KR101371641B1 - Support Panel And Heat Exchanger adopting the same - Google Patents

Abstract

The present invention relates to a reinforcing panel and a plate heat exchanger employing the same, and in particular, the present invention relates to an upper substrate including a top fluid inlet / outlet, through which fluid flows in or out, and a sidewall formed perpendicular to the bottom surface in an edge region, the top fluid. A lower substrate including a lower plate fluid inlet portion provided at a position opposite to the inlet and outlet portion and a sidewall formed perpendicularly to the bottom surface at the edge region, and having an inner pin disposed therein to maintain airtightness with the upper substrate; A reinforcing fluid inlet is formed at a position facing the lower plate fluid inlet and formed in a disc shape, and includes a reinforcing support wall extending at a predetermined height in at least a portion of an edge of the reinforcing fluid inlet and toward the lower plate fluid inlet; Reinforcing protrusions protruding by a certain height in a direction opposite to the reinforcing support wall It discloses a structure of a plate type heat exchanger and a reinforcing panel applied thereto comprising a reinforcing panel comprising.

Description

Reinforcement panel and plate heat exchanger employing the same {Support Panel And Heat Exchanger adopting the same}

The present invention relates to a plate heat exchanger, and more particularly, to a reinforcement panel and a plate heat exchanger employing the same to support effective heat exchange based on the reinforcement panel having a moderate strength while achieving weight reduction.

The heat exchanger generally includes a header tank through which the heat exchange medium is introduced and discharged, and a tube which connects the header tanks to allow heat exchange while distributing the heat exchange medium therein. At this time, the heat exchanger can be divided into two types. The fin-tube type heat exchanger is formed by inserting a plurality of tubes into a tank, and the plate type heat exchanger in which a plurality of plates are stacked to form a tube part and a tank part. It can be divided into a plate heat exchanger. The heat exchanger is mainly used in the water-cooled cooling method mounted inside the radiator tank, and is widely used because it can realize high performance in a compact size.

On the other hand, the oil cooler for automobile transmission has been mainly used double tube oil cooler, but the performance required by the performance improvement of the transmission is increasing, the plate heat exchanger combined with the plate and fin is required to improve the flow resistance resistance The trend is increasing. In particular, in the case of the transmission oil cooler, it is difficult to secure a sufficient plate thickness and reinforcement due to the high operating pressure of the oil, making it difficult to manufacture a compact heat exchanger. In order to solve this problem, a plate heat exchanger having fins in the entire channel without a reinforcing plate has been proposed, but although the number of parts and the weight can be achieved, the flow resistance increases, which makes it difficult to actually apply the plate heat exchanger.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, by providing a reinforcing plate shape of the reinforcing plate of the reinforcement panel to support the weight reduction while maintaining the pressure resistance performance and employing the same One plate heat exchanger is provided.

It is also an object of the present invention to provide a reinforcement panel and a plate heat exchanger employing the same to provide a direction to the flow of the fluid to support smooth flow flow improvement and to provide a performance improvement effect.

Reinforcement panel according to the present invention for achieving the above object is a disk-shaped reinforcement bottom portion, reinforcing fluid inlet and outlet formed to penetrate through the center of the reinforcement bottom portion, reinforcement protrusion formed by the recessed portion of the reinforcement bottom portion, the fluid And a reinforcement support wall extending from the reinforcement bottom part at a border of the entrance and exit and having a predetermined height, a predetermined width, and a length.

Here, the reinforcement panel may further include extension parts formed at positions spaced apart at regular intervals in a direction in which a mall reinforcement support wall is formed at an outer portion of the reinforcement bottom part, and bent parts formed in a direction perpendicular to the extension parts. .

In addition, the bent portions may be formed to have the same direction and the same height as the reinforcement protrusion.

The reinforcing support wall may extend perpendicularly to the reinforcement bottom portion at some edges of the circular edges of the reinforcement fluid inlet or outlet, or may have a predetermined obtuse angle with respect to the vertical direction of the reinforcement bottom portion.

