KR20110032268A - The structure of header tank equipped with guide for preventing sepsration in heat exchanger - Google Patents

Abstract

PURPOSE: A structure of a header tank for a heat exchanger with a separation preventing guide is provided to prevent the generation of the leak of a heat exchange medium since air-tightness between a tank and a header is stably maintained. CONSTITUTION: A structure of a header tank for a heat exchanger with a separation preventing guide comprises a tank(100), a header(200), and a gasket(300). A coupling part(110) is formed along the edge of the tank. A U-shaped insertion part(210) is formed along the edge of the header. The insertion part is coupled to the coupling part of the tank. The gasket maintains air-tightness between the tank and the header. The gasket is not sandwiched between the inner surface of the coupling part and the inner surface of the insertion part. The separation preventing guide is formed on the bottom of the coupling part.

Description

The structure of header tank equipped with guide for preventing sepsration in heat exchanger}

The present invention relates to an assembly structure of a header tank for a heat exchanger for maintaining the airtightness of the header tank, and more specifically, to form an escape prevention guide projecting portion in the coupling portion of the tank 'olamam part of the gasket to leave the proper position The present invention relates to an assembly structure of a header tank for a heat exchanger having a release preventing guide capable of maintaining the airtightness of the header tank by preventing the phenomenon.

1A and 1B show a cross sectional view of a header tank of the prior art, and FIG. 2 shows a perspective view of the tank of the prior art.

1A and 1B, a conventional heat exchanger including a radiator includes a tank 10 and a header 20. The tank 10 has a coupling portion 11 protruded along the edge. The header 20 is formed with an insertion portion 21 into which the coupling portion 10 of the tank 10 is fitted along the edge.

1A and 1B, a gasket 30 is interposed between the coupling part 11 and the insertion part 21. The gasket 30 is for maintaining airtightness between the tank 10 and the header 20. When the contact between the coupling portion 11 and the insertion portion 21 and the gasket 30 is good, as shown in FIG. 1A, the gasket 30 does not move away from the proper position of the insertion portion 21 and thus the gasket 30. ), The compression ratio is sufficient, so that leakage of the heat exchange medium does not occur. However, when the contact between the coupling portion 11 and the insertion portion 21 and the gasket 30 is not good, as shown in FIG. 1B, a portion of the gasket 30 is properly positioned at the insertion portion 21. 'Olatam phenomenon', which is a phenomenon that is separated from the occurrence of the gasket 30 is twisted, the portion of the gasket 30 'olatam phenomenon' occurs in the compression rate of the gasket 30 is not enough of the heat exchange medium There is a problem that a leak occurs.

Referring to FIG. 2, the prior art has formed an air flow groove 13 in the tank 10 to detect the 'olatam phenomenon' as shown in FIG.

Although not shown in FIG. 1B, when an 'olatam phenomenon' occurs in a portion of the gasket 30, a flow groove 13 between FIG. 2), the airtightness is destroyed and air flows, so that the 'olatam phenomenon' of the gasket 30 can be detected through the airtightness test.

However, in the prior art, since the 'olatam phenomenon' is found in the airtightness test process, there is a problem in that the heat exchanger needs to be scraped.

The present invention is to provide an assembly structure of the heat exchanger header tank that can maintain the airtightness of the header tank by preventing the 'olatam phenomenon' in which a part of the gasket leaves the proper position by protruding the departure prevention guide to the coupling portion of the tank. do.

The present invention is a heat exchanger header tank that can detect the 'olatam phenomenon' of the gasket through the airtightness test when the 'olam phenomenon' that a part of the gasket is out of the proper position occurs even though the departure prevention guide is formed To provide an assembly structure.

According to the present invention, a tank 100 having a coupling part 110 protruding along an edge, and an inserting portion 210 having a “U” shape to which the coupling part 110 of the tank 100 is coupled along an edge is provided. In the assembly structure of the heat exchanger header tank including the formed header 200 and the gasket 300 interposed to maintain the airtightness between the tank 100 and the header 200, the gasket 300 is the The bottom surface of the coupling part 110 of the coupling part 110 is prevented from being caught between the coupling part inner surface 111 of the coupling part 110 and the insertion part inner side surface 211-1 of the insertion part 210. Reference numeral 113 relates to an assembly structure of a heat exchanger header tank having a departure prevention guide, wherein the departure prevention guide 400 is formed to protrude.

