KR20130081708A - Plate heat exchanger - Google Patents

Abstract

The present invention relates to a plate heat exchanger (1) comprising a core of a heat exchanger plate (4) arranged between the first and second end plates (2, 3) and the first and second end plates (2, 3). And a plurality of threaded tightening bolts 5a, 5b, 5c extend between the first and second end plates 2, 3, and with the help of nuts 6 or the like these plates At least one guiding element for guiding the first end plate 2 and the heat exchanger plate 4 with respect to the second end plate 3, arranged to hold at a desired distance from each other to hold the cores together; 7, 7a, 7b are releasably arranged in at least one of the threaded tightening bolts 5a, 5b, the guide element 7a extends through the opening 8 in the first end plate 2, At least one guide element 7a, 7b receives at least one of the threaded tightening bolts 5a, 5b. To be provided with a through-hole 9, and the outer form 10 corresponding to the notches 11 of the heat exchanger plates 4 and the first end plate (2).

Description

Plate Heat Exchanger {PLATE HEAT EXCHANGER}

The present invention relates generally to plate heat exchangers that allow heat transfer between two fluids at different temperatures for various purposes. In particular, the present invention relates to a plate heat exchanger comprising a first end plate, a second end plate and a package of heat exchanger plates located between the frame plate and the pressure plate. The plurality of threaded tightening bolts extend between the first end plate and the second end plate and are arranged to hold these plates at a desired distance from each other to hold these plates with the package of the heat exchanger plate with the aid of a nut or the like. .

Plate heat exchangers generally include a frame plate, a pressure plate, also called an end plate, and a package of heat exchanger plates positioned between and adjacent to the frame plate and the pressure plate. The gasket is disposed between the heat exchanger plates. The gasket is received in a gasket groove on the heat exchanger plate, which groove is formed during form-pressing of the heat exchanger plate. The plate heat exchanger further comprises an inlet and an outlet port, which ports extend through the plate package to treat two or more media in the plate heat exchanger. A plurality of threaded tightening bolts extend between the frame plate and the pressure plate, and with the help of nuts or the like keep these plates at a target distance from each other in order to keep them with the package of the heat exchanger plate and prevent the plate heat exchanger from leaking. Are arranged to ensure.

The heat exchanger plate is generally made by foam pressing of sheet metal, the first plate intermediate space in communication with the first inlet port and the first outlet port, and the second plate in communication with the second inlet port and the second outlet port. It is placed in the plate package in such a way as to form an intermediate space. The first and second plate intermediate spaces are alternately arranged in the plate package.

The design of the heat exchanger plate for the plate heat exchanger aims to use as much heat transfer or heat exchange area as possible for heat exchange between two or more media, but also how the gasket is on the heat exchanger plate. It is necessary to consider whether it can be applied, firmly fastened and fulfill its sealing function. The position of the threaded tightening bolt is preferably selected to obtain a plate heat exchanger that is not exposed to too much stress.

 SE-C-171 499 shows a plate heat exchanger with a frame plate, a pressure plate, a package of heat exchanger plates, two tie bars as well as a special support device. Both the frame plate and the support device have feet. Among other things, pressure is generated on the pressure plate through the influence of the yoke and the plate package is held together. This structure shows the disadvantage that both the support device and the pressure plate are inevitably produced in the form of a very strong structure. In addition, the auxiliary transfer bar for supporting the plate in connection with mounting and detaching the heat exchanger introduces unnecessary complexity.

EP-B1-1 027 571 shows another plate heat exchanger in which a tightening bolt is integrated into the transfer bar and the guide bar and creates a guide element for the pressure plate and the heat exchanger plate. Thus, the position of the tightening bolts is further optimized to resist the force exerted on the plate heat exchanger during operation. The guide element extends from the frame plate to the pressure plate and is surrounded by a protective sleeve which protects the threaded portion of the guide element from engaging the heat exchanger plate. In addition, the guide element is arranged to be connected to a support device located at a substantial distance from the pressure plate.

The drawback of this solution is that the stress and force are too large when the solution is applied to a large plate heat exchanger.

It is an object of the present invention to create a structure that provides an optimized load distribution while still being cheaper and less complex to manufacture than described above for plate heat exchangers.

An advantage is obtained by using a guide element releasably arranged on at least one of the threaded tightening bolts as at least one guide element for guiding the first end plate and the heat exchanger plate with respect to the second end plate. The guide element extends through the opening, the at least one guide element having a through hole for receiving at least one of the threaded tightening bolts and an outer shape corresponding to the cutout of the first end plate and the heat exchanger plate. .

