KR20200072134A - Heat exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger comprising: a case having an accommodation space formed therein, and having header fitting portions formed on both opened sides; a plurality of flow path plates provided inside the case and each forming a flow path through which cooling water and air flow through lamination; and a pair of headers respectively inserted into and coupled to the header fitting portions of the case. The header is formed with an opening penetrating both sides of a frame portion, and formed with a support portion connecting the inside of the frame portion. The support portion is formed in a twisted form at both ends connected to the frame portion, so that the flow resistance of air passing through the header can be reduced, and sufficient internal pressure performance of the header can be secured against the pressure or external force of air passing through the inside.

Description

Heat exchanger {Heat exchanger}

The present invention relates to a heat exchanger, and relates to a heat exchanger capable of cooling compressed air at high temperature and pressure by a supercharger to increase the output of the engine.

An intercooler among heat exchangers is a device that cools compressed air at high temperature and high pressure by a supercharger to increase engine power.

The air compressed rapidly by the supercharger has a very high temperature, which causes the volume to expand and the oxygen density to fall, resulting in a decrease in filling efficiency in the cylinder. Therefore, the intercooler cools the compressed high-temperature air in the supercharger, thereby increasing the intake efficiency of the engine cylinder and improving the combustion efficiency, thereby increasing fuel efficiency.

The intercooler that plays this role can be divided into a water cooling type and an air cooling type according to the cooling method. Among them, the water-cooled intercooler 10 has a similar principle to the air-cooled intercooler, but differs in that it cools compressed air using cooling water or water of a vehicle instead of outside air when cooling the intercooler through which hot air passes. .

The water-cooled intercooler 10 illustrated in FIG. 1 includes a first header tank 20 and a second header tank 30 spaced apart at a predetermined distance and arranged side by side; A first inlet pipe 40 and a first outlet pipe 50 through which air is formed and formed in the first header tank 20 or the second header tank 30, respectively; A plurality of tubes 60 fixed to both ends of the first header tank 20 and the second header tank 30 to form an air passage; And a fin 70 interposed between the tubes 60. The tube 60 and the assembly of the pin 70 is accommodated, the cover member 80 which is opened on one side and the other side on which one end of the tube 60 is located; And is formed on one side of the cover member 80, the second inlet pipe 41 and the second outlet pipe 51 is discharged cooling water flow; It is formed including.

In addition, on the contrary, the coolant passes through the inside of the tube, and the heat exchanger core, which is an assembly in which header tanks, tubes, and fins are assembled, is disposed inside and a case is formed to surround the core, while air passes through the inside of the case, and the core It can be configured to cool the air.

However, the water-cooled intercooler must have sufficient internal pressure performance so as not to be deformed or damaged by the pressure or external force of the cooling water and air passing through the inside. In particular, the headers constituting the header tank must be formed with a structure having sufficient pressure resistance while simultaneously reducing resistance to the flow of air, because an opening must be formed to allow air to pass therethrough.

KR 10-1116844 B1 (2012.02.08)

The present invention has been devised to solve the problems as described above, and the object of the present invention is to reduce the flow resistance of air passing through the header and to provide sufficient pressure resistance of the header against the pressure or external force of air passing through the inside. It is to provide a heat exchanger that can be secured.

Heat exchanger of the present invention for achieving the above object, the receiving space is formed inside, both sides are opened case (100); A plurality of flow path plates 200 provided inside the case 100 and forming flow paths through which cooling water and air flow by stacking, respectively; And a pair of headers 300 coupled to both open sides of the case 100. It is made to include, the header 300 is formed on the inner side of the frame portion 310, the opening 330 penetrating both sides, the support portion 320 is formed to connect the inside of the frame portion 310 is formed , The support part 320 may be formed in a twisted form of the connection part 321 of both ends connected to the frame part 310.

In addition, the support part 320 may be formed parallel to the flow direction of air.

In addition, the support portion 320 may be formed as a flat plate portion 322 in the form of a flat plate having a wide width (w) compared to the thickness (t) of the portion between the connecting portions 321 on both sides.

Further, the flat plate portion 322 of the support portion 320 may be formed perpendicular to the plane formed by the frame portion 310.

