DE112022002135T5 - Heat exchanger - Google Patents

Abstract

A heat exchanger 100 that performs heat exchange between a refrigerant circulating in a refrigeration cycle and outside air includes: a plurality of tubes 1 arranged in parallel and configured to allow the refrigerant to flow therethrough; a fin 3 provided between the mutually adjacent tubes 1 and configured to allow the outside air to pass therethrough. The fin 3 includes: a plurality of contact portions 31 alternately in contact with one and the other of the adjacent tubes 1; a plurality of wall portions 32 each connecting the mutually adjacent contact portions 31 to connect the adjacent tubes 1; an extension portion 35 extending from the contact portions 31 and the wall portions 32 and protruding upstream of the tubes 1 in a flow direction of the outside air; and a plurality of fins 36 provided on each of the wall portions 32 continuously along the flow direction of the outside air. A downstream end portion 36b of a most upstream fin 36 in the flow direction of the outside air is arranged upstream of a front end 12 of each of the tubes 1 in the flow direction of the outside air.

Description

Technical area

The present invention relates to a heat exchanger.

State of the art

JP5563162 B discloses an outdoor heat exchanger of a vehicle air conditioner, the outdoor heat exchanger comprising a plurality of flat tubes and corrugated fins provided between adjacent flat tubes, a plate portion of each of the corrugated fins comprising a plurality of slits, and the plate portion comprising an extension portion extending from a connection region with the flat tube against the wind.

Summary of the invention

However, if the vehicle air conditioning system in the outdoor heat exchanger in JP5563162 B performs heating operation, water vapor contained in outdoor air is cooled and frost may be formed on the expansion portion. When frost is formed on the expansion portion, the outdoor air does not directly contact the flat tube and thus the heat exchange performance of the outdoor heat exchanger decreases.

It is an object of the invention to prevent a decrease in the heat exchange performance of a heat exchanger.

According to an aspect of the present invention, a heat exchanger that performs heat exchange between a refrigerant circulating in a refrigeration cycle and outside air, the heat exchanger comprising a plurality of tubes arranged in parallel and configured to allow the refrigerant to flow therethrough, a fin provided between the mutually adjacent tubes and configured to allow the outside air to pass therethrough, the fin comprising a plurality of contact portions alternately in contact with one and the other of the adjacent tubes, a plurality of wall portions respectively connecting the mutually adjacent contact portions to connect the adjacent tubes, an extension portion extending from the contact portions and the wall portions and protruding upstream in a flow direction of the outside air from the tubes, and a plurality of fins provided in each of the wall portions continuously along the flow direction of the outside air, each of the wall portions comprising a flat plate portion formed in a flat plate shape and arc portions respectively formed in an arc shape of the flat plate portion are curved toward an associated one of the contact portions, the fins include a first fin formed most upstream in the flow direction of the outside air in the extension portion and a second fin formed downstream of the first fin in the flow direction of the outside air on a downstream side of an upstream end portion in the flow direction of the outside air in the tubes, the first fin and the second fin are formed at the same height throughout the height direction of the flat plate portion, and a downstream end portion of the first fin is located upstream of a front end of each of the tubes in the flow direction of the outside air and is formed at the same cut-and-raised height over a height toward the downstream end portion.

In the above aspect, the fin includes the extension portion protruding upstream of the pipe in the flow direction of the outside air, and a plurality of fins provided in each of the wall portions continuously along the flow direction of the outside air. Accordingly, when a heating operation is performed while a temperature of the outside air is low, water vapor contained in the outside air is cooled and frost may be formed on a most upstream first fin in the flow direction of the outside air. However, since the frost is intensively formed on the most upstream first fin, the frost is less likely to be formed on a downstream second fin. In addition, since the downstream end portion of the most upstream first fin is located upstream of the front end of the pipe in the flow direction of the outside air, a gap remains between the first fin and the pipe even if the frost is formed on the first fin. Therefore, the outside air entering through the gap flows through the pipe and heat exchange can be carried out between the refrigerant and the outside air. Therefore, the decrease in the heat exchange performance of the heat exchanger can be prevented.

