KR101992758B1 - Heat exchanger with a mounting means - Google Patents

Abstract

According to the invention, there is provided a pair of header tanks for receiving and discharging a working fluid; A plurality of tubes forming a plurality of flow paths between each header tank of the pair of header tanks for the working fluid; A pair of supports fixed at both ends to the header banks, the bottom plate and the pair of flanges, the pair of flanges forming a gap therebetween; And at least one mounting bracket comprising a mounting portion having a mounting hole for the fastening means and a support portion disposed between the pair of flanges, wherein the pair of flanges are mounted on the support portion. The mounting brackets are fastened to the support by including a deformable portion.

Description

Heat exchanger with a mounting means

The present invention relates to a heat exchanger, in particular a heat exchanger having mounting means for mounting the heat exchanger to the vehicle body.

Conventionally, heat exchangers are devices used to transfer heat between one or more fluids, and generally used in cooling or heating systems. Heat exchangers are also used in vehicle HVAC systems, and condensers or radiators typically disposed in the front of the engine compartment of a vehicle are examples of such heat exchangers used in vehicles.

One of the capacitors is shown in FIG. Referring to FIG. 1, the condenser 10 includes two header tanks at both side ends thereof, which are supported by a pair of supports 12 spaced apart from each other in the vertical direction. In addition, a plurality of tubes 14 are connected between two header tanks, thereby defining a plurality of flow paths extending between the two header tanks.

Here, a plurality of mounting brackets 12a are provided on the supports 12. Each of the mounting brackets includes mounting holes that allow fastening bolts (not shown) to pass through the brackets. Since the mounting brackets are firmly connected to the support 12, the entire condenser 10 may be mounted in the engine room of the vehicle by the mounting bracket to be attached to the vehicle body.

Therefore, it is important how to fix the mounting bracket to the support 12. 2, the mounting bracket 12a includes a lower portion 12b formed by bending an end portion of the mounting bracket. The bottom portion 12b extends between two flanges of the support 12, and both ends of the bottom portion 12b are adjacent to the interior of the two flanges of the support 12.

The body of the mounting bracket 12a is partially supported by the flange of the support 12, and the rivet 12c inserted in both the flange of the support 12 and the mounting bracket 12a fastens the two together.

After the fastening is completed, the support 12 and the mounting bracket 12a are soldered together in the furnace to make the final joining of the parts.

As described, one problem with conventional assemblies is that the rivet process is a manual process and the process time is high, which may reduce the productivity of the capacitor assembly. In addition, since the flange of the support 12 is the base for the rivet, the flange must have sufficient strength to support the rivet. The flange must therefore have a height of over 12 mm, which can increase the overall size of the condenser assembly.

It is an object of the present invention to provide a heat exchanger with mounting means, which may be possible to reduce the height and manufacturing time of the flange.

According to one aspect of the invention, a pair of header tanks for receiving and discharging a working fluid; A plurality of tubes forming a plurality of flow paths between each header tank of the pair of header tanks for the working fluid; A pair of supports fixed at both ends to the header banks, the bottom plate and the pair of flanges, the pair of flanges forming a gap therebetween; And at least one mounting bracket comprising a mounting portion having a mounting hole for the fastening means and a support portion disposed between the pair of flanges, wherein the pair of flanges are mounted on the support portion. The mounting brackets are fastened to the support by including a deformable portion.

Here, at least one slot may be formed in the flanges for each of the deformable parts and disposed at the boundary of the deformable part. The slot may be at the cutout of the flanges.

Here, the deformation portion may be a polygonal shape. For example, the deformation portion is triangular in shape.

In addition, at least two deformation parts are arranged to face each other, and a mounting part of the mounting bracket is disposed between two opposite deformation parts. The mounting portion may be sandwiched between two opposing deformation portions. Otherwise, the mounting portion may be sandwiched between two opposing deformation portions, where there is a gap between the mounting portion and the deformation portion.

Here, the mounting portion of the mounting bracket can be connected to the substantially central portion of the support portion of the mounting bracket.

In addition, at least one alignment slot may be formed in the bottom plate of the support, and at least one alignment protrusion to be inserted into the alignment slot is formed in the supporting portion of the mounting bracket. Alignment protrusions and slots can prevent the mounting bracket from moving in the longitudinal direction of the support before the soldering process is complete.

In addition, the supporting portion may be engaged between the lower surface of the deformable portion and the upper surface of the bottom plate.

Here, the distance d between the bottom of the deformable part and the top of the bottom plate may be smaller than the thickness D of the supporting part for a tight connection therebetween.

Here, at least one soldered portion may be formed between the lower surface of the deformable portion and the support portion.