In addition, the frame portion side and the plate portion side of the connection portion 321 may be formed perpendicular to each other.

In addition, the flat plate portion 322 of the support portion 320 may be formed to be inclined in a plane formed by the frame portion 310.

In addition, the connecting portion 321 of the support portion 320 may be formed along a direction in which the width (w) direction of the frame portion 310 is formed in a portion connected to the frame portion 310 side.

Further, the support part 320 may be integrally formed with the frame part 310.

In addition, both connection portions 321 of the support portion 320 may be formed in a twisted shape in opposite directions.

In addition, the support part 320 is composed of a plurality of spaced apart from each other, and some of the support parts 320 are formed in a form in which the connecting part 321 is twisted in one direction, and the rest is formed in a twisted form in the other direction. Can be.

In addition, the direction in which the connecting portions 321 of the supporting portions 320 are twisted based on the center in which the supporting portions 320 are arranged may be symmetrically formed.

Further, the support part 320 may be disposed at a position corresponding to the flow path plates 200.

In addition, the support portion 320 is formed of a flat plate portion 322 having a wide width (w) compared to the thickness (t) of the portion between the connecting portions 321 on both sides, the flat plate portion 322 is a flow path It may be formed so as not to block the air passage between the plates (200).

In addition, a plurality of pins 400 interposed in the air flow path between the flow path plates 200 may be further included.

In addition, header openings 110-1 and 110-2 are formed on both open sides of the case 100, and the pair of headers 300 are the header matching portions 110-1 and 110-2, respectively. ).

The support portion connecting the frame portion of the header of the present invention is formed in a twisted shape, and there is an advantage in that it is very easy to manufacture a support portion integrally formed with the frame portion.

In addition, it is possible to reduce the flow resistance of air passing through the header, and has the advantage of ensuring sufficient pressure resistance performance of the header against the pressure or external force of the air passing through the inside.

1 is an exploded perspective view showing a conventional water-cooled intercooler.
2 and 3 are perspective and exploded perspective views showing a heat exchanger according to an embodiment of the present invention.
4 and 5 is an exploded perspective view and an assembly perspective view showing a stacked structure of flow path plates and fins in a heat exchanger according to an embodiment of the present invention.
6 is a front view showing a heat exchanger according to an embodiment of the present invention.
7 is a cross-sectional view taken along line AA′ in FIG. 6.
8 is a cross-sectional view taken along line BB' in FIG. 6.
9 and 10 is a perspective view showing a support formed in the header in the heat exchanger according to an embodiment of the present invention.

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

2 and 3 are assembly and exploded perspective views showing a heat exchanger according to an embodiment of the present invention, and FIGS. 4 and 5 are stacked structures of flow path plates and pins in a heat exchanger according to an embodiment of the present invention. It is an exploded perspective view and an assembled perspective view. In addition, Figure 6 is a front view showing a heat exchanger according to an embodiment of the present invention, Figures 7 and 8 are AA' direction cross-sectional view and BB' direction cross-sectional view of FIG.

As shown, the heat exchanger according to an embodiment of the present invention may be largely composed of a case 100, a plurality of flow path plates 200 and a pair of headers 300. In addition, although not shown, a pair of headers 300 may be combined with a header so that a tank can be coupled to form a space through which air can flow. At this time, the tank may be formed in the form of a container with an open side facing the header, and the tank may be formed with an inlet and an outlet through which air is introduced.

Case 100 may be composed of a first member (100-1) and a second member (100-2), the first member (100-1) and the second member (100-2) is coupled to the inside An accommodation space can be formed. In addition, the case 100 is formed with header fitting portions 110-1 and 110-2 at both ends where the first member 100-1 and the second member 100-2 are coupled, and thus the header fitting portion 110 is formed. Headers 300 may be inserted into -1, 110-2) and accommodated. Here, in the case 100, the body 130-1, 130-2 may be formed in a square tube shape, and the header fitting portions 110 formed at both open ends of the bodies 130-1, 130-2 -1, 110-2) may be formed in a form in which both ends of the body are extended to the outside.

