JP2008527297A - Heat exchanger equipment - Google Patents

Abstract

The heat exchanger apparatus has a number of plate heat exchangers (1) including at least a first plate heat exchanger. Each plate heat exchanger is formed with a frame plate (2), a pressure plate (3), a first plate space (6) for condensing water vapor, and a second plate space (7) for evaporating liquid. And a plurality of heat transfer plates arranged in this manner. Each plate heat exchanger has a water vapor inlet channel (21) in communication with the first plate space, a condensate outlet channel in communication with the first plate space, and a liquid inlet flow in communication with the second plate space. It has a channel (23) and a water vapor outlet channel (24) communicating with the second plate space. The housing (30) forms a first outlet chamber (31) adjacent to the frame plate and arranged to receive water vapor formed from the water vapor outlet flow path. A first liquid separator (32) is provided in the housing and takes in liquid from water vapor flowing through the first outlet chamber.

Description

  The present invention includes at least a first heat exchanger, and each plate heat exchanger includes a frame plate, a pressure plate, a first plate space for condensing water vapor, and a second plate space for evaporating liquid. A heat exchanger having a plurality of heat transfer plates provided as a plate package adjacent to each other between the frame plate and the pressure plate, each plate heat exchanger comprising: A steam inlet channel extending through the frame plate and substantially all of the heat transfer plates and in communication with the first plate space, and at least condensate extending through substantially all of the heat transfer plates and in communication with the first plate space. An outlet channel, a liquid inlet channel extending through almost all heat transfer plates and communicating with the second plate space, and through the frame plate and almost all heat transfer plates. Extending, it relates to a heat exchanger device having a steam outlet passage communicating with the second plate space. The invention also relates to a heat exchanger device according to claim 33 and a heat exchanger device according to claim 34.

  Seawater desalination equipment has been manufactured for several years, where packages with heat transfer plates form the main component in the process. Each plate does not have a port for water vapor; instead, a plate heat exchanger is located in the vessel and the space outside each plate is one or two for water vapor depending on the type of process. It is used as the above flow path. The container is often a cylindrical pressure vessel. Swedish Patent No. 464938 discloses such a desalination plant with a plate package provided in a cylindrical vessel. In a large plant containing several plate packages, these can be located in the longitudinal direction of the cylinder. Containers limit to some extent how large a plant can be if it should not be possible to include multiple containers in the plant.

  U.S. Pat. No. 4,511,436 is welded in pairs to provide a heat transfer plate provided in a plate package to form a first plate space for condensation and a second plate space for evaporation. Other large desalination plants having a process line including several continuous heat exchanger stages with each heat exchanger stage having a plate package of This process line is provided in a sealed pressure vessel which is shown schematically. See also U.S. Pat. No. 4,514,260.

  At least for smaller or medium sized plants, the cost of the container accounts for the majority of the total cost of the plant. Both container manufacture and installation are complex and time consuming. Furthermore, plant maintenance is difficult, for example, because it is difficult to reach individual plate packages and heat transfer plates within the container.

  An object of the present invention is to provide a heat exchanger apparatus that has a simple configuration and facilitates maintenance and cleaning. It is another object of the present invention to provide such a heat exchanger apparatus having a configuration that allows the apparatus to be larger and include multiple heat exchanger stages.

  The object is to form a first outlet chamber adjacent to the frame plate and arranged to receive the water vapor formed from the water vapor outlet flow path, and to be provided in the housing and through the first outlet chamber. This is achieved by a heat exchanger device as defined at the beginning, characterized in that it has a first liquid separator adapted to take up liquid from the flowing water vapor.

  With such a housing, a heat exchanger device can be configured without a container surrounding the plate heat exchanger. Accordingly, conditions are established that are suitable for manufacturing and mounting the heat exchanger apparatus at low cost. The proposed arrangement also makes it possible to easily manufacture the heat exchanger device in various sizes, i.e. to manufacture a heat exchanger with almost any number of plate heat exchangers. Thus, each plate heat exchanger and individual heat transfer plate can be easily reached during inspection, maintenance, and cleaning. The heat exchanger apparatus is configured for the evaporation and condensation of the two media, respectively, and is therefore suitable for seawater desalination or other evaporation or distillation applications.

  In one embodiment of the invention, the apparatus has a first inlet chamber arranged to pump water vapor into the water vapor inlet channel. According to a first alternative embodiment, the first inlet chamber can be separated from the housing and housed in a separate casing adjacent to the frame plate. According to the second alternative embodiment, the first inlet chamber can be further housed in the housing. Furthermore, the first inlet chamber and the second outlet chamber can be separated by an inner wall in the housing.