Short description of the drawings

• [ 1 ] 1 is a front view of a heat exchanger according to an embodiment of the invention.
• [ 2 ] 2 is an enlarged front view showing tubes and a fin.
• [ 3 ] 3 is a perspective view showing the tubes and fin.
• [ 4 ] 4 is a cross-sectional view along a line IV-IV in 2 .
• [ 5 ] 5 is a cross-sectional view along a line VV in 2 .
• [ 6 ] 6 is a view illustrating an operation of the heat exchanger.
• [ 7 ] 7 is a view illustrating an operation of the heat exchanger.
• [ 8th ] 8th is a schematic view illustrating formation of frost on a rib according to a comparative example.
• [ 9 ] 9 is a schematic view illustrating the formation of frost on the rib.
• [ 10 ] 10 is a cross-sectional view showing a modification of the rib.

Description of embodiments

Hereinafter, a heat exchanger 100 according to an embodiment of the invention will be described with reference to the drawings.

First, an overall configuration of the heat exchanger 100 will be described with reference to 1 described. 1 is a front view of the heat exchanger 100.

The heat exchanger 100 is mounted in a vehicle (not shown). The heat exchanger 100 is an outdoor heat exchanger in a refrigeration cycle of an air conditioner (not shown). The heat exchanger 100 performs heat exchange between a refrigerant circulating in the refrigeration cycle and outside air. The heat exchanger 100 functions as a condenser when the air conditioner performs a cooling operation and functions as an evaporator when the air conditioner performs a heating operation.

The heat exchanger 100 includes a plurality of tubes 1, a pair of tanks 2a and 2b, and a plurality of fins 3. The tubes 1, the tanks 2a and 2b, and the fins 3 are made of metal such as aluminum, and integrally connected to each other by brazing or the like.

The tubes 1 are arranged in parallel and layered at intervals. A flow path through which the refrigerant flows is formed in each tube 1. The tube 1 is arranged so that a heat exchange surface 11 in contact with the fin 3 is horizontal.

The tank 2a and the tank 2b are arranged to be connected to both end portions of the tube 1 in a longitudinal direction, respectively. The tank 2a and the tank 2b are arranged to be connected to the plurality of tubes 1 from the longitudinal direction. The tank 2a and the tank 2b temporarily store the refrigerant.

The refrigerant circulating in the refrigeration cycle and used for air conditioning flows into the tank 2a. The refrigerant flowing into the tank 2a flows through the plurality of tubes 1. The refrigerant performs heat exchange with the outside air as it flows through the tubes 1.

The refrigerant flowing through the pipes 1 flows into the tank 2b. The refrigerant flowing into the tank 2b circulates again in the refrigeration circuit and is used for air conditioning.

The fins 3 are each provided between adjacent tubes 1 and are alternately layered with the tubes 1. The fin 3 is formed in a wave shape along the longitudinal direction of the tube 1 and is connected to two tubes 1 adjacent thereto. The outside air introduced by running the vehicle and an outside fan (not shown) passes around the plurality of tubes 1 and the fins 3. Therefore, the refrigerant flowing in the tube 1 can perform heat exchange with the outside air via a surface of the tube 1 and the fin 3. In this way, the fin 3 promotes heat exchange between the refrigerant and the outside air.

The plurality of tubes 1 and fins 3 of the heat exchanger 100 function as a core 9 that performs heat exchange between the refrigerant flowing in the tubes 1 and the outside air flowing around the tubes 1.

Next, the rib 3 is described in detail with reference to the 2 to 5 to be discribed. 2 is an enlarged front view showing the tubes 1 and the fin 3. 3 is a perspective view showing the tubes 1 and the fin 3. 4 is a cross-sectional view along a line IV-IV in 2 . 5 is a cross-sectional view along a line VV in 2 .

As in the 2 and 3 As shown, each rib 3 comprises contact portions 31, wall portions 32, an extension portion 35, and fins 36. The contact portions 31 and the wall portions 32 are connected in a wave shape.

As in 2 As shown, a plurality of contact portions 31 are provided and are alternately in contact with one and the other of the adjacent tubes 1. Each contact portion 31 is in a flat plate shape made of The contact portion 31 is connected to the heat exchange surface 11 of the tube 1 by soldering or the like.

