SE528310C2 - Plate heat exchanger for, e.g. desalination of seawater, comprises compression-molded heat exchanger plates successively provided in plate package that encloses evaporation, separation, and condensation sections - Google Patents

Abstract

A plate heat exchanger for treatment of a medium, comprises compression-molded heat exchanger plates (1), which are successively provided in a plate package and which form first plate interspaces (5) for the medium and second plate interspaces. The first and second plate interspaces are provided in an alternating order in the plate package. The plate package encloses an evaporation section, a separation section, and a condensation section provided in such a way that the evaporation, separation and condensation are permitted in each of the first interspaces. A plate heat exchanger for treatment of a medium comprises compression-molded heat exchanger plates, which are successively provided in a plate package and which form first plate interspaces for the medium and second plate interspaces. The first and second plate interspaces are provided in an alternating order in the plate package. The plate package encloses an evaporation section, a separation section, and a condensation section. The evaporation section permits evaporation of at least a part of the medium flowing through the first plate interspaces. The separation section separates non-evaporated liquid from the evaporated part of the medium. The condensation section condenses the evaporated part flowing through the first plate interspaces. The evaporation section, separation section and condensation section are provided in such a way that the evaporation, separation and condensation are permitted in each of the first interspaces.

Description

528 310 SUMMARY OF THE INVENTION The object of the invention is to provide an improved plate heat exchanger for distilling a medium and especially for desalination of saline water. A further object of the invention is to provide such a plate heat exchanger which is efficient and which can be manufactured in a simple and cost-effective manner.

Another object is to provide such a plate heat exchanger which allows easy maintenance. This object is achieved with the initially indicated plate heat exchanger which is characterized in that the plate package encloses an evaporator section, a separation section and a condensing section, the evaporator section being arranged to allow evaporation of at least a part of the medium flowing through the first plate spaces. the separating section is arranged to separate non-evaporated liquid from the evaporated part of the medium and the condensing section is arranged to condense the evaporated part flowing through the first plate gaps.

Such a plate heat exchanger thus offers the possibility of carrying out the entire desired treatment of the medium, for example desalination of seawater, in the plate package. The plate heat exchanger therefore does not need a container in which the plate package is enclosed. Consequently, a plate heat exchanger is achieved which is efficient and which can be manufactured in a simple and cost-effective manner. Furthermore, maintenance and cleaning of the plate package and the individual heat exchanger plates is simplified.

According to a preferred embodiment of the invention, a center axis extends substantially centrally between two side edges of each heat exchanger plate and substantially vertically when the plate package is in a normal position of use. The center shaft can advantageously extend substantially centrally through the evaporating section, the separating section and the condensing section, the evaporating section being at the bottom and the condensing section at the top in the normal position of use. According to a further embodiment of the invention, substantially each of the second plate gaps of the evaporating section forms a heating space which is closed to the first plate gaps and to the separation section and the condensing section and arranged to allow flow of a heating medium for heating. to the medium flowing in the first plate gaps of the evaporation section to effect the evaporation. The evaporation section can then be closed by means of a gasket which extends around the evaporation space.

According to a further embodiment of the invention, the evaporator section comprises at least one inlet for the medium, the inlet being formed by an inlet port in substantially each heat exchanger plate in the plate package, which inlet ports form a port channel which is closed to the second plate gaps and communicates with the first plate gaps. Advantageously, the inlet port channel of the inlet may be closed to the other plate gaps by means of an inlet gasket extending around the inlet port in each of the other plate gaps. Furthermore, the inlet port channel can communicate with the first plate gaps via at least a relatively small hole arranged between the inlet port and the inlet gasket and extending through every other heat exchanger plate in the plate pack from the second plate gaps to the first plate gaps. With such a relatively small hole, a relatively large pressure drop is obtained, which enables a good distribution of the medium entering the first plate gaps in the evaporation section and in this way an efficient heating and evaporation of the medium is achieved. the inlet port channel can then be closed to the first plate gaps by means of an additional gasket extending around the inlet port between the hole and the inlet port in each of the first plate gaps.