The plurality of flow path plates 200 may be stacked and joined in the height direction, and after being stacked, they may be joined by brazing or the like, and cooling water flow paths through which cooling water flows and air flow paths through which air can flow may be formed, respectively. As shown as an example, the flow path plates 200 may be formed with holes penetrating up and down on both sides in the longitudinal direction, and the periphery of the holes may protrude toward the air flow path to form the cup portion 202. That is, the cup portion 202 is formed in a cup shape with a hole in the bottom surface, is concavely formed on the cooling water flow path side surface with respect to the plate 201, and may be convexly formed on the air flow path side surface. In addition, an inflow blocking portion 203 and a side support portion 204 are formed to block the periphery of the cup portion 202 in a position close to the cup portion 202, and air flows toward the cup portion 202 by the inflow blocking portion 203. This can be blocked and the pin 400 can be supported by the side support 204. That is, when high-temperature air is introduced into the air flow path, which is a space in which the fins 400 between the flow path plates 200 are disposed on one side in the longitudinal direction, air is flowed toward the cup portion 202 by the inflow blocking portion 203. Since it cannot be introduced, air may flow into the pins 400 disposed on both sides of the cup portion 202 in the width direction to flow in the longitudinal direction. Thus, by stacking a plurality of flow path plates 200, an inlet tank portion 210 through which cooling water is introduced is formed on one side in the longitudinal direction, and an outlet tank portion 220 through which cooling water is discharged from the other side may be formed. In addition, the flow path plate 200 is, for example, laminated and bonded so that two flow path plates face each other, and is formed as a single tube in which a cooling water flow path is formed, and a corrugated fin 400 is interposed between the tubes. It can be joined to the tube and the empty space between the tubes can be formed as an air flow path through which air flows. 4 and 5 shows an assembly in which pins 400 are interposed between two flow path plates 200, and air flows between the two flow path plates 200 in which the fins 400 are disposed. A flow path can be formed. In addition, as shown in FIG. 3, a plurality of assemblies as described above may be stacked to form an assembly in which channel plates and pins are stacked and assembled. In addition, the shape of the pin is not shown in FIGS. 2 and 3, and the shape of the pin 400 is only partially illustrated in FIG. 6, but the pins are arranged in a uniform arrangement as described above and the illustrated structure. Can be.

The header 300 is a portion that is combined with the tank as described above to form a space through which air can flow, and the header 300 has header fitting portions 110-1 and 110-2 on both sides of the case 100. ) After being inserted into each, it can be joined by brazing. In addition, the header 300 is formed in the form of a square frame 310 so that an opening 330 penetrating both sides in the longitudinal direction is formed inside, and the opening 330 is an air flow path formed by stacking the flow path plates 200. It can be connected with. In addition, the header 300 may be formed with support parts 320 connecting and supporting the inside of the frame 310.

Thus, the cooling water flowing into the cooling water inlet part 131-2 formed in the second member 100-2 of the case 100 flows to the inlet tank part 210 formed by the lamination of the flow path plates 200, thereby providing a flow path plate. Cooling water outlets (131-) formed in the second member (100-2) of the case (100) are gathered in the outlet tank (220) formed by lamination of the flow path plates (200) through the cooling water flow paths formed by (200) 1). And air may flow from one side of the header 300 toward the other side, and the air passes through the air flow path between the flow path plates 200 through the opening 330 of the one side side header 300 and the other side of the lengthwise header. It may flow through the opening 330 of 300.

Here, the header 300 is composed of a frame portion 310 and a plurality of support portions 320 in which the openings 330 are formed, and the support portions 320 have both ends on the width direction, which is a direction facing each other in the frame portion 310. It may be formed in a connected form. In addition, the support portion 320 may include a twisted connection portion 321 formed at both ends of the flat plate portion 322. At this time, the flat plate portion 322 of the support portion 320 may be disposed in a direction parallel to the longitudinal direction of the flow direction of air, and the connection portions 321 are formed at both ends of the flat plate portion 322 in the width direction of the heat exchanger. The flat plate portion 322 may be formed to be connected to the frame portion 310 by the connection portion 321. That is, the support part 320 is formed integrally with the frame part 310 to be parallel to the plane formed by the frame part 310, and then holds and twists a portion corresponding to the flat part 322, thereby flattening the flat part of the support part 320 ( 322) may be erected in a direction perpendicular to the plane formed by the frame portion 310, and the connecting portions 321 connected to both ends of the flat portion 322 may be formed in a twisted shape.