According to another aspect of the invention, there is provided a method of preparing a pair of supports comprising a bottom plate and a pair of flanges, the pair of flanges forming a gap therebetween and comprising at least one slot; Inserting at least one mounting bracket into the gap, the mounting bracket comprising a mounting portion having a mounting hole for fastening means and a support portion disposed between the pair of flanges; Forming at least one deformable portion by replacing a portion adjacent the slot to a support portion of the mounting bracket; And adhering the mounting bracket to the support by soldering.

Here, the method may further comprise limiting the movement of the mounting bracket with respect to the longitudinal direction of the support by inserting the alignment protrusion in the alignment slot, wherein the alignment protrusion is formed on the underside of the support portion, the alignment slot being the support Is formed on the bottom surface.

1 is a perspective view of a conventional capacitor assembly.
FIG. 2 is an enlarged perspective view of the condenser assembly of FIG. 1. FIG.
3 is a perspective view of a support according to an embodiment of the present invention.
4 is an enlarged perspective view of the support of FIG. 3.
5 is a cross-sectional view of the support of FIG. 3.
6 is a front view of the support before deformation.
7 is an enlarged perspective view of the support before deformation.

Hereinafter, preferred embodiments of the present invention are described with reference to the accompanying drawings.

The first preferred embodiment of the present invention will be described with reference to FIGS. The first embodiment may be a condenser assembly as shown in FIG. 1 except for the support 12 and the mounting bracket 12a. Therefore, for the purpose of explanation, the description of header tanks and tubes will be omitted below.

The first embodiment 100 includes a pair of supports as shown in FIG. Note that only one support 102 is shown in FIG. 3 for illustration. The support 102 is shaped to extend in the longitudinal direction and has a "U" shaped section.

The support 102 also includes a holder 104 at each end for attaching a header tank to the support 102. The holder 104 includes two arms extending parallel to each other and having a gap therebetween.

On the bottom plate of the support 102, two alignment slots 106 are formed which extend in the longitudinal direction of the support 102. Two mounting brackets are provided in each of the alignment slots for securing the condenser assembly to the vehicle body, in particular inside the engine compartment. The two mounting brackets are spaced apart from each other along the longitudinal direction of the support 102.

In the first embodiment, the number of alignment slots corresponds to the number of mounting brackets 110. That is, one alignment slot is arranged for one mounting bracket. However, the number of alignment slots is not limited as shown, but instead two or more alignment slots may be allocated for a single mounting bracket. In addition, the support may comprise three or more mounting brackets.

Referring to FIG. 4, the mounting bracket 110 includes a mounting portion 111 having a mounting hole 112. The mounting portion 111 is a flat body and the mounting hole 112 is formed to penetrate the mounting portion, thereby allowing the fastening means, for example mounting bolts, to penetrate the mounting hole 112. The support portion 114 is formed integrally with the mounting portion 111. The support portion extends in the direction perpendicular to the longitudinal direction of the support 102, whereby the mounting bracket 110 becomes a "T" shape. Here, the mounting portion 111 is disposed in the center portion of the support portion 114, but the mounting portion 111 may be at any position on the support portion 114.

The support 102 includes a pair of flanges 102a and a bottom plate 102b therebetween. The pair of flanges 102a extend parallel to each other and form a gap therebetween. The width of the gap is substantially the same as the width of the support portion 114 of the mounting bracket 110 or slightly larger than the width of the support portion 114. Thus, the bottom surface of the support portion 114 contacts the bottom plate 102b of the support so that the support portion can be easily mounted between the pair of flanges 102a.

Two slots 120 are formed in each of the pair of flanges 102a. Two slots are laterally disposed in the mounting bracket 110. The slots are formed by cutting off a portion of the flange 102a, which divides the upper portion of the flange from the lower portion. The split top is deformed into a triangular shape using any associated tool as shown in FIG. That is, the deformable portion 122 is formed by bending the upper portion divided over the supporting portion 114. Here, two deformable portions 122 are formed with respect to one surface of the mounting bracket 110.

Referring to FIG. 5, the bottom surface of the deformable portion 122 contacts the top surface of the support portion 114 to limit the vertical movement of the mounting bracket. For a secure fastening, the gap d between the bottom of the deformable portion 122 and the top of the bottom plate 102b is set smaller than the thickness D of the supporting portion 114. Thus, upon completion of the bending process, the support portion 114 is press-fit between the bottom of the deformable portion 122 and the top of the bottom plate 102b.

The support portion further includes an alignment protrusion 115 to be inserted into the alignment slot 106 of the support 102. As shown in FIG. 5, the alignment protrusion is configured to be inserted into the alignment slots, thereby preventing longitudinal movement of the support portion as described above.

In FIG. 5, the mounting portion comprises a mounting portion, in particular an inclined portion 111a which moves the mounting hole laterally with respect to the center of the supporting portion. By the inclined portion 111a, the mounting portion can be arranged closer to the mounting surface of the vehicle (not shown).