In the present invention, the departure prevention guide 400 is formed to protrude so that the departure prevention guide inner surface 410 of the separation prevention guide 400 is in contact with the inner side 111 of the coupling portion 110 of the coupling portion 110. Can be.

In the present invention, the coupling part inner surface 111 of the coupling portion 110, the separation prevention guide inner surface 410 of the separation prevention guide 400 and the separation prevention guide bottom surface of the separation prevention guide 400 430, the tank when the gasket 300 is caught between the inner side surface 111 of the engaging portion 110 of the coupling portion 110 and the inner side surface 211-1 of the insertion portion of the insertion portion 210. The inner side flow groove 111g of the engaging portion, the release preventing guide inner side flow groove 410g, and the release preventing guide bottom flow groove 430g, which are in communication with each other so that the airtightness between the 100 and the header 200 is destroyed. Each can be formed.

In the present invention, one side end of the coupling portion 110 is located on the inner side 111 of the coupling portion of the coupling portion 110 and the other end of the separation prevention guide outer surface 420 of the separation prevention guide 400. A flow hole (FH) is spaced apart and is located on the bottom 113 of the coupling portion of the coupling portion 110 is formed, one side end of the flow hole (FH) is the bottom surface of the coupling portion of the coupling portion 110 Far from the point corresponding to the bent portion 230 that connects the insertion portion 210 and the body 220 of the header 200 of the coupling portion inner surface 111 of the coupling portion 110 from (113) It may be formed at the point.

In the present invention, since the separation prevention guide protrudes from the coupling portion of the tank, the 'olatam phenomenon' of the gasket 300 is prevented, so that the compression ratio is sufficient over the entire area of the gasket, so that the airtightness between the tank and the header is stably maintained. Therefore, there is an advantage that the leak of the heat exchange medium does not occur.

The present invention has the advantage of detecting the 'olatam phenomenon' of the gasket through the airtightness test even when the 'olatam phenomenon' of the diarrhea gasket to form a flow groove or a flow hole.

Hereinafter, with reference to the drawings will be described in detail an embodiment of the present invention.

3 is a cross-sectional view of an essential part of an embodiment of the present invention in a state where the gasket is prevented from being separated, FIG. 4 is an exploded perspective view of a tank and a header of an embodiment of the present invention, and FIG. 5 is a cross-sectional view of AA ′ of FIG. 4. 6 is a cross-sectional view of an essential part of an embodiment of the present invention when the gasket is detached, FIG. 7 is a cross-sectional view corresponding to FIG. 5 of another embodiment of the present invention, and FIG. 8 is a view when the gasket is detached. A sectional view of an essential part of another embodiment shown in FIG. 7 is shown.

Referring to FIG. 3, an embodiment of the present invention relates to an assembly structure of a heat exchanger header tank including a tank 100, a header 200, and a gasket 300.

Referring to FIG. 4, the coupling part 110 protrudes along the edge of the tank 100. Coupling portion 110 is a coupling portion inner surface 111 located inside the tank 100, coupling portion outer surface 112 located outside the tank 100 and coupling portion inner surface 111 and coupling portion An engagement bottom surface 113 joining the outer surface 112.

Referring to Figure 4, the header 200 is formed with an insertion portion 210 that can be coupled to the coupling portion 100 of the tank 100 along the edge. Insertion portion 210 may be formed so that the cross section is a "U" shape.

Referring to FIG. 4, the insertion unit 210 includes an insertion unit inner side 211 positioned inside the insertion unit 210 and an insertion unit outer side 212 positioned outside the insertion unit 210. Insertion portion inner side 211 is the insertion portion inner side 211-1, which is positioned on the body 220 side of the header 200, insertion portion outer side facing the inner side 211-1 insertion portion The inner side surface 211-2 and the insertion part inner side surface 211-1 and the insertion portion bottom inner side surface 211-2 connecting the insertion portion outer side inner surface 211-2 are included.

