KR101353716B1 - Plate heat exchanger - Google Patents

Abstract

The plate heat exchanger comprises a plurality of first heat exchanger plates 1 and a second heat exchanger plate 2, wherein the first heat exchanger plate 1 and the second heat exchanger plate 2 are provided side by side with each other and the surrounding A plate package 3 is formed having an edge side, a first plate gap for the first medium and a second plate gap for the second medium. The first heat exchanger plate 1 together with the second heat exchanger plate 2 forms a pair of heat exchanger plates surrounding the first plate gap. The plate package includes a plurality of such pairs. Each heat exchanger plate has two port holes, the port holes extending through the plate package and forming a port in communication with the first plate gap. The second plate gap is open through the peripheral edge side. Each first heat exchanger plate includes a first bend 21 that cooperates with the bends 22 of the second heat exchanger plate to ensure that these two heat exchanger plates take a defined position relative to each other. do. Each port hole of the first heat exchanger plate cooperates with a corresponding port hole of the second heat exchanger plate to ensure that each pair takes a defined position relative to the adjacent pair.

Plate heat exchanger, heat exchanger plate, port hole, bent part, plate interspace

Description

Plate Heat Exchanger {PLATE HEAT EXCHANGER}

The present invention relates to a plate heat exchanger comprising a plurality of heat exchanger plates according to the preamble of claim 1. Such plate heat exchangers can be used in a variety of applications, for example in the combustion gas channels of a combustion plant which obtain thermal energy from the combustion gases.

In a plate heat exchanger of the above kind, which is open outwardly towards the peripheral edge side and does not have any downwardly bent flanges along the edge of each heat exchanger plate, in connection with the mounting of the plate package, It is difficult to guide the plate. As a result, it is difficult to accurately position each individual heat exchanger plate relative to another heat exchanger plate when the plate package is mounted and during the joining of the heat exchanger plates to each other, for example during the subsequent brazing process of the plate package. Guiding and arranging heat exchanger plates requires the use of various types of external guiding elements with the latest technology.

US application 5,918,664 discloses a plate heat exchanger of the type initially formed comprising a plurality of heat exchanger plates. Each heat exchanger plate extends parallel to the main extension plane. The heat exchanger plates are provided next to each other to form a plate package having a peripheral edge side, a first plate gap for the first medium and a second plate gap for the second medium.

The first heat exchanger plate together with the second heat exchanger plate forms a pair of heat exchanger plates surrounding the first plate gap and the plate package includes a plurality of heat exchanger plate pairs. It is formed by the first heat exchanger plate and the remaining heat exchanger plate is formed by the second heat exchanger plate. Each heat exchanger plate has at least two port holes, the port holes extending through the plate package and forming a port in communication with the first plate gap. The heat exchanger plate is configured such that the second plate gap opens through the peripheral edge side.

US application 5,967,227 discloses another kind of plate heat exchanger comprising a plurality of heat exchanger plates extending parallel to the main extension plane. The heat exchanger plates are provided alternately next to each other to form a plate package. The heat exchanger plate forms a first plate gap for the first medium and a second plate gap for the second medium. The first plate gap and the second plate gap are sealed by surrounding gaskets. Each heat exchanger plate has two port holes extending through the plate package and forming a port in communication with the first plate gap, and two ports forming a port extending through the plate package and in communication with the first plate gap. With holes. Each heat exchanger plate includes a bend at each corner, and the bend cooperates with a corresponding bend of an adjacent heat exchanger plate in the plate package.

It is an object of the present invention to overcome the above mentioned problems and to facilitate guiding and arranging heat exchanger plates in connection with mounting and coupling of the plate package.

This object can be achieved by a plate heat exchanger of the kind initially formed, which ensures that each pair of heat exchanger plates occupies a predetermined position relative to an adjacent heat exchanger plate pair. A port hole is configured to cooperate with an opposing port hole of the second heat exchanger plate.

When the first heat exchanger plate is placed on the second heat exchanger plate, the two heat exchanger plates are guided to the correct position by two bends which cooperate with each other, and this position during the whole process of mounting and combining the plate package and the plate heat exchanger. Can be guaranteed to be maintained. When the two heat exchanger plates are attached to each other, the two bends can prevent the two heat exchanger plates from being displaced or rotated with respect to each other in a plane parallel to the extension plane. Moreover, due to the fact that the port holes are designed to cooperate with the corresponding port holes of adjacent pairs in the plate package, it is easy to place the other pairs accurately with respect to each other. Thus, the port holes will guide the heat exchanger plate pairs into position relative to each other and will contribute to maintaining the heat exchanger plate pairs in this position during the entire manufacturing process.