Thus, the heat exchanger of the present invention has an advantage in that the support part connecting the frame part of the header is formed in a twisted form, and it is very easy to manufacture the support part integrally with the frame part. In addition, it is possible to reduce the flow resistance of the air passing through the header and to secure sufficient pressure resistance performance of the header against the pressure or external force of the air passing through the inside.

Hereinafter, a detailed configuration of the support part 320 of the header 300 will be described in detail.

9 and 10 is a perspective view showing a support formed in the header in the heat exchanger according to an embodiment of the present invention.

As illustrated, the support portion 320 may be formed as a flat plate portion 322 in the form of a flat plate having a wide width (w) compared to a thickness (t). That is, sufficient structural strength can be secured by the flat plate portion 322.

Further, the flat plate portion 322 of the support portion 320 may be formed perpendicular to the plane formed by the frame portion 310. That is, as shown, the flat plate portion 322 is disposed parallel to the longitudinal direction perpendicular to the surface formed by the frame portion 310 to minimize flow resistance to air passing through the opening 330. Here, the connection portions 321 that are both ends of the support portion 320 may be formed perpendicularly to the frame portion side, which is a portion connected to the frame portion 310, and a plate portion side, which is a portion connected to the flat plate portion.

In addition, the flat plate portion 322 of the support portion 320 may be formed to be inclined in a plane formed by the frame portion 310. Although not shown, an inlet or an outlet through which air is introduced or discharged may be formed in a tank combined with the header 300 to form a space through which air flows, and the direction of the inlet or outlet or the shape of the tank Depending on the direction in which the air flows toward the opening 330 of the header 300 may be formed in a direction inclined with respect to the longitudinal direction, the inclined angle of the flat plate portion 322 may be inclined according to the flow direction of air. You can.

In addition, the connecting portion 321 of the support portion 320 may be formed along a direction in which the width (w) direction of the frame portion 310 is formed in a portion connected to the frame portion 310 side. That is, since the support part 320 can be formed in a twisted shape by holding and twisting the flat plate part 322, the connection part 321 has a width (w) direction in a part connected to the frame part 310. It may be formed along the portion 310.

Further, the support part 320 may be integrally formed with the frame part 310. In more detail, the shape of the frame portion 310 and the opening 330 are formed by pressing one flat plate, and the portion that remains between the openings 330 and is connected to the frame portion 310 is twisted and twisted. 320 can be formed. Thus, the support part 320 may be formed integrally with the frame part 310, and since the support part 322 is not formed separately from the frame part 310, it is easy to manufacture and the pressure resistance can be improved.

In addition, both connection portions 321 of the support portion 320 may be formed in a twisted shape in opposite directions. That is, since the support portion 320 may be formed by holding and twisting the flat plate portion 322, the connection portions 321 on both sides of one support portion 320 may be formed in twisted shapes in opposite directions.

In addition, the support part 320 is composed of a plurality of spaced apart from each other, some of the plurality of support parts 320 are formed in a twisted form of the connection part 321 in one direction, and the other support part 320 is the connection part 321 ) May be formed in a twisted form in the other direction. That is, as illustrated, there may be support portions 320 twisted in a clockwise direction, and support portions 320 twisted in a counterclockwise direction may be together. Thus, when holding and twisting the flat plate portion 322, the twisting force in both directions acts to form the support portions 320, thereby preventing the frame portion 310 from being deformed to one side.

In addition, the direction in which the connecting portions 321 of the supporting portions 320 are twisted based on the center in which the supporting portions 320 are arranged may be symmetrically formed. That is, when the direction in which the support portions 320 are twisted is formed symmetrically with respect to the central portion, it is possible to prevent the support portion from being deformed only to one side by pressure acting from the inside to the outside of the frame portion 310. have.

