SE533783C2 - plate heat exchangers - Google Patents

Abstract

A plate heat exchanger comprises a plate package (1) with heat exchanger plates (2) forming primary plate gaps (3) for a primary medium and secondary plate gaps (4) for a secondary medium. A primary inlet (11) transports the primary medium into the primary plate gaps. A primary outlet (12) transports the primary medium out of the primary plate gaps. A secondary inlet (21) transports the secondary medium into the secondary plate gaps. A secondary outlet (22) transports the secondary medium out of the secondary plate gaps. A sensor device (30) comprises an enclosed space (31) which contains a sensor medium which is affected by the temperature of the secondary medium. A restrictor (35) connected to the sensor device controls the flow of the primary medium depending on the sensor medium. The space is formed by a closed plate gap (3 ') adjacent to at least one adjacent (4') of the secondary plate gaps. The plate heat exchanger comprises flow reducing means arranged to reduce the flow of the secondary medium by adjacent the secondary plate gaps. (Fig. 2)

Description

533 783 forms, the closed space of the sensor device is formed by two of the heat exchanger plates in the plate package. In this way, the enclosed space can be arranged in very close heat-transferring contact with one or both of the media. This creates opportunities to obtain a large contact area of the sensor device. With a large contact area, a large driving force is achieved for, for example, a control valve whose valve position is controlled by means of the sensor medium.

A problem that is not solved in an optimal way with the plate heat exchanger shown in US-B-7,152,663 is that the sensor device can give rise to an undesirably large control deviation on the secondary side when operational changes occur. The solution shown in US-B-7,152,663 does not ensure that the sensor device can optimally sense a temperature of the secondary medium which is representative of the desired temperature of the secondary medium.

A further problem in this context is that the temperature profile along the plate gaps can be such that it is difficult to obtain a representative and good temperature sensing of the sensor device. If the sensor medium comprises, for example, a gas phase and a liquid phase, the result of the temperature effect on the sensor device will be different at the different phases. Due to the fact that the boundary between the gas phase and the liquid phase is not at a constant level, the regulation can become problematic. The temperature effect on the gas phase results in a relatively smaller pressure increase in the sensor medium than the temperature effect on the liquid phase. If the gas phase with a substantial part is in the area where the secondary medium has a high temperature, this temperature may rise without obtaining a sufficient pressure increase of the sensor medium and thus not a sufficient influence on the throttling member.

SUMMARY OF THE INVENTION The object of the present invention is to eliminate the above-mentioned problems and to provide a plate heat exchanger with an improved sensor device which ensures a good and even control of the temperature of the secondary medium.

This object is achieved with the initially indicated plate heat exchanger which is characterized in that the space is formed by a closed plate gap which is adjacent to an adjacent one of the secondary plate gaps and that the plate heat exchanger comprises flow reducing means arranged to reduce the flow of the secondary medium.

By such a reduction of the flow, or the amount of flow, the temperature of the secondary medium in the adjacent secondary plate gap, which adjoins the closed space, will increase. With such a reduction it is possible to achieve the same, or substantially the same, temperature profile on the secondary medium in the adjacent secondary plate gaps as in the other secondary plate gaps.

According to an embodiment of the invention, the closed plate gap is located at the outermost part of the plate package at the rear, the adjacent secondary plate gap forming an outermost secondary plate gap.

According to an embodiment of the invention, the flow reducing means comprise a restriction arranged to restrict the flow of the secondary medium. Advantageously, the throttle may be arranged in the port hole of the heat exchanger plate adjacent to the adjacent secondary plate gaps and to the adjacent of the primary plate gaps. Furthermore, the throttle can be arranged in this heat exchanger plate in the door hole which forms part of the secondary inlet port channel or the secondary outlet port channel.

According to an embodiment of the invention, the flow reducing means comprise a reduced thickness of the adjacent secondary plate gaps relative to the thickness of the other secondary plate gaps. According to a further embodiment, each heat exchanger plate has a heat transfer surface with a corrugation, wherein the flow reducing means, as a complement or an alternative, may comprise a modification of the corrugation of the heat transfer surface of at least one of the heat exchanger plates which limit the adjacent secondary plate spacing in comparison with the corrugation of the other heat exchanger plates.

