KR20140098398A - Evaporator - Google Patents

Abstract

The present invention relates to an evaporator of an air conditioner for an automobile. Regarding to the evaporator, wherein both ends of the tubes are separated at a predetermined interval in parallel and fixated to a pair of header tanks to form a flow passage of a heat exchange medium, while having a fin sandwiched between the tubes; tube insertion holes are formed in a slot shape having a predetermined width on the header tanks, and drainage grooves are formed along the longitudinal direction of the tubes, while omitting the drainage grooves on both ends of the tube inserted and coupled to the tube insertion holes of the header tanks. Thereby, the generation of corrosion and stench on the surface of the evaporator can be prevented by enhancing the drainage of condensate water generated on the surface of the evaporator, while being easily manufactured and assembled.

Description

Evaporator {Evaporator}

The present invention relates to an evaporator for an automotive air conditioner, and more particularly, to an evaporator which can improve the drainage of condensed water generated on the surface of an evaporator, suppress the occurrence of corrosion and odor on the surface of the evaporator,

Generally, automotive air conditioners are used to cool the interior of a vehicle during the summer season or to remove gaps from windows by moisture during rain.

The refrigeration cycle of the air conditioner includes a compressor for compressing and sending the refrigerant; A condenser for condensing high-pressure refrigerant discharged from the compressor; An expansion valve for expanding the refrigerant condensed and liquefied in the condenser; And an evaporator that cools the air blown into the room by an endothermic effect due to latent heat of evaporation of the refrigerant by heat-exchanging the low-pressure liquid refrigerant expanded by the expansion valve with air blown to the interior of the vehicle. And is connected to a refrigerant pipe to cool the interior of the vehicle through the refrigerant circulation process.

That is, heat exchange occurs in the evaporator, thereby absorbing heat in the vehicle interior and lowering the temperature.

At this time, the evaporator maintains a very low temperature state, and the temperature around the evaporator is lowered by heat exchange, and condensation occurs on the surface of the evaporator.

However, such condensed water not only lowers the heat exchange efficiency of the evaporator, but also causes growth of microorganisms or bacteria when it is left on the surface of the evaporator at the fin for a long time, thereby causing a malodor.

1 and 2, a conventional evaporator (Korean Patent Laid-Open Publication No. 10-2012-0017632) has a structure in which a first header 10 and a second header 20, through which refrigerant is guided, A tube 30 fixed between the first and second headers to guide the refrigerant from the first header 10 to the second header 20 and a pin 40 mounted between the tubes 30 for heat exchange, A condensate water generated in the fin 40 is moved by gravity or flowing air and is discharged to the outside of the drainage duct section 50. [ And condensed water is drained in the longitudinal direction of the tube 30 by a drain groove 51 formed concavely between the drainage lead portion 50 and the tube 40.

The evaporator has a drain hole 51 extending to both longitudinal ends of the tube 30 and a tube insertion hole (not shown) formed in the first and second headers 10 and 20 for receiving an end of the tube 30 11 and 21 are not slots of a uniform shape, it is difficult to insert the tube 30, which makes it difficult to assemble the first and second headers 10 and 20 and the tube 30.

Due to the shape of the tube insertion holes 11 and 21 formed in the first and second headers 10 and 20, a punching mold for forming the tube insertion holes 11 and 21 is formed in the drain groove 51 There is a disadvantage that the punching mold becomes weak because the concave portion is formed so as to correspond thereto.

Further, since the cross section to be cut at the time of manufacturing the tube 30 becomes thick, it is difficult to cut and manufacture the tube 30.

KR 10-2012-0017632 A (2012.02.29.)

It is an object of the present invention to provide an evaporator which can improve the drainage of condensed water generated on the surface of an evaporator and is easy to manufacture and assemble.

According to an aspect of the present invention, there is provided an evaporator comprising: a pair of header tanks (100) formed in parallel to each other with a predetermined distance therebetween and having an inlet pipe and an outlet pipe connected to a heat exchange medium ); A plurality of tubes (200) having both ends fixed to the pair of header tanks (100) to form a flow path of the heat exchange medium; And a plurality of fins 300 interposed between and contacting the tubes 200. The header tank 100 has a tube insertion hole 110 through which an end of the tube 200 is inserted, The tube 200 is formed with a drainage groove 210 along the longitudinal direction and the drainage groove 210 is formed in the tube 200, And is not formed at both ends in the longitudinal direction of the frame.

The end of the tube 200 is inserted into the tube insertion hole 110 of the header tank 100 and the end of the tube 200 where the drainage groove 210 is not formed is inserted and coupled .