According to a further embodiment of the invention, a limiting pack is arranged in the first plate gaps and is arranged to limit the evaporation space of the medium in the evaporation section and to allow transport of the medium to the separation section. According to a further embodiment of the invention, the separation section is arranged to allow flow of the medium through the first plate gaps and the second plate gaps. The first and second plate gaps thus communicate with each other in the separation section and both of these plate gaps can be used for the flow of the medium. This reduces the flow rate and can achieve a more efficient capture of liquid droplets. Advantageously, the heat exchanger plates 1 in the separation section can be corrugated in such a way that they allow capture of liquid from the medium flowing through the first plate gaps and the second plate gaps.

According to a further embodiment of the invention, the separation section is arranged to direct the captured liquid to a liquid outlet for discharge of. the captured liquid. Advantageously, the gasket of the evaporator section adjacent to the separation section can be arranged in such a way that the trapped liquid flows along the gasket towards the liquid outlet. The gasket of the evaporator section, which adjoins the separation section, can then slope downwards and outwards from the center axis towards the side edges. Furthermore, the boundary gasket and the evaporator section gasket can together define a side passage between these gaskets and the respective side edge, these side passages comprising both the first and second plate gaps and are arranged to lead the trapped liquid further to the liquid outlet.

According to a further embodiment of the invention, substantially each of the second plate gaps of the condensing section forms a cooling space which is closed to the first plate gaps and to the separation section and the extension section and is arranged to allow flow of a cooling medium for heat transfer from the medium. flowing in the first plate gaps of the condensing section to effect the condensation. Furthermore, the condensing section comprises at least one media outlet, the media outlet being formed by an outlet port in substantially each heat exchanger plate in the plate package, which outlet ports form one of a port channel extending through substantially the entire plate package. According to a further embodiment of the invention, substantially each heat exchanger plate in the separation section comprises at least one collecting port which forms a collecting channel which extends through substantially the entire plate package and is arranged to lead the medium into the first plate gaps of the condensing section. Advantageously, essentially each heat exchanger plate may comprise at least two collecting ports forming a separate such collecting duct, one such collecting port being arranged in the vicinity of each side edge of each heat exchanging plate.

According to a further embodiment of the invention, a guide gasket is arranged in each of the first plate gaps and arranged to define the separation section from the condensing section. Advantageously, the guide gasket slopes downwards towards the port channel of the media outlet and is arranged to guide the medium condensed in the condensing section towards the media outlet. Furthermore, the media outlet can be arranged in a central position, wherein the guide gasket slopes downwards towards the port channel of the media outlet from two positions which are located in the vicinity of each of said collecting ports.

According to a further embodiment of the invention, the plate heat exchanger is designed to pass the medium through the second plate gaps of the condensing section before the medium is led into the first plate gaps of the evaporation section, the medium forming the cooling medium.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will now be explained in more detail by means of a description of various embodiments and with reference to the accompanying drawings.

Fig. 1 shows a side view of a plate heat exchanger according to an embodiment of the invention.

Fig. 2 shows a plan view of a heat exchanger plate with gaskets in a first plate gap.

Fig. 3 shows a plan view of a heat exchanger plate with gaskets in a second plate gap. us 528 310 DETAILED DESCRIPTION OF DIFFERENT EMBODIMENTS OF THE INVENTION Fig. 1 shows a plate heat exchanger for treating a medium. The following description describes an application for desalination of seawater. It should be noted, however, that the invention is not limited to this application but may also relate to other treatment, for example distillation of a liquid.

The plate heat exchanger comprises a large number of molded heat exchanger plates 1 which are arranged parallel to and one after the other in such a way that they form a plate package 2. ' The plate package 2 is arranged between a frame plate 3 and a pressure plate 4. Between the heat exchanger plates 1 first plate plate spaces 5 and second plate spaces 6 are formed. The first plate spaces 5 and the second plate spaces 6 are arranged in an alternating order in the plate package 2 in each first plate gap 5 is surrounded by two second plate gaps 6 and substantially every second plate gap 6 is surrounded by two first plate gaps 5. Different sections of the plate package 2 are delimited by means of gaskets in each plate gap 5, 6, which will be explained. further below.

