KR20140083287A - Heat exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger. More specifically, the heat exchanger includes: a pair of header tanks spaced apart from each other; a plurality of coolant tubes connected to both ends of the header tanks; a plurality of pins which are disposed between the coolant tubes and are coupled to the outer side of the outermost coolant tube; and a support coupled to the exterior of the outermost pints The support includes a first support and a second support coupled to each other to slide in the longitudinal direction and be fixed in the width and height directions. The present invention can absorb the thermal deformation in the longitudinal direction of the coolant tubes due to the repeated heating and cooling of the heat exchanger and enhance the durability by using vibration.

Description

Heat exchanger

The present invention relates to a heat exchanger, and more particularly, to a heat exchanger in which a support for supporting between header tanks of a heat exchanger is formed by a first support and a second support, and two supports are slidably engaged with each other, To a heat exchanger capable of absorbing thermal deformation due to repetition and improving durability due to vibration.

Generally, a heat exchanger is a device that absorbs heat from one side to the other and dissipates heat to the other between two environments with a temperature difference. When the heat is absorbed and released to the outside, the cooling system absorbs heat from the outside, When it emits, it acts as a heating system.

In the vehicle, an air conditioner for cooling or heating the vehicle interior and a cooling device for cooling the engine are provided. The air conditioner supplies air heated by using waste heat of an engine or the like, or air cooled by an independently provided air conditioner to a blower through a duct system configured inside the vehicle to heat or cool the vehicle.

The heat exchanger used in the air conditioner or the cooling apparatus generally uses a method of generating heat exchange between the refrigerant or the cooling water accommodated in the heat exchanger and the outside air. At this time, in order to effectively perform heat exchange between the refrigerant or the cooling water and the outside air, the outside air needs to be quickly replaced. For this purpose, a heat exchanger such as an evaporator of the air conditioner or a radiator of the cooling device has a fan In most cases.

1, the conventional heat exchanger 1 includes a pair of header tanks 10 arranged in parallel to each other with a predetermined distance left and right as shown in FIG. 1, a plurality of refrigerant tubes 20 A pin 30 interposed between the refrigerant tubes 20 and coupled to the outside of the outermost tube and a support 40 connected to the outside of the outermost fin and coupled to the header tank 10 in the longitudinal direction, . At this time, the support 40 can be formed both on the upper side and the lower side. Thus, the heat exchanger 1 is configured to be supported by the support 40 to prevent damage to the refrigerant tube 20 and the fins 30 due to deformation and vibration.

At this time, since the heating and cooling of the heat exchanging medium flowing in the refrigerant tubes 20 are repeated, thermal deformation occurs in the longitudinal direction, and in order to absorb such thermal deformation, The cutout portion 41 and the bent portion 42 are formed. The bending portion 42 absorbs thermal deformation to prevent deformation due to thermal expansion of the refrigerant tube 20 and the support 40.

However, since the cutouts 41 and the bending portions 42 are formed in the support 40 so as to absorb thermal deformation, the rigidity of the support 40 is reduced and it is vulnerable to vibration in the width direction and the height direction .

As a related art related to this, Korean Patent Laid-Open Publication No. 2011-0045483 entitled " Radiator Support Structure "is disclosed.

KR 2011-0045483 A (2011.05.04)

It is an object of the present invention to provide a heat exchanger capable of absorbing thermal deformation in a support of a heat exchanger to prevent deformation of a refrigerant tube and a fin, And to provide a heat exchanger capable of improving durability due to vibration without deterioration.

According to an aspect of the present invention, there is provided a heat exchanger including: a pair of header tanks (100) spaced apart from each other by a predetermined distance; A plurality of refrigerant tubes (200) connected at both ends to the header tanks (100); A plurality of pins (300) interposed between the refrigerant tubes (200) and coupled to the outermost refrigerant tube (200); And a support 400 coupled to the outside of the outermost pin 300. The support 400 includes a first support 500 and a second support 600, The first support 500 and the second support 600 are coupled to each other so that they are coupled to each other so as to slide in the longitudinal direction and fixed in the width direction and the height direction.

In addition, the second support 600 is inserted into one side of the first support 500, and one side of the second support 600 is coupled.

The first support 500 includes a vertical portion 520 on both sides of the horizontal portion 510 and a vertical portion 520 on one side of the first support 500 to which the second support 600 is inserted, And a bent portion 521 is formed on the inner side of the base portion 520.

The bent portion 521 of the first support 500 is formed by bending a part of the vertical portion 520 inward.

The second support 600 is formed with a step 640 at one side coupled to the first support 500 so that one side of the second support 600 is inserted into one side of the first support 500 Is limited in length.

The cladding layers 530 and 630 are formed on the surfaces of the first and second supports 500 and 600 that are coupled to the pin 300 so that the first support 500 and the second support 600 are bonded to each other, Are each coupled to the pin (300) by brazing.

The other side of the first support 500 and the second support 600 is coupled to the outside of the header tank 100 or inserted into the header tank 100.