  According to another embodiment of the invention, the number of plate heat exchangers is at least one. Thus, the heat exchanger apparatus according to the invention can advantageously be realized by a plate heat exchanger and a housing connected to and adjacent to the frame plate of the plate heat exchanger. In this way, a simple and small device is realized. Advantageously, the apparatus may have a compressor arranged to send the formed water vapor from the first outlet chamber to the first inlet chamber and the water vapor inlet channel.

  According to another embodiment of the invention, the number of plate heat exchangers is at least two, the first outlet chamber is adjacent to the frame plates of both first plate heat exchangers, and both first Including two such first plate heat exchangers parallel to each other so as to be coupled to the steam outlet flow path of one plate heat exchanger, wherein the first liquid separator includes both first plate heats The liquid is taken in from the water vapor coming from the exchanger. This embodiment in principle works in the same way as the defined embodiment, but the steam is carried simultaneously to the two plate heat exchangers and the steam generated in the plate heat exchanger is used further in the subsequent stages. The difference is that it is discharged into the common outlet chamber as possible or as inlet steam to two parallel plate heat exchangers.

  According to another embodiment, the first inlet chamber is connected to the water vapor inlet channels of both first plate heat exchangers. Thus, the inlet chamber may be common to the two plate heat exchangers. Advantageously, the housing may have two generally parallel side walls facing each other, and the plate heat exchanger extends outwardly from each side wall in substantially opposite directions. In this way, an advantageous layout is realized that allows for easy installation and proper access.

  According to another embodiment of the invention, the number of plate heat exchangers is at least two and the apparatus comprises a first stage including at least a first plate heat exchanger and at least one final such And a final stage including a plate heat exchanger. In this way, an apparatus is realized in which the process can be performed in several stages or so-called effects. The device also has a common housing and several plate heat exchangers, can be easily manufactured, and allows proper access during maintenance and cleaning.

  According to another embodiment of the present invention, the housing is adjacent to the frame plate of the final plate heat exchanger and is arranged to receive water vapor formed from the water vapor outlet channel of the final plate heat exchanger. A final exit chamber is formed. Furthermore, the apparatus may have a final inlet chamber arranged to pump water vapor into the water vapor inlet channel of the final plate heat exchanger. Advantageously, the final inlet chamber is also housed in the housing.

  According to another embodiment of the present invention, the first outlet chamber is connected to the final inlet chamber, and the water vapor formed in the first plate heat exchanger is transferred to the water vapor inlet channel of the final plate heat exchanger. Make it possible to send. Thus, a heat exchanger apparatus having several stages or effects is easily realized. According to an alternative embodiment, the apparatus may comprise a preferably mechanical compressor arranged to send the formed water vapor from the final outlet chamber to the first inlet chamber. Further, the apparatus may have a final liquid separator provided in the final outlet chamber and adapted to take in liquid from water vapor flowing through the final outlet chamber.

  According to an alternative embodiment of the invention, the housing has at least one side wall, and the first plate heat exchanger and the second plate heat exchanger extend outwardly from the side wall in substantially the same direction.

  According to another alternative embodiment of the present invention, the housing may have two generally parallel side walls facing each other, the first plate heat exchanger and the second plate heat exchanger from each side wall. The outer sides extend in substantially opposite directions.

  According to another embodiment of the present invention, the apparatus has at least one intermediate stage including at least one intermediate plate heat exchanger, and the intermediate inlet chamber passes the water vapor to the water vapor inlet channel of the intermediate plate heat exchanger. And an intermediate outlet chamber is arranged to receive water vapor from the water vapor outlet flow path of the intermediate plate heat exchanger, and the intermediate outlet chamber communicates with the final inlet chamber via the intermediate liquid separator. The apparatus advantageously has one, two, three, four, five, six or more successive intermediates each having at least one intermediate such plate heat exchanger. You may have a step. The arrangement of the invention makes it very easy to manufacture and install a very large heat exchanger plant with a large number of stages or effects, all connected to a common housing.

  According to another embodiment of the invention, the apparatus has a condenser which is arranged downstream of the final outlet chamber and condenses water vapor sent to the final outlet chamber. Advantageously, the apparatus is adapted to operate by supplying high pressure external water vapor and receives at least a portion of the water vapor sent to the final outlet chamber or one of the final outlet chambers; There may be a thermal compressor adapted to mix this part of the water vapor with the external water vapor, and the mixture forms water vapor that is fed to the first inlet chamber.

