (P1).

The heat exchange medium flowing from the second front row one side space 301A to the second rear row one side space 301C and the heat exchange medium flowing from the second back row one side space 301C flow to the first rear row central space 201E, as described above. The path is referred to as the second pass P2.

The flow path from the first rear row central space 201E to the second rear row other side space 301D is called a third path P3, and flows from the second rear row other side space 301D to the first rear row other side space 201F. is referred to as the fourth pass (P4), and the heat exchange medium flowing to the first rear row other side space 201C communicating with the first rear row other side space 201F flows to the second front row other side space 301B, as described above. This route is referred to as the fifth pass (P5).

In order to be discharged through the discharge port in the space on the other side of the second heat transfer row 301B, the heat exchange medium flows into the central space 201B of the first heat transfer row communicating with the discharge port, and the above-described path is referred to as the sixth pass P6.

As described above, the heat exchanger 1000 according to the first embodiment of the present invention forms six passes for the heat exchange medium flowing between the first header tank 200 and the second header tank 300, , Compared to the conventional heat exchanger, the number of passes is increased so that the distribution of the heat exchange medium can be uniformly distributed, thereby improving the performance and temperature distribution of the heat exchanger.

The configuration for forming six passes in the heat exchanger 1000 according to the first embodiment of the present invention described above will be described in more detail.

The first header tank 200 includes a first partition 210 formed to be divided into a front row and a rear row, and the first partition 210 is formed to have a certain length in the longitudinal direction.

At this time, the first compartment 210 includes a first through-portion 211 formed by penetrating so that the first front row one side space 201A and the first rear row one side space 201D communicate with each other, and the first first front row one side space 201C. and a second through-portion 212 formed by penetrating to communicate with the first rear row other side space 201F.

The shapes of the first through part 211 and the second through part 212 are not limited, and they must be formed in a shape that does not hinder the flow of the heat exchanging medium.

In addition, the second header tank 300 includes a second partition 310 that divides the front row and rear row, and the second partition 310 includes a second front row side space 301A and a second back row side space ( 301C) is formed to communicate with the third through-portion 311, so that the heat exchange medium flowing in the one side space 301A of the second front row during the first pass flows into the one side space 301C of the second rear row. .

In addition, the first header tank 200 includes the first header tank partition wall portion 220 which divides in the longitudinal direction to form the above-described six regions together with the first partition portion 210 described above.

The first header tank partition 220 includes a first front row partition 221 partitioning the front row of the first header tank 200 and a first back row partition 222 partitioning the rear row of the first header tank 200. made including

The first heat transfer barrier 221 divides the front row of the first header tank 200 in the longitudinal direction, and together with the first partition 210, the first heat transfer partition 201A, the first heat transfer central space 201B, and The 1-1 front row partition 221-1 forms the first front row other side space 201C, and the first front row partition 221 partitions the first front row one side space 201A and the first front row central space 201B. ), and the first and second heat transfer partitions 221-2 to form the first heat transfer central space 201B and the first heat transfer other side space 201C.

The first rear row bulkhead 222 partitions the rear row of the first header tank 200 in the longitudinal direction, and together with the first partition 210, the first rear row side space 201D, the first rear row central space 201E, and The first rear row other side space 201F is formed, and the first rear row partition 222 divides the first rear row one side space 201D and the first rear row central space 201E. ), and the first-second rear partition 222-2 partitioning the first rear row central space 210E and the first rear row other side space 201F.

In addition, the second header tank 300 includes the second header tank partition wall portion 320 which divides in the longitudinal direction and forms the above-described four regions together with the second partition portion 310 described above.

The second header tank partition 320 includes a second front row bulkhead 321 dividing the front row of the second header tank 300 and a second back row bulkhead 322 dividing the rear row of the second header tank 300. made including

The second front row partition 321 partitions the front row of the second header tank 300 in the longitudinal direction, and together with the second partition 310, the second front row one side space 301A and the second second front row other side space 301B. The second heat transfer partition 321 includes the 2-1 heat transfer partition 321-1 that divides the space on one side of the second heat transfer row 301A and the space on the other side of the second heat transfer row 201B.

