SE519038C2 - Heat exchangers as well as ways of making them - Google Patents

Abstract

The invention concerns a heat exchanger and ventilation arrangement whose main casing 1 is divided into left and right halves, whereas the heat exchanger 2 is installed on crosspieces in the center part of the casing. The interior of one half of the main casing 1 is delimited by one of a pair of intermediate partition devices 5 positioned symmetrically relative to heat exchanger 2 to create a waste air passage, whereas the other intermediate partition device 5 delimits the interior of the other half of the casing to create a feed air passage. Each intermediate partition device 5 includes an intermediate position placed on the heat exchanger side and running parallel to the side surface of the main casing 1, an elongated partition 13 running parallel to the front end of the main casing 1 to its side surface and a transverse partition 14 running essentially parallel to the bottom of the main casing. Each surface in the heat exchanger in contact with a certain device is covered with a seal. An air-tight arrangement with low resistance is obtained with this simple design.

Description

: nano 11.1, 1.41: 519 038 2 ducts extend from the chamber 34 to the fan 33 which is used to blow exhaust air via one working flow duct of the heat exchanger 31, which ducts are used as an exhaust air duct for blowing out the air in a room to the outside, while a number of ducts extends from the second chamber 34 to the fan 33, which serves to blow supply air through the second working flow duct of the heat exchanger 31, which ducts are used as supply air duct to supply outdoor air to the room. As can be seen from the above description, the exhaust air duct is separate from the supply air duct.

The conventional device constructed as described above is mounted in a special space under the ceiling of the room to perform a ventilating function by means of pipelines through which the supply air duct communicates with the interior of the room, while the exhaust air duct communicates with the outside of the room.

More specifically, the air from the room is introduced into the exhaust air duct through the exhaust air inlet 35 so that it is blown out to the outside of the room through the exhaust air outlet 37 and the pipeline. On the other hand, fresh outdoor air is introduced into the supply air duct through the supply air inlet 38 so that it is supplied to the room through the supply air outlet 36 and the pipeline. Heat exchange is achieved between the supply air flow and the exhaust air flow as the two air flows pass through the working flow channels of the heat exchanger 31, whereby ventilation of the room is achieved by both the supply air flow and the exhaust air flow with few changes in the device operating condition.

Figs. 12-14 show a conventional heat exchanger, for example of the type described in Japanese Laid-Open Publication No. 57-178988 for utility models. In the drawings, reference numeral 51 denotes a heat exchanger part which is composed of a plurality of heat conducting plates 42 stacked on each other with a predetermined space between adjacent plates for the exchange of heat and moisture. opposite surfaces of the heat exchanger part 51, and the reference numeral 44 denotes frames, each of which is connected to resp. corner edge portion of the heat exchanger portion 51 and then fixedly fixed at Reference numeral 43 denote plates fixed at .in ISM; ~,>. : annu s 19 oss * 3 the plates 43 through fastening screws 45. Reference numeral 46 denotes a sealing element which is used to airtight seal the space between the heat exchanger part 51 and the frame 44.

The conventional heat exchanger constructed as described above is installed in the position where a supply air duct intersects an exhaust air duct in a ventilation device (not shown) to simultaneously effect air supply and air delivery for a room and both the supply air duct and the exhaust air duct are defined by the plates 43 and the frames 44 51. When the ventilation device is in operation, an air flow P on the outside of the room and an air flow Q on the outside enter simultaneously in the heat exchanger part 51 in which heat exchange takes place between them, and after complete heat exchange another air flow P 'and another air flow Q' leave the heat exchanger part 51.

In the conventional device described in an official Japanese public publication no. 63-181743 for utility models, the supply air duct and the exhaust air duct shall be housed in the narrow interior of the main housing 30 to meet requests for construction of small size devices, and in addition, complicated elements represented here by reference numerals 39, 41 and 42 are required to form partitions. which not only extend forwards / backwards but also upwards / downwards. Thus, a problem arises in that both the supply air duct and the exhaust air duct have a complicated structure because they extend irregularly, which means that the resistance to the air flow is destroyed. Another problem is that air leaks are likely to occur in the interior of the main cover 30.