  According to another embodiment of the invention, each stage has at least two such plate heat exchangers. In this way, the physical dimensions of the plant can be maintained at a relatively low level. Advantageously, the housing may have two generally parallel side walls facing each other, with each stage plate heat exchanger extending outwardly from each side wall in a generally opposite direction. In this case, the housing may extend outward substantially perpendicularly from two substantially parallel longitudinal walls of the centrally located housing.

  According to another embodiment of the invention, substantially each heat transfer plate has a first port hole that forms a first water vapor inlet channel and at least a second port that forms a condensate outlet channel. It has a hole, a third port hole that forms a liquid inlet channel, and at least a fourth port hole that forms a water vapor outlet channel. Further, substantially each heat transfer plate may have a central heat transfer region, the first port hole is disposed above the central heat transfer region, and the second port hole is below the central heat transfer region. Placed in. Advantageously, the third port hole may be located near the upper end of the central heat transfer region, extends across the heat transfer plate along the upper end of the central heat transfer region, and the central heat transfer region The heat transfer plate is configured such that a dispersion space in which the liquid is dispersed throughout is formed in each of the second plate spaces.

  According to another embodiment of the present invention, each plate heat exchanger has at least one elongate support member extending substantially perpendicularly from the frame plate, and the heat transfer plate and the pressure plate are attached to the support member. In addition, each plate heat exchanger may have a number of tie bolts that extend between the frame plate and the pressure plate and are arranged to allow the heat transfer plate to be compressed.

  The object is a heat exchanger device as defined at the beginning, which has a housing adjacent to the frame plate of each plate heat exchanger, the housing being formed from the water vapor outlet flow path of the first plate heat exchanger. Forming a first outlet chamber arranged to receive the water vapor and a final outlet chamber arranged to receive the water vapor formed from the water vapor outlet flow path of the final plate heat exchanger. It is also realized by a heat exchanger device.

  Furthermore, the object is a heat exchanger apparatus as defined at the beginning, which is adjacent to the frame plate of each plate heat exchanger, so as to feed water vapor into the water vapor inlet channel of the first stage plate heat exchanger. A first inlet chamber disposed; a first outlet chamber disposed to receive water vapor from a water vapor outlet flow path of the first stage plate heat exchanger; and a second stage plate heat exchanger. A housing forming a final inlet chamber arranged to feed water vapor into the water vapor inlet channel and a final outlet chamber arranged to receive water vapor from the water vapor outlet channel of the second stage plate heat exchanger It is realized by a heat exchanger device characterized by having.

  The present invention will now be described in more detail by way of example with reference to the accompanying drawings as an example.

  1 to 6 disclose a heat exchanger apparatus according to a first embodiment. The disclosed embodiments are primarily intended for desalination of salt-containing liquids, so-called brine, but are not limited to this application and can be used for distillation or evaporation in other applications. The heat exchanger apparatus has a plate heat exchanger 1 having a frame plate 2, a pressure plate 3, and a plurality of heat transfer plates 4, 5 arranged as plate packages adjacent to each other. Please refer to FIGS. The heat transfer plates 4 and 5 are composed of the frame plate 2 and the pressure plate 3 in the plate heat exchanger 1 so that a first plate space 6 for condensing water vapor and a second plate space 7 for evaporating liquid are formed. Are alternately arranged adjacent to each other (see also FIG. 8). A small number of the total number of heat transfer plates 4, 5 and plate spaces 6, 7 is schematically shown.

  Each of the heat transfer plates 4 and 5 and the frame plate 2 includes two first port holes 11 that form a water vapor inlet channel 21, a second port hole 12 that forms a condensate outlet channel 22, and a liquid inlet. It has the 3rd port hole 13 which forms the flow path 23, and the two 4th port holes 14 which form the water vapor | steam exit flow path 24. Each heat transfer plate 4, 5 also has a central heat transfer region 15. The first port hole 11 is disposed above the central heat transfer region 15 when the heat transfer plates 4 and 5 are disposed at normal use positions in the plate heat exchanger 1. At this time, the second port hole 12 is disposed below the central heat transfer region 15. The third port hole 13 is disposed near the upper edge of the central heat transfer region 15, and the fourth port hole 14 is disposed below the central heat transfer region 15 in a normal use position. The pressure plate 3 is continuous in the disclosed embodiment, that is, the pressure plate 3 has no port holes.