Also, the drain groove 210 of the tube 200 is formed by a pressing process.

In addition, the tube 200 is formed such that the cross-sectional thickness of the portion where the drainage groove 210 is formed before the drainage groove 210 is formed is thicker than the circumference.

In addition, a cross section of a portion where the drainage groove 210 is formed is formed so that the inside thereof is convex.

INDUSTRIAL APPLICABILITY The evaporator of the present invention can improve the drainage of condensed water generated on the surface of an evaporator to suppress the occurrence of corrosion and odor on the surface of the evaporator and prevent the condensed water from flowing into the interior of the vehicle through a vent outlet And it is easy to manufacture and assemble the evaporator because the coupling between the header tank and the tube is simple.

1 and 2 are a perspective view and a cross-sectional view of a condensate drainage groove formed in a tube of a conventional evaporator;
3 is a perspective view showing an evaporator according to the present invention.
4 and 5 are a perspective view and a cross-sectional view of a tube according to the invention;
6 is a partially enlarged view showing a coupling structure of a header tank and a tube according to the present invention.
7 is a cross-sectional view showing the state before and after the pressing process for forming the drain groove of the tube according to the present invention.

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

First, the evaporator of the present invention can be manufactured with an extruded tubular evaporator in which a tube is integrally formed through extrusion molding and both ends are fixed to a pair of tanks. Hereinafter, an embodiment of an extruded tubular evaporator will be described.

FIG. 3 is a perspective view showing an evaporator according to the present invention, and FIGS. 4 and 5 are a perspective view and a sectional view showing a tube according to the present invention.

As shown in the drawing, the evaporator 1000 of the present invention includes a pair of header tanks 100 formed in parallel and spaced apart from each other by a predetermined distance, and having an inlet pipe and an outlet pipe connected to one side to allow a heat exchange medium to flow in or out; A plurality of tubes (200) having both ends fixed to the pair of header tanks (100) to form a flow path of the heat exchange medium; And a plurality of fins 300 interposed between and contacting the tubes 200. The header tank 100 has a tube insertion hole 110 through which an end of the tube 200 is inserted, The tube 200 is formed with a drainage groove 210 along the longitudinal direction and the drainage groove 210 is formed in the tube 200, As shown in Fig.

First, the header tank 100 is a space through which the heat exchange medium is introduced and discharged. The header tank 100 guides the heat exchange medium to the tube 200, and is spaced apart from the header tank 100 by a predetermined distance.

An inlet pipe through which the heat exchanging medium flows and an outlet pipe through which the heat exchanging medium is discharged are formed in the header tank 100 on one side.

At this time, the inlet pipe and the outlet pipe may be formed in any one of the pair of header tanks 100, or may be formed in different header tanks 100, respectively. Also, the positions where the inlet pipe and the outlet pipe are formed may be variously formed to control the flow of the heat exchange medium.

In the header tank 100, a baffle for blocking the flow of the heat exchange medium may be formed to control the flow of the heat exchange medium. At this time, the baffle may be formed in various positions and shapes to control the flow of the heat exchange medium.

The tube 200 is fixed to the pair of header tanks 100 at both ends to form a flow path of the heat exchange medium.

The pins (300) are interposed between the tubes (200).

At this time, the fin 300 is connected to the tube 200, and is formed in a zigzag or corrugated plate to improve the heat exchange efficiency of the heat exchange medium passing through the tube 200 .

Here, the header tank 100 is formed with a tube insertion hole 110 through which the end of the tube 200 is inserted. The tube insertion hole 110 is formed in a slot having a constant width. The tube 200 is formed with drainage grooves 210 along the longitudinal direction and the drainage grooves 210 are not formed at both ends of the tube 200 in the longitudinal direction.

3 to 5, a drainage groove 210 is formed in the longitudinal direction of the tube 200 at both ends of the tube 200 except for both ends thereof. The drainage groove 210 is inserted into the tube insertion hole 110 of the header tank 100, The tube insertion hole 110 formed in the header tank 100 may be formed in a slot shape having a constant width.

The condensed water generated in the tube 200 and the fin 300 is collected by the cooling air and the gravity into the drain groove 210 by the drain groove 210 formed in the tube 200, It can be drained to the lower side, thereby improving drainage. Accordingly, it is possible to suppress the generation of corrosion and odor on the surface of the evaporator, and it is possible to prevent the condensed water from being introduced into the vehicle through the vent outlet through the wind.

Since the tube insertion hole 110 formed in the header tank 100 is formed in a slot shape having a predetermined width, the weak portion of the punching mold for punching the tube insertion hole 110 does not occur, do.