With the conventional heat exchanger described in the official Japanese public publication no. 57-178988 for utility models, the sealing element 46 often fails to completely seal the space between the heat exchanger part 51 and the frames 44 due to the surface tension which arises therein even if the space therebetween is filled by the sealing element 46, which results in pockets and confinement of air being easily caused. as shown in Fig. 14. a | | ~ | In ænnn ».>; || nanm »519 oss 4 Thus, a problem arises in that the air flow P on the room side and the air flow Q on the outside enter the above-mentioned spaces, whereby the capacity of the heat exchanger deteriorates.

The present invention has been added taking into account the above problems.

An object of the present invention is to provide a heat exchange and ventilation device which guarantees that a supply air duct and an exhaust air duct can be created with low resistance to air flow and with excellent air tightness using a small number of elements each of which has a simple construction. - tion.

Another object of the present invention is to provide a heat exchange and ventilation device which offers a high degree of freedom with respect to the pipeline connections.

A further object of the present invention is to provide a heat exchange and ventilation device which can perform a normal ventilation function without any heat exchange taking place in the device.

Yet another object of the present invention is to provide a heat exchanger which guarantees that the space between a heat exchanger part and resp. frame is completely sealed by a sealing element, not only without the occurrence of air leakage but also without any entry of air flow from the room side or air flow from the outside to the above-mentioned space.

A further object of the present invention is to provide a process for the manufacture of a heat exchanger of the preceding kind.

According to a first aspect of the present invention, there is provided a heat exchange and ventilation device wherein the device is characterized in that a heat exchanger which has a laminated cone n | ~ ø n oo a> ans .laun; ».; | 1-11; 1519 038 structure is transversely mounted in the middle part of a main housing which has a rectangular box-shaped construction, that an exhaust air duct to allow flow of air in a room is delimited by the heat exchanger and by one of a pair of separating elements symmetrically arranged relative to the heat exchanger, exhaust air duct crosses the heat exchanger to provide heat exchange therein, one end of the exhaust air duct being connected to an exhaust air inlet on one side of the main cover, while the other end thereof is connected to an exhaust air outlet on the other side of the main cover, to supply air duct which allows flow of outdoor air is delimited by the heat exchanger and the second separating element, which supply air duct crosses the heat exchanger to achieve heat exchange therein, one end of the supply air duct communicating with a supply air outlet, while the other end is connected to it supply air inlet on the other side of the main cover n, that a fan for blowing exhaust air is arranged for the exhaust air duct in one half of the main cover which is symmetrically delimited relative to the heat exchanger, and that a fan for 'blowing of' supply air is arranged for the supply air duct in the other half of the main cover, wherein each of the pair of partitions is composed of a partition wall, located on the heat exchanger side, and extends parallel to the side surface of the main housing to reach between its front and rear surfaces, a longitudinally extending partition wall bent at right angles to the heat exchanger side parallel to the heat exchanger side with the front and rear surfaces of the main cover to reach between the side surfaces thereof, and a transverse partition wall extending from the lower end of the longitudinally extending partition wall to reach between the front and rear surfaces of the main cover, the transverse partition being substantially extends parallel to the bottom surface of the main cover.

Usually, each of the pairs of separating elements is provided in the form of a single plate which is subjected to bending. n n v u o n | en ||, a | .519 038 6 To maintain air tightness with resp. the air tightness maintaining element in the form of a sealing element applied to resp. contact surface that is adapted to establish a partition is a contact between the main cover and the heat exchanger. According to a second aspect of the present invention, the fan for blowing supply air through the supply air duct and the fan for blowing exhaust air through the exhaust air duct are arranged so that they are angularly displaced in a horizontal plane with an angle of 90 ° and a further supply air outlet and an exhaust air outlet are on the front and back of the main cover, which correspond to the angular displacement of the two fans.

According to a third aspect of the present invention, the supply air duct or exhaust air duct comprises a bypass duct to allow the inlet side to be directly connected to the outlet side of the device and not via the heat exchanger, the bypass duct being equipped with a damper arranged to be opened and closed. of the exhaust duct.