According to an embodiment of the invention, the adjacent secondary plate gap communicates with the secondary inlet and the secondary inlet port channel as well as the secondary outlet and the secondary outlet port channel.

According to an embodiment of the invention, the closed plate gap is closed relative to the primary inlet port channel and the primary outlet port channel by means of closed port holes in the heat exchanger plate adjacent to the closed plate gap.

According to an embodiment of the invention, the plate heat exchanger comprises a front side plate which is located at the front side and adjoins an outermost heat exchanger plate. Advantageously, the primary inlet port channel, the primary outlet port channel, the secondary inlet port channel and the secondary outlet port channel may extend through the front side plate.

According to an embodiment of the invention, the throttling means comprises an actuating means which is connected to the space and arranged to act on the throttling means by sensing a pressure change of the sensor medium in the space.

According to an embodiment of the invention, the throttling means is arranged to control the flow of the primary medium through the primary plate gaps depending on the sensor medium. 10 15 20 25 30 35 533 'F83 BRIEF DESCRIPTION OF THE DRAWINGS The present invention will now be explained in more detail by a description of various embodiments and reference to the accompanying drawings.

Fig. 1 schematically shows a front view of a plate heat exchanger according to the invention.

Fig. 2 schematically shows a side view through the plate heat exchanger according to a first embodiment of the invention along the line ll-ll in Fig. 1.

Fig. 3 schematically shows a side view through the plate heat exchanger according to the first embodiment along the line III-III in Fig. 1.

Fig. 4 schematically shows a side view through the plate heat exchanger I according to a second embodiment of the invention along the line ll-ll in Fig. 1.

Fig. 5 schematically shows a side view through the plate heat exchanger according to the second embodiment along the line V1-V1 in Fig. 4.

DETAILED DESCRIPTION OF DIFFERENT EMBODIMENTS OF THE INVENTION Figs. valleys, schematically indicated in Fig. 1. The heat exchanger plates 2 are arranged next to each other in the plate package 1 in such a way that they form primary plate gaps 3 for a primary medium and secondary plate gaps 4 for a secondary medium, see Figs. 2 and 3. The primary and secondary plate spaces 3 and 4 are arranged in an alternating order in the plate package 1, i.e. every other plate space is a secondary plate space 4. The plate heat exchanger shown is specially designed for an application in a local heating network or a district heating network, for example for heating tap water, the primary medium being district heating water from a central district heating system and second the medium is tap water that is to be heated by the district heating water in the plate heat exchanger. In the heating network, any heat source can be used, for example a heating plant, an oil boiler, a solar heating system, etc. It should be noted, however, that the plate heat exchanger according to the invention can also be used in other applications, for example for cooling, in heat pump systems, in industrial processes. for cooling and / or heating in vehicles etc.

The plate package 1 has a first end 1 'and a second opposite end 1 "and a front side 5 and an opposite back side 6. A front side plate 7 is arranged at the far end of the front side 5 and can be formed by an outermost heat exchanger plate 2 or a flat plate arranged outside but preferably against the outermost heat exchanger plate 2. The plate heat exchanger may also comprise a corresponding back plate 8 which is arranged at the outermost side of the back 6 and which may be formed by the outermost heat exchanger plate 2 or by a flat plate arranged outside but preferably against the outermost heat exchanger plate 2.

In the embodiments shown, the heat exchanger plates 2 are permanently connected to each other by, for example, soldering, gluing or welding. Preferably, the front side plate 7, and possibly the back side plate 8, are also permanently connected to the heat exchanger plates 2 by, for example, soldering, gluing or welding. The front side plate 7 and the back side plate 8 can then form part of the plate package 1.

It should be noted, however, that the invention is also applicable to plate heat exchangers which are held together in other ways, such as by means of the clamping housing. The plate heat exchanger comprises a primary inlet 11 and a primary outlet 12 for the primary medium and a secondary inlet 21 and a secondary outlet 22 for the secondary medium, see Figs. 1 and 3.

