SE533583C2 - plate heat exchangers - Google Patents

Description

533 583 to how the gaskets can be arranged on the heat transfer plates so that they can be securely attached and fulfill their sealing functionality. The location of the threaded clamping bolts is preferably chosen so that the plate heat exchanger is not subjected to excessive stresses.

SE-C-171 499 discloses a plate heat exchanger with a stand plate, one in pressure plate, a package with heat exchanger plates, two drawbars and a special one in support device. The stand plate and the support device are both provided with feet.

Through the influence of, among other things, the yoke, a pressure is created against the pressure plate so that the plate package is held together. The construction has the disadvantage that both the support device and the pressure plate are necessarily designed as a very strong construction. Furthermore, the extra support shaft in support of the plates is an unnecessary complication in connection with assembly and disassembly of the heat exchanger. EP-l31-1 027 571 shows another plate heat exchanger where clamping bolts have been integrated in the support shaft and the control shaft, so that a control device is created for the pressure plate and the heat exchanger plates. The clamping bolts thereby have a more optimal location to be able to withstand the forces to which the plate heat exchanger is exposed during operation. The control device is surrounded by a protective collar which runs from the frame plate to the pressure plate and protects the threads of the control device from gripping the heat transfer plates. The guiding device is also arranged so that it is connected to a support device which is located at a considerable distance from the pressure plate. The disadvantages of the above solutions are that the stresses and forces become too great if the solutions are applied to larger plate heat exchangers.

DISCLOSURE OF THE INVENTION The object of the present invention is to provide a construction which provides an optimal load distribution over the plate heat exchanger, but which is still cheaper and less complicated to manufacture than those described above.

The advantages are achieved by using at least one guiding device which aligns the first end plate and the heat exchanger plates relative to the second end plate, and where the guiding device is releasably arranged against at least one of the threaded clamping bolts. The guide device runs through an opening, and at least one of the guide devices is provided with a through hole for receiving at least one of the threaded clamping bolts and external geometry corresponding to a cut-out in the heat exchanger plates and. the first end plate. In accordance with another aspect of the invention, the plate heat exchanger is provided with two control devices. with a first control device arranged in an upper part of the plate heat exchanger and a second control device arranged in a lower part of the plate heat exchanger. The first and second * control devices may have identical cross-sectional profiles. In accordance with another aspect of the invention, the second guiding device is further provided with a guide rail in order to be able to movably receive the second guiding device.

In accordance with yet another aspect of the invention, the control frame which can movably receive the second control device rests, in whole or in part, on the ground. In accordance with yet another aspect of the invention, the control device or devices include two separate parts, and the control device or devices are made of an extrudable material. In accordance with yet another aspect of the invention, a support device is releasably disposed at a considerable distance from the first end plate at the ends of the upper and lower clamping bolts, and so as to extend between the upper and lower clamping bolts. According to a further aspect of the invention, the control device or devices are movable along the clamping bolts, where a part of the control device can be removed when the heat transfer plates are compressed by the first end plate to form the finished plate heat exchanger, after which the removed part of the control the device can be arranged on a free part of the clamping bolt outside the plate heat exchanger. In accordance with a further aspect of the invention, the object is achieved with a plate heat exchanger where the heat exchanger plates rest on the control device in the devices or devices and where the first end plate rests against a guide rail on which the control device or devices can be received movably.

Additional aspects of the invention are defined in the dependent claims. 10 15 '_ 20 25 V30 533 583 BRIEF DESCRIPTION OF THE DRAWINGS NOW The present invention is explained in the following with descriptions of various embodiments and references to the accompanying figures.

Fig. 1 shows a perspective view of a plate heat exchanger in accordance with an embodiment of the invention; Fig. 2 shows a side view of a plate heat exchanger in accordance with an embodiment of the invention; Fig. 3 shows a partial view of a plate heat exchanger in accordance with an embodiment of the invention; In Fig. 4 shows a sectional view A-A of a plate heat exchanger in accordance with 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 invention; Fig. 6 shows a second partial detail view C of the plate heat exchanger from Fig. 4 in accordance with an embodiment of the invention; Figs. 7a-b show different views of a control device in accordance with the invention, and Figs. 8a-b show different views of a guide rail in accordance with the invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS OF THE INVENTION Heat exchangers are used to transfer heat between two liquids separated by a solid body§ Heat exchangers can be of different types. the most common are spiral heat exchangers, tube and tube heat exchangers and plate heat exchangers. Flat heat exchangers are used to transfer heat between a cold and a hot liquid that flows in different flow passages that are formed between a set of heat transfer plates. An arrangement of heat transfer plates according to the above definition are enclosed between end plates which are comparatively. thicker than the heat transfer plates. the inside of each end plate is flush with the heat transfer plates.