The present invention also provides an upper substrate including a top fluid inlet and a fluid inflow or outflow, and an upper substrate including sidewalls formed perpendicularly to the bottom surface in the edge region, and a bottom fluid inlet and outlet at a position opposite to the top fluid inlet and The lower substrate includes a sidewall formed perpendicular to the bottom surface in the edge region and is formed in a disc shape having a lower substrate coupled with the upper substrate to maintain hermeticity with inner pins disposed therein, and facing the lower plate fluid inlet / outlet. A reinforcement fluid inlet / outlet is provided in the reinforcing fluid inlet and outlet, and includes a reinforcing support wall extending at a predetermined height in the direction of the lower plate fluid inlet and outlet at least in a portion of the edge of the reinforcing fluid inlet and outwardly Disclosed is a configuration of a plate heat exchanger including a reinforcement panel including a protrusion.

The lower substrate may further include at least one locking step provided in an area adjacent to the lower plate fluid inlet and outlet to align the inner pins.

The plate heat exchanger includes a first auxiliary support formed in a direction parallel to the side wall of the lower plate at one edge semicircle of the region adjacent to the lower plate fluid inlet and the upper plate at one edge semicircle of the region adjacent to the upper plate fluid inlet and outlet. It may further include a second auxiliary support formed in a direction parallel to the side wall of the second auxiliary support provided in a position symmetrical with the first auxiliary support when facing the substrate.

The reinforcement panel is formed at a position spaced apart at regular intervals in the direction of forming the reinforcement support wall in the outer portion of the reinforcement bottom portion, and the stretched portions facing the rear surface of the lower substrate when the substrates are stacked, perpendicular to the stretched portions. It may further include a bent portion formed in the direction and the end when the stack of the substrate facing the upper surface of the upper substrate.

In this case, the upper substrate may further include at least one fixing protrusion formed on one side of an upper surface to align the bent portions when the substrates are stacked.

The bent portions may be formed to have the same direction and the same height as the reinforcement protrusions.

On the other hand, the reinforcing support wall disposed at the position where the fluid is introduced may be formed with a certain obtuse angle with respect to the vertical direction of the reinforcing bottom portion.

In addition, the reinforcing support wall disposed at the position at which the fluid is discharged may extend perpendicularly to the reinforcing bottom portion at some edges of the circular edge of the fluid inlet and outlet.

As described above, according to the reinforcing panel according to the present invention and a plate heat exchanger employing the same, the present invention is disposed between the substrates stacked with appropriate rigidity to stably support the maintenance of the spacing of the substrates, while the weight of the reinforcing plate is It can be reduced and improves fluid flow to help provide better performance.

1 is a view schematically showing the appearance of the plate heat exchanger and the shape of the substrates according to an embodiment of the present invention.
2 is a view showing a part of the front surface of the substrate module of the present invention.
Figure 3 is a view showing a part of the transparent perspective of the substrate module of the present invention.
4 is a view showing in more detail the reinforcing panel and the lower substrate of the present invention.
5 is a perspective view showing a part of the plate heat exchanger of the present invention.
6 is a front view showing a part of the plate heat exchanger of the present invention.
7 is a transparent perspective view showing a part of the plate heat exchanger of the present invention.
8 is a cross-sectional view showing a partial cross section of the plate heat exchanger of the present invention.
9 is a perspective view showing another form of the reinforcing panel of the present invention.
10 is a cross-sectional view taken along the line AA ′ of FIG. 9.
11 is a front view of another form of the upper substrate of the present invention and a reinforcement panel laminated thereto.

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

In the following description of the embodiments of the present invention, descriptions of techniques which are well known in the technical field of the present invention and are not directly related to the present invention will be omitted. In addition, detailed description of components having substantially the same configuration and function will be omitted.

For the same reason, some of the elements in the accompanying drawings are exaggerated, omitted, or schematically shown, and the size of each element does not entirely reflect the actual size. Accordingly, the present invention is not limited by the relative size or spacing depicted in the accompanying drawings.

1 is a view schematically showing the appearance of the plate heat exchanger 1 and the configuration of the upper substrate 200 and the lower substrate 100 according to an embodiment of the present invention, Figure 2 is a top substrate 200 and a lower substrate 100 is a view showing a part of the form of the substrate module 300 coupled with the reinforcement panel 400 in more detail, Figure 3 is a view showing the side of the substrate module 300 of FIG. 4 is a view showing in detail the reinforcement panel 400 and the lower substrate 100 according to an embodiment of the present invention.