The primary inlet 11 is arranged to transport the primary medium into the plate package 1 to the primary plate gaps 3. The primary inlet 11 comprises a primary inlet port channel 13 which extends through at least a part of the plate package 1. The primary inlet port channel 13 is formed by a gate hole through each and one of the heat exchanger plates 2 in addition to some of the heat exchanger plates 2 as shown in more detail below. The primary inlet 11 comprises an external inlet pipe 15 in line with the primary inlet port channel 13.

The primary outlet 12 is arranged to transport the primary medium out of the plate package 1 from the primary plate gaps 3. The primary outlet 12 comprises a primary outlet port channel 14 extending through at least a part of the plate package 1. The primary outlet port channel 14 is formed by a port hole through each and every one of the heat exchanger plates 2 in addition to some of the heat exchanger plates 2 as shown in more detail below. The primary outlet 12 includes an external outlet pipe 16 in line with the primary outlet port channel 14.

Secondary inlet 21 is arranged to transport the secondary medium into the plate package 1 to the secondary plate gaps 4. The secondary inlet 21 comprises a secondary inlet port channel 23 extending through at least a part of the plate package 1. The secondary inlet port channel 23 formed by a gate hole through each and one of the heat exchanger plates 2 in addition to some of the heat exchanger plates 2 as shown in more detail below. The secondary inlet 21 comprises an external inlet pipe 25 in line with the secondary inlet port channel 23.

The secondary outlet 22 is arranged to transport the secondary medium out of the plate package 1 from the secondary plate gaps 4. The secondary outlet 22 comprises a secondary outlet port channel 24 which extends through at least a part of the plate package 1. The secondary outlet port channel 24 is formed by a port hole through each of the heat exchanger plates 2 except for some of the heat exchanger plates 2 as shown in more detail below. The secondary outlet 22 includes an external outlet pipe 26 in line with the secondary outlet port channel 24.

The primary inlet port channel 13, the primary outlet port channel 14, the secondary inlet port channel 23 and the secondary outlet port channel 24 thus extend through the front side plate 7, i.e. outwards from the front side 5 via the respective external inlet or outlet pipes 15, 16, 25 and 26.

The plate heat exchanger comprises a sensor device 30, which comprises a space 31 which is closed to the primary plate gaps 3 and to the secondary plate gaps 4. The space 31 contains a sensor medium which is influenced by the temperature of the secondary medium. The sensor medium may advantageously comprise or consist of a substance which is in gas phase and liquid phase at the temperature and at the pressure prevailing in space 31. The sensor medium may, for example, comprise or consist of carbon dioxide and activated carbon or a gas-liquid mixture.

The space 31 is defined by two of the heat exchanger plates 2 or by one of the heat exchanger plates 2 and one of the back plate 8 or the front side plate 7. In the embodiments shown, the space 31 is formed by a closed plate gap 3 'adjacent to an adjacent 4' of the secondary plate gaps 4, is traversed by the secondary medium. The closed plate gap 3 'is thus located at the outermost part of the plate package 1 at the rear 6. The adjacent secondary plate gap 4' is located immediately inside the space 31 and next to the outermost part of the plate gaps 3, 4 with respect to the rear side 6. The adjacent secondary plate gap 4 'thus forms the outermost secondary plate gap.

As shown in Fig. 2, the adjacent of the secondary plate gaps 4 communicates with the secondary outlet 22 and the secondary outlet port channel 24. As shown in Fig. 3, the closed plate gap 3 'is closed opposite the primary inlet port channel. 13 and the primary outlet port channel 14.

The plate heat exchanger is connected to or comprises a throttling means 35 which is connected to the sensor device 30. In the embodiments shown, the throttling means 35 is arranged to control the flow of the primary medium through the primary plate gaps 3 depending on the sensor medium. It should be noted, however, that the throttling means 35 may be arranged to control the flow of the secondary medium through the secondary plate gaps 4 depending on the sensor medium. The throttling member 35 can be realized in the form of a valve of suitable design. In the embodiments shown, the throttling means 35 is arranged on the external outlet pipe 16 to the primary outlet 12, but it can also be arranged on the external inlet pipe 15 to the primary inlet 11.