Figs. 1-2 show a schematic view of a plate heat exchanger 1 consisting of a number of molded heat transfer plates 4 mounted in parallel one after the other so that they together form a plate package. The plate package is accommodated between a first end plate 2, also called pressure plate, and a second end plate 3, also 10 '15 A20 25 30 533 583 in called stand plate. Between the heat transfer plates 4 primary and _ secondary plate gaps are formed. The end plates 2 and 3 are pressed against the plate package and against each other by means of clamping bolts or tie rods 5a-c, which run through the end plates 2 and 3, and whose clamping bolts 5a-c are held in place by nuts 6, 20. The plate heat exchanger 1 has a primary inlet opening and a primary "I outlet opening for the primary side medium, and a secondary inlet opening and a secondary outlet opening for the secondary side medium. The inlet and outlet openings run through the second end plate 3 and the plate package. outlet openings on both sides of plate heat exchanger 1, ie on both end plates 2 and 3. The two media can be introduced in the same or opposite directions relative to each other.

The heat transfer plates 4 in the embodiment shown are arranged in such a way that the plate package is formed so that primary plate gaps are formed which communicate with the primary inlet opening and the primary outlet opening, and secondary plate gaps which communicate with the secondary inlet opening and the secondary outlet opening. The primary and secondary plate gaps are located alternately in the plate package. The separation of the plate gaps can be effected by means of gaskets arranged in packing grooves which are formed during the compression molding of the heat transfer plates.

The gaskets are usually made of a rubber or polymeric material.

The heat exchanger plates 4 are provided with a corrugated pattern to improve the heat transfer between the two liquids.

In order to align the heat exchanger plates 4, protect the threaded clamping bolts - 5a, 5b from wear from the heat exchanger plates 4, simplify the construction and make the construction cheaper, control devices 7, 7a, 7b have been arranged on the upper and lower clamping bolts 5a.

Compared with a plate protection exchanger in accordance with the state of the art, the upper and lower clamping bolts 5a, 5b replace the conventional support and control shafts, which otherwise serve to enable opening / closing of the plate heat exchanger by making it possible to surface the first end plate 2 in 4 along the support and control shafts with the plate heat exchanger in a standing position. By arranging upper and lower guiding devices 7a, 7b_ on the clamping bolts 5a and 5b, where the guiding devices 7a, 7b have one. external cross-sectional geometry (see Figs. 7a-b) similar to the conventional support shaft, the heat exchanger plates 4, with a cut-out profile 11 corresponding to a lower part ¿i of the control devices 7a, 7b, can have an external geometry. 10, is guided along the upper guiding device 7a. The clamping bolts 5a, 5b run through an opening or a through hole 9 in the guiding devices 7a, 7b, where said through hole 9 extends along the entire length of the guiding devices 7a, 7b. The control devices 7a, 7b are made of an extrudable material to make production cheaper and to make the construction easier. The extrudable material may be plastic, aluminum or any other suitable manufacturing material.

Additional clamping bolts 5c are arranged in the usual way between the second end plate 3 and the first end plate 2, and are arranged in instructions or depressions along the edges of the second end plate 3 and the first end plate 2.

Since the control devices 7a, 7b are made of an extrudable material, they cannot withstand the same load as the corresponding metal structures.

Therefore, the load is transferred from the heat exchanger plates 4 and the first end plate 2 to the substrate via a second or lower control device 7b and a guide rail 12. The upper control device 7a and the lower control device 7b are preferably identical to reduce manufacturing costs, but different shapes are also possible. In the embodiment shown, see e.g. Fig. 6, the lower extreme geometry 10 of the lower guide device 7b corresponds to an internal shape 16 of the guide rail 12, so that the guide device 7b can be secured in the guide rail 12 and still be surface along the guide rail 12. In some applications the plate guard exchanger is arranged 1 on a frame which fully or partially supports the guide rail 12.

The upper guide device 7a runs through an opening 8 in the upper part of the first end plate 2 so that the first end plate 2 is superficial relative to the upper guide device fa. Similarly, the lower guide device 7b passes through an opening 17 in the lower part of the first end plate 2. Both the lower guide device 7b and the upper guide device 7a control only the first end plate 2, while the weight of the first end plate 2 is supported by the guide rail 12 against which the first end plate 2 rests. The heat exchanger plates 4 rest against the lower control unit device 7b and are held in place laterally by the upper control device 7a.