1 to 4, the plate heat exchanger 1 of the present invention may be formed to include a coupling tube 50 and a substrate module 300. The substrate module 300 may be configured by sequentially stacking a plurality of upper substrates 200, a lower substrate 100, and a reinforcement panel 400. Such a plate heat exchanger 1 of the present invention is disposed in the reinforcement panel 400 having a reinforcing protrusion spaced apart by a certain height from the bottom surface of the thin plate form in the process of coupling the upper substrate 200 and the lower substrate 100 As a result, the flow path of the fluid flowing into or out of the substrate module 300 based on the reinforcing support wall protruding toward the fluid inlet / outlet portion of the lower substrate 100 while maintaining the distance between the respective substrate modules 300. Can help improve the

The coupling tube 50 serves as a gateway for fluid inflow. That is, one side of the coupling tube 50 is connected to a hose and the like to support the movement of the fluid, for example, oil, etc. into the stacked substrate modules 300, and the other side of the coupling tube 50 is stacked on the substrate module 300. It supports the role of the passageway through which the flow-flowed fluid can flow out.

The upper substrate 200 may be disposed to cover the lower substrate 100 and may be hermetically sealed to the lower substrate 100 through welding or the like. The upper substrate 200 may be provided in a shape similar to the overall shape of the lower substrate 100. For example, the upper substrate 200 may have a predetermined width and length, and the horizontal direction may be provided as a plate having a relatively long shape as compared with the vertical direction, and both edges of the plate may be provided as a semi-circular shape. In addition, an upper plate fluid inlet and outlet 210 may be provided at both edges of the upper substrate 200 to allow the fluid to flow in and out of the coupling tube 50. The upper plate fluid inlet and outlet part 210 includes inlets and outlets provided on left and right sides.

In particular, both edges of the upper substrate 200 of the present invention are in contact with the lower substrate 100 in an outward direction of the region where the upper plate fluid inlet / outlet 210 is provided to support the internal space of the substrate module 300, while the inlet or outlet flows into the outlet. The second auxiliary support 220 may be provided to withstand the internal pressure of the fluid. The second auxiliary support 220 is formed to protrude from the outer surface of the plate of the upper substrate 200 in the inner surface direction may be provided in a semi-circular protruding strip shape to correspond to the edge of the semi-circular upper substrate 200. That is, the second auxiliary support 220 may be formed to protrude in the same direction as the sidewall formed at the edge of the upper substrate 200. One second auxiliary support 220 may be provided at each of both edges of the plate of the upper substrate 200.

The lower substrate 100 may be provided in a shape opposite to the upper substrate 200. That is, the lower substrate 100 may be provided in a plate shape having a width and a length similar to those of the upper substrate 200. In addition, lower plate fluid inlets 110 may be provided at both edges of the plate 100 of the lower substrate 100 to allow the fluid from the coupling tube 50 to flow in or flow out from the center of the substrate. The first auxiliary support 120 corresponding to the second auxiliary support 220 may be provided in an area adjacent to the area where the lower plate fluid inlet / out part 110 is provided. The first auxiliary support 120 may be formed in a curved strip shape protruding from the outer surface of the lower substrate 100 by a predetermined height in the inner surface direction. Similar to the second auxiliary support 220, the first auxiliary support 120 may also be provided on each side of each of the edges of the lower substrate 100, and may protrude in the same direction as the edge sidewall of the lower substrate 100. .

On the other hand, the lower substrate 100 may be provided with a locking step 150 for supporting the inner pin 350 in the region adjacent to the lower plate fluid inlet and outlet 110. The locking step 150 may serve as an alignment mark for allowing the inner pin 350 to be disposed at a predetermined position while the inner pin 350 is seated on the lower substrate 100. At least one locking jaw 150 may be provided at an upper side and a lower side of the lower substrate 100 in the width direction, respectively. Alternatively, the designer may have a predetermined width regardless of the upper side and the lower side according to the intention of the designer. Although the illustrated figure is shown to be formed only at one edge of the lower substrate 100, the locking step 150 of the same shape may be provided at the opposite edge. Accordingly, the inner pin 350 may be provided to be sized to be seated in a space formed by the locking projections 150 disposed at both edges of the lower substrate 100.