<Second Embodiment>

5 is a view conceptually showing the flow of the heat exchange medium in the heat exchanger according to the second embodiment of the present invention, and FIG. 6 is a view conceptually showing the heat exchanger according to the second embodiment of the present invention.

5 and 6, in the second header tank 300 of the heat exchanger 1000 according to the second embodiment of the present invention, a throttle 323 is further provided in the space 301B on the other side of the second transfer row. .

That is, in the heat exchanger, the heat exchange medium is driven downstream in each pass due to the inertia of the heat exchange medium, which makes the distribution of the heat exchange medium non-uniform.

To this end, the heat exchanger 1000 according to the second embodiment of the present invention exchanges heat for flow through the second header tank 300 located below the first header tank 200, particularly through the sixth pass P6. By providing the throttle 313 in the space 301B on the other side of the second heat exchanger where the medium flows, the tendency of the heat exchange medium to flow downstream is suppressed.

That is, the heat exchange medium distribution uniformity in the fifth pass P5 and the sixth pass P6 can be improved by preventing the heat exchange medium from being excessively driven downstream through the throttle 313 .

<Third Embodiment>

7 is a view conceptually showing the flow of a heat exchange medium in a heat exchanger according to a third embodiment of the present invention, and FIG. 8 is a view conceptually showing a heat exchanger according to a second embodiment of the present invention.

7 and 8, in the heat exchanger 1000 according to the third embodiment of the present invention, the first front row central space 201B of the first header tank 200 is separated from the first front row side space 201A. It is divided into a 1-1 row center space 201B-1 adjacent to the other side in the longitudinal direction and from which heat exchange medium is discharged, and a 1-2 row center space 201B-2 adjacent to the 1-2 row center space 201C adjacent to the first row other side space 201C. 2-1 front row in which the second front row other side space 301B is connected to the 1-1 front row central space 201B-1 and the 1-2nd front row central space 201B-2 through the tube 400 The other side space 301B-1 and the 2-1st front row other side space 301B located on the farthest side in the longitudinal direction and connected to the 1-2nd row central space 201B-2 and the 1st front row other side space 201C -2), so that the front row has two more passes.

That is, since the heat exchanger 1000 according to the third embodiment of the present invention has 8 passes, the heat exchange medium can be more uniformly distributed.

As described above, in the heat exchanger 1000 according to the third embodiment of the present invention, the front row of the first header tank 200 is divided into four zones in the longitudinal direction, and the rear row is partitioned into three zones in the longitudinal direction. The front row of the second header tank 300 is divided into three zones, and the rear row is divided into two zones.

To explain the flow of the heat exchange medium in the heat exchanger 1000 according to the third embodiment of the present invention having the above-described configuration, the first heat transfer side space 201A and the first heat transfer side space through the inlet 110 The heat exchange medium flows into the first rear row one side space 201D communicating with the first rear row 201A, from the first front row one side space 201A to the second front row one side space 301A, and from the first rear row one side space 201D to the second front row one side space 201A. The heat exchange medium flows into the space 301C on one side of the second rear row, and the above-described path is referred to as the first pass P1.

The heat exchange medium flowing from the second front row one side space 301A to the second rear row one side space 301C and the heat exchange medium flowing from the second back row one side space 301C flow to the first rear row central space 201E, as described above. The path is referred to as the second pass P2.

The flow path from the first rear row central space 201E to the second rear row other side space 301D is called a third path P3, and flows from the second rear row other side space 301D to the first rear row other side space 201F. is referred to as the fourth pass (P4), and the heat exchange medium that has flowed into the first rear row other side space 201C communicated with the first rear row other side space 201F is transferred to the 2-1st front row other side space 301B-2. It flows, and the above-described path is referred to as the fifth pass (P5).

The heat exchange medium flows from the other side space 301-1B of the 2-1 row to the central space 201B-2 of the 1-2 row, which is referred to as the sixth pass P6.