  The water vapor inlet channel 21 extends through the frame plate 2 and almost all the heat transfer plates 4 and 5 and communicates with the first plate space 6. The condensate outlet channel 22 extends through the frame plate 2 and almost all the heat transfer plates 4, 5 and communicates with the first plate space 6. The liquid inlet channel 23 extends through the frame plate 2 and almost all the heat transfer plates 4 and 5 and communicates with the second plate space 7. The water vapor outlet channel 24 extends through the frame plate 2 and almost all the heat transfer plates 4 and 5 and communicates with the second plate space 7.

  The heat transfer plates 4 and 5 are configured such that a dispersion space 16 is formed in each of the second plate spaces 7. The dispersion space 16 extends across the heat transfer plates 4, 5 along the upper end of the central heat transfer region 15, and disperses the liquid from the liquid inlet channel 23 over the entire central heat transfer region 15. Yes.

  The plate heat exchanger 1 has elongated support members 17 and 18 to which the heat transfer plates 4 and 5 and the pressure plate 3 are attached. The support members 17 and 18 are configured as beams extending substantially horizontally from the frame plate 2 in a normal use position. Furthermore, the plate heat exchanger 1 has a number of tie bolts 19 (see FIG. 7) that extend between the frame plate 2 and the pressure plate 3 and are arranged to allow the heat transfer plates 4 and 5 to be compressed. is doing. In the disclosed embodiment, a gasket 21 is provided between the heat transfer plates 4, 5 to seal the first plate space 6 against the surroundings, the liquid inlet channel 23, and the water vapor outlet channel 24, The two plate spaces 7 are sealed against the surroundings, the steam inlet channel 21 and the condensate outlet channel 22. It is also possible to use a permanent connection of adjacent heat transfer plates 4, 5 by means of a paired weld, a paired bond, a fully welded plate package, or a fully bonded plate package. is there.

  The heat exchanger apparatus also has a housing 30 that is disposed near the heat transfer plates 4, 5 and more specifically adjacent to the frame plate 2. In the first embodiment, the housing 30 forms a first outlet chamber 31 arranged to receive the water vapor formed from the water vapor outlet channel 24. The first liquid separator 32 provided in the first outlet channel 31 in the housing 30 and taking in liquid from the water vapor flowing through the first outlet chamber 31 also has a heat exchanger device. is doing. Furthermore, the heat exchanger apparatus has a first inlet chamber 33 arranged to feed water vapor into the first inlet channel 21. According to the first embodiment, the first inlet chamber 33 is housed in a separate casing 34 that is also adjacent to the frame plate 2 but separated from the housing 30.

  The heat exchanger apparatus also has a mechanical compressor 40 in the form of a pump or fan member. The compressor 40 is provided between the first liquid separator 32 and the first inlet chamber 33. Accordingly, the compressor 40 sends the formed water vapor from the first outlet chamber 31 to the first inlet chamber 33 and the water vapor inlet passage 21 through the first liquid separator 32 and the connection passage 39. Is arranged. A salt-containing liquid, so-called salt water, is supplied to the liquid inlet channel 23 via the liquid conduit 41. The formed condensate is discharged from the condensate outlet channel 22 via a condensate conduit 42. The salt-containing liquid separated by the first liquid separator 32 is collected in the bottom space 43 and discharged by the conduit 44.

  7-11 disclose a heat exchanger apparatus according to a second embodiment. It should be noted that the same reference numerals are used in all embodiments for members and components having corresponding functions. The second embodiment differs from the first embodiment in that the first inlet chamber 33 is housed in the housing 30, that is, the same housing 30 as the first outlet chamber 31. The first inlet chamber 33 and the first outlet chamber 33 are separated from each other by an inner wall 46 in the housing 30.

  Furthermore, in the second embodiment, the heat transfer plates 4 and 5 are configured to be somewhat different. The heat transfer plates 4 and 5 have a first port hole 11 that forms a water vapor inlet channel 21 and a fourth port hole 14 that forms a water vapor outlet channel 24. Further, each heat transfer plate 4, 5 has two second port holes 12 that form a condensate outlet channel 22.

  Further, the second embodiment may include a mechanical compressor of the type disclosed in FIGS.