The heat exchanger of the present invention is capable of absorbing thermal deformation of the refrigerant tube and the fin due to repetition of heating and cooling and has an advantage of improving the durability due to vibration without lowering the rigidity of the heat exchanger.

1 is a perspective view of a conventional heat exchanger;
2 is a front view of a conventional heat exchanger and a top plan view showing a support.
3 is a perspective view of a heat exchanger of the present invention.
4 is a cross-sectional perspective view in AA 'direction of FIG. 3;
5 is a perspective view showing a state in which a first support and a second support according to the present invention are moved in the longitudinal direction by thermal deformation;
6 is a front view showing a state in which a first support and a second support according to the present invention are engaged with pins;
7 and 8 are perspective views showing a coupling structure of a header tank and a first support and a second support according to the present invention.

Hereinafter, the heat exchanger of the present invention having the above-described configuration will be described in detail with reference to the accompanying drawings.

3 is a perspective view of a heat exchanger of the present invention.

As shown in the drawing, the heat exchanger 1000 of the present invention includes a pair of header tanks 100 formed to be spaced apart from each other by a predetermined distance. A plurality of refrigerant tubes (200) connected at both ends to the header tanks (100); A plurality of pins (300) interposed between the refrigerant tubes (200) and coupled to the outermost refrigerant tube (200); And a support 400 coupled to the outside of the outermost pin 300. The support 400 includes a first support 500 and a second support 600, The first support 600 and the second support 600 are coupled to each other so that they are coupled to each other so as to slide in the longitudinal direction and fixed in the width direction and the height direction.

First, the header tank 100 has a space in which a heat exchange medium is stored and flows, and is spaced apart from the header tank 100 by a predetermined distance. The header tank 100 is formed with an inlet pipe through which the heat exchanging medium flows and an outlet pipe through which the heat exchanging medium is discharged.

The refrigerant tube 200 is connected at both ends to the header tanks 100 and forms a flow path of the heat exchange medium.

The fin 300 is interposed between the refrigerant tubes 200 and is connected to the refrigerant tube 200 by brazing or the like to receive heat from the heat exchange medium flowing into the refrigerant tube 200, Release. At this time, the fin 300 is formed in a corrugated shape or in a zigzag shape so as to widen the heat radiation area.

Thus, the heat exchange medium flowing into the inlet pipe is discharged to the outlet pipe through the header tank 100, the refrigerant tube 200, and the header tank 100, exchanges heat with the external cooling air while passing through the outlet pipe, To the outside.

The fin 300 is interposed between the refrigerant tubes 200, and the fin 300 is coupled to the outside of the outermost refrigerant tube 200. That is, the pins 300 are respectively coupled to the upper surface of the uppermost refrigerant tube 200 and the lower surface of the lowermost refrigerant tube 200 in the height direction.

The support 400 is coupled to the outer side of the outermost upper or lower fin 300 and both ends of the support 400 are coupled to the header tank 100 in the longitudinal direction. That is, a plurality of coolant tubes 200 and the fins 300 are stacked in the height direction, and the supporter 400 is coupled to the outermost upper and lower ends. At this time, the support 400 may be formed at the upper end or the lower end, or may be formed at the upper end and the lower end. Thus, the header tank 100, the refrigerant tube 200, and the fins 300 can be firmly fixed by the support 400.

The support 400 is formed of a first support 500 and a second support 600 and is coupled and fixed to the pin 300. The first support 500 and the second support 600 are fixed to each other And is coupled such that the movement is fixed in the width direction and the height direction.

When the heat exchanger is heated and the refrigerant tube 200 expands in the longitudinal direction, the coupling part of the first support 500 and the second support 600 is slid in the longitudinal direction so that the first support 500 and the second support 600 600 can be made longer to absorb thermal deformation. In contrast, when the heat exchanger is cooled and the refrigerant tube 200 is contracted in the longitudinal direction, the refrigerant tube 200 can be slid and reduced to absorb thermal deformation.

At this time, the first support 500 and the second support 600 are slidable in the longitudinal direction by the coupling portion, but are coupled so that the movement in the width direction and the height direction is fixed. Thus, it is possible to absorb the thermal deformation in the longitudinal direction, and the rigidity in the width direction and the height direction can be increased.

As described above, the heat exchanger of the present invention is capable of absorbing thermal deformation of the refrigerant tube and the fin due to repetition of heating and cooling, and has an advantage of improving durability due to vibration without lowering the rigidity of the heat exchanger.

In addition, one side of the second support 600 may be inserted into one side of the first support 500. 4, one side of the first support 500 and the second support 600 are slid with respect to each other, and a second support 500 is fixed to one side of the first support 500 so that the movement is fixed in the width direction and the height direction, And one side of the base plate 600 is inserted.

The first support 500 includes a vertical portion 520 on both sides of the horizontal portion 510 and a vertical portion 520 on one side of the first support 500 to which the second support 600 is inserted, And a bent portion 521 is formed on the inner side of the base portion 520.