According to one embodiment of the invention, each of the first heat exchanger plate and the second heat exchanger plate has a compression molding pattern extending in the pressing direction with respect to the extension plane, wherein the first bent portion is the extension plane of the first heat exchanger plate. Extends in a first direction with respect to the second bent portion in a second direction with respect to the extension plane of the second heat exchanger plate, wherein the second direction extends in a direction opposite to the first direction but opposite to the pressing direction. . Since the bends extend in different directions with respect to the extension plane and with respect to the heat exchange pattern and the port region of the compression molded plate, the bend preferably is a shaping operation after the main compression molding forming the pattern and the port area of the plate. Is manufactured in. In this case, the first direction and the second direction may extend across the extension plane or substantially across. Furthermore, each second heat exchanger plate may be rotated 180 ° relative to each first heat exchanger plate in the finished plate package. In this way the first bend and the second bend will extend in the same direction in the finished plate package, which is in each pair between the first bend and the second bend and thus the first heat exchanger plate and the second bend. It makes it possible to provide proper form fitting and proper form locking between the heat exchanger plates.

According to another embodiment of the invention, each heat exchanger plate extends along a longitudinal centerline extending through the bend. Moreover, each second heat exchanger plate may be rotated 180 ° around the centerline of the heat exchanger plate in the plate package.

According to another embodiment of the invention, the first heat exchanger plate and the second heat exchanger plate are permanently coupled to each other in the plate package. Such a permanently bonded plate package can be achieved by brazing, gluing or welding.

According to another embodiment of the invention, each first heat exchanger plate comprises two first bends and each second heat exchanger plate comprises two second bends. These two bends of each heat exchanger plate are sufficient to ensure placing the heat exchanger plates as described above with respect to each other.

According to another embodiment of the invention, two first bends are provided opposite each other along each edge of the first heat exchanger plate, and two second bends are mutually along each edge of the second heat exchanger plate. Provided oppositely.

According to another embodiment of the invention, each port hole comprises a peripheral port area, wherein the port area around the first port hole of each heat exchanger plate is located at a first level with respect to the extension plane, The port area around the second port hole of the heat exchanger plate is located at a different level with respect to the extension plane. Preferably, the port area about the first port hole of the first pair of heat exchanger plates may be configured to engage the port area around the second port hole of the second pair of adjacent heat exchanger plates. Further, the port area around the second port hole of the first heat exchanger plate second pair may be configured to engage with the port area around the first port hole of the second pair of heat exchanger plate second adjacent. In this way, the port holes can contribute to guiding the heat exchanger plate pairs into position relative to each other and to maintain the heat exchanger plate pairs in this position during the entire manufacturing process.

The invention is explained in more detail through the description of a non-limiting embodiment with reference to the accompanying drawings below.

1 discloses an exploded perspective view of a plate heat exchanger according to an embodiment of the present invention.

2 discloses a top view of the plate heat exchanger of FIG. 1.

3 discloses a cross-sectional view of the plate heat exchanger taken along line III-III of FIG. 2.

4 discloses a cross-sectional view of a plate heat exchanger taken along line IV-IV of FIG. 2.

5 discloses in more detail a part of the edge region V of the plate heat exchanger.

6 discloses a simplified exploded perspective view of a plate package of a plate heat exchanger according to the invention.

1 to 5 an embodiment of a plate heat exchanger is disclosed. The plate heat exchanger comprises a plurality of heat exchanger plates 1, 2. The heat exchanger plates 1, 2 consist of a first heat exchanger plate 1 and a second heat exchanger plate 2. All heat exchanger plates 1, 2 have a heat exchange function in the plate heat exchanger. 3, each heat exchanger plate 1, 2 extends parallel to the main extension plane p. The main extension plane p can be thought to extend in parallel with the base plane of each heat exchanger plate 1, 2 through the base plane of each heat exchanger plate 1, 2. 1, 2) are compression molded from each plane in a manner known per se to achieve a compression molding pattern comprising a heat exchanger pattern with a pleat and port region pattern.