Each control device 7a, Tb consists of two parts 13a, 14a and 13b, 14b (see fi g. 3) which enable control of the heat exchanger plates 4 in connection with opening and closing of the plate heat exchanger 1, and enables an external, control device part 14a, 14b is removed when the heat exchanger plates 4 and the first end plate 2 are screwed together to form the finished plate heat exchanger _ 1, and nuts 6 are arranged on the clamping bolts 5a, 5b to hold the first end plate 2 in place and the heat exchanger plates 4 tightened between the first end plate 2 and the length of the inner guide plate I of the device parts 13a, 13b is preferably slightly shorter than the length corresponding to the total thickness of all the heat exchanger plates 4 in the plate package and the first end plate 2. The length of the outer guide device parts 14a, 14b is preferably slightly shorter than the remaining free end of the clamping bolts 5a, 5b near the inner guiding device parts 13a, 13b have been arranged in on the clamping bolts 5a, 5b.

The upper guide device 7a may be provided with a wear protection device to reduce wear from the heat exchanger plates 4. The wear protection device may be made of a sheet metal or rubber material or other suitable material, and is preferably clamped to the upper guide member. device 7a.

The guide devices 7a, 7b have an upper part formed with an external geometry 19 »with a width corresponding to the opening width in the cut-out 11 in the heat exchanger plates 4 and the cut-outs 8, 17 in the first end plate 2. In this way both the upper guide device 7a and the lower guide device 7b hold the first end plate 2 in place laterally, the weight from. the first end plate 2 is supported by the guide rail 12. The upper guiding device 7a and the lower guiding device 7b also control the heat exchanger plates 4 laterally by means of the external geometry 19 of the guiding devices 7a, 7b at the same time as the lower the control device 7b carries the weight from the heat exchanger plates 4. The weight is transferred directly to the guide rail 12 and further to the base. The external geometry 10 of the lower part of the upper control device 7a controls the heat exchanger plates 4 and acts as a rollover protection for the heat exchanger plates 4 when the plate heat exchanger 1 is open. It is also possible that the upper control device Ya fully or partially carries the weight of the heat exchanger plates 4 via the external geometry 10. In Figs. 5-6 the control devices 7a, 7b and the guide rail 12 in more detail in the partial magnifications B and C from Fig. 4, such as those arranged in the plate heat exchanger V1. An advantage of the proposed guide profiles 7a, 7b is that the same component can be used both as a supporting and guiding device in the upper part of the plate heat exchanger 1 and as a supporting and guiding device in the lower part of the plate heat exchanger 1. The guide rail 12 functions as a weight distribution component which also enables the lower outer control device 14b to be removed when the heat exchanger plates 4 and the first end plate 2 are tightened so that a nut 6 can be arranged on the lowest clamping bolt 5b against the first end plate 2 and thus keep the plate heat exchanger 1 in closed operating position. As shown in Figs. 1-2, the plate heat exchanger 1 can also be provided with a support device 15 which makes it possible to open the plate heat exchanger 1 in a simple manner, in that the support device 15 is arranged on the free end of the clamping bolts 5a, 5b and is held in place of the nuts 20. The support device 15 extends between the two clamping bolts 5a and 5b and ensures that the distance between the two clamping bolts 5a and 5b is constant and that the forces acting on the upper clamping bolt 5a are transmitted to the ground. Details about function. and operation of the support device 15 is provided in connection with the description of how the plate heat exchanger 1 is opened and closed.

Below is a description of how the plate heat exchanger 1 is opened. Figs. 1 and 2 show the plate heat exchanger 1 operating mode. The plate heat exchanger 1 can be opened to enable maintenance such as cleaning repairs and replacement of heat exchanger plates etc. The nuts 20 are unscrewed and the support device 15 and the outer guide devices 14a, 14b are removed from the clamping bolts 5a, 5b. The nuts 6 on the clamping bolts 5a, 5b are unscrewed and the outer guiding devices 14a, 14b are again arranged on the free ends of the clamping bolts 5a, 5b and are pressed directly against the inner guiding devices 13a, 13b. The package with heat exchanger plates 4 and the first end plate 2 are still held together by the other clamping bolts 5c. The support device 15 is again mounted on the free ends of the upper and lower clamping bolts 5a, 5b. The support device 15 is supported by the base via the outer guide device 14b and the guide rail 12. The nuts 20 10 15A * 20 25 533 583 9 _ _ are arranged on the clamping bolts 5a, 5b and tightened. The other clamping bolts 5c _ * i i are disassembled. When the clamping bolts 5c have been loosened, the first end plate 2 and the heat exchanger plates 4 fl can be moved along the guiding devices 7a, 7b. This achieves an open service position for the plate heat exchanger 1, where the heat exchanger plates 4 can be separated between the end plates 2, 3 for cleaning and one or more of the heat exchanger plates 4 are removed and possibly new ones inserted without the other heat exchanger plates 4 having to be dismantled. Closing and tightening the plate heat exchanger 1 in operating mode is performed in a corresponding, but reverse manner; The support device 15 consists of a strut, flat iron or the like with sufficient length to be able to keep the upper and lower clamping bolts 5a, 5b at the correct distance relative to each other and at the same time in open position for service of the plate heat exchanger 1 so that the support device 15 can stabilize the whole plate heat exchanger 1 together with the second end plate 2. It further ensures that the forces acting on the upper clamping bolt 5a are transmitted to the ground via the lower clamping bolt 5b.