In addition, when the tube 200 is cut to a predetermined length, the cut surface is not increased as compared with the tube 200 having no drain groove 210, so that it is easy to manufacture.

In addition, the tube insertion hole 110 of the header tank 100 is formed into a slot having a predetermined width, and both ends of the tube 200 coupled to be inserted into the tube insertion hole 110 are formed in a corresponding manner Assembly of the header tank 100 and the tube 200 is facilitated, and the fabrication and assembling performance of the evaporator is improved.

As shown in the drawing, the evaporator 1000 of the present invention is configured such that a pair of header tanks 100 are vertically spaced apart, and a tube 200 and a pin 300 are vertically formed therebetween, So that it can be drained along the drainage groove 210 of the tube 200 by gravity.

The end of the tube 200 is inserted into the tube insertion hole 110 of the header tank 100 and the end of the tube 200 where the drainage groove 210 is not formed is inserted and coupled.

6, the header tank 100 and the tube 200 are coupled by brazing after the end of the tube 200 is inserted into the tube insertion hole 110 of the header tank 100, A portion where the drain grooves 210 at both ends are not formed is inserted into the tube insertion hole 110 and then brazed so that the header tank 100 and the tube 200 are sealed.

At this time, as shown in the drawing, the pin 300 is formed such that the pin 300 is formed between the tubes 200 by a predetermined distance from the header tank 100 so that the tube 200 is inserted into and joined to the header tank 100 The fin gap 310 may be formed in the tube 200 and the end of the drain groove 210 formed in the tube 200 may be coupled to the fin gap 310.

Also, the drain groove 210 of the tube 200 may be formed by a pressing process.

4 and 5, in order to form the drainage groove 210 in the tube 200, the tube 200 is first formed by extrusion molding in the form of the drainage groove 210 without the drainage groove 210, 200 may be cut and then subjected to a pressing process so that drainage grooves 210 are formed on both sides or one side of the tube 200 in the longitudinal direction. At this time, the drain grooves 210 may be formed in the widthwise center, one side or both sides of the tube 200.

In addition, the tube 200 may be formed such that the cross-sectional thickness of the portion where the drainage groove 210 is formed before the drainage groove 210 is formed is thicker than the peripheral portion.

That is, when manufacturing the tube 200 before the drain groove 210 is formed as shown in FIG. 7 (a), the section thickness t ₂ of the portion where the drain groove 210 is to be formed is smaller than the other portion t ₁ The thickness of the portion where the drainage groove 210 is formed is thinner than the thickness of the other portion due to the deformation of the tube 200 due to the deformation to the inside of the tube 200 when the drainage groove 210 is pressed as shown in FIG. Can be prevented.

Therefore, it is possible to prevent the drain groove 210 from being deformed or damaged by the pressure of the heat exchange medium flowing in the tube 200.

At this time, the cross section of the portion where the drainage groove 210 is formed may be formed such that the inside thereof is convex.

That is, the inside of the tube 200 is formed in a convex shape without forming the overall thickness of the portion where the drain groove 210 is to be formed, and the inside of the drain groove 210 is formed in a post- 210 can be uniformly formed.

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: evaporator (of the present invention)
100: Header tank
110: tube insertion hole
200: tube
210: drainage groove
300: pin
310: Fin gap < RTI ID = 0.0 >

Claims (5)

A pair of header tanks (100) formed parallel to each other with a predetermined distance therebetween and having an inlet pipe and an outlet pipe connected to one side to allow the heat exchange medium to flow in or out;
A plurality of tubes (200) having both ends fixed to the pair of header tanks (100) to form a flow path of the heat exchange medium; And
And a plurality of pins (300) interposed between and contacting the tubes (200)
The header tank 100 is formed with a tube insertion hole 110 through which an end of the tube 200 is inserted and coupled. The tube insertion hole 110 is formed in a slot having a constant width,
Wherein the tube (200) is formed with a drain groove (210) along the longitudinal direction, and the drain groove (210) is not formed at both ends of the tube (200) in the longitudinal direction.
The method according to claim 1,
The end of the tube 200 is inserted into the tube insertion hole 110 of the header tank 100 and the end of the tube 200 where the drainage groove 210 is not formed is inserted and coupled .
The method according to claim 1,
Wherein the drain groove (210) of the tube (200) is formed by a pressing process.
The method of claim 3,
Wherein a section of the tube (200) where the drain groove (210) is formed before the drain groove (210) is formed is thicker than a circumference of the section.
5. The method of claim 4,
Wherein a cross section of a portion where the drainage groove (210) is formed is formed so as to be convex inward.

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