According to a fourth embodiment of the present invention, there is provided a heat exchanger having a heat exchanger portion having a laminated structure comprising a plurality of rectangular heat conducting plates stacked on top of each other with a predetermined space between adjacent plates intended for heat exchange or of heat and moisture plates, fixed at opposite ends of the heat exchanger part, and four L-shaped frames fitted against four corner edge portions of the heat exchanger part, wherein the heat exchanger is characterized in that an elastic sealing element and in that it is fixed to the inner wall surface of resp. frame, viscous liquid sealant is applied to the sealing element.

According to a sixth aspect of the present invention there is further provided a method of manufacturing a heat exchanger, wherein the method is characterized in that a sealant is applied to n - o o o n | a: un. The area where an elastic sealing element attached to the inner wall surface of an L-shaped frame is in contact with resp. corner edge portion of a heat exchanger part which has a plurality of heat conducting plates stacked on top of each other for the purpose of exchanging heat or heat and moisture, and of the frame then being fixed at resp. corner of the heat exchanger part to allow the sealing element to be impregnated with the sealant before the sealant hardens.

With the heat exchange and ventilation device according to the present invention, a part of the supply air duct in the left half of the main housing is delimited relative to the heat exchanger located in the middle part of the main housing by one of a pair of partitions each having a partition wall located on the heat exchanger side. a partition wall extending in the longitudinal direction and a partition wall extending in the transverse direction, while a part of the exhaust air duct in the right half thereof is delimited by the second partition element in the same manner as the supply air duct.

Thus, the device is constructed with low resistance to air flow because both the supply air duct and the exhaust air duct are built up of straight duct portions.

Since the contact surfaces on resp. separating elements are fitted with means for maintaining air tightness, in addition excellent air tightness is ensured for both the supply air duct and the exhaust air duct.

In addition to the above-mentioned functional properties, the device can, since the direction of blowing air from a room and the direction of blowing outdoor air can optionally be changed by the fans, as well as pipelines which are to be connected to it at different angles. Earlier mentioned.

Particularly when the bypass duct is opened by operating the damper, the air from the room or the outdoor air can flow through the bypass duct instead of through the heat exchanger. Ventilation can thus be achieved without heat exchange. another .MIn 11,; -. In the heat exchanger according to the present invention, an elastic sealing element is applied to the inner wall surface of resp. frame, and then a viscous liquid sealant is applied to the sealing element.

Thus, the space or space between the heat exchanger part and resp. frame is reliably sealed with the sealing element and the sealant.

Brief Description of the Drawings FIGURE FIGURE FIGURE FIGURE FIGURE FIGURE FIGURE FIGURE FIGURE 1 is a perspective view of a heat exchange and ventilation device in accordance with a first embodiment of the present invention. is a fragmentary perspective view of the heat exchange and ventilation device shown in Fig. 1 and shows in particular essential parts which constitute the heat exchange and ventilation device. is a plan cross-sectional view of the heat exchange and ventilation device shown in Fig. 1, and specifically shows an operating mode thereof. is a vertical cross-sectional view of the heat exchange and ventilation device shown in Fig. 1, showing in particular an operating position thereof. is a plan cross-sectional view of a heat exchange and ventilation device in accordance with a second embodiment of the present invention. is a plan cross-sectional view of a heat exchange and ventilation device in accordance with a third embodiment of the present invention. is a front cross-sectional view of the heat exchange and ventilation device shown in Fig. 5. is a perspective view of a heat exchanger in accordance with a fourth embodiment of the present invention, showing in particular essential parts constituting the heat exchanger in the disassembled state. is a cross-sectional view of the heat exchanger of Fig. 8 taken along the line A-A '. is an enlarged, broken away cross-sectional view of the heat exchanger shown in Fig. 9. u 4 u c o c u u: \ »u |» nun »of exhaust air and a separating element 5. FIGURE 11 is a perspective view of a conventional heat exchange and ventilation device.

FIGURE 12 is a perspective view of a conventional heat exchanger.