Each of the lower substrate 100 and the upper substrate 200 may have sidewalls formed at a predetermined height on an outer portion thereof. Sidewalls of the lower substrate 100 and the upper substrate 200 are formed to be higher than the protruding heights of the second auxiliary support 220 and the first auxiliary support 120 so that the substrates can be hermetically sealed during welding.

The inner pin 350 is seated on the bottom surface of the lower substrate 100, and is arranged to be airtight inside the substrate module 300 according to the coupling of the upper substrate 200, and the heat of fluid flowing into the substrate module 300. It absorbs and dissipates heat. The inner pin 350 may be provided to have a shape in which the surface area becomes more than a predetermined value in order to absorb more heat of the fluid and then radiate heat faster. For example, the inner pin 350 may be provided in a wrinkled shape. In addition, the inner pin 350 may be manufactured in various forms to increase the surface area. The inner pin 350 may be uniformly disposed on the locking step 150 in the process of being disposed on the lower substrate 100. The inner pin 350 may be attached and fixed by the locking jaw 150. To this end, the inner pin 350 may further include a structure, for example, a hook-type structure that is coupled to the locking step 150. Accordingly, the inner pin 350 may be prevented from flowing by vibration or internal pressure after being seated in the substrate module 300. In addition, the inner pin 350 is fixed to support a more uniform performance evaluation and provision in a structure in which a plurality of substrate modules 300 are stacked.

The reinforcement panel 400 may be disposed in an area adjacent to the lower plate fluid inlet / outlet 110 of the lower substrate 100. The reinforcement panel 400 may be provided in a strip shape with a center penetrating through the disk shape. In addition, one side of the reinforcement panel 400 is provided with extension parts 421 and 422 and bending parts 431 and 432 protruding outward to align the reinforcement panels 400 and to maintain a gap between the substrate modules 300. Can support

In particular, the reinforcement panel 400 of the present invention is a partial region of the reinforcing fluid inlet and outlet 411, the reinforcing bottom portion 412 forming the reinforcing fluid inlet and outlet 411, and a portion of the reinforcing fluid inlet and outlet 411. The reinforcing support wall 413 formed perpendicular to the reinforcement bottom portion 412 is formed to include a reinforcement protrusion 414 formed at a negative angle from the reinforcement bottom portion 412.

The reinforcing bottom portion 412 is formed in an annular shape based on the reinforcing fluid inlet and outlet 411 formed in a circular shape in the center, and a reinforcing protrusion 414 engraved in a band shape may be provided at the center of the reinforcing bottom portion 412. have. The height of the reinforcement protrusions 414 determines the stacking height of the substrate modules 300. Accordingly, in the process of forming the reinforcement protrusion 414, the reinforcement protrusion 414 may be manufactured in consideration of the height of the predesigned substrate module 300. In addition, since the reinforcement protrusion 414 supports the substrate modules 300, the thickness of the reinforcement protrusion 414 may be uniformly formed with the thickness of the reinforcement panel 400 or may have a thickness capable of maintaining a target rigidity. I can make it.

The reinforcing support wall 413 may be formed to have a predetermined height and width in an upper direction perpendicular to the reinforcing fluid inlet / outlet 411 in the edge region of the reinforcing fluid inlet / outlet 411, in particular, in a direction in which the upper substrate 200 is coupled. For example, the reinforcing support wall 413 may have a width that does not exceed half of the reinforcing fluid inlet / outlet 411 and may be lower than a height formed by the upper substrate 200 and the lower substrate 100. The reinforcing support wall 413 may be formed in an outward direction with respect to the center of the lower substrate 100. Accordingly, the reinforcing support wall 413 of the present invention can support the fluid flowing from the coupling pipe 50 to flow in the direction of the center of the lower substrate 100.