  12 and 13 schematically disclose a heat exchanger apparatus according to a third embodiment. In this heat exchanger apparatus, each plate heat exchanger 1 has two plate heat exchangers 1 having substantially the same configuration as the plate heat exchanger 1 of the second embodiment. For simplicity of explanation, certain details disclosed in FIGS. 7-11 are not shown in FIGS. The two plate heat exchangers 1 are provided in series with each other so as to form a first stage having at least a first plate heat exchanger 1 and a final stage having at least a final plate heat exchanger 1. The third embodiment has a common housing 30 for both plate heat exchangers 1 or stages. The housing 30 is adjacent to the frame plate 2 of both plate heat exchangers 1 and has a first outlet arranged to receive the water vapor formed from the water vapor outlet channel 24 of each plate heat exchanger 1. A chamber 31 and a final outlet chamber 31 are formed. A liquid separator 32 that takes in liquid from water vapor flowing through each outlet chamber 31 is provided in each outlet chamber 31. The housing 30 also forms a first inlet chamber 33 and a final inlet chamber 33 that are arranged to feed water vapor into the water vapor inlet channel 21 of each plate heat exchanger 1.

  The final outlet chamber 31 is connected to the final inlet chamber 33 via a connecting flow path 39, and is connected by a compressor 40 arranged to send the formed water vapor from the final outlet chamber 31 to the first inlet chamber 33. It makes it possible to send the water vapor formed in one plate heat exchanger 1 to the water vapor inlet channel 21 of the final plate heat exchanger 1. In a third embodiment, the housing 30 has two generally parallel side walls 50 facing each other, which can be formed by the frame plate 2 of the respective plate heat exchanger 1 according to an alternative embodiment. Yes. As can be seen from FIGS. 12 and 13, the first plate heat exchanger 1 and the second plate heat exchanger 1 extend outwardly from each of these side walls 50 in substantially opposite directions. An inner wall 46 that separates the different chambers 31 and 33 from each other is provided in the housing 30.

  14 to 16 schematically disclose a heat exchanger apparatus according to a fourth embodiment. In this heat exchanger apparatus, each plate heat exchanger 1 has ten plate heat exchangers 1 having substantially the same configuration as the plate heat exchanger 1 of the second and third embodiments. For simplicity of explanation, certain details disclosed in FIGS. 7-11 are not shown in FIGS.

  The heat exchanger apparatus according to the fourth embodiment also has a common housing 30 for all plate heat exchangers 1. The housing 30 has two substantially parallel side walls 50 facing each other, and the plate heat exchanger 1 extends outward from these side walls 50 in substantially opposite directions. Each plate heat exchanger 1 is arranged in pairs, and each pair of plate heat exchangers 1 forms a stage or so-called effect in the process. The plate heat exchangers 1 in the respective stages are arranged to face each other on both sides of an elongated housing 30 disposed in the center so as to extend outward from the longitudinal side wall 50 in substantially opposite directions. Thus, each stage plate heat exchanger 1 is parallel to each other and has a common outlet chamber 31 and a common inlet chamber 33, ie, the first outlet chamber 31 is both plates of the first stage. Adjacent to the frame plate 2 of the heat exchanger 1, the heat exchanger 1 is connected to the water vapor outlet channels 24 of both plate heat exchangers 1 of the final stage. Similarly, the first inlet chamber 32 is adjacent to the frame plate 2 of both plate heat exchangers 1 of the first stage and is connected to the water vapor inlet channel 21 of both plate heat exchangers 1 of the last stage. ing. Between each stage is a liquid separator 32 that acts as a boundary between one stage outlet chamber 31 and the subsequent stage inlet chamber 33. See FIG. One stage inlet chamber 33 is separated from the same stage outlet chamber 31 by an inclined inner wall 46.

  The heat exchanger apparatus according to the fourth embodiment includes a condenser 55 that is provided on the downstream side of the final outlet chamber 31 and condenses water vapor sent to the final outlet chamber 31. In the disclosed embodiment, the condenser 55 has two plate heat exchangers that are parallel to each other and extend in opposite directions so as to correspond to the plate heat exchanger 1 outward from the housing 30. The condenser 55 finally condenses the water vapor sent to the final outlet chamber 31. An external cooling medium is supplied to the condenser 55. It should be noted that the condenser 55 can be configured differently than the method disclosed in FIG. The heat exchanger apparatus according to the fourth embodiment also has a thermal compressor 60 which is adapted to operate through the supply of high-pressure external steam as is known per se. External steam is supplied to the thermal compressor 60 via the supply conduit 61. The thermal compressor 60 supplies a certain compression and a certain temperature of water vapor to the first inlet chamber 33 via a supply conduit 62. This pressure and this temperature correspond to the pressure and temperature in the first inlet chamber and the first plate space 6 of the first stage plate heat exchanger 1, but lower than the ambient atmospheric pressure and ambient temperature, respectively. . The pressure and temperature then decrease continuously in subsequent stages. A portion of the water vapor sent from one or several of the final stages is returned to the thermal compressor 60 via conduit 63. The thermal compressor 60 has a nozzle that recirculates the returned water vapor to the supply conduit 62 by external water vapor.