FIGURE 13 is a cross-sectional view of the conventional heat exchanger of Figure 12 taken along line B-B '. FIGURE 14 is an enlarged, broken-away cross-sectional view of the conventional heat exchanger shown in FIG.

Fig. 1 is a perspective view of a heat exchange and ventilation device (hereinafter simply referred to as a device) in accordance with a first embodiment of the present invention, showing in particular essential parts constituting the device; Fig. 2 is a perspective view of several parts essential to the device which are shown in disassembled condition, Fig. 3 is a planar cross-sectional view of the device, and Fig. 4 is a cross-sectional front view of the device, and shows in particular an operating position thereof.

As shown in Fig. 1, a square columnar heat exchanger 2 which has a laminated structure is mounted in the middle part of a rectangular box-shaped main cover 1 of the device. and extends in the transverse direction, and the left and right halves of the main cover 1 are symmetrically arranged with the heat exchanger 2 as a central part. The left half of the main cover 1 comprises a fan 3 for blowing supply air and a separating element 5, while the right half of it comprises a fan 4 for blowing While a rectangular roof plate part 6 is used as an upper cover and is arranged to be moved up or down The main housing of the head in the middle part is a heat exchanger 2 which more particularly comprises a laminated structure and a pair of separating elements 5 in the left and right halves of the main housing 1 in a mutually symmetrical relationship relative to the heat exchanger 2. Resp. separating element 5 is bent at a right angle around the corresponding fan to independently delimit an exhaust air duct or a supply air duct to allow outdoor air to flow therethrough. One end of the exhaust air duct communicates with an exhaust air inlet 7 on the left side of the main cover.l, while the other end of the same via the fan |>; || = »= 1w xuyæ» 19 0 3 8 §II = zff; - - 4 is connected to an exhaust air outlet 8 on the right-hand side of the main housing 1. On the other hand, one end of the supply air duct is connected to a supply air outlet 9 on the left-hand side of the main housing 1 via the fan 3, while the other end of the same via the fan 3 is connected to a supply air inlet 10 on the right side of the main cover 1. Sealing elements 11 are arranged on the contact surface of the main cover 1 and adapted to be in contact with the upper cover 6 in the same way as the contact surface of the upper cover 6 is adapted to be in contact with the upper edge portion of the heat exchanger 2 in order to maintain air tightness along the said contact surfaces.

As can be seen from Fig. 2, resp. partition element 5 composed of a partition wall 12 located on the heat exchanger side and furthermore in contact with the front surface or the rear surface of the main cover 1, a longitudinally extending partition wall 13 which extends parallel to the front surface or the rear surface of the main cover 1 to reaching its side surface, and a transverse partition wall 14 which extends substantially parallel to the bottom surface of the main cover 1 to reach the front surface or the rear surface of the main cover 1. The separating element 5 is fixedly attached to the main cover 1 in such a way that the upper end of the former is located at the same level as the upper end of the latter. All surfaces of resp. separating elements 5 which are adapted to be in contact with other specific elements are edged with sealing elements 11 in order to achieve air tightness along the previously mentioned surfaces. The lower edge of the partition wall 12 in the partition element 5 which is located on the heat exchanger side and the inner end surface of the transverse partition wall 14 are in contact with the edge portion of the heat exchanger 2 which is located in a middle portion thereof in order to form a boundary between an open and another open surface of the active flow channel in the heat exchanger 2. With the separating element constructed in the manner described above, the interior of the main cover 1 is divided into four compartments, i.e. an upper front compartment, an upper rear compartment, a lower front compartment and a lower rear compartment. n o:. u n I o no up. The fan 3 for blowing supply air is mounted in the substantially square area bounded by the partition wall 12, the partition wall 13, the front or rear surface of the main cover 1 and its side surface in such a way that its suction opening is located in the lower part of the same and its pressure opening communicates with the supply air outlet 9 with a horizontal position. In the same way, the fan 4 for blowing exhaust air is mounted in the substantially square area delimited by the partition wall 12, the partition wall 13, the rear or front surface of the main cover 1 and its side surface in such a way that its suction opening is located in its lower part. part and its pressure opening is connected to the exhaust air outlet 8 in a horizontal position. With this construction in which the lower part of the area delimited by the partition 13, the partition 14, the rear or front surface of the main cover 1 and its side surface is closed with the partition 14 in a central height position measured from the bottom of the main cover 1, the side part of the area is in connection to the supply air inlet 10 or the exhaust air inlet 7, and the inwardly facing part of the area is kept open towards the surface which is in communication with the upper effective flow channel in the heat exchanger 2. The lower part of the main cover 1 is divided into two parts with the heat exchanger 2 as a central part, of which the left part communicates with the suction side of the fan 3 and the right part communicates with the suction side of the fan 4.