A plurality of wall portions 32 are provided and connect adjacent contact portions 31 so as to connect the adjacent pipes 1. Each wall portion 32 includes a flat plate portion 33 and arc portions 34.

Each flat plate portion 33 is formed in a flat plate shape. The flat plate portions 33 are inclined in opposite directions so as to be zigzagged. The sipes 36 are formed in the flat plate portion 33.

Each arc portion 34 is curved in an arc shape from the flat plate portion 33 toward the contact portion 31. By providing the arc portions 34, the flat plate portion 33 and the contact portion 31 are connected by a uniform curved surface.

As in 3 As shown, the extension portion 35 projects upstream in a flow direction of the outside air from the pipe 1 by extending the contact portions 31 and the wall portions 32.

As in 4 As shown, a length LP [mm] of a flat portion 35a in which the fin 36 is not provided in the extension portion 35 is shorter than a length LL [mm] of a fin forming portion 35b in which the fin 36 is formed in the extension portion 35. This is because heat exchanging performance may be deteriorated if the length of the flat portion 35a in the extension portion 35 is longer.

As in the 4 and 5 As shown, in the flat plate portion 33, a plurality of fins 36 are provided continuously along the flow direction of the outside air. A downstream end portion 36b of a most upstream fin 36 in the flow direction of the outside air is a linearly cut and raised end portion located upstream of a front end 12 of the pipe 1 in the flow direction of the outside air. That is, the entire most upstream fin 36 (first fin) in the flow direction of the outside air is located upstream of the front end 12 of the pipe 1 in the flow direction of the outside air. In 3 triangular portions located above and below the downstream end portion 36b, which is the linearly cut and raised end portion of the slat 36, are merely portions that simply connect the downstream end portion 36b of the slat 36 and the wall portion 32 of the rib 3. That is, in 3 the downstream end portion 36b is a linearly cut and raised downstream end portion of the slat 36 and does not include the triangular portion located above and below it.

As in 5 , the most upstream louver 36 in the flow direction of the outside air is a single louver (single-side opening louver) 361 in which only the downstream end portion 36b is cut and raised in one side surface of the wall portion 32. Each of other louvers 36 (second louvers) continuously provided downstream of the single louver 361 is a double louver (double-side opening louver) 362 in which the downstream end portion 36b is cut and raised in one side surface of the wall portion 32 and an upstream end portion 36a is cut and raised in the other side surface of the wall portion 32.

The slat 36 is not formed in the arc shape 34. The slat 36 is formed along an entire height direction of the flat plate portion 33 of the wall portion 32. Accordingly, since the slat 36 is as large as a height H [mm] (see 2 ) can be formed over the entire flat plate portion 33, the outside air can be prevented from bypassing the louver 36 and flowing downstream. Therefore, frost can be prevented from being formed downstream in the flow direction of the outside air.

There is a downstream end portion 36b of the fin 36 located upstream of the front end 12 of the tube 1 in each wall portion 32. That is, only one fin 36 projects upstream of the front end 12 of the tube 1. Even though two or more fins 36 may project upstream of the front end 12 of the tube 1, since frost is intensively formed on the most upstream fin 36, no severe frost is formed on the second fin 36. Therefore, in the heat exchanger 100, by forming only one fin 36 projecting upstream of the front end 12 of the tube 1, a decrease in heat exchange performance is prevented while an increase in flow resistance of the outside air is prevented.

Next, effects of the heat exchanger 100 will be described with reference to the 6 to 9 described. 6 is a view that the operation of the heat exchanger 100 and represents a condition before frost F is formed. 7 is a view illustrating the operation of the heat exchanger 100 and showing a state after the frost F is formed. 8th is a schematic view illustrating formation of the frost F on a rib according to a comparative example. 9 is a schematic view illustrating the formation of frost F on rib 3.

As in 6 As shown, the fin 3 includes the extension portion 35 protruding upstream in the flow direction of the outside air from the tube 1 and the plurality of fins 36 provided in the wall portion 32 continuously along the flow direction of the outside air. In a general state in which the frost F is not formed in the heat exchanger 100, the outside air flows through the tubes 1. Therefore, the refrigerant flowing inside the tube 1 performs heat exchange with the outside air via the surface of the tube 1 and the fin 3.