The heat exchange medium flowing in the central space 201B-2 of the 1-2 row flows to the other side space 301B-1 of the 2-1 row, which is referred to as the 7th pass (P7), and the other side of the 2-1 row. In the space 301B-1, the heat exchange medium flows to the 1-1 front row central space 201B-1 communicating with the outlet to be discharged through the outlet, and the above-described path is referred to as the eighth pass P8.

As described above, the heat exchanger 1000 according to the third embodiment of the present invention forms eight passes for the heat exchange medium flowing between the first header tank 200 and the second header tank 300. , the distribution of the heat exchange medium can be more uniformly distributed, and through this, the performance and temperature distribution of the heat exchanger can be further improved.

The configuration for forming eight passes in the heat exchanger 1000 according to the third embodiment of the present invention described above will be described in more detail.

The above-described first front row bulkhead 221 of the first header tank partition 220, together with the first partition 210, connects the first front row central space 201B to the discharge port and communicates with the 1-1 front row central space ( 201B-1) and the 1st-3rd front row partition wall 221-3 partitioning the 1st-2nd front row central space 201B-2.

In addition, the second front row partition 321, together with the second partition 310, divides the second row other side space 301B into the 2-1 row other side space 301B-1 and the 2-2 row other side space 301B. -2) further comprising a 2-2 heat transfer partition 321-2 partitioned.

In addition, in the heat exchanger 1000 according to the third embodiment of the present invention, a throttle may be further provided in the other side space 301B-1 of the 2-1 front row, but is not limited thereto.

The present invention is not limited to the above-described embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

1000: heat exchanger
110: inlet 120: outlet
200: first header tank
201A: One side space of the first row 201B: Center space of the first row
201B-1: Center space of row 1-1 201B-2: Center space of row 1-2
201C: space on the other side of the first front row 201D: space on one side of the first rear row
201E: First rear row center space 201F: First rear row other side space
210: compartment
211: first through part 212: second through part
220: first header tank bulkhead
221: first front heat bulkhead
221-1: 1-1 front heat bulkhead 221-2: 1-2 front heat bulkhead
221-3: 1-3 front row bulkhead
300: second header tank
301A: space on one side of the second row 301B: space on the other side of the second row
301B-1: other side space of row 2-1 301B-2: other side space of row 2-2
301C: space on one side of the second rear row 301D: space on the other side of the second rear row
310: second compartment
311: 3rd penetration
320: second header tank bulkhead
321: second front heat bulkhead
321-1: 2-1 front heat bulkhead 321-2: 2-2 front heat bulkhead
322: second aft bulkhead 322-1: 2-1 aft thermal bulkhead
323: throttle
400: tube

Claims (8)