Referring to FIG. 3, a gasket 300 is interposed between the coupling part 110 and the insertion part 210. The gasket 300 is for maintaining airtightness between the tank 100 and the header 200.

3 and 4, the separation preventing guide 400 protrudes from the coupling part bottom surface 113 of the coupling part 100. The departure prevention guide 400 may have a plate shape. The separation prevention guide 400 is for preventing the gasket 300 from being caught between the inner side surface 111 of the coupling portion 110 and the inner side surface 211-1 of the insertion portion 210 of the insertion portion 210. will be.

Referring to FIG. 5, the departure prevention guide 400 has a departure prevention guide inner surface 410, a departure prevention guide outer surface 420, and a departure prevention guide bottom surface 430. The departure prevention guide 400 is formed to protrude so that the departure prevention guide inner surface 410 is in contact with the coupling inner surface 111.

4 and 5, the coupling part inner side 111 is formed with the coupling part inner side flow groove 111g, and the release prevention guide inner side 410 is formed with the release prevention guide inner side flow groove 410g. The departure prevention guide bottom surface 430 is provided with a departure prevention guide bottom surface groove 430g. The coupling part inner side flow groove 111g, the release prevention guide inner side flow groove 410g, and the release prevention guide bottom flow groove 430g are sequentially communicated with each other to form one flow groove FG. On the other hand, the plurality of flow grooves (FG) may be formed at equal intervals. The flow groove FG is such that when the gasket 300 is sandwiched between the inner side of the coupling part 111 and the inner side of the insertion part 211-1, the airtightness between the tank 100 and the header 200 is destroyed. It is to. Accordingly, a certain part of the gasket 300 is separated from the proper position of the insertion part 210 by the airtightness test, and is caught between the coupling part inner surface 111 and the insertion part inner inner surface 211-1. It is possible to detect the Olamta phenomenon.

Referring to FIG. 3, the coupling part 110 is fastened to the insertion part 210 in a state where the gasket 300 is placed in the insertion part 210. At this time, since the separation prevention guide 400 is protruded to the coupling portion 110, the 'olatam phenomenon' of the gasket 300 is prevented. Therefore, the compression ratio is sufficient over the entire area of the gasket 300, so that the airtightness between the tank 100 and the header 200 is stably maintained, so that leakage of the heat exchange medium does not occur.

Referring to FIG. 6, even when the departure prevention guide 400 protrudes, when the 'olatam phenomenon' occurs in the gasket 300, the 'olatam phenomenon' of the gasket 300 may be detected by the airtightness test. Will be. That is, when the gasket 300 is pinched by the inner side of the coupling part 111 and the inner side of the insertion part 211-1 (refer to FIG. 4), the inner side of the coupling part 111 and the inner side of the separation prevention guide 410. (See FIG. 5) and the air gap between the tank 100 and the header 200 by the flow groove FG formed in the release prevention guide bottom surface 430 (see FIG. 5), so that the gasket 300 is opened by the airtightness test. It is possible to prevent the 'olatam phenomenon'.

Referring to FIG. 7, in another embodiment of the present invention, a flow hole FH may be formed instead of the flow groove FG.

Referring to Figure 7, the flow hole (FH) is formed in the coupling portion 110, one end is located on the inner side of the coupling portion 111, the other end is spaced apart from the departure prevention guide outer surface 420, the bottom of the coupling portion It is formed to be located at 113. The flow hole FH is for detecting the 'olatam phenomenon' of the gasket 300 like the flow groove FG.

Referring to FIG. 8, the header 200 has a bent portion 230 connecting the insertion portion 210 and the body 220. The body 220 is where a tube insertion hole (not shown) into which a plurality of tubes (not shown) of the header 200 is inserted is formed. One side end of the flow hole (FH) is formed at a point farther than the point corresponding to the bent portion 230 of the inner side 111 of the coupling portion from the bottom 113. This is to prevent one side end of the flow hole (FH) from being blocked by the gasket 300 even if the gasket 300 is sandwiched between the bend 230 and the coupling portion 110.