The heat exchanger plates 1, 2 are provided next to each other to form a plate package 3 with an edge side 4, which edge side 4 extends around the plate package 3. 3, the heat exchanger plates 1, 2 in the plate package 3 form a first plate gap 5 for the first medium and a second plate gap 6 for the second medium. In addition, the heat exchanger plates 1, 2 in the plate package 3 so that one heat exchanger plate of the two becomes the first heat exchanger plate 1 and the other heat exchanger plate becomes the second heat exchanger plate 2. Is provided. In particular, as can be seen in FIGS. 1 and 3, the first heat exchanger plate 1 and the adjacent second heat exchanger plate 2 form a pair of heat exchanger plates in the plate package 3, such that A pair of substrates surrounds the first interplate pole 5. As can be seen, the plate package 3 in the disclosed embodiment comprises three pairs of such heat exchanger plates 1, 2. Of course, the plate heat exchanger may comprise fewer or more such pairs of heat exchanger plates 1, 2 depending on the specific use of the plate heat exchanger.

In the disclosed embodiment, each heat exchanger plate 1, 2 has two port holes 8, 9, which port holes 8, 9 extend through the plate package 3 and have a first plate gap. A port communicating with (5) is formed. Thus, one of the port holes 8, 9 forms an inlet port for the first medium which enters the first plate gap 5, and the other port hole 9 is the first exiting from the first plate gap 5. 1 Form an outlet port for the medium.

The heat exchanger plates 1, 2 are configured such that the second plate gap 6 opens through the peripheral edge side 4. Thus, the second medium can flow freely into the second plate gap 6 through the edge side 4 of the plate heat exchanger. Depending on how the plate heat exchanger is arranged for the flow of the second medium, the flow direction of the second medium through the plate heat exchanger can be determined.

Each port hole 8, 9 includes a peripheral port area 10, 11. 3, the port region 10 around the first port hole 8 of each heat exchanger plate 1, 2 is located at the first level p ′ with respect to the main extension plane p, The second port region 11 around the second port hole 9 of each heat exchanger plate 1, 2 is located at the second level p ″ with respect to the main extension plane p. In the disclosed embodiment, the two port regions 10, 11 are both located on the same side of the main extension plane p, where level p 'is further from the extension plane p than level p' '. It is located far apart.

In addition, the plate heat exchanger includes a frame plate 13 and a pressure plate 14, and the frame plate 13 and the pressure plate 14 do not have any heat exchange function. In the disclosed embodiment, the pressure plate 14 does not have a port hole, while the frame plate 13 has a port hole concentric with the port holes 8, 9, respectively. The connecting pipes 15, 16 are connected to the frame plate 13 to enable communication with each one of the aforementioned ports.

Each first heat exchanger plate 1 comprises two first bends 21, and each second heat exchanger plate 2 comprises two second bends 22. The first bends 21 each heat exchanger in order to ensure that the heat exchanger plates 1, 2 in each pair occupy a defined position relative to each other and that this position is maintained during the entire manufacturing process of the plate heat exchanger. It is arranged to cooperate with the second bend 22 of the pair of plates 1, 2.

In the disclosed embodiment, the first bend 21 extends in a first direction with respect to the main extension plane p of the first heat exchanger plate 1, more precisely in a direction away from the main extension plane p. . The second bent portion 22 extends in a second direction with respect to the main extension plane p of the second heat exchanger plate 2, that is, in a direction spaced apart from the main extension plane p. The second direction is a direction opposite to the first direction with respect to the main extension plane p. 1 to 5, the first direction is a direction opposite to the pressing direction described above. Thus, the second bend 22 extends in the same direction or substantially the same direction as the compression molding patterns of the heat exchanger plates 1, 2 and the port regions 10, 11. The first direction and the second direction extend across or substantially across the main extension plane p. Thus, all of the heat exchanger plates 1, 2 in the plate package 3 are identical except for the bent portions 21, 22 extending in opposite directions.