a first header tank 200 and a second header tank 300 having a certain length in the longitudinal direction and divided into two rows, a front row and a back row, in a width direction perpendicular to the longitudinal direction; And a tube 400 connecting the front row of the first header tank 200 and the second header tank 300 and the rear row of the first header tank 200 and the second header tank 300 to each other, Heat exchange formed by the inlet 110 and the outlet 120 communicating with the front row of the first header tank 200 in the width direction so that the heat exchange medium is introduced into and discharged from the front row of the first header tank 200 in the width direction. In terms of
the heat exchanger
When the path in which the heat exchange medium flows between the first header tank 200 and the second header tank 300 is referred to as a path, the back row is a heat exchange medium in the width direction at one side of the first header tank 200 in the longitudinal direction. is introduced into the front row and back row, and has four passes, including one pass through which the heat exchange medium flows through the front row and back row of the second header tank 300, and the front row is the front row of the second header tank 300. It has two passes, including one pass for discharging the heat exchange medium by flowing through the electric heat of the first header tank 200,
The heat exchange medium that has flowed through the four passes of the back row flows into the passes of the front row through one through-hole,
The heat exchanger 1000 is
The first electric row of the first header tank 200 is adjacent to the first front row in the longitudinal direction from one side space 201A into which the heat exchange medium is introduced in the width direction to the other side in the longitudinal direction, and the heat exchange medium is discharged in the width direction. It is partitioned into a central space 201B and a first front row other side space 201C on the farthest side in the longitudinal direction, and from the first rear row one side space 201D in which the rear row communicates with the first front row one side space 201A to the other side in the longitudinal direction. It is partitioned into a first rear row other side space 201F at the farthest side in the longitudinal direction communicating with the neighboring first rear row central space 201E and the first front row other side space 201C,
A first pass (P1) through which the heat exchange medium flows into the first front row one side space 201A and the first rear row one side space 201D communicating with the first front row one side space 201A through the inlet 110; ,
The first electric row through a second electric row one side space 301A in which the electric row of the second header tank 300 is connected to the first electric row one side space 201A through the tube 400 and the tube 400 It is partitioned into a central space 201B and a second front row other side space 301B connected to the first front row other side space 201C, and the rear row communicates with the second front row one side space 301A through the tube 400. The first rear row central space 201E and the first rear row through the tube 400 and the second rear row one side space 301C connected to the first rear row one side space 201D and the first rear row central space 201E. A heat exchanger partitioned into a second rear row other side space 301D connected to the other side space 201F.
delete According to claim 1,
The first header tank 200 is
The first through-portion 211 formed in the longitudinal direction so as to divide the front row and the back row, and is formed through such that the space on one side of the first front row 201A and the space on the other side of the first back row 201D communicate with each other; A first compartment 210 including a second through part 212 formed by penetrating so that the other side space 201C and the first rear row other side space 201F communicate with each other,
The second header tank 300
The second compartment is formed in the longitudinal direction to divide the front row and the rear row, and includes a third through-portion 311 penetrated so that the second front row one side space 301A and the second rear row one side space 301C communicate with each other. The heat exchanger further comprising section 310.
According to claim 3,
The first header tank 200 is
The 1-1 front row partition wall 221-1 dividing the first front row one side space 201A and the first front row central space 201B, and the first front row central space 201B and the first front row other side space ( 201C) and a first heat transfer partition 221 including 1-2 heat transfer partitions 221-2 partitioning;
The 1-1 rear row partition wall 222-1 dividing the first rear row one side space 201D and the first rear row central space 201E, and the first rear row central space 201E and the first rear row other side space ( 201F), and a first header tank partition wall portion 220 further including a first rear heat partition 222 including first and second rear heat partitions 222-2 partitioning the heat exchanger.
According to claim 4,
The second header tank 300
a second heat transfer partition 321 including a 2-1 heat transfer partition 321-1 partitioning the space on one side of the second heat transfer row 301A and the space on the other side of the second heat transfer row 301B;
A second header tank bulkhead including a second rear row bulkhead 322 including a 2-1 rear row bulkhead 322-1 dividing the second rear row one side space 301C and the second second rear row other side space 301D. The heat exchanger further comprising section 320.
The method of any one of claims 1 and 5,
The second header tank 300
A throttle 323 is provided in the second heat exchanger side space 301B.
The method of any one of claims 1 and 5,
The heat exchanger 1000 is
The first electric row central space 201B is adjacent to the other side of the first electric row in the longitudinal direction from the first electric row central space 201A, and the 1-1 electric row central space 201B-1 in which the heat exchange medium is discharged in the width direction, and the first electric row central space 201B-1 It is divided into the other front row space (201C) and the adjacent 1-2 front row central space (201B-2),
The 2-1st row's other side space 301B is connected to the 1-1st row's central space 201B-1 and the 1-2nd row's central space 201B-2 through the tube 400. The other side space of the first row (301B-1) and the other side space of the 2-1 row (located on the farthest side in the longitudinal direction and connected to the central space of the 1-2 row (201B-2) and the other side space of the first row (201C) 301B-2),
A heat exchanger in which the front row has two more passes.
According to claim 7,
The first front row partition 221 divides the first row center space 201B into the 1-1 row center space 201B-1 and the 1-2 row center space 201B-2. -3 further including the front heat bulkhead (221-3),
The second front row partition wall 321 divides the second row other side space 301B into a 2-1 row other side space 301B-1 and a 2-2 row other side space 301B-2. 2, heat exchanger further comprising a heat transfer partition (321-2)

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