This is because the first support 500 and the second support 600 are bent in a U-shape with the upper side opened and the upper side of one vertical portion 520 of the first support 500 is bent inward, And the second support 600 is also bent in a U-shape with the upper side opened to form a horizontal portion 610 and a vertical portion 620 on both sides thereof, (Not shown).

Thus, the movement of the first support 500 and the second support 600 in the width direction and the height direction can be fixed while being coupled to each other. Since the inner support of the first support 500 and the second support 600 coupled to be inserted into the first support 500 are formed in a U-shape, rigidity against torsion around the longitudinal direction is secured, The durability can be further improved.

At this time, the bent portion 521 of the first support 500 may be formed by bending a part of the vertical portion 520 inward.

4 and 5, when the bent part 521 is formed by bending a part of the vertical part 520 inwardly, the first support 500 is bent at both sides in the width direction of the plate material having a constant width The horizontal portion 510 and the vertical portion 520 can be formed and then the bent portion 521 can be formed as described above so that the material can be reduced and the first support 500 can be manufactured only by bending There are advantages to be able to.

The second support 600 is formed with a step 640 at one side coupled to the first support 500 so that one side of the second support 600 is inserted into one side of the first support 500 To be limited in length.

That is, since the support 400 is disposed between the pair of header tanks 100 when the heat exchanger is manufactured, the minimum length of the first support 500 and the second support 600 The step 640 can be formed.

The cladding layers 530 and 630 are formed on the surfaces of the first and second supports 500 and 600 that are coupled to the pin 300 so that the first support 500 and the second support 600 are bonded to each other, Respectively, by brazing.

6, the clusters 530 and 630 are formed on the lower surfaces of the first and second supports 500 and 600 so that the first support 500 and the second support 600 are fixed to the pin 300, Can be coupled and fixed by brazing, respectively. At this time, the clad layers 530 and 630 may be formed of a clad sheet to bond the clad sheet to the lower surfaces of the first and second supports 500 and 600, and may be coupled to the fin 300 through brazing .

Here, the clad layer and the clad sheet are formed of an alloy in which aluminum, magnesium, silicon, iron, copper, manganese and titanium are added to form the material of the header tank 100, the refrigerant tube 200, Melting point of aluminum is lower than that of aluminum, so that it can be melted and joined by brazing.

The first support 500 and the second support 600 are coupled to the pin 300 while the first support 500 and the second support 600 are not welded in the longitudinal direction, Welded and fixed.

The other side of the first support 500 and the second support 600 may be coupled to the outside of the header tank 100 or may be inserted into the header tank 100 and coupled thereto.

7 and 8, the first support 500 and the second support 600 are coupled so that one side of the first support 500 and the second support 600 are slidably engaged with each other, and the other side is coupled to the header tank 100. At this time, The other side of the support 500 and the second support 600 is fixedly coupled to the header tank 100. The supports 500 and 600 are fixed to the outside of the header tank 100 or inserted into the header tank 100 .

That is, since the first support 500 and the second support 600 can absorb longitudinal thermal deformation, the other side of the supports 500 and 600 can be coupled to the outside of the header tank 100, It is possible to apply the present invention to a case where a part is inserted and coupled to the inner side of the frame.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1000: heat exchanger
100: Header tank
200: Refrigerant tube
300: pin
400: Support
500: First support
510: horizontal part 520: vertical part
521: bent portion 530: clad layer
600: Second Support
610: horizontal part 620: vertical part
630: cladding layer 640: step

Claims (7)

A pair of header tanks 100 spaced apart from each other by a predetermined distance; A plurality of refrigerant tubes (200) connected at both ends to the header tanks (100); A plurality of pins (300) interposed between the refrigerant tubes (200) and coupled to the outermost refrigerant tube (200); And a support 400 coupled to the outside of the outermost pin 300,
The support 400 includes a first support 500 and a second support 600. The first support 500 and the second support 600 are coupled to each other at one side thereof, And is fixed to be fixed in the width direction and the height direction.
The method according to claim 1,
Wherein one side of the second support (600) is inserted into one side of the first support (500).
3. The method of claim 2,
The first support 500 includes a vertical portion 520 on both sides of the horizontal portion 510 and a vertical portion 520 at one side of the first support 500 to which the second support 600 is inserted, ) Is formed with a bent portion (521) inward.
The method of claim 3,
Wherein a bent part (521) of the first support (500) is formed by bending a part of the vertical part (520) inward.
3. The method of claim 2,
The second support 600 has a step 640 formed at one side of the first support 500 to be coupled with the first support 500 and a second support 600 having one side inserted into one side of the first support 500 Is limited. ≪ / RTI >
The method according to claim 1,
Cladding layers 530 and 630 are formed on the surfaces of the first and second supports 500 and 600 that are coupled to the pin 300. The first and second supports 500 and 600 Is coupled to the pin (300) by brazing.
The method according to claim 1,
Wherein the other side of the first support (500) and the second support (600) is coupled to the outside of the header tank (100) or inserted into the header tank (100).

Images