As in 7 As shown, when the heating operation is carried out while a temperature of the outside air is low, water vapor contained in the outside air is cooled and the frost F may be formed on the most upstream fin 36 in the flow direction of the outside air.

In particular, there is 8th illustrated comparative example, there is no fin 36 protruding upstream of the front end 12 of the pipe 1. In this case, the frost F intensively formed on the most upstream fin 36 may come into contact with the front end 12 of the pipe 1 to block a flow path of the outside air.

On the other hand, as in 9 As shown, in the heat exchanger 100, the downstream end portion 36b at the most upstream fin 36 is located upstream of the front end 12 of the tube 1 in the flow direction of the outside air. Since the frost F is intensively formed at the most upstream fin 36, the frost F is less likely to be formed downstream. Even if the frost F is intensively formed at the most upstream fin 36, a gap remains between the most upstream fin 36 and the front end 12 of the tube 1. Therefore, the outside air penetrating through the gap flows through the tube 1, and thus the heat exchange between the refrigerant and the outside air can be carried out. Therefore, the decrease in the heat exchange performance of the heat exchanger 100 can be prevented.

Thereafter, even if the frost F increases and blocks the gap between the front end 12 of the pipe 1, the heat exchange between the refrigerant and the outside air can be carried out by the heat exchanger 100 until the gap is blocked. Therefore, a service life of the heat exchanger 100 can be extended.

When the frost F increases and blocks the gap with the front end 12 of the pipe 1, for example, a defrosting operation (hot gas operation) is carried out in which a high-temperature refrigerant compressed by a compressor (not shown) in the refrigeration cycle is caused to flow through the pipe 1. Accordingly, at a position downstream in the flow direction of the outside air where the frost F is comparatively thin, the frost F is immediately melted and becomes water when the defrosting operation is carried out.

At this time, the tube 1 is arranged so that the heat exchange surface 11 in contact with the fin 3 is horizontal. Since the frost F is porous, water adhering downstream in the flow direction of the outside air moves upstream in the flow direction of the outside air along the heat exchange surface 11 and is absorbed by the frost F formed on the most upstream fin 36 due to a capillary phenomenon. Thereafter, when the frost F formed on the extension portion 35 melts, the defrosting is completed. In this way, the downstream end portion 36b of the most upstream fin 36 is located upstream of the front end 12 of the tube 1 in the flow direction of the outside air, and thus drainage during the defrosting operation can be facilitated.

According to the above embodiment, the following effects are achieved.

The heat exchanger 100 that performs heat exchange between the refrigerant circulating in the refrigeration cycle and the outside air includes: the plurality of tubes 1 arranged in parallel and configured to allow the refrigerant to flow therethrough; the fin 3 provided between the tubes 1 adjacent to each other and configured to allow the outside air to flow therethrough. The fin 3 includes: the plurality of contact portions 31 alternately in contact with one and the other of the adjacent tubes 1; the plurality of wall portions 32 each connecting the contact portions 31 adjacent to each other to connect the adjacent tubes 1; the extension portion 35 extending from the contact portions 31 and the wall portions 32 extends and projects upstream in the flow direction of the outside air from the tubes 1; and the plurality of fins 36 provided in each of the wall portions 32 continuously along the flow direction of the outside air. Each of the wall portions 32 includes the flat plate portion 33 formed in a flat plate shape and the arc portions 34 each curved in an arc shape from the flat plate portion 33 toward an associated one of the contact portions 31. The fins 36 include the first fin formed most upstream in the flow direction of the outside air in the extension portion 35 and the second fin formed downstream of the first fin in the flow direction of the outside air on a downstream side of an upstream end portion in the flow direction of the outside air in the tubes 1. The first fin and the second fin are formed at the same height in the progression of height toward the flat plate portion 33. The downstream end portion 36b of the first fin is arranged upstream of the front end of the pipe 1 in the flow direction of the outside air, and is formed at the same cut-and-raised height in a height direction of the downstream end portion 36b.