  FIG. 17 illustrates the fifth embodiment, which differs from the fourth embodiment in that it has two, four plate heat exchangers 1 on each side of the housing 30.

  According to a sixth embodiment, which is a modified embodiment of the fourth or fifth embodiment, each stage has a plate heat exchanger 1 extending outwardly from the same side wall 50 of the elongated housing 30 in substantially the same direction. You may have. In other respects, the fifth embodiment can be configured in the same manner as the fourth embodiment.

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

It is the schematic from the top of the heat exchanger apparatus by the 1st Embodiment of this invention. FIG. 2 is a schematic partial cross-sectional side view of the heat exchanger apparatus along line II-II in FIG. 1. FIG. 3 is a cross-sectional view taken along line III-III in FIG. 2. FIG. 4 is a sectional view taken along line IV-IV in FIG. 2. It is a top view of the 1st heat exchanger plate of the heat exchanger apparatus of FIG. It is a top view of the 2nd heat exchanger plate of the heat exchanger apparatus of FIG. It is the schematic from above of the heat exchanger apparatus by the 2nd Embodiment of this invention. FIG. 8 is a schematic partial cross-sectional side view of the heat exchanger apparatus along line VIII-VIII in FIG. 7. It is sectional drawing along line IX-IX of FIG. It is a top view of the 1st heat exchanger plate of the heat exchanger apparatus of FIG. It is a top view of the 2nd heat exchanger plate of the heat exchanger apparatus of FIG. It is the schematic from above of the heat exchanger apparatus by the 3rd Embodiment of this invention. It is a general | schematic fragmentary sectional side view of the heat exchanger apparatus of FIG. It is the schematic from above of the heat exchanger apparatus by the 4th Embodiment of this invention. FIG. 15 is a cross-sectional view taken along line XV-XV in FIG. 14. FIG. 15 is a cross-sectional view taken along line XVI-XVI in FIG. 14. It is a schematic sectional drawing similar to sectional drawing of FIG. 16 of the heat exchanger apparatus by the 5th Embodiment of this invention.

Claims (34)