Each heat exchanger plate has two opposite substantially parallel side edges 7, 8, an upper edge 9 and a lower edge 10. A center axis x extends substantially centrally between the two side edges 7 and 8 and substantially vertically when the plate package 2 is in a normal position of use. .

The flat package 2, ie. the heat exchanger plates 1 and the gaskets lying therebetween are held together by means of schematically indicated tension bolts 11 in a manner known per se.

An embodiment of the plate heat exchanger will now be explained in more detail with reference to Figs. a passage for the medium to be treated; in this case seawater to be desalinated. Fig. 3 shows a side of a heat exchanger plate 1 facing one of the other plate gaps 6. 528 510 The plate package 2 encloses an evaporation section E, a separation section S and a condensing section C. The evaporation section E is arranged to allow evaporation of at least a part of the medium flowing through the first plate gaps 5. The separation section S is arranged to separate non-evaporated liquid from the evaporated part of the medium. The condensing section C is arranged to condense the evaporated part flowing through the first plate gaps 5. The center axis x extends substantially centrally through the evaporating section E, the separating section S and the condensing section C. As shown in Figs. 2 and 3, the evaporating section C is at the bottom at the top and the separation section S between the evaporator section E and the condensing section C when the plate heat exchanger is in the normal position of use.

In each of the first plate gaps 5 and the second plate gaps 6 there is a main gasket 13 extending around the evaporation section E, the separation section S and the condensing section C in the vicinity of the edges 7, 8, 9 and 10. substantially each of the second plate gaps 6 of the evaporator section E forms a heating space 15, which is closed towards the first plate gaps 5 and towards the separation section S and the condensing section C by means of a gasket 16 extending around the heating space 15. The heating space 15 is the heating space 15. allowing flow of a heating medium for heat transfer to the medium flowing in the first plate gaps 5 of the evaporation section E to effect the evaporation. Each heat exchanger plate 1 comprises an inlet port 17 and an outlet port 18, which are located in the heating space 15 inside the gasket 16 and form an inlet port channel and an outlet port channel for the heating medium, the inlet port channel and the outlet port outlet 20 are connected to the external outlet port. for the heating medium, see Fig. 1. Between the inlet port 17 and the outlet port 18, each heat exchanger plate 1 has a corrugation 21 which faces inwards in the heating space 15 and forms a barrier which directs the heating medium outwards towards the side edges 7, 8 from the inlet port 528 310 in such a way that the entire surface of the heating space 15 can be utilized.

The evaporator section E comprises at least one inlet for the medium.

In the embodiment shown, the evaporator section E comprises two inlets, which are formed by two inlet ports 25 in each heat exchanger plate 1 in the plate package 2. The inlet ports 25 each form a gate channel which is closed towards the second plate gaps 6 and communicates with the first plate gates. opposite the other plate gaps 6 by means of their respective inlet gasket 26 which extends around the respective inlet port 25 in each of the other plate gaps 6 and which forms part of the gasket 16. The inlet port channels of the inlet are connected to their respective inlet line 27, see FIG. in the plate package from the second plate gaps 6 to the first plate gaps 5. The inlet port channels are further closed to the first plate gaps 5 by means of their respective packing 29 extending around the respective inlet port 25 between the respective holes 28 and the respective inlet port 25 in each of the first plate gaps 5. A boundary gasket 30 is arranged in each one of the first plate gaps 5 and arranged to limit the evaporation space of the medium in the evaporation section E and to direct the medium to the separation section S. The boundary gasket 30 thus extends partly around the evaporation space in the first plate gaps 5 at a small distance from the circumferential main gasket 13. The boundary gasket 30 also includes a gasket section 31 extending around each of the inlet port 17 and the outlet port 18 to seal them against each other and against the evaporation space of the first plate gaps 5.