The reinforcement panel 400 may be provided with extension parts 421 and 422 in a direction parallel to a direction in which the reinforcement support wall 413 is formed at one edge of the reinforcement bottom part 412. The extension parts 421 and 422 may extend by a predetermined length in the outward direction with respect to the center of the reinforcement panel 400 at positions spaced apart from each other by a predetermined distance. At the ends of the extension parts 421 and 422, the bent parts 431 and 432 may be provided in a direction perpendicular to the bottom of the reinforcing bottom part 412, that is, in a direction in which the reinforcing protrusion part 414 is formed. Each of the bent portions 431 and 432 may be formed perpendicular to the extension portions 421 and 422 and may be formed at positions facing each other. The lengths of the bent portions 431 and 432 may be formed to be the same as the height of the reinforcement protrusions 414.

Substantially, the bent portions 431 and 432 support the substrate modules 300 in the upper and lower portions, respectively, due to the structure disposed between the substrate modules 300 in the process of stacking the substrate modules 300. That is, the bent portions 431 and 432 consequently perform the same supporting function as the reinforcement protrusions 414. Accordingly, the heights of the bent portions 431 and 432 may be formed to be the same as the heights of the reinforcement protrusions 414. In addition, as the reinforcement panel 400 is rotated in a predetermined direction while the lower substrate 100 is coupled to the lower substrate 100, the reinforcement panel 400 may not be arranged in a direction desired by the designer. And it is possible to check whether the reinforcement panel 400 is disposed at a normal position by checking the positions of the extension parts 421 and 422.

Meanwhile, the extension parts 421 and 422 and the bent parts 431 and 432 may be omitted according to a designer's intention. That is, the reinforcement panel 400 of the present invention may be provided in a form in which the reinforcement protrusion 414 protrudes in an annular strip form without the extension parts 421 and 422 and the bent parts 431 and 432.

5 is a front view showing the front of the appearance of the plate heat exchanger 1 according to an embodiment of the present invention, Figure 6 is a side perspective view of the appearance of the plate heat exchanger of the present invention, Figure 7 is a plate heat exchanger of the present invention 8 is a cross-sectional view showing a side view of the coupling tube side of the plate heat exchanger of the present invention.

5 to 8, in the plate heat exchanger 1 of the present invention, a first lower substrate 100 may be disposed at a bottom thereof and a first upper substrate 200 may be disposed at an upper portion thereof. In this case, a separate fluid inlet / out unit may not be provided on the first lower substrate 100 disposed at the bottom. In addition, the first upper substrate 200 may be provided with a fluid inlet and outlet. Accordingly, the fluid flowing from the upper side may move in the outlet direction through the respective substrate modules. In this case, the moving fluids flow through the inner pins 350 disposed on the substrate modules, respectively.

Meanwhile, the reinforcement panel 400 disposed between the substrate modules 300 supports the interval between the substrate modules 300 by using the reinforcement protrusions 414 and the bent portions 431 and 432. . Accordingly, the cooling fluid flowing into the tank of the radiator in which the plate heat exchanger 1 is disposed may flow between the gaps of the substrate modules 300 to support cooling of the substrate modules 300 heated by the fluid.

At this time, the reinforcement panel 400 of the present invention supports the fluid flowing into the inner substrate 350 while being inserted into the lower substrates 100. In this process, an area except for the reinforcing support wall 413 of the reinforcing panel 400 may be exposed to the outside, resulting in contact with the cooling medium. Accordingly, the reinforcement panel 400 of the present invention may serve to transfer the heat of the fluid to the cooling medium to further improve the cooling function. In addition, the bent parts 431 and 432 and the extension parts 421 and 422 formed in the reinforcement panel 400 of the present invention are disposed to protrude from the substrate module 300 of the plate heat exchanger 1 by a predetermined length, thereby cooling fluid. The plate heat exchanger 1 may serve as a guide to more easily flow in the direction of the substrate module 300. That is, since the reinforcement panels 400 are disposed in the form in which the substrate modules 300 are stacked, the reinforcement panels 400 serve as cooling fluid guides by the bent parts 431 and 432 and the extending parts 421 and 422. Accordingly, the plate heat exchanger 1 of the present invention can support the improved cooling function by more smoothly supporting the flow of the cooling fluid.

9 is a view showing another form of the reinforcing panel 400 of the configuration of the plate heat exchanger 1 according to an embodiment of the present invention, Figure 10 is a cross-sectional view showing a cross-sectional view taken along line A-A 'of FIG.