The restrictor 35 comprises an actuating means 36 which is connected to the space 31 via a conduit 37, for example an electrical conduit or a capillary tube which is designed to transmit a pressure change in the space 31 to the actuating means 36. The actuating means 36 is arranged to actuate the restricting means 35 by sensing a pressure change of the sensor medium in the space 31. The pressure of the sensor medium is dependent on the temperature. An increase in the temperature of the secondary medium leads to an increase in the pressure of the sensor medium which, via the actuating means 36, increases the throttling of the throttling means 35 so that the flow of the primary medium is reduced. Correspondingly, a decrease * of the temperature of the secondary medium leads to a decrease of the pressure of the sensor medium which via the actuating means 36 reduces the throttling of the throttling means 35 so that the flow of the primary medium is increased. In a cooling application, the actuating means 36 is inverted so that an increase in the temperature of the secondary medium leads to an increase in the pressure of the sensor medium which via the actuating means 36 reduces the throttling of the throttling means 35 so that the flow of the primary medium is increased.

The plate heat exchanger also comprises flow reducing means arranged to reduce the flow of the secondary medium by adjoining the secondary plate gaps 4. By such a reduction of the flow, or the amount of flow, the temperature of the secondary medium in the adjacent secondary plate spacing 4 'to increase. In this way, essentially the same temperature profile on the secondary medium can be achieved in the adjacent secondary plate gaps 4 'as in the other secondary plate gaps 4.

According to the first embodiment shown in particular in Figs. 2 and 3, the flow reducing means comprise a choke 40 which is arranged to restrict the flow of the secondary medium. As shown in Fig. 2, the throttle 40 is arranged in one of the port holes of the heat exchanger plate 2 adjacent to the adjacent secondary plate gap 4 'and to the adjacent one of the primary plate gaps 3. More specifically, the throttle 40 is arranged in this heat exchanger plate. 2 in the port hole located in or forming part of the secondary inlet port channel 23.

It should be noted that it is possible, as a complement or alternative, to arrange the choke 40 in this heat exchanger plate 2 in the port hole located in or forming part of the secondary outlet port channel 24.

According to a further alternative, it is possible to arrange the throttle 40 in any suitable position in the adjacent outermost plate gap 4 '.

Figs. 4 and 5 show a second embodiment of the plate heat exchanger according to the invention. It should be noted that the same or similar elements have been provided with the same reference numerals in the illustrated embodiments. The second embodiment differs from the first embodiment in that the flow reducing means, instead of a choke, comprise a thickness of the adjacent secondary plate gap 4 ', which thickness is reduced in relation to the thickness of the other secondary plate means. As shown in Figs. 4 and 5, the adjacent secondary plate gap 4 ', which adjoins the closed plate gap 3', has a thickness which is considerably less than the thickness of the other secondary plate gaps 4. For example, the adjacent secondary plate gaps 4 'may have a thickness that is half as large, or substantially half as large, as the thickness of the other secondary plate gaps 4. The reduction of the adjacent secondary plate gaps 4 "thickness, or depth, can be achieved by a reduced pressing depth during the compression molding of this heat exchanger plate 2, i.e. the heat exchanger plate 2 adjacent to the adjacent of the secondary plate gaps 4 and to the adjacent of the primary plate gaps 3.

As an alternative or complement, the throttling can be increased by a modification of the corrugation 2 "of the heat transfer surface 2 'of one or both of the heat exchanger plates 2 which delimits the adjacent secondary plate gap 4' in comparison with the corrugation 2" of the other heat exchanger plates 2. In this way For example, the flow resistance in the adjacent secondary plate spacing 4 'can be increased.

The invention is not limited to the embodiments shown but can be varied and modified within the scope of the appended claims.

It is possible to leave the space 31 within the scope of the invention located in a closed plate gap 3 'which is located inside the plate package 1, preferably between two secondary plate gaps.

In the embodiments shown, the plate heat exchanger is designed for countercurrent flow of the primary medium and the secondary medium. It is possible to design the plate heat exchanger according to other flow principles, such as parallel flow or co-flow.

Furthermore, the primary inlet port channel 13 and the primary outlet port channel 14 may be located diagonally and not directly above each other as shown in the figures. The same, of course, applies to the secondary inlet port channel 23 and the secondary outlet port channel 24.