The boundary gasket 30 is open along its upper end, the separating section S being arranged to allow flow of the medium through both the first plate gaps 5 and the second plate gaps 6. The heat exchanger plates 1 are corrugated in the separating section S 528 310 with a corrugation 32 with ridges and valleys in such a way that they allow the collection of liquid from the medium flowing through the first plate gaps 5 and the second plate gaps 6. The corrugation 32, i.e. the ridges and valleys of the corrugation, extends in the embodiment shown across the center axis x, preferably substantially perpendicularly. the center axis x. - The separating section S is further arranged to direct the trapped liquid to two liquid outlets 33 for discharging the trapped liquid. The above-mentioned gasket 16 of the evaporation section E in the first plate gaps 5 adjoins the separation section S and is arranged in such a way that the liquid trapped in the separation section S flows along the gasket 16 towards the liquid outlets 33. In the embodiment shown this gasket 16 downwards and outwards from the center axis x towards the side edges 7 and 8. The boundary gasket 30 and the gasket 16 are arranged and positioned in such a way that they together define a side passage between these gaskets 30, 16 and the respective side edges 7 and 8 and more particularly between these gaskets 30, 16 and the main gasket 13. These side passages 35 thus extend through both the first plate gaps 5 and the second plate gaps 6. The side passages 35 are arranged to guide the trapped liquid further from the separation section S itself to the liquid outlets 33 which are located below the heating area 15 and the evaporation section E. As shown in Figs. The liquid outlets located above the lower edge 10 and a lower part of the main gasket 13 and below a lower part of the boundary gasket 30 and the gasket 16. substantially each of the other plate gaps 6 of the condensing section C form a cooling space 40 which is the end towards the first plate gaps 5 and towards the separation section S and the evaporation section E by means of a gasket 41 extending around the cooling space 40. The cooling space 40 is arranged to allow flow of a cooling medium for heat transfer from the medium flowing in the first plate gaps 5 of condensation section C to effect the condensation. Each heat exchanger plate 1 comprises an inlet port 42 and an outlet port 43, which are located in the cooling space 40 inside the gasket 41 and 528 310 form an inlet port channel and an outlet port channel for the coolant, respectively. The inlet port channel and the outlet port channel are connected to an external inlet line 44 and an external outlet line 45 for cooling, respectively, see Fig. 1. Between the inlet port 42 and the outlet port 43, each heat exchanger plate 1 has a corrugation 45 which faces inwardly in the cooling space 40 the coolant outwards towards the side edges 7, 8 from the inlet port 42 in such a way that the entire surface of the cooling space 40 can be used for condensing the medium.

The main gasket 13 in the first plate gaps 5 also includes a gasket section 46 extending around each of the inlet port 42 and the outlet port 43 to seal them against each other and against the condensing space in the first plate gaps 5.

The condensing section C comprises at least one media outlet formed by an outlet port 50 in substantially each heat exchanger plate 1 in the plate package 2. The outlet ports 50 form one of a port channel extending through substantially the entire plate package 2 and are connected to a discharge channel 55 for discharge outlet 55. the condensed medium, ie in the example shown, the desalinated seawater is discharged as fresh water. Furthermore, substantially each heat exchanger plate 1 in an upper part of the separation section S- comprises two collecting ports 51 in the vicinity of each side edge 7, 8. These collecting ports 51 form four collecting channels which extend through substantially the entire plate package 2 and are arranged to lead the medium from the second plate gaps 6 of the separation section S into the first plate gaps 5 of the condensing section C.

The outlet port 50 is closed relative to the second plate gaps 6 by means of an outlet gasket 52 in each of the second plate gaps 6. Each such outlet gasket 52 extends around the outlet port 50 in the respective second plate gaps. The outlet gasket 52 partly coincides with the gasket 41 of the cooling space 40.