The guide devices 7a, 1b and the guide rail 12 are preferably made of an extrudable material such as a plastic or aluminum profile, but may also be made by some other manufacturing method or by some other material. _ The invention is not limited to the constructions described above and shown in the drawings. but may be supplemented and modified in any manner consistent with the object of the invention as set forth in the appended claims.

Claims (5)

A plate heat exchanger (1) including a first and second end plate (2, 3), and a package of heat exchanger plates (4) disposed between the first and second end plates (2, 2). 3), where a number of threaded clamping bolts (5a, 5b, 5c) - i extend between the first and the second end plate (2, 3) and are arranged, - by means of nuts (6, 20) or the like, so that they keep these plates at the desired distance from each other so that the package of heat exchanger plates (4) is held together, where at least one guiding device (7a, 7b) for aligning the first end plate (2) and the heat exchanger plates (4) relative to the second end plate (3 ) is releasably arranged opposite at least one (of the threaded clamping bolts (5a, 5b), wherein said guide device (7a) runs through an opening (8) in the first end plate (2), characterized by the guide device or the devices (7, 7a, 7b) are provided with a through hole (9) for receiving the thread or threads the clamping bolts (5a, 5b) and that the control device or devices (7, 1, 7a, 7b) have an external geometry (1 (_)) which corresponds to a cut-out (11) in the heat exchanger plates (4) and the first end plate (2). ). A plate heat exchanger (1) according to claim 1, wherein the plate heat exchanger (1) is provided with two control devices (7a, 7b), a first control device (7a) arranged in an upper part of the plate heat exchanger (1) and a second control device (7b) arranged in a lower part of the plate heat exchanger (1). A plate heat exchanger (1) according to claim 1 or 2, wherein the first and the second control device (7b) have identical cross-sectional profiles. A plate heat exchanger (1) according to claim 2 or 3, wherein the second in the control device (7b) is further provided with an eryfekene (12) for a movable "1 to be able to receive the second control device (7b). A plate protection exchanger (1) according to claim 4, wherein the guide rail (12) which can movably receive the second guiding device (7b) is fully or partially supported by the ground. . A single plate heat exchanger (1) according to any one of the preceding claims, wherein the controlling device or devices (7a, 7b) include two separate parts (13a, 13b, 14a, 14b). A plate heat exchanger (1) according to any one of the preceding claims, wherein the control device or devices (7a, 7b) and the guide rail (12) i are made of an extrudable material. A plate heat exchanger (1) according to any one of the preceding claims, wherein the control device or devices (7, 7a, 7b) are movable along the clamping bolts (5a, 5b) and wherein a part (14a, 14b) of the control devices - (7a, 7b) can be removed when the heat exchanger plates (4) are tightened together with the first end plate (2) to form the finished plate heat exchanger (1), after which the removed part (14a, 14b) of the control device (7a) is removed. , 7b) can be arranged on a free part of the clamping bolt (5a, 5b) outside the first end plate (2). A plate heat exchanger (1) according to any one of the preceding claims, wherein a support device (15) is detachably arranged at a considerable distance from the first end plate (2) at the end of the respective clamping bolt (5a, 5b), and extending in between the clamping bolts (5a, 5b). A plate heat exchanger (1) including a first and second end plate (2, 3), and a package of heat exchanger plates (4) arranged between the first and the second end plate (2, 3), wherein a number of threaded clamping bolts (5a) , 5b, 5c) extend between the first and the second end plate (2, 3) and are arranged, by means of nuts (6, 20) or the like, so that they keep these plates at the desired distance from each other so that the package of heat exchanger plates held together, where at least one narrow guiding device (7a, 7b) for aligning the first end plate (2) and the heat exchanger plates (4) relative to the second end plate (3) are releasably arranged against at least one of the threaded clamping bolts (5a, 5b), where said guiding device (7a) runs through an opening (8) in the first end plate (2). - (Z) rests with a guide rail (121) pad which the guiding device or an the arrangements (7b) can be received in a variable manner. A plate heat exchanger (1) according to claim 10, wherein an upper control device (Ya) controls only the heat exchanger plates (4) and the first end plate (2).