With the device constructed as described above, the supply air duct and the exhaust air duct communicate with the ventilated room via pipelines (not shown) to allow the air in the room to be ventilated. More specifically, as shown in Figs. 3 and 4, the room air in the main housing 1 is introduced through the exhaust air inlet 7, flows linearly through the exhaust air duct delimited by the partition wall 13 and the partition wall 14, passes through a working flow duct in the heat exchanger 2 extending obliquely from it side to the bottom, reaches the lower side or bottom side of the right half of the main cover 1 to be sucked through the fan 4, and is finally blown out from the room to the outside through the exhaust air outlet 8 and via a pipeline. On the other hand u n. u n | . uu »nano |>,>; In mono 519 os 12, fresh outdoor air is introduced into the main housing 1 through the supply air inlet 10, flows linearly through the supply air duct delimited by the partition wall 13 and the partition wall 14, passes past another working flow duct in the heat exchanger. 2 * which likewise extends inclined from the upper side to the lower side, reaches the bottom side of the left half of the main cover 1 to be sucked through the fan 3, and is finally blown into the room through the supply air outlet 9 and via a pipeline. Heat exchange takes place between the supply air flow and the exhaust air flow as these pass through the working flow channels in the heat exchanger 2, whereby air exchange or ventilation is achieved with the two supply and exhaust air flows with few variations in the operating condition of the device. A characteristic feature of the device is that the left and right halves of the main cover 1 are symmetrically arranged with the heat exchanger 2 as a central part, and the supply air duct and the exhaust air duct are built by combining the heat exchanger 2 with the rectilinear parts of a pair of separating elements 5. simple construction. Each of the additional resp. the exhaust air ducts have a simple construction and exert low resistance to air flow and at the same time maintain excellent air tightness with the aid of the sealing elements 11. In addition, since the symmetrical construction of the device according to the above makes it easy to reflect the internal structure of the device, maintenance service can be easily performed on the device.

Fig. 5 is a plan cross-sectional view of a heat exchange and ventilation device (hereinafter simply referred to as the device) in accordance with a second embodiment of the present invention. In this embodiment the device is designed so that two supply air outlets 9, two supply air inlets 10, two exhaust air outlets 8 and two exhaust air inlets 7 are arranged with one offset placed from the other at an angle of 90 ° in such a way that they can optionally be opened and closed. The internal structure of the device is identical to that in the first embodiment with the exception that the fans 3 and 4 are arranged in positions which are angularly offset from the positions in the first embodiment by an angle of 90 °. In this embodiment, fixing means 15 are also arranged to enable the fans 3 and 4 to be mounted steadily nunvn ø-zø »1.11. Even when they are displaced by rotation at an angle of 90 ° away from the positions at which they are fixedly fixed to the separating elements as in the first embodiment.

With the device constructed in the manner described above, the supply air outlets 9, the supply air inlets 10, the exhaust air outlets 8 and the exhaust air inlets 7 can optionally be opened in directions which differ from each other by an angle of 90 °. Thus, pipelines can be connected to the device with a high degree of freedom, especially with respect to alignment. In other words, the device can be mounted with very few limitations.

Fig. 6 is a planar cross-sectional view of a heat exchange and ventilation device (hereinafter simply referred to as the device) in accordance with a third embodiment of the present invention, and Fig. 7 is a vertical cross-sectional view of the device shown in Fig. 6.