9 and 10, another type of reinforcement panel 400 of the present invention has a configuration similar to that of the reinforcement panel 400 described previously. That is, the reinforcement panel 400 of the present invention includes a reinforcement bottom portion 412, a reinforcement fluid inlet and outlet 411, a reinforcement protrusion 414, extension parts 421 and 422, and bending parts 431 and 432. The reinforcement panel 400 of another embodiment of the present invention may include a reinforcement support wall 423 formed at an obtuse angle with respect to the vertical direction with respect to the front surface of the reinforcement bottom 412.

The reinforcing support wall 423 according to another embodiment of the present invention may be formed to be elongated at an angle in an upward direction from the edge of the reinforcing fluid inlet and outlet 411. In particular, the reinforcing support wall 423 of the present invention may be formed to be bent in the outward direction from the center of the reinforcing fluid inlet and outlet 411. At this time, the bending direction of the reinforcing support wall 423 may be toward the auxiliary supports 120 and 220 of each substrate. In particular, the reinforcement panel 400 having a predetermined angle and employing the curved reinforcement support wall 423 may be disposed only in the direction of the fluid inlet part of the fluid inlet and outlet part. Since the reinforcing support wall 423 is bent in the direction of the auxiliary supporters 120 and 220, the fluid flowing from the coupling pipe 50 moves inside each substrate module 300 together with the support of the reinforcing support wall 423. Can be. In this case, the reinforcing support wall 423 of the present invention is disposed in a bent state at an angle, so that fluid flowing downward from the coupling pipe 50 flows more quickly toward the center of the substrate module 300 along the reinforcing support wall 423. Support to move. In addition, since the reinforcing support wall 423 is disposed at an angled angle, the reinforcing support wall 423 may receive relatively less fluid pressure flowing through the coupling pipe 50 as compared with the vertical arrangement. In addition, the fluid leaving the reinforcing support wall 423 is supported by the auxiliary supports 120 and 220 to move toward the center of the substrate module 300.

Meanwhile, in the case of the reinforcement panel 400 disposed at the fluid outlet portion, the reinforcement panel 400 may be disposed perpendicularly to the substrate without bending so that the fluid can be quickly discharged in the direction of the coupling pipe 50. When the reinforcing support wall 423 having the deflection is disposed, the fluid flowing in the edge direction from the center of the substrate module 300 moves faster in the edge direction along the surface thereof, so that the edge direction of the substrate module 300 becomes closer. A lot of pressure can be applied.

Therefore, the reinforcement panel 400 disposed in the direction in which the fluid is introduced may include a reinforcement support wall 423 bent at an angle to the outside of the substrate module 300, and the reinforcement panel disposed in the direction in which the fluid flows out. 400 may be provided in a form that extends perpendicularly to the front surface of the substrate module 300.

11 is a view showing another structure of the upper substrate 200 and the structure of the reinforcement panel 400 stacked thereon according to an embodiment of the present invention in more detail.

Referring to FIG. 11, the upper substrate 200 according to the embodiment of the present invention may have the upper fluid inlet 210 and the second auxiliary support 220, the plate and the plate, like the upper substrate 200 described above. It includes a side wall 240 formed by a predetermined height perpendicular to the edge. In particular, the upper substrate 200 of the present invention may be provided with at least one fixing protrusion 230 on the outer surface opposite to the inner surface to which the lower substrate 100 is coupled.

The fixing protrusion 230 may be provided with a first fixing protrusion 231 and a second fixing protrusion 232 spaced apart at regular intervals. The interval between the first fixing protrusion 231 and the second fixing protrusion 232 may be formed to be similar to the separation distance of the bent portions 431 and 432 provided in the reinforcing panel 400. Accordingly, the reinforcement panel 400 is inserted into the lower plate fluid inlet and outlet 110 of the lower substrate 100, and then bent to the fixing protrusions 230 of the upper substrate 200 in the process of stacking each substrate module 300. 431 and 432 may be aligned. Since the bent portions 431 and 432 are fixed by the fixing protrusion 230, the upper substrate 200 is supported so that the reinforcement panel 400 does not rotate the lower plate fluid inlet 110 of the lower substrate 100 about its axis. can do.