A guide gasket 53 is arranged in each of the first plate spaces 5 and arranged to define the separation section S from the condensing section C. The guide gasket 53 slopes downwards towards the outlet port 50 and the media channel port channel and is arranged to guide it in the condensing section C condensed the medium towards the media outlet. The media outlet is arranged in a central position, the guide gasket 53 sloping downwards towards the outlet port 50 from two positions located in the vicinity of the collecting ports 51 at each side edge 7, 8. As can be seen from Fig. 2, the guide gasket 53 extends below the outlet port 50. The control gasket 53 also has the task of guiding the medium in the separation section S outwards towards the collecting ports 51. * As can be seen from Fig. 1, the plate heat exchanger is designed to guide the medium, i.e. the seawater, through the other plate gaps 6 of the condensing section C in the first plate gaps 5 of the evaporator section E in such a way that the medium forms the coolant in the condensing section C, i.e. the outlet line 45 from the cooling space 40 is connected to the two inlet lines 27.

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

It should be noted, for example, that the different sections can be placed in a different way in the plate package than the location shown. The evaporation section may, for example, be located in the vicinity of a lower corner of the plate package, the separation section in the upper part of the plate package and the condensing section in the other lower corner of the plate package. It should also be noted that all heat exchanger plates 1 are substantially identical except for the relatively small holes 28 which are only accommodated in every other heat exchanger plate 1. In connection with the mounting of the plate package 2, every other plate is rotated about the center axis x in a manner known per se.

Claims (24)