In this embodiment the device is designed so that a longitudinally extending space is formed between the inner side wall of the heat exchanger 2 and the front or the rear surface of a main cover 1 so that the inlet side is in direct connection with the outlet side of the device via a bypass channel 16 instead of via a supply air duct, an exhaust air duct and the heat exchanger 2, the bypass duct 16 being formed by utilizing the above. In addition, a damper 17 mounted on the damper 17 is opened and closed when the duct leading to the heat exchanger 2 is opened and said gaps. the inlet side i. the bypass duct 16. closes. Since the structure in addition to what has been mentioned above is identical to the structure of the first embodiment, a repeated description is not required.

With the device constructed in the manner described above, a ventilation work is carried out when the bypass duct 16 is kept open, especially during intermediate seasons, ie. spring or autumn, to be able to enjoy a pleasant experience of the surroundings through normal air supply and air exhaust but without heat exchange and air ventilation. n fi aan mpa »... ßv a | | I o ~ v oo 519 03 8 iäzfi; Figs. 8 to 10 show a heat exchange and ventilation device (hereinafter simply referred to as the device) in accordance with a fourth 8. plates 22 which are stacked on top of each other at a predetermined space between adjacent plates 22 which each have a heat exchange or heat and moisture exchange embodiment of the present invention. In fig. Reference numeral 23 denotes a plate which is fixedly fixed to the upper and lower surfaces of the heat exchanger section 20.

Reference numeral 24 denotes a frame which is to be attached to resp. corner edge portion 25 of the heat exchanger section 20. The frame 24 is treated in such a way that it is bent to have an L-shaped cross section to be in close contact with the corner edge portion 25, the plates 23 by fastening screws (not shown). Reference numeral 26 denotes a sealing element which is to be adhesively attached to the inner wall surface of the frame 24. The sealing element 26 is molded. the reference numeral 27 denotes a sealant which is prepared using a highly viscous liquid material. The sealing means 27 is applied to the surface of the sealing element 26.

The device constructed according to the above description is mounted in the following manner. First, the sealing element 26 is attached to the inner wall surface by resp. frame 24 using an adhesive and the sealant 27 is then carefully applied to the sealing member 26 without the appearance of uncovered surfaces, stains or the like.

Then the frame 24 is attached to resp. corner edge portion 25 of the heat exchanger section 20 before the sealant 27 cures. Thereafter, the opposite ends of the frames 24 are firmly fixed to the plates 23 by the fixing screws. The heat exchanger is mounted in the position where it crosses a supply air duct in a ventilation device (not shown) in the same way as in the conventional heat exchanger. When the heat exchanger is a thread mounted in this way, the supply air duct is delimited by the plates 23 and the frames 24. When the ventilation device is operating, as shown in Fig. 8, an air flow P enters: ryan: m «| 111m * .A 519 us the room side and an air flow Q on the outside simultaneously in the heat exchanger section 20 in which heat exchange is obtained between them. When the heat exchange is complete, another air flow P 'and another air flow Q' leave the heat exchanger section 20. It should be noted that no air leakage occurs at any position along the area where the frames 24 are in contact with the corner edge portions 25 of the heat exchanger section 20 due to the arrangement of the sealing elements 26 and the sealing means 27 applied to the former, neither when passing the air flows P nor the air flows Q through the heat exchanger section 20.

Alternatively, the sealant may be applied along the resp. the corner edge portions 25. In addition, the sealant may be applied to the inner wall surface of resp. plate 23.

It need not be mentioned that the heat exchanger, constructed in the manner described above, can be combined with the heat exchange and ventilation device specified in any of the claims 1, 2 and 3.

As can be seen from the above description, in accordance with one aspect of the present invention, a portion of the supply air duct in one half of the main housing is defined with the heat exchanger as a central portion by one of a pair of partitions each having a partition located on the heat exchanger side, a longitudinally extending partition and a transverse partition in the three-dimensional direction, ie. the left / right direction, the forward / backward direction and the upward / downward direction, while a part of the exhaust air duct is delimited in the other half of the main cover by the second separating element in the same way as that in the supply air duct.