According to another aspect of the invention, the plate heat exchanger has two guide elements, the first guide element is arranged on top of the plate heat exchanger and the second guide element is arranged on the bottom of the plate heat exchanger. The first and second guide elements can have the same cross-sectional profile.

According to another aspect of the invention, the second guide element further comprises a guiding rail for movably receiving the second guide element.

According to another aspect of the invention, the guide rail for movably receiving the second guide element is fully or partially supported by the ground.

According to another aspect of the invention, the at least one guide element comprises two separate parts, and the at least one guide element and the guide rail are made of extrudable material.

According to another aspect of the invention, the support device is releasably arranged at a significant distance from the first end plate at the ends of the upper and lower tightening bolts and extends between the upper and lower tightening bolts.

According to another aspect of the invention, the at least one guide element is movable along the tightening bolt, wherein a portion of the guide element forms a plate heat exchanger in which the heat exchanger plates are pressed together by the first end plate to operate. The removed portion of the guide element can then be arranged on the free portion of the tightening bolt on the outside of the plate heat exchanger.

According to another aspect of the invention, the object is that a heat exchanger plate lies on at least one guide element, a first end plate lies on a guide rail, and on which the at least one guide element is movable. Achieved by an accommodating plate heat exchanger.

Further aspects of the invention are defined in the dependent claims.

It is possible to create structures that are cheaper and less complex to manufacture while providing optimized load distribution compared to the prior art.

The invention will now be described more closely by the description of the various embodiments and with reference to the accompanying drawings.
1 shows a perspective view of a plate heat exchanger according to one embodiment of the invention.
2 shows a side view of a plate heat exchanger according to one embodiment of the invention.
3 shows a partial view of a plate heat exchanger according to one embodiment of the invention.
4 shows a cross section AA of a plate heat exchanger according to an embodiment of the invention.
FIG. 5 shows a first partial detail view B of the plate heat exchanger of FIG. 4 in accordance with an embodiment of the present invention. FIG.
FIG. 6 shows a second partial detail C of the plate heat exchanger of FIG. 4 in accordance with an embodiment of the present invention. FIG.
7a and 7b show another view of the guide element according to the invention.
8a and 8b show another view of a guide rail according to the invention.

Heat exchangers are used to transfer heat between two fluids separated by a solid body. Heat exchangers can take several forms, the most common being helical heat exchangers, tubular heat exchangers, and plate heat exchangers. Plate heat exchangers are used for heat transfer between hot and cold fluids flowing in alternating flow paths formed between a set of heat exchanger plates. The arrangement of heat exchanger plates defined above is enclosed between end plates which are relatively thicker than the heat exchanger plates. The inner surface of each end plate faces the heat transfer plate.

1 and 2 show schematic diagrams of a plate heat exchanger 1 comprising a plurality of compression-molded heat exchanger plates 4, the heat exchanger plates 4 being mutually shaped to form a plate package. Are provided parallel to and continuously. The plate package is provided between a first end plate 2, also called a pressure plate, and a second end plate 3, also called a frame plate. Between the heat exchanger plates 4 a first interspace and a second interplate space are formed. The end plates 2 and 3 are pressed against the plate package and against each other by tightening bolts or tie bars 5a to 5c extending through the end plates 2 and 3, and the tightening bolts 5a to 5c are It is held in place by the nuts 6, 20.

The plate heat exchanger 1 comprises a first inlet port and a first outlet port for the first medium, a second inlet port and a second outlet port for the second medium. The inlet and outlet ports extend through the second end plate 3 and the plate package. Of course, it is also possible for the inlet and outlet ports to be arranged on both sides of the plate heat exchanger 1, ie on both end plates 2 and 3. The two media can be guided in the same or opposite directions with respect to each other.

The heat exchanger plate 4 of the illustrated embodiment forms a first plate intermediate space in communication with the first inlet port and a first outlet port, and a second plate intermediate space in communication with the second inlet port and the second outlet port. In a plate package. The first and second plate intermediate spaces are alternately arranged in the plate package. The plate intermediate spaces can be separated by a gasket extending in the gasket groove formed during foam pressing of the heat exchanger plate. Gaskets are usually made of rubber or polymer material. The heat exchanger plate 4 has a corrugated pattern to improve heat exchange between the two fluids.

Tightening bolts 5a to guide the heat exchanger plate 4 and to protect the threaded tightening bolts 5a, 5b from wear of the heat exchanger plate 4, simplify the structure, and make the structure cheaper. Guide elements 7, 7a, 7b are provided on the top and bottom of 5b).