1A and 1B are combined cross sectional views of a header tank of the prior art;

2 is a perspective view of a tank of the prior art;

Fig. 3 is a sectional view of an essential part of an embodiment of the present invention in a state where the gasket is prevented from detaching.

Figure 4 is an exploded perspective view of the tank and the header of one embodiment of the present invention.

5 is a cross-sectional view taken along the line AA ′ of FIG. 4.

Fig. 6 is a sectional view of an essential part of an embodiment of the present invention when the gasket is detached.

Fig. 7 is a sectional view corresponding to Fig. 5 of another embodiment of the present invention.

Fig. 8 is a sectional view of an essential part of another embodiment shown in Fig. 7 in the case where the gasket is detached.

<Description of the symbols for the main parts of the drawings>

100: tank 110: coupling part

111: Inner side of the engaging portion 111g: Flow groove in the inner side of the engaging portion

112: outer side of the coupling portion 113: bottom surface of the coupling portion

200: header 210: inserting portion

211: Insertion inner side 211-1: Insertion inner side

211-2: Inner side of insert outside 211-3: Inner side of insert bottom

212: insertion part outer side surface 220: body

230: bend 300: gasket

400: departure prevention guide 410: departure prevention guide inner surface

410 g: Release prevention guide inner surface Flow groove 420: Release prevention guide outer surface

430: Release prevention guide bottom surface 430 g: Release prevention guide bottom surface flow groove

FG: Flow groove FH: Flow hole

Claims (4)

A header formed with a tank 100 having a coupling portion 110 protruding along an edge, and an insert portion 210 having a “U” shape through which the coupling portion 110 of the tank 100 may be coupled along the edge. In the assembly structure of the heat exchanger header tank including a gasket 300 interposed to maintain the airtight between the tank 100 and the header 200 and 200), In order to prevent the gasket 300 from being caught between the inner side surface 111 of the coupling portion 110 of the coupling portion 110 and the inner side surface 211-1 of the insertion portion of the insertion portion 210, the coupling portion ( Assembling structure of the heat exchanger header tank having a departure prevention guide, characterized in that the departure prevention guide 400 is formed protrudingly formed on the bottom surface 113 of the engaging portion. The method of claim 1, The separation prevention guide 400 is separated from the separation prevention guide 400, the separation prevention guide inner surface 410 is formed so as to protrude so as to be in contact with the coupling portion inner surface 111 of the coupling portion 110. Assembly structure of heat exchanger header tank with prevention guide. The method of claim 2, On the inner side surface 111 of the engaging portion 110 of the coupling portion 110, the inner surface 410 of the separation prevention guide 400 of the separation prevention guide 400 and the bottom surface of the separation prevention guide 400 of the separation prevention guide 400, When the gasket 300 is sandwiched between the inner side surface 111 of the coupling portion 110 and the inner side surface 211-1 of the insertion portion 210 of the coupling portion 110, the tank 100 and the The coupling part inner side flow groove 111g, the release preventing guide inner side flow groove 410g, and the release preventing guide bottom side flow groove 430g are formed to communicate with each other so that the airtightness between the headers 200 is respectively formed. Assembly structure of a header tank for heat exchangers provided with the departure prevention guide. The method of claim 2, One side end of the coupling part 110 is located on the inner side surface 111 of the coupling part of the coupling part 110 and the other end is spaced apart from the departure prevention guide outer surface 420 of the separation prevention guide 400 and the coupling Flow hole (FH) is formed in the bottom surface 113 of the coupling portion 110, One side end of the flow hole (FH) is the insertion portion 210 and the header of the coupling portion inner surface 111 of the coupling portion 110 of the coupling portion bottom surface 113 of the coupling portion 110 Assembly structure of a heat exchanger header tank having a departure prevention guide, characterized in that formed at a point farther away from the point corresponding to the bent portion 230 connecting the body 220 of the 200.

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