Meanwhile, in the above description, the first fixing protrusion 231 and the second fixing protrusion 232 are described as being spaced apart at a predetermined interval, but the present invention is not limited thereto. That is, the first fixing protrusion 231 and the second fixing protrusion 232 may be disposed in contact with each other at a predetermined gap. Accordingly, the upper substrate 200 in which the first fixing protrusion 231 and the second fixing protrusion 232 are disposed has only one bending portion among the bending portions 431 and 432 in the process of the reinforcing panel 400 is aligned. Support this to be fixed. For example, the bent portion 431 located on the upper side of the reinforcement panel 400 may be fixed by the fixing protrusion 230 formed to be biased on the upper side. In this case, the gap of the fixing protrusion 230 may be provided in a form corresponding to the thickness of the bending portion 431 to fix the upper bending portion 431. In addition, the fixing protrusion 230 may be provided in the form of fixing the respective bent portions (431, 432) individually.

As described above, another form of the upper substrate 200 according to the embodiment of the present invention allows the reinforcement panel 400 to flow by allowing the bent portions 431 and 432 to be uniformly arranged while the reinforcement panel 400 is seated. Supported so as not to support the reinforcement panel 400 can be uniformly aligned. Accordingly, the fluid inflow or outflow by the reinforcement panel 400 may be uniformly generated, thereby supporting uniformly maintaining the performance of the plate heat exchanger 1.

As described above, the reinforcement panel and the plate heat exchanger employing the same according to the embodiment of the present invention maintain the spacing of the substrate modules by providing protrusions and bent portions while reducing the material required for the reinforcement panel by making the reinforcement panel thin. It can provide a certain strength for. In particular, the reinforcement panel of the present invention provides a reinforcing support wall 423 in the region coupled to the lower substrate to support the inflow of the fluid flow more quickly in the center direction, and also the outflow of fluid flowing from the center direction to the edge direction Can be supported more reliably. In particular, the reinforcing panel of the present invention and the plate heat exchanger employing the same provide extension and bending parts to guide the flow of the cooling fluid along with the strength reinforcement, and to more quickly dissipate heat transferred from the fluid.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. , And are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention may be practiced without departing from the scope of the invention disclosed herein.

1: plate heat exchanger 100: lower substrate
110: lower plate fluid inlet and outlet 120: first auxiliary support
140: side wall 150; Jaw
200: upper substrate 210: upper plate fluid entry and exit
220: second auxiliary support 300: substrate module
350: inner pin 400: reinforcement panel
411: reinforcing fluid inlet and outlet 412: reinforcing bottom
413, 423: reinforcing support wall 414: reinforcing protrusion
421, 422 kidney parts 431, 432 bent parts
50: coupling tube

Claims (12)