Compared to the state of the plate heat exchanger of the art, the top and bottom of the tightening bolts 5a, 5b replace the conventional transfer and guide bars, otherwise the transfer and guide bars are removed while the plate heat exchanger is stopped. The first end plate 2 and the heat exchanger plate 4 serve to move along the transfer bar and the guide bar to enable opening / closing of the plate heat exchanger. Guide elements 7a and 7b, respectively, having upper and lower guide elements 7a and 7b arranged on the tightening bolts 5a to 5b, having an external cross-sectional shape (see FIGS. 7a to 7b) similar to a conventional transfer bar. By providing a heat exchanger plate 4 having a cutout profile 11 corresponding to the bottom of the guide elements 7a, 7b with the outer shape 10 can be guided along the upper guide element 7a. . Tightening bolts 5a, 5b are received in the openings or through holes 9 of the guide elements 7a, 7b, the through holes 9 extending along the entire longitudinal length of the guide elements 7a, 7b. The guide elements 7a, 7b are made of extrudeable material to make the structure cheaper and lighter to manufacture. The extrudable material may be plastic, aluminum or any other suitable structural material.

In addition, the tightening bolt 5c is present in a conventional manner between the second end plate 3 and the first end plate 2, at the edge of the second end plate 3 and the first end plate 2. It is located in the notch or recess.

Since the guide elements 7a and 7b are made of extrudable material, they cannot bear the same load as the corresponding metal structure. Thus, the load of the heat exchanger plate 4 and the first end plate 2 will be transmitted to the ground via the second or lower guide element 7b and the guide rail 12. The upper guide element 7a and the lower guide element 7b are preferably the same to reduce manufacturing costs, but different shapes are possible. In the illustrated embodiment, for example with reference to FIG. 6, the lower outer feature 10 of the guide element 7b is such that the guide element 7b is fixed to the guide rail 12 and the guide rail 12 is fixed. It corresponds to the inner shape 16 of the guide rail 12 which can be made to be movable accordingly. In some applications the plate heat exchanger 1 is arranged on a frame that fully or partially supports the guide rail 12.

The upper guide element 7a extends through the top opening 8 of the first end plate 2 so that the first end plate 2 is movable relative to the upper guide element 7a. Similarly the lower guide element 7b extends through the lowermost opening 17 of the first end plate 2. Both the lower guide element 7b and the upper guide element 7a only guide the first end plate 2, the load of the first end plate 2 being guide rails on which the first end plate 2 rests. 12) is conveyed by. The heat exchanger plate 4 rests on the lower guide element 7b and is laterally guided by the upper guide element 7a.

Each guide element 7a, 7b comprises two parts 13a, 13b; 14a, 14b (see FIG. 3), which two parts exchange heat plate during the opening and closing process of the plate heat exchanger 1. By enabling the guidance of (4), the outer guide element portions 14a, 14b are removed when the heat exchanger plate 4 and the first end plate 2 are tightened together to form the working plate heat exchanger 1. , The nut 6 is applied onto the tightening bolts 5a, 5b to hold the first end plate 2 in place and the heat exchanger plate 4 is fitted with the first end plate 2 and the second end. Tighten together between the plates 3. The length of the inner guide element portions 13a, 13b may preferably be slightly smaller than the length corresponding to the total thickness of both the heat exchanger plate 4 and the first end plate 2 in the package of the plate. The length of the outer guide element portions 14a, 14b is preferably slightly less than the remaining free ends of the tightening bolts 5a, 5b when the inner guide element portions 13a, 13b are arranged on the tightening bolts 5a, 5b. small.

The upper guide element 7a can be provided with a wear protection feature for reducing wear from the heat exchanger plate 4. The wear protection feature may be a plate or rubber material or any other suitable material and is preferably clamped onto the upper guide element 7a.

The guide elements 7a, 7b have an outer shape 19 having a width corresponding to the opening width of the cutout 11 of the heat exchanger plate 4 and the openings 8, 17 of the first end plate 2. Has a top formed as). Thus both the upper guide element 7a and the lower guide element 7b can guide the first end plate 2 laterally, while the load of the first end plate 2 is applied to the guide rail 12. Are transported by In addition, the upper guide element 7a and the lower guide element 7b will guide the heat exchanger plate 4 laterally by the outer contour 19 of the guide elements 7a, 7b, and the lower guide element ( 7b) will carry the load of the heat exchanger plate 4. The load is transmitted directly to the guide rail 12 and also to the ground. The outer shape 10 at the bottom of the upper guide element 7a guides the heat exchanger plate 4 when the plate heat exchanger 1 is opened and serves as an anti-tilt for the heat exchanger plate 4.

It is also possible for the upper guide element 7a to completely or partially transfer the load of the heat exchanger plate 4 by the outer contour 10.