At least a first plate heat exchanger (1) and each plate heat exchanger includes a frame plate (2), a pressure plate (3), a first plate space (6) for condensing water vapor and a liquid A plurality of plate packages provided as plate packages adjacent to each other between the frame plate (2) and the pressure plate (3) so as to form a second plate space (7) for evaporating water. A heat exchanger apparatus having a number of plate heat exchangers (1) having heat transfer plates (4, 5),
Each plate heat exchanger (1)
A steam inlet channel (21) extending through the frame plate (2) and almost all the heat transfer plates (4, 5) and communicating with the first plate space (6);
At least a condensate outlet channel (22) extending through almost all the heat transfer plates (4, 5) and communicating with the first plate space (6);
A liquid inlet channel (23) extending through almost all the heat transfer plates (4, 5) and communicating with the second plate space (7);
In a heat exchanger apparatus having a steam outlet channel (24) extending through the frame plate (2) and almost all the heat transfer plates (4, 5) and communicating with the second plate space (7) ,
A housing forming a first outlet chamber adjacent to the frame plate and arranged to receive water vapor formed from the water vapor outlet flow path;
And a first liquid separator provided in the housing and adapted to take in liquid from the water vapor flowing through the first outlet chamber.   The device according to claim 1, characterized in that it comprises a first inlet chamber (33) arranged to feed water vapor into the water vapor inlet channel (21).   The first inlet chamber (33) is separated from the housing (30) and housed in a separate casing (34) adjacent to the frame plate (2). The device described in 1.   Device according to claim 2, characterized in that the first inlet chamber (33) is housed in the housing (30).   Device according to claim 4, characterized in that the first inlet chamber (33) and the first outlet chamber (31) are separated by an inner wall (46) in the housing (30).   The apparatus according to any one of claims 1 to 5, wherein the number of the plate heat exchangers (1) is at least one.   The apparatus comprises a compressor (40) arranged to send the formed water vapor from the first outlet chamber (31) to the first inlet chamber (33) and the water vapor inlet channel (21). 7. The device according to claim 2 and 6, characterized in that The number of the plate heat exchangers is at least two, the first outlet chamber (31) is adjacent to the frame plate (2) of both the first plate heat exchangers (1), and both Two such first plate heat exchangers (1) parallel to each other so as to be connected to the water vapor outlet channel (24) of the first plate heat exchanger (1) of
The first liquid separator (32) takes liquid from the water vapor coming from both the first plate heat exchangers (1), according to any one of the preceding claims. The device described.   The first inlet chamber (33) is connected to the water vapor inlet channel (24) of both the first plate heat exchangers (1), according to any one of claims 2 to 8 A device according to claim 1.   The housing has two substantially parallel side walls (50) facing each other, and the plate heat exchanger (1) extends outwardly from each side wall (50) in substantially opposite directions. 10. An apparatus according to any one of claims 8 and 9.   The number of plate heat exchangers (1) is at least two, and the apparatus comprises a first stage including at least the first plate heat exchanger (1) and at least one final plate heat exchanger ( 6. A device according to any one of the preceding claims, characterized in that it has a final stage comprising 1).   The housing (30) is adjacent to the frame plate (2) of the final plate heat exchanger (1) and is formed from the water vapor outlet channel (24) of the final plate heat exchanger (1). 12. A device according to claim 11, characterized in that it forms a final outlet chamber (31) arranged to receive the water vapor.   13. The device according to claim 2, wherein the device comprises a final inlet chamber (33) arranged to feed water vapor into the water vapor inlet channel (21) of the final plate heat exchanger (1). The device described in 1.   14. Device according to claim 13, characterized in that the final inlet chamber (33) is housed in the housing (30).   The first outlet chamber (31) is connected to the final inlet chamber (33), and the water vapor formed in the first plate heat exchanger (1) is transferred to the final plate heat exchanger (1). 15. The device according to any one of claims 13 and 14, characterized in that it can be sent to the water vapor inlet channel (21).   14. The apparatus according to claim 13, characterized in that it comprises a compressor (40) arranged to send the formed water vapor from the final outlet chamber (31) to the first inlet chamber (33). The device according to any one of 1 to 15.   The apparatus comprises a final liquid separator (32) provided in the final outlet chamber (31) and adapted to take in liquid from the water vapor flowing through the final outlet chamber (31). The apparatus according to any one of claims 12 to 16.   The housing (30) has at least one side wall (50), and the first plate heat exchanger (1) and the second plate heat exchanger (1) are outward from the side wall (50). 18. A device according to any one of claims 11 to 17, characterized in that they extend in substantially the same direction.   The housing has two substantially parallel side walls (50) facing each other, and the first plate heat exchanger (1) and the second plate heat exchanger (1) are respectively connected to the side walls (50). 18. Device according to any one of claims 11 to 17, characterized in that they extend outwardly from each other in substantially opposite directions. The apparatus comprises at least one intermediate plate heat exchanger (1) arranged such that an intermediate inlet chamber (33) feeds water vapor into the water vapor inlet channel (21) of the intermediate plate heat exchanger (1). At least one intermediate stage comprising
An intermediate outlet chamber (31) arranged to receive water vapor from the water vapor outlet flow path (24) of the intermediate plate heat exchanger (1);