When the plate heat exchanger is mounted, all the second heat exchanger plates 2 are rotated 180 ° with respect to all the first heat exchanger plates 1. In particular, referring to FIG. 5, after the second heat exchanger plate 2 is rotated in this manner, the first bent portion 21 and the second bent portion 22 are thus in the same direction in the finished plate package 3. Will extend. Each heat exchanger plate 1, 2 extends along a longitudinal center line x parallel to the main extension plane p. The second heat exchanger plate 2 is rotated 180 ° around each longitudinal center line x in the plate package. 6 schematically discloses in a simplified manner a plate package 3 with two pairs of heat exchanger plates 1, 2, wherein the second heat exchanger plate 2 is about the longitudinal center line x. It is rotated 180 degrees. Thus, the bent portions 21, 22 extend in the same direction in the plate package 3.

As can be seen in FIGS. 1, 2, and 6, the first bends 21 of each first heat exchanger plate 1 define the respective edge 23 of the first heat exchanger plate 1. Thus provided opposite each other. More precisely, each first bend 21 is provided concentrically with respect to the longitudinal center line x such that the longitudinal center line x extends centrally through the first bend 21. In the same way, the second bends 22 of each second heat exchanger plate 2 are provided opposite each other along each edge of the second heat exchanger plate 2. More precisely, each second bend 22 is provided concentric with respect to the longitudinal center line x such that the longitudinal center line x extends centrally through the second bend 22.

1 to 5, each heat exchanger plate has two opposing short edges 23 and two opposing long edges 24. As can be seen, the first bent portion 21 and the second bent portion 22 are provided on two short edges 23. As an alternative to the two bends of each heat exchanger plate, providing a bend along the long edge 24 or providing a bend along the long edge 24 to reinforce each heat exchanger plate with four bends. Of course it is possible.

In the disclosed embodiment, each heat exchanger plate 1, 2 has an edge region 25, which is adjacent to the short edge 23 and the long edge 24 and the heat exchanger plate 1. , 2) and extend around the port regions 10, 11. The edge region 25 is substantially planar and parallel to the main extension plane p. In the disclosed embodiment, the major extension plane p is also located in the edge region 25. As can be seen in FIG. 3, the edge region 25 of the first heat exchanger plate 1 is the edge region 25 of the second heat exchanger plate 2 in each pair of heat exchanger plate 1, 2. Contact with

Thus, the plate heat exchanger comprises the aforementioned heat exchanger plate 21, 22 pairs. These pairs are placed next to each other in the plate package. Thus, each port hole 8, 9 of this pair of first heat exchanger plates 1 is positioned at a position with respect to the pair of heat exchanger plates 1, 2 to which each pair of heat exchanger plates 1, 2 is adjacent. In order to ensure that it occupies, it is configured to cooperate with the opposing port holes 8, 9 of this adjacent pair of second heat exchanger plates 2. More specifically, the port area 10 around the first port hole 8 of the first pair of heat exchanger plates 1, 2 is a second port hole 9 of the second pair of adjacent heat exchanger plates 1, 2. It is configured to engage with the port area (11) around. The port region 11 around the first port hole 9 of the first pair is configured to engage the port region 10 around the first port hole 8 of the second pair.

Because of the guidance of the heat exchanger plates 1, 2 achieved by the bends 21, 22 and the port regions 10, 11, all parts of the plate package 3, in other words at least all heat exchanger plates 1, 2) and also possibly frame frame 13, pressure plate 14 and connecting pipes 15, 16 together with suitable braze material can be mounted and placed in the final position between the parts, the The thick plate package 3 can be placed in an oven and brazed in a manner known per se. It is also conceivable to braze the two heat exchanger plates 1, 2 into the pair described above in the first stage and to braze the pair thus formed in the second stage. In addition, brazing and other joining methods may be used, such as, for example, welding or bonding.

According to another alternative embodiment, the bent portions 21, 22 may extend in the same direction spaced apart from the main extension plane p. When the plate package 3 is mounted, all the second heat exchanger plates are rotated 180 °, and in each pair the bent portions 21, 22 of the heat exchanger plates 1, 2 face each other in opposite directions. Will extend. To fix this position, the bends 21, 22 can then be displaced from the longitudinal center line x such that the bends 21, 22 are adjacent to the longitudinal center line x. This embodiment has the advantage that all heat exchanger plates 1, 2 can be made exactly the same. If possible, bends along the respective edges 23, 24 can improve the fixation of the position.

The invention is not limited to the disclosed embodiments, but may be changed and modified within the scope of the following claims.