10 15 20 25 30 35 528 310 12 Patent claims A plate heat exchanger for treating a medium, comprising a number of molded heat exchanger plates (1) arranged one after the other in a plate package (2) and forming a first plate space (5) for the medium and second plate spaces (6), the first the plate gaps (5) and the other plate gaps (6) are arranged in an alternating order in the plate pack (2), characterized in that the plate pack (2) encloses an evaporation section, a separation section and a condensing section, the evaporation section being arranged to allow evaporation of at least a portion of the medium flowing through the first plate gaps, the separating section is arranged to separate non-vaporized liquid from the vaporized part of the medium and the condensing section is arranged to condense the vaporized part flowing through the first plate gaps, and the narrowing section, the separating section and the condensing section are arranged in such a way that in each of the The first plate gaps allow said evaporation, said separation and said condensation of the medium. Plate heat exchanger according to claim 1, characterized in that a center axis (x) extends substantially centrally between two side edges (7) of each heat exchanger plate (1) and substantially vertically when the plate package (2) is in a normal position of use. Plate heat exchanger according to claim 2, characterized in that the center axis (x) extends substantially centrally through the evaporating section (E), the separating section (S) and the condensing section (C), the evaporating section (E) being located at the bottom and the condensing section (C) exceeds the normal operating mode. Plate heat exchanger according to any one of the preceding claims, characterized in that substantially each of the second plate gaps (6) of the evaporation section (E) forms a heating space (15), which is closed relative to the first plate gaps (5). and with respect to the separation section (S) and the condensing section (C) and arranged to allow flow of a heating medium for heat transfer to the medium flowing in the first plate gaps (5) of the evaporating section (5). E) to effect the evaporation. A plate heat exchanger according to claim 4, that the heating space (15) is closed by means of a gasket (16) extending around the evaporation space (15). A plate heat exchanger according to any one of claims 4 and 5, wherein the evaporating section (E) comprises at least one inlet for the medium, the inlet being formed by an inlet port (25) in substantially each heat exchanger plate (1) in the plate package (2), which inlet ports (25) form a port channel which is closed to the second plate gaps (6) and communicates with the first plate gaps (5) - Plate heat exchanger according to claim 6, characterized in that the inlet port channel is closed to the other plate gaps (6) by means of an inlet gasket (26) extending around the inlet port (25) in each of the other plate gaps (6). Plate heat exchanger according to claims 6 and 7, characterized in that the inlet port channel communicates with the first plate gaps (5) via at least a relatively small hole (28) arranged between the inlet port (25) and the inlet gasket (26) and extends through every other heat exchanger plate (1) in the plate package (2) from the second plate gaps (6) to the first plate gaps (5). Plate heat exchanger according to claim 8, characterized in that the inlet port channel is closed to the first plate gaps (5) by means of a further gasket extending around the inlet port (25) between the hole (28) and the inlet port (25) in each of the first plate gaps (5). Plate heat exchanger according to any one of the preceding claims, characterized in that a limiting gasket (30) is arranged in the first plate gaps (5) and arranged to limit the evaporation space of the medium in the evaporation section (E) and allow transport of the medium to the separation section (S). Plate heat exchanger according to any one of the preceding claims, than; characterized in that the separating section (S) is arranged to allow flow of the medium through the first plate gaps (5) and the second plate gaps (6). Plate heat exchanger according to claim 11, characterized in that the heat exchanger plates (1) in the separation section (S) are corrugated in such a way that they allow capture of liquid from the medium flowing through the first plate gaps (5) and the second plate gaps. lanrummen (6). Plate heat exchanger according to claim 12, characterized in that the separating section (S) is arranged to direct the trapped liquid to a liquid outlet (33) for discharging the trapped liquid. Plate heat exchanger according to claims 5 and 13, characterized in that the gasket (16) of the evaporator section (16) adjacent to the separation section (S) is arranged in such a way that the trapped liquid flows along the gasket (16) towards the liquid outlet (33). ). Plate heat exchanger according to claims 3 and 14, characterized in that the gasket (16) of the evaporator section (16) adjacent to the separation section (S) slopes downwards and outwards from the center axis (x) towards the side edges (7, 8). Plate heat exchanger according to claims 2, 5 and 15, characterized in that the boundary gasket (30) and the gasket (16) of the evaporator section (E) together define a side passage (35) between these gaskets and the respective side edge (7, 8), these side passages (35) comprise both the first and second plate gaps (5, 6) and are arranged to direct the trapped liquid further to the liquid outlet (33). Plate heat exchanger according to any one of the preceding claims, characterized in that substantially each of the other plate gaps (6) of the condensing section (C) forms a cooling space (40) which is closed relative to the first plate gaps (5) and opposite the separation section (S) and the evaporating section (E) and is arranged to allow flow of a cooling medium for heat transfer from the medium flowing in the first plate gaps (5) of the condensing section (C) to effect the condensation . Plate heat exchanger according to claim 17, characterized in that the condensing section (C) comprises at least one media outlet, the media outlet being formed by an outlet port (50) in substantially each heat exchanger plate (1) in the plate package (2), which outlet ports (50) forms one of a port channel extending through substantially the entire plate package (2). Plate heat exchanger according to any one of claims 17 and 18, Kåge; characterized in that substantially each heat exchanger plate (1) in the separation section (S) comprises at least one collecting port (51) forming a collecting channel extending through substantially the entire plate package (2) and arranged to guide the medium into the first plate spaces (5) of the condensing section (C). Plate heat exchanger according to claims 2 and 19, characterized in that substantially each heat exchanger plate (1) in the separation section (S) comprises at least two collecting ports (51) each forming such a collecting duct, such a collecting port (51) being arranged in the vicinity of each side edge (7, 8) on each heat exchanger plate (1). Plate heat exchanger according to one of Claims 17 to 20, characterized in that a guide gasket (53) is arranged in each of the first plate gaps (5) and is arranged to delimit the separation section (S) from the condensation section (C). Plate heat exchanger according to claims 18 and 21, characterized in that the control gasket (53) slopes downwards towards the port channel of the media outlet and is arranged to guide the medium condensed in the condensing section (C) towards the media outlet. Plate heat exchanger according to claims 20 and 22, characterized in that the media outlet is arranged in a central position, wherein the control gasket (53) slopes downwards towards the port channel of the media outlet from two positions located in the vicinity of each of said collection ports (51). Plate heat exchanger according to any one of claims 17 to 23. characterized in that the plate heat exchanger is designed to guide the medium through the second plate gaps (6) of the condensing section (C) before the medium is led into the first plate gaps (5) of the condenser section. the steaming section (E), the medium forming the cooling medium.