In the configuration, the fin 3 includes the extension portion 35 protruding upstream of the pipe 1 in the flow direction of the outside air and the plurality of fins 36 provided in each of the wall portions 32 continuously along the flow direction of the outside air. Accordingly, when a heating operation is performed while a temperature of the outside air is low, water vapor contained in the outside air is cooled and the frost F may be formed on the most upstream first fin in the flow direction of the outside air. However, since the frost F is intensively formed on the most upstream first fin, the frost F is less likely to be formed on the downstream second fin. In addition, since the downstream end portion 36b of the most upstream first fin is located upstream of the front end 12 of the tube 1 in the flow direction of the outside air, a gap remains between the first fin and the tube 1 even if the frost F is formed on the first fin. Therefore, the outside air entering through the gap flows through the tube 1 and the heat exchange can be carried out between the refrigerant and the outside air. Therefore, the decrease in the heat exchange performance of the heat exchanger 100 can be prevented.

Thereafter, even if the frost F increases and blocks the gap with the front end 12 of the pipe 1, the heat exchange between the refrigerant and the outside air can be carried out by the heat exchanger 100 before the gap is blocked. Therefore, a service life of the heat exchanger 100 can be extended.

Embodiments of the present invention have been described above, but the above embodiments are merely examples of the applications of this invention, and the technical scope of this invention is not limited to the specific structures of the above embodiments.

For example, in the above embodiment, the most upstream louvre 36 in the flow direction of the outside air is the single louvre 361, and the other louvres 36 arranged downstream of the single louvre 361 are the double louvres 362. As shown in 10 However, as shown in Fig. 1, the most upstream fin 36 in the flow direction of the outside air may be the double fin 362 similar to the other fins 36. In this case, similarly to the above embodiment, the decrease in the heat exchange performance of the heat exchanger 100 can also be prevented.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• JP5563162 [0002, 0003]

Claims (6)

A heat exchanger configured to perform heat exchange between a refrigerant circulating in a refrigeration cycle and outside air, the heat exchanger comprising: a plurality of tubes arranged in parallel and configured to allow the refrigerant to flow therethrough; a fin provided between the mutually adjacent tubes and configured to allow the outside air to pass therethrough, wherein the fin includes a plurality of contact portions alternately in contact with one and the other of the adjacent tubes, a plurality of wall portions respectively connecting the mutually adjacent contact portions to connect the adjacent tubes, an extension portion extending from the contact portions and the wall portions and protruding upstream in a flow direction of the outside air from the tubes, and a plurality of fins provided in each of the wall portions continuously along the flow direction of the outside air, each of the wall portions includes a flat plate portion formed in a flat plate shape and arc portions each curved in an arc shape from the flat plate portion toward an associated one of the contact portions, the fins include a first fin formed most upstream in the flow direction of the outside air in the extension portion and a second Fin formed downstream of the first fin in the flow direction of the outside air on a downstream side of an upstream end portion in the flow direction of the outside air in the tubes, the first fin and the second fin are formed at the same height throughout the height direction of the flat plate portion, and a downstream end portion of the first fin is arranged upstream of a front end of each of the tubes in the flow direction of the outside air and is formed at the same cut-and-raised height throughout a height toward the downstream end portion. The heat exchanger according to Claim 1 wherein the first slat is a single slat in which only the downstream end portion is cut and raised in one side surface of the wall portion, and the second slat is a double slat in which the downstream end portion is cut and raised in one side surface of the wall portion and an upstream end portion is cut and raised in the other side surface of the wall portion. The heat exchanger according to Claim 1 or 2 wherein a length of a planar portion in which the first slat is not provided in the extension portion is shorter than a length of a slat-forming portion in which the first slat is provided in the extension portion. The heat exchanger according to one of the Claims 1 until 3 , wherein the number of the downstream end portion of the first fin located upstream of the front end of the tube on each of the wall portions is one. The heat exchanger according to one of the Claims 1 until 4 wherein the tube is arranged so that a heat exchange surface thereof in contact with the fin is horizontal. The heat exchanger according to one of the Claims 1 until 5 wherein the wall portion comprises the arc portions each curved in an arc shape toward an associated one of the contact portions, and the slats are not formed in the arc portions.

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