Further, the support part 320 may be disposed at a position corresponding to the flow path plates 200. As illustrated, the support part 320 is formed along the width direction of the heat exchanger, and is arranged so that the flat plate part 322 of the support part 320 is positioned at the height at which the flow path plates 200 are disposed when viewed from the front. Can be. Here, the two flow path plates 200 may be joined to form a tube in which a cooling water flow path is formed, and the fin 400 may be connected to the tube by interposing a fin 400 in an air flow path that is a space between the tubes. . At this time, the thickness of the flat plate portion 322 is formed to be less than or equal to the thickness of the tube, the flat plate portion 322 may be disposed in an area where the tube is disposed in the height direction, and the fin 400 is disposed in the height direction. The flat plate portion 322 may not be disposed in the region. Thus, the flat portion 322 does not block the portion where the air flows, thereby reducing the flow resistance of the air.

Further, as an example, the first member 100-1 and the second member 100-2 constituting the case 100 may be bent and formed in an L-shape, respectively. That is, the first member 100-1 is bent in an L-shape, so that the body 130-1 and the header fitting portions 110-1 on both sides may be integrally formed, and likewise, the second member 100-2 is also provided. Bend in an L-shape, the body 130-2 and the header fitting portions 110-2 on both sides may be integrally formed. Here, the second member 100-2 may be formed by rotating the first member 100-1 by 180 degrees. That is, the first member 100-1 and the second member 100-2 have the same shape, but only the arrangement may be configured to rotate 180 degrees from each other. Thus, since the first member and the second member are the same, the number of parts can be reduced. In addition, the case 100 may be coupled by bonding end portions adjacent to each other of the first member 100-1 and the second member 100-2. In addition, the header fitting portions 110-1 and 110-2 of the first member 100-1 and the second member 100-2 are bent outwardly from both ends of the bodies 130-1 and 130-2. Consists of first bends (111-1, 111-2) and second bends (121-1, 121-2) bent in the longitudinal direction at the ends of the first bends (111-1, 111-2) Can be. At this time, the first bending portion (111-1, 111-2) may be bent in a direction perpendicular to the body (130-1, 130-2), the second bending portion (121-1, 121-2) The first bent portion may be bent toward the outside in the longitudinal direction.

In addition, the first member (100-1) and the second member (100-2) constituting the case 100 as shown is coupled to the case coupling portions (120-1, 120-), the ends of which are adjacent to each other bent. 2) can be formed. That is, the right end of the first surface portion 130-1a, which is a portion disposed in the horizontal direction among the bodies 130-1 of the first member 100-1, is bent upward and the case coupling portion 120-1 is It may be formed, the case coupling portion 120-1 of the first member (100-1) is a second surface portion of the body 130-2 of the second member (100-2) disposed in the vertical direction ( 130-2b) may be in contact with the surface of the inner surface to be joined by bonding. Similarly, the left end of the first surface portion 130-2a, which is a portion disposed in the horizontal direction among the bodies 130-2 of the second member 100-2, is bent downward, thereby forming the case coupling portion 120-2. Can be, the case coupling portion 120-2 of the second member 100-2 is the second surface portion 130 which is a part disposed in the vertical direction of the body 130-1 of the first member 100-1 -1b) is in contact with the inner surface may be joined by bonding.

In addition, the corners of the portion in which the first member 100-1 and the second member 100-2 are adjacent parts are formed in an angled shape, so that the first member 100-1 and the second member 100 are formed. -2) may be formed so that there are no empty spaces at the portions where the joints are adjacent to each other. In addition, both ends of the case coupling portion 120-1 of the first member 100-1 may be integrally formed in a form connected to the first bending portions 111-1 of the header matching portion 110-1. In addition, the corner portion to which the case coupling portion 120-1 and the first bending portion 111-1 are connected may also be formed in an angled shape. In addition, a portion adjacent to the first bent portion 111-1 of the corner portions where the case coupling portion 120-1 and the body 130-1 may meet may be formed in an angled shape. Also, the second member 100-2 may be formed in the same shape as the first member.

In addition, the first bent portions 111-1 and 111-2 of the header fitting portions 110-1 and 110-2 of the case 100 are the L-shaped bent corner connecting portions 111-1a and 111- 2a) may be formed, and the connecting portions 111-1a and 111-2a may be integrally formed with the first bent portions 111-1 and 111-2 and the bodies 130-1 and 130-2. . That is, as shown, when the first member 100-1 and the second member 100-2 constituting the case 100 are formed in an L-shape, header fitting portions 110-1 and 110-2 ), the first bent portions 111-1 and 111-2 may also be formed in an L shape. At this time, the connecting portions 111-1a and 111-2a may be integrally formed with the first bending portions 111-1 and 111-2 and the bodies 130-1 and 130-2 by bending.