In FIGS. 5 and 6, the guide elements 7a, 7b and the guide rail 12 are shown in more detail as partial enlargements B and C of FIG. 4 arranged in the plate heat exchanger 1. The advantage of the proposed guide profile 7a, 7b is that the same components can be used not only as the transfer and guide bar in the upper section of the plate heat exchanger 1 but also as the transfer and guide bar in the lower section of the plate heat exchanger 1. Can be. The guide rail 12 functions as a weight transfer element, which also allows the nut 6 to be arranged on the bottom tightening bolt 5b in contact with the first end plate 2 and the plate heat exchanger 1. The lower outer guide element 14b can be removed when the heat exchanger plate 4 and the first end plate 2 are tightened together to keep it in the closed operating mode.

As shown in FIGS. 1 and 2, the plate heat exchanger 1 may also be provided with a support device 15 which allows the plate heat exchanger 1 to open easily, the support device 15 having a tightening bolt ( Provided at the free ends of 5a, 5b and held in place by nuts 20. The support device 15 extends between the two tightening bolts 5a and 5b, the distance between the two tightening bolts 5a and 5b does not change and the force affecting the upper tightening bolt 5a. To ensure that it is delivered to the ground. Further details of the function and operation of the support device 15 will be described in connection with the description of the opening and closing process of the plate heat exchanger 1.

The opening of the plate heat exchanger 1 will now be described. In Figures 1 and 2 the plate heat exchanger 1 is in operating mode. The plate heat exchanger 1 can be opened to enable maintenance, such as cleaning, repairing, replacing or the like of the heat exchanger plate. The nut 20 is unscrewed and the support device 15 and the external guide elements 14a, 14b are separated from the tightening bolts 5a, 5b. The nuts 6 arranged on the tightening bolts 5a, 5b are unscrewed and the outer guide elements 14a, 14b are again arranged on the free portions of the tightening bolts 5a, 5b to allow the inner guide elements 13a, 13b Is pressed against the The package of heat exchanger plate 4 and the first end plate 2 are still held together by an additional tightening bolt 5c. The support device 15 is again mounted onto the free portions of the upper and lower tightening bolts 5a, 5b. The support device 15 is supported on the ground via the outer guide element 14b and the guide rail 12. The nut 20 comes onto the tightening bolts 5a and 5b and is tightened. The additional tightening bolt 5c is detached. When the fastening bolts 5c are released the first end plate 2 and the heat exchanger plate 4 can thus be moved along the guide elements 7a, 7b. Thereby an open mode of service of the plate heat exchanger 1 is achieved when the heat exchanger plate 4 is located between the end plates 2, 3 and can be separated for cleaning and one or several heats The exchanger plate 4 can be taken out and eventually a new one can be put in without having to remove the rest of the heat exchanger plate 4. Tightening the closing or plate heat exchanger 1 together in the operating mode is similarly performed upside down.

The support device 15 keeps the top and bottom tightening bolts 5a, 5b at the correct distance from each other and at the same time the whole plate together with the second end plate 2 in the service open mode of the plate heat exchanger 1. A bar iron, plate iron, or the like, having a length sufficient to function as the support device 15 for the heat exchanger 1. This also ensures that the force affecting the upper tightening bolt 5a is transmitted to the ground via the lower tightening bolt 5a.

The guide elements 7a, 7b and the guide rail 12 are preferably made of a compressible material, such as a plastic or aluminum profile, but may be made of any other suitable manufacturing method or material.

The invention is not limited to the embodiments shown in the drawings and described above, but can be supplemented and modified in any manner within the scope of the invention as defined by the appended claims.

Claims (1)

As a plate heat exchanger (1) comprising first and second end plates (2, 3) and a core of a heat exchanger plate (4) arranged between the first and second end plates (2, 3),
A plurality of threaded tightening bolts 5a, 5b, 5c extend between the first and second end plates 2, 3, and with the help of nuts 6, 20 or the like these plates are exchanged to the heat exchanger plate 4 Are arranged to keep at a target distance from each other to keep with the core of
At least one guide element 7a, 7b for guiding the first end plate 2 and the heat exchanger plate 4 with respect to the second end plate 3 is provided with at least one of the threaded tightening bolts 5a, 5b. In the plate heat exchanger, releasably arranged on one, the guide element 7a extends through the opening 8 in the first end plate 2.
At least one guide element 7, 7a, 7b has a through hole 9 for receiving at least one of the threaded tightening bolts 5a, 5b and at least one guide element 7, 7a, 7b. ) Is characterized in that it has an outer shape 10 corresponding to the cutout 11 of the first end plate 2 and the heat exchanger plate 4.
Plate heat exchanger.

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