Here, the deformation portion is not limited to the triangular shape, but instead the deformation portion may be any polygonal shape or curved shape. Further, although the deformable portion does not contact the side surface of the mounting portion 111, it may also be possible that the deformable portion is adjacent to the lateral surface of the mounting portion 111.

As described, the mounting bracket 110 is secured by the deformable portion 122 until the soldering process is complete, and the height of the flange can be 12 mm shorter, which does not require a riveting process. Therefore, the amount of raw materials used can be reduced, and the manufacturing time can also be reduced by eliminating the riveting process.

In the following, the manufacturing method of the first embodiment will be described with reference to FIGS. 6 and 7.

First, the support 102 is prepared to have a pair of flanges and a bottom plate. Because the support has a section that is even over the entire length of the support and includes shorter flanges, the support can be prepared using an extrusion process rather. In addition, the mounting bracket also has an even cross section, and thus it can also be manufactured in an extrusion process rather than a stamping process as in conventional condensers which leads to an increase in cost and manufacturing time.

Next, as shown in FIG. 6, a slot 120 and an alignment slot 106 are formed in the support 102.

After completing the formation of the two slots, mounting brackets are placed adjacent to the slots 120 as shown in FIG. In the state shown in FIG. 7, the mounting bracket cannot move in the longitudinal and lateral directions of the support, but it can still move in the vertical direction.

Next, the deformed portion is formed using the associated tool so as to have a shape as shown in FIG. 4. Since the deformable portion 122 presses down the supporting portion of the mounting bracket, the mounting bracket cannot move in any direction after the deformable portion is formed.

In this state, the soldering process is executed. Thus all the contacting surfaces are bonded to each other by the soldering process, so that the deformation portion and the support portion also include the adhesive surface.

According to an embodiment, the support is formed with a lower flange height and thinner thickness than the previous support, which allows for a lower weight and less blank size required to make the support due to the reduced flange height and thinner thickness. do.

In addition, an extrusion bracket may be used instead of a stamping bracket. Since stamping brackets are currently used, extrusion brackets that are less expensive to ship than stamping brackets will be used.

In addition, the rivet will remove the rivets and the manufacturing process can be improved from manual to automated by eliminating the riveting process requiring manual operations.

Claims (11)

As a heat exchanger,
A pair of header tanks for receiving and discharging a working fluid;
A plurality of tubes forming a plurality of flow paths between each header tank of the pair of header tanks for the working fluid;
A pair of supports fixed at both ends to the header tanks and including a bottom plate and a pair of flanges, the pair of flanges forming a gap therebetween; And
At least one mounting bracket comprising a mounting portion having a mounting hole for the fastening means and a support portion disposed between the pair of flanges,
The pair of flanges includes a deformable portion mounted on the support portion to fasten the mounting brackets to the support,
The support portion is engaged between the bottom surface of the deformable portion and the top surface of the bottom plate, and the distance d between the bottom surface of the deformable portion and the top surface of the bottom plate is smaller than the thickness D of the support portion,
At least one slot is formed in the flanges for each of the deformable portions and is disposed at a boundary of the deformable portion,
The deformable portion is disposed above the slot
heat exchanger. delete The method of claim 1,
The deformation part is polygonal shape,
heat exchanger. The method of claim 1,
At least two deformation parts are arranged to face each other, and a mounting part of the mounting bracket is disposed between two opposite deformation parts,
heat exchanger. The method of claim 4, wherein
The mounting portion of the mounting bracket is connected to a substantially central portion of the support portion of the mounting bracket,
heat exchanger. The method of claim 1,
At least one alignment slot is formed in the bottom plate of the support, and at least one alignment protrusion to be inserted into the alignment slot is formed in the support portion of the mounting bracket,
heat exchanger. delete delete The method of claim 1,
At least one soldered portion is formed between the bottom surface of the deformable portion and the support portion,
heat exchanger. As a method of manufacturing a heat exchanger,
Preparing a pair of supports comprising a bottom plate and a pair of flanges, the pair of flanges forming a gap therebetween and comprising at least one slot;
Inserting at least one mounting bracket into the gap, the mounting bracket comprising a mounting portion having a mounting hole for fastening means and a support portion disposed between the pair of flanges;
Forming at least one deformable portion by replacing a portion adjacent to the slot in the support portion of the mounting bracket to press the support portion between the bottom of the deformable portion and the top surface of the bottom plate; And
Bonding the mounting bracket to the support by soldering;
The deformable portion is disposed on top of the slot,
How to make a heat exchanger. The method of claim 10,
Limiting the movement of the mounting bracket with respect to the longitudinal direction of the support by inserting an alignment protrusion in the alignment slot,
The alignment protrusion is formed on the bottom surface of the support portion, and the alignment slot is formed on the bottom surface of the support,
How to make a heat exchanger.

Images