21. Apparatus according to any one of claims 11 to 20, characterized in that the intermediate outlet chamber (31) communicates with the final inlet chamber (33) via an intermediate liquid separator (32).   21. Apparatus according to claim 20, characterized in that the apparatus comprises at least two successive intermediate stages, each having at least one intermediate plate heat exchanger (1).   21. Apparatus according to claim 20, characterized in that the apparatus comprises at least three successive intermediate stages, each having at least one intermediate plate heat exchanger (1).   12. The device according to claim 11, characterized in that it comprises a condenser (55) arranged downstream of the final outlet chamber (31) and condensing the water vapor sent to the final outlet chamber (31). The apparatus according to any one of claims 22 to 22.   The apparatus is adapted to operate through a supply of high pressure external water vapor and receives at least a portion of the water vapor sent to the final outlet chamber (31) and mixes this portion of water vapor with the external water vapor. 24. Apparatus according to claim 23, characterized in that it has a thermal compressor (60) adapted to form a mixture of water vapor that is fed to the first inlet chamber (33).   The apparatus is adapted to operate through a supply of high-pressure external water vapor and receives at least a portion of the water vapor sent to one of the final outlet chambers (31). 23. A thermal compressor (60) adapted to mix the external water vapor, wherein the mixture forms water vapor that is fed to the first inlet chamber (33). 24. The apparatus according to 23.   26. Apparatus according to any one of claims 11 to 25, characterized in that each stage has at least two plate heat exchangers (1).   The housing (30) has two substantially parallel side walls facing each other, and the plate heat exchangers (1) of each stage extend outward from the respective side walls (50) in substantially opposite directions. 27. Apparatus according to claim 26, characterized. Substantially each heat transfer plate has a first port hole (11) forming the water vapor inlet channel (21),
At least a second port hole (12) forming the condensate outlet channel (22);
A third port hole (13) forming the liquid inlet channel (23);
28. Device according to any one of the preceding claims, characterized in that it has at least a fourth port hole (14) forming the water vapor outlet channel (24).   Substantially each of the heat transfer plates (4, 5) has a central heat transfer region (15), and the first port hole (11) is disposed above the central heat transfer region (15), 29. Apparatus according to claim 28, characterized in that a fourth port hole is arranged below the central heat transfer area (15). The third port hole is disposed near an upper end of the central heat transfer region;
A dispersion that extends across the heat transfer plate (4, 5) along the upper end of the central heat transfer area (15) and is adapted to disperse the liquid throughout the central heat transfer area (15). 30. Apparatus according to claim 29, characterized in that the heat transfer plate is configured such that a space (16) is formed in each of the second plate spaces (7).   Each plate heat exchanger (1) has at least one elongated support member (17, 18) extending substantially perpendicularly from the frame plate (2), the heat transfer plate (4, 5) and the pressure plate Device according to any one of the preceding claims, characterized in that (3) is attached to the support member (17, 18).   Each plate heat exchanger (1) extends between the frame plate (2) and the pressure plate (3) and is arranged to allow the heat transfer plates (4, 5) to be compressed. 32. Device according to any one of the preceding claims, characterized in that it comprises a number of tie bolts (19) arranged. At least a first plate heat exchanger (1) and a final plate heat exchanger (1), each said plate heat exchanger (1) comprising a frame plate (2), a pressure plate (3), Between the frame plate (2) and the pressure plate (3), a first plate space (6) for condensing water vapor and a second plate space (7) for evaporating liquid are formed. A heat exchanger device having a number of heat transfer plates (4, 5) provided as a plate package adjacent to the plate package,
Substantially each heat transfer plate (4, 5) extends through the frame plate (2) and almost all of the heat transfer plates (4, 5) and is in water communication with the first plate space (6). An inlet channel (21);
A condensate outlet channel (22) extending through almost all the heat transfer plates (4, 5) and communicating with the first plate space (6);
A liquid inlet channel (23) extending through almost all the heat transfer plates (4, 5) and communicating with the second plate space (7);
In a heat exchanger apparatus having a steam outlet channel (24) extending through the frame plate (2) and almost all the heat transfer plates (4, 5) and communicating with the second plate space (7) ,
The apparatus has a housing (30) adjacent to the frame plate (2) of each plate heat exchanger (1), the housing being the water vapor outlet of the first plate heat exchanger (1). A first outlet chamber (41) arranged to receive water vapor formed from the flow path (24), and water vapor formed from the water vapor outlet flow path of the final plate heat exchanger (1). And a final outlet chamber (31) arranged in the heat exchanger device. Each plate heat exchanger (1) having at least a first stage including at least two first plate heat exchangers (1) and a second stage including at least two plate heat exchangers (1). ) To form a frame plate (2), a pressure plate (3), a first plate space (6) for condensing water vapor, and a second plate space (7) for evaporating liquid. A heat exchanger apparatus having a plurality of heat transfer plates (4, 5) provided as a plate package adjacent to each other between the frame plate (2) and the pressure plate (3),
Substantially each heat transfer plate (4, 5) extends through the frame plate (2) and almost all of the heat transfer plates (4, 5) and is in water communication with the first plate space (6). An inlet channel (21);
At least a condensate outlet channel (22) extending through almost all the heat transfer plates (4, 5) and communicating with the first plate space (6);
A liquid inlet channel (23) extending through almost all the heat transfer plates (4, 5) and communicating with the second plate space (7);
In a heat exchanger apparatus having a steam outlet channel (24) extending through the frame plate (2) and almost all the heat transfer plates (4, 5) and communicating with the second plate space (7) ,
The apparatus is adjacent to the frame plate (2) of each of the plate heat exchangers (1) and to the steam inlet channel (21) of the plate heat exchanger (1) of the first stage. A first inlet chamber (33) arranged to feed
A first outlet chamber (31) arranged to receive water vapor from the water vapor outlet flow path (24) of the plate heat exchanger (1) of the first stage;
A final inlet chamber (33) arranged to feed water vapor into the water vapor inlet channel (21) of the plate heat exchanger (1) of the second stage;
A housing (30) forming a final outlet chamber (31) arranged to receive water vapor from the water vapor outlet flow path (24) of the plate heat exchanger (1) of the second stage. Features heat exchanger device.

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