Disc-shaped reinforcement bottoms;
A reinforcing fluid inlet and outlet formed through the center of the reinforcing bottom portion;
A reinforcement protrusion formed by engraving a predetermined region of the reinforcement bottom portion;
A reinforcing support wall extending from the reinforcing bottom portion at a border of the fluid inlet and outlet having a predetermined height, a predetermined width, and a length; / RTI >
Extension parts formed at positions spaced apart at regular intervals in a direction in which the reinforcement support wall is formed at an outer portion of the reinforcement bottom part;
Bending parts formed in a direction perpendicular to the extension parts;
Reinforcement panel, characterized in that it further comprises. delete The method of claim 1,
The folds
Reinforcement panel, characterized in that it is formed having the same direction and the same height as the reinforcement protrusion. Disc-shaped reinforcement bottoms;
A reinforcing fluid inlet and outlet formed through the center of the reinforcing bottom portion;
A reinforcement protrusion formed by engraving a predetermined region of the reinforcement bottom portion;
A reinforcing support wall extending from the reinforcing bottom portion at a border of the fluid inlet and outlet having a predetermined height, a predetermined width, and a length; / RTI >
The reinforcing support wall is
Extends perpendicular to the reinforcement bottom at some of the circular edges of the reinforcement fluid inlet or outlet;
Reinforcement panel, characterized in that it is formed with a certain obtuse angle with respect to the vertical direction of the reinforcement bottom. An upper substrate including a top plate fluid inlet / outlet through which fluid flows in or out and a sidewall formed perpendicular to the bottom surface at an edge region thereof;
A lower plate fluid inlet and a side wall formed at a position opposite to the upper plate fluid inlet and a sidewall formed to be perpendicular to the bottom surface, and coupled to the upper substrate in an inner pin disposed therein to maintain airtightness; Lower substrate;
A reinforcing bottom portion formed in a disc shape, and a reinforcing fluid inlet is provided at a position facing the lower plate fluid inlet and the reinforcement extending at a predetermined height in a direction of the lower plate fluid inlet at least in a region of the edge of the reinforcing fluid inlet and outlet. A reinforcement panel including a support wall and including a reinforcement protrusion protruding by a predetermined height in a direction opposite to the reinforcement support wall; / RTI >
A first auxiliary support formed in a direction parallel to the side wall of the lower plate at one edge semicircle of the region adjacent to the lower plate fluid inlet and outlet;
A second auxiliary support formed in a direction parallel to the side wall of the top plate at one edge semi-circular side of the region adjacent to the top fluid inlet / outlet and symmetrical with the first auxiliary support;
Plate heat exchanger comprising a further. 6. The method of claim 5,
The lower substrate is
At least one catching jaw provided at a region adjacent the lower plate fluid inlet / outlet to align the inner pins;
Plate heat exchanger comprising a further. delete An upper substrate including a top plate fluid inlet / outlet through which fluid flows in or out and a sidewall formed perpendicular to the bottom surface at an edge region thereof;
A lower plate fluid inlet and a side wall formed at a position opposite to the upper plate fluid inlet and a sidewall formed to be perpendicular to the bottom surface, and coupled to the upper substrate in an inner pin disposed therein to maintain airtightness; Lower substrate;
A reinforcing bottom portion formed in a disc shape, and a reinforcing fluid inlet is provided at a position facing the lower plate fluid inlet and the reinforcement extending at a predetermined height in a direction of the lower plate fluid inlet at least in a region of the edge of the reinforcing fluid inlet and outlet. A reinforcement panel including a support wall and including a reinforcement protrusion protruding by a predetermined height in a direction opposite to the reinforcement support wall; / RTI >
The reinforcement panel is
Extension parts formed at positions spaced apart at regular intervals in a direction in which the reinforcement support wall is formed from an outer portion of the reinforcement bottom part and facing the rear surface of the lower substrate when the substrates are stacked;
Bent portions formed in a direction perpendicular to the elongated portions and having end portions facing the upper surface of the upper substrate when the substrates are stacked;
Plate heat exchanger comprising a further. 9. The method of claim 8,
The upper substrate is
At least one fixing protrusion formed on one side of an upper surface to align the bent portions when the substrates are stacked;
Plate heat exchanger comprising a further. 9. The method of claim 8,
The folds
And a plate heat exchanger having the same direction and the same height as the reinforcement protrusion. An upper substrate including a top plate fluid inlet / outlet through which fluid flows in or out and a sidewall formed perpendicular to the bottom surface at an edge region thereof;
A lower plate fluid inlet and a side wall formed at a position opposite to the upper plate fluid inlet and a sidewall formed to be perpendicular to the bottom surface, and coupled to the upper substrate in an inner pin disposed therein to maintain airtightness; Lower substrate;
A reinforcing bottom portion formed in a disc shape, and a reinforcing fluid inlet is provided at a position facing the lower plate fluid inlet and the reinforcement extending at a predetermined height in a direction of the lower plate fluid inlet at least in a region of the edge of the reinforcing fluid inlet and outlet. A reinforcement panel including a support wall and including a reinforcement protrusion protruding by a predetermined height in a direction opposite to the reinforcement support wall; / RTI >
The reinforcing support wall disposed at the position where the fluid is introduced
Plate-type heat exchanger characterized in that it is formed with a certain obtuse angle with respect to the vertical direction of the reinforcing bottom portion. 6. The method of claim 5,
The reinforcing support wall disposed at the position at which the fluid flows out
A plate heat exchanger characterized in that it extends perpendicular to the reinforcement bottom portion at some edges of the circular edge of the fluid inlet and outlet.

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