It should be noted that the flow reducing agents may also comprise a combination of two or more of the above embodiments thereof.

Claims (11)

10 15 20 25 30 35 533? B3 13 Patent claims Plate heat exchanger comprising a plate package (1) with a plurality of heat exchanger plates (2) arranged next to each other in the plate package (1) in such a way that they form primary plate gaps (3) for a primary medium and secondary plate gaps (4) for a secondary medium, which primary and secondary plate gaps (3, 4) are arranged in an alternating order in the plate package (1), the plate package (1) having a first end (1 ') and a second opposite end (1 "). and a front side (5) and an opposite rear side (6), a primary inlet (11), which is arranged to transport the primary medium into the plate package (1) to the primary plate gaps (3) and comprises a primary inlet port channel (13), a primary outlet (12), which is arranged to transport the primary medium out of the plate package (1) from the primary plate gaps (3) and comprises a primary outlet port channel (14), a secondary inlet (21), which is arranged to transport the secondary medium into the plate package (1) to the secondary plate centers the compartments (4) and comprises at least one secondary inlet port channel (23), a secondary outlet (22), which is arranged to transport the secondary medium out of the plate package (1) from the secondary plate gaps (4) and comprises a secondary outlet port channel (24), a sensor device (30) comprising a space (31) closed to the primary plate gaps (3) and the secondary plate gaps (4), the space (31) containing a sensor medium which is influenced by the temperature of the secondary medium , and a throttling means (35) connected to the sensor device (30) and arranged to control the flow of one of the primary medium and the secondary medium depending on the sensor medium, characterized in that the space (31) is formed by a closed plate gap (3 ') which adjoining at least one adjacent (4 ') of the secondary plate gaps (4) and that the plate heat exchanger comprises flow reducing means.The means arranged to reduce the flow of the secondary medium provide through the adjacent secondary plate gap (4 '). A plate heat exchanger according to claim 1, wherein the closed plate gap (3 ') is located at the outermost part of the plate package (1) at the rear (6), the adjacent secondary plate gap (4') forming an outermost secondary plate gap. A plate heat exchanger according to any one of claims 1 and 2, wherein the flow reducing means comprises a choke (40) adapted to choke the fate of the secondary medium. Plate heat exchanger according to claim 3, wherein the choke (40) is arranged in a port hole of the heat exchanger plate (2) adjacent to the adjacent of the secondary plate gaps (4) and to the adjacent of the primary plate gaps (3). A plate heat exchanger according to claim 4, wherein the throttle (40) is arranged in the port hole forming part of the secondary inlet port channel (23) or the secondary outlet port channel (24). A plate heat exchanger according to any one of the preceding claims, wherein the flow reducing means comprises a reduced thickness of the adjacent secondary plate gaps (4 ') relative to the thickness of the other secondary plate gaps (4). Plate heat exchanger according to any one of the preceding claims, wherein each heat exchanger plate (2) has a heat transfer surface (2 ') with a corrugation (2 ") and wherein the flow reducing means comprises a modification of the corrugation (2") of the heat transfer surface (2 ') of at least one of the heat exchanger plates (2) which delimit the adjacent secondary plate gap (4') in comparison with the corrugation (2 ") of the other heat exchanger plates (2). 15 15 533 783 15 Plate heat exchanger according to any one of the preceding claims, wherein the closed plate gap (3 ') is closed to the primary inlet port channel (13) and the primary outlet port channel (14) by means of closed port holes in the heat exchanger plate (2) which adjacent to the closed plate gap (3 '). A plate heat exchanger according to any one of the preceding claims, wherein the plate heat exchanger comprises a front side plate (7) located at the front side (5) and adjacent to an outermost heat exchanger plate (2). A plate heat exchanger according to claim 9, wherein the primary inlet port channel (13), the primary outlet port channel (14), the secondary inlet port channel (23) and the secondary outlet port channel (24) extend through the front side plate (7). A plate heat exchanger according to any one of the preceding claims, wherein the throttling means (35) comprises an actuating means (36) connected to the space (31) and arranged to act on the throttling means (35) by sensing a pressure change of the sensor medium in the space (31). ). '