Claims (13)

A plurality of heat exchanger plates (1, 2), Each heat exchanger plate 1, 2 extends in parallel with the main extension plane p and is provided side by side to each other so that the peripheral edge side 4, the first plate clearance 5 for the first medium and the second Forming a plate package 3 having a second plate gap 6 for the medium, One heat exchanger plate is formed by the first heat exchanger plate 1 and the other heat exchanger plate is formed by the second heat exchanger plate 2, so that the first heat exchanger plate 1 is the second heat exchanger. Together with the substrate 2, one pair of heat exchanger plates 1, 2 is formed surrounding the first plate gap 5, and the plate package 3 comprises a plurality of heat exchanger plates 1, 2. Contains a pair, Each said heat exchanger plate has at least two port holes 8, 9, which port holes 8, 9 extend through the plate package 3 and communicate with the first plate gap 5. To form a port, The heat exchanger plates 1, 2 are plate heat exchangers which are configured such that the second plate gap 6 is opened through the peripheral edge side 4, Each of the first heat exchanger plates 1 includes two separate first bends 21 and each of the second heat exchanger plates 2 has two separate second bends 22. Include, The two first bent portions 21 are provided opposite to each other along each edge of the first heat exchanger plate 1, and the two second bent portions 22 are arranged on the second heat exchanger plate ( Are provided opposite each other along each edge of 2),  In each pair of heat exchanger plates (1, 2) the first bends are arranged in order to ensure that the two heat exchanger plates (1, 2) in each pair occupy a predetermined position relative to each other. 22) and arranged to cooperate with Each port hole 8, 9 of the first heat exchanger plate 1 ensures that each pair of heat exchanger plate 1, 2 occupies a defined position relative to an adjacent pair of heat exchanger plate 1, 2. And for guiding with opposing port holes 8, 9 of the second heat exchanger plate 2, Each of the first heat exchanger plate 1 and the second heat exchanger plate 2 has a compression molding pattern extending in the pressing direction with respect to the main extension plane p, Each of the first bent portions 21 extends in a first direction with respect to the main extension plane p of the first heat exchanger plate 1, and includes a curved surface, Each of the second bent portions 22 extends in a second direction with respect to the main extension plane p of the second heat exchanger plate 2, and includes a curved surface, And the second direction is the same as the pressing direction but extends in a direction opposite to the first direction. delete The method of claim 1, And said first direction and said second direction extend across said main extension plane (p). The method according to claim 1 or 3, A plate heat exchanger, characterized in that each second heat exchanger plate (2) is rotated 180 ° with respect to each first heat exchanger plate (1) in the finished plate package (3). The method according to claim 1 or 3, Each second heat exchanger plate 2 is rotated 180 ° relative to each first heat exchanger plate 1 in the finished plate package 3, And said first bent portion (21) and said second bent portion (22) extend in the same direction in said completed plate package (3). The method according to claim 1 or 3, A plate heat exchanger, characterized in that each heat exchanger plate (1, 2) extends along a longitudinal center line (x) extending through the bends (21, 22). The method according to claim 6, Each second heat exchanger plate (2) in the plate package (3) is rotated 180 ° around the longitudinal center line (x) of the heat exchanger plate. The method according to claim 1 or 3, And the first heat exchanger plate and the second heat exchanger plate are permanently coupled to each other in the plate package. delete delete The method according to claim 1 or 3, Each port hole 8, 9 includes a peripheral port area 10, 11, The port area 10 around the first port hole 8 of each heat exchanger plate 1, 2 is located at a first level p 'with respect to the main extension plane p, The port area 11 around the second port hole 9 of each heat exchanger plate 1, 2 is located at a second level p ″ with respect to the main extension plane p. Plate heat exchanger. 12. The method of claim 11, The port area 10 around the first port hole 8 of the first pair of heat exchanger plates 1, 2 is connected to the second port hole of the adjacent pair of second heat exchanger plates 1, 2. 9) Plate heat exchanger, characterized in that it is configured to engage with the port area (11) around. The method of claim 12, The port region 11 around the second port hole 9 of the first heat exchanger plate 1, 2 pair is the first port hole of the adjacent second heat exchanger plate 1, 2 pair. (8) A plate heat exchanger, characterized in that it is configured to engage with the port area (10) around it.

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