Thus, both the supply air duct and the exhaust air duct can be constructed of a straight duct portion which has a simple construction with low resistance to air flow. Consequently, the heat exchange and ventilation device can be manufactured at a reduced cost while maintaining excellent air tightness along each of the supply air and exhaust air ducts.

Resp. partitions are made in the form of a single bent sheet, and the portions of the partitions in resp. separating elements that are in contact with the main cover and the heat exchanger are clad or f n. ; - ø c u nu s »» r | ;; ..,: | z »n 519 038 16 edged with means for maintaining air tightness. Thus, another advantageous effect of the present invention is that heat exchange and air tightness can be improved. According to another aspect of the present invention, the blowing direction of air from a room and the blowing direction of outdoor air can be optionally changed by angular movement of the fans. Thus, the degree of freedom with respect to the alignment of pipe connections can be increased.

In addition, according to another aspect of the present invention, the air from the room or outdoor air can pass directly through the bypass duct without passing through the heat exchanger when the damper in the bypass duct is kept open. Thus, normal ventilation can be achieved by air supply and air exhaust without any heat exchange, especially in intermediate seasons, ie. spring or autumn. Thus, the functional properties of the heat exchange and ventilation device can be improved.

According to yet another aspect of the present invention, the heat exchanger has a heat exchanger section having a laminated structure comprising a plurality of rectangular heat conducting plates stacked on top of each other with a predetermined space between adjacent plates for the purpose of exchanging heat or heat and moisture, which plates are fixedly fixed to opposite ends of the heat exchanger section, and four L-shaped frames fitting against four corner edge portions of the heat exchanger section, which heat exchanger is improved in such a way that an elastic sealing element is attached to the inner wall surface of resp. frame and a viscous liquid sealant are then applied to the sealing element. The areas where the corner edge portions of the heat exchanger section are in contact with the frames are thus completely sealed without any malfunction such as air leakage. Thus, the heat exchange capacity: L of the heat exchanger can be equalized, and furthermore the reliability of the heat exchanger is improved. u - n ø u - - nu

Claims (4)

519 038 I? n a n o n nu PATENTKRAV A heat exchanger (21) comprising a heat exchanging section (20) composed of a plurality of rectangular heat conducting plates (22) configured to be stacked on top of each other as in a laminate, maintaining a predetermined distance between adjacent plates to provide heat exchange or exchange of heat and moisture, the heat-conducting plates (22) being fixed by means of four pieces, in cross-section L-shaped corner frame elements (24) each, on the side which is adapted to be applied to a corner edge portion (25) of the heat exchanging section carries an elastic sealing element (26) sealingly abutting against said corner edge portions (25) and a curable, viscous and liquid sealing means (27) is arranged in the space between adjacent plates (22) in the corner edge sections of the heat exchanging section (25), characterized in that the sealing element (26) is impregnated by the sealing means (27) which in the cured state fills the space between adjacent plates in heating the corner edge portions of the shaft section and extend integrally into the sealing element for anchoring the sealing element at the corner edge portion of the heat exchanger section. Heat exchanger according to claim 1, characterized in that said sealing means (27) is also applied to the inside of each of the two end plates (23) of the heat exchanging section, arranged in the mutually opposite ends of the heat exchanging section (20). A method of manufacturing a heat exchanger (21), comprising stacking a number of rectangular heat conducting plates (22) on each other as in a laminate with predetermined distances between adjacent plates to achieve heat exchange or exchange of heat and moisture in a heat exchanging section (20), wherein in cross-section L-shaped corner frame elements (24) on the side adapted to be applied to a corner edge portion (25) of the heat exchanging section support an elastic sealing element (26) which is brought into 519 038/8 sealing abutment against said corner edge portions (25), characterized by the step of applying a curable, viscous and liquid sealant (27) in the corner edge portion between adjacent plates in such a way that the sealant (27) is allowed to penetrate into the sealing element (24) to subsequently cure and anchor the sealing element at the corner edge portion of the heat exchanger section. Manufacturing method according to claim 3, characterized in that said sealing means (27) is applied to the inside of the two end plates (23) of the heat exchanging section before their assembly, preferably by means of fixing screws, at the mutually opposite ends of the heat exchanging section (20).