In addition, the pins 400 may be formed with louvers formed to penetrate both surfaces in a portion forming a flat surface except for the curved portion forming the mountain and valley.

The present invention is not limited to the above-described embodiments, and of course, the scope of application is diverse, and anyone who has ordinary knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications are possible.

100: case
100-1: first member
110-1: Header fitting portion 111-1: First bending portion
112-1: second bent portion 111-1a: connecting portion
120-1: case coupling part 130-1: body
130-1a: first surface portion 130-1b: second surface portion
131-1: Cooling water outlet
100-2: second member
110-2: Header fitting portion 111-2: First bending portion
112-2: second bent portion 111-2a: connecting portion
120-2: case coupling portion 130-2: body
130-2a: first surface portion 130-2b: second surface portion
131-2: Cooling water inlet
200: Euro plate
201: plate 202: cup portion
203: inflow block 204: side support
210: inlet tank portion 220: outlet tank portion
300: header 310: frame portion
320: support 321: connecting portion
322: flat plate portion 330: opening
400: pin

Claims (15)

An accommodation space is formed inside, and both sides are opened;
A plurality of flow path plates 200 provided inside the case 100 and forming flow paths through which cooling water and air flow by stacking, respectively; And
A pair of headers 300 coupled to both open sides of the case 100; It is made, including
The header 300 has an opening 330 penetrating both surfaces inside the frame part 310, and a support part 320 connecting the inside part of the frame part 310 is formed, and the support part 320 is provided. The heat exchanger, characterized in that the connection portion 321 of both ends connected to the frame portion 310 is formed in a twisted form.
According to claim 1,
The support part 320 is a heat exchanger, characterized in that formed in parallel with the flow direction of the air.
According to claim 1,
The support portion 320 is a heat exchanger, characterized in that the portion between the connecting portions 321 on both sides is formed of a flat plate portion 322 having a wide width (w) compared to the thickness (t).
According to claim 3,
Heat exchanger, characterized in that the flat portion 322 of the support 320 is formed perpendicular to the plane formed by the frame portion 310.
According to claim 4,
Heat exchanger, characterized in that the frame portion side and the plate portion side of the connection portion 321 is formed perpendicular to each other.
According to claim 3,
Heat exchanger, characterized in that the flat portion 322 of the support 320 is formed to be inclined to the plane formed by the frame portion 310.
According to claim 1,
The connection part 321 of the support part 320 is a heat exchanger characterized in that the width (w) direction is formed along the direction in which the frame part 310 is formed in a part connected to the frame part 310 side.
According to claim 1,
The support portion 320 is a heat exchanger, characterized in that formed integrally with the frame portion (310).
The method of claim 8,
Heat exchanger, characterized in that the connection portion 321 of the support portion 320 is twisted in opposite directions to each other.
According to claim 1,
The support part 320 is composed of a plurality of spaced apart from each other, and some of the plurality of support parts 320 are formed in a form in which the connection part 321 is twisted in one direction and the rest is formed in a twisted form in the other direction. Heat exchanger.
The method of claim 10,
Heat exchanger characterized in that the direction in which the connecting portion 321 of the supporting portions 320 is twisted based on the center in which the supporting portions 320 are arranged.
According to claim 1,
The support portion 320 is a heat exchanger, characterized in that disposed at a position corresponding to the flow path plate (200).
The method of claim 12,
The support portion 320 is formed of a flat plate portion 322 in the form of a flat plate having a wide width (w) compared to the thickness (t) of the portion between the connecting portions 321 on both sides,
The flat plate portion 322 is a heat exchanger, characterized in that formed so as not to block the air passage between the flow path plates (200).
According to claim 1,
Heat exchanger further comprises a plurality of fins (400) interposed in the air flow path between the flow path plate (200).
According to claim 1,
Header matching portions 110-1 and 110-2 are formed on both open sides of the case 100, and the pair of headers 300 are respectively provided on the header matching portions 110-1 and 110-2. Heat exchanger characterized in that it is inserted and coupled.

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