SE531267C2 - Plate heat exchanger and plate module - Google Patents

Description

The exchange plates, wherein substantially each heat exchanger plate has at least a first port hole and a second port hole, the first port holes forming an inlet channel for the refrigerant medium to the plate spacer and the the second port holes form an outlet channel for the refrigerant from the flat space TV and the inlet channel is designed to allow separation of the refrigerant in a main gas phase and a main hydrogen S-A phase.

The refrigerant supplied to the inlet duct with such a plate heat exchanger for evaporating the refrigerant is usually present in both the gas and liquid phases. It is thereby difficult to achieve an optimal distribution of the refrigerant to the various ones. the plate gaps in the evaporator so that an equal amount of refrigerant is supplied and flows through each plate gap intended for the refrigerant. If the refrigerant has a relatively high speed into the inlet duct, the liquid phase tends to be transported furthest into the inlet duct. If the refrigerant has a relatively low velocity, the liquid phase reaching only the plate gaps located in the plate heat exchanger tends furthest out in the inlet duct. It is difficult to achieve an optimal speed in this respect. It is known that this problem with the distribution. of the refrigerant can be at least partially dissolved by arranging a restriction of the refrigerant at each plate intermediate. In this way a pressure drop of the "refrigerant" is obtained when it enters .JJ1 in the respective plate gaps.

However, this solution is primarily suitable for relatively small evaporators but not large evaporators in industrial applications. SUMMARY OF THE INVENTION The object of the present invention is to provide an improved plate heat exchanger for evaporating a refrigerant. A further object is to provide such a plate heat exchanger which contributes to a good distribution of refrigeration. 267 _medium_to all plate gaps for the refrigerant. A further object is to provide such a flat heat exchanger which is compact and easy to manufacture. This object is achieved with the initially indicated plate heat exchanger which is characterized in that it comprises at least one primary passage for guiding the gas phase from the inlet duct to the inlet duct. first plate gaps and at least one secondary passage to direct the liquid phase from the inlet channel to the. the first plate gaps, the primary passage and the secondary passage meeting in an area for remixing the liquid phase in the gas phase for transporting this mixture further into the first plate gaps.

With such a plate heat exchanger, the gas phase and the liquid phase of the incoming refrigerant will be separated from each other and then remixed before entering the first plate gaps. The "separated gas phase" can be used to entrain a part of the liquid phase into each of the first plate gaps in such a way that the liquid phase is evenly distributed between all the first "plate gaps of the" plate heat exchanger.

According to an embodiment of the invention. the primary passage is designed to increase the velocity of the gas phase and to direct the gas phase to and past the liquid phase in such a way that liquid is remixed in the gas phase by means of ejector action. In this way, an effective mixing of the liquid-in-gas phase is achieved substantially immediately before the refrigerant is distributed in the first plate gaps. According to a further embodiment of the invention, the inlet channel is connected to at least one upper outlet which forms a wine outlet to the primary passage and at least one lower outlet which forms an inlet to the secondary passage.

In doing so, the primary passage can extend to the secondary passage. ” According to a further embodiment of the invention, the plate heat exchanger is adapted to be arranged in such a way that the lower outlet is located below the upper outlet, where it is located. 'at the lower outlet is dimensioned in such a way that it' 'allows liquid from the liquid phase to accumulate upstream of the lower outlet. In this case, the liquid in the liquid phase can accumulate in a lower part of the inlet duct, preferably along the substantially entire length of the inlet duct. In this way, there will always be liquid which can be carried by the gas phase in the primary passage to each of the first plate gaps. According to a further embodiment of the invention, the primary passage has a total minimum flow area and the secondary passage whereby the secondary passage minimum flow area is less than the minimum flow area of the primary passage. In this way it can be ensured that liquid accumulates upstream of the secondary passage and that the liquid is successively discharged from the inlet duct in a controlled manner.

According to a further embodiment of the invention, the heat exchanger plates are molded in such a way that a substantially closed channel is formed which extends around at least a part of the inlet channel in substantially each of the first plate gaps, these closed channels being comprised of the primary passage. In this way, the arrangement with the separate primary and secondary passages for the gas phase and the liquid phase, respectively, can be achieved in a simple manner during the compression molding of the heat exchanger plates. No additional components than the heat exchanger plates are necessary to achieve the desired function. Advantageously, the heat exchanger plates can then be molded in such a way that the upper outlet is designed as a channel which extends from the inlet; V the channel to the substantially closed channel i. Substantially each of the first plate gaps. Furthermore, the heat exchanger plates can also be compression molded in such a way that the lower outlet is formed as a channel extending from the inlet channel in substantially each direction. one of the first plate gaps. Even these two channels which form outlet V from the inlet channel can thus be achieved in a simple manner during the compression molding of the heat exchanger plates.

According to a further embodiment of the invention, the primary passage comprises two primary sections which from an area at an upper part of the inlet duct extend at different directions around the inlet duct, the two primary sections meeting substantially immediately downstream of the lower outlet. Thus, two upper outlets for each of the first flat gaps can extend from the inlet duct. Alternatively, the primary passage may be divided substantially immediately "downstream" around the upper outlet into two primary sections.

According to another embodiment of the invention, each heat exchanger plate is designed in such a way that it has a lower opening which is located below the first door hole and which is delimited from the first door holder by means of a first dividing section, the first dividing section being designed to allowing at least said liquid phase to pass the first dividing section and the lower openings forming a liquid channel extending through the plate package substantially parallel to the inlet channel. Even such an out-. forming can be accomplished in a simple manner by the mold pressing and punching of the heat exchanger plates. No additional 'A' additional components are required. In this case, the lower outlet can advantageously extend from the liquid channel. According to this embodiment. liquid can thus accumulate in the liquid channel, the liquid being successively discharged from the liquid channel in a controlled manner through the lower outlet; According to a further embodiment of the invention, each heat exchanger plate is designed in such a way that it has an upper opening which is delimited from the first gate holder by means of a second dividing section, the upper openings " 'forms.a gas duct extending through the plate package.pa-I, rallellt Amed' is accomplished-in connection with the molding and punching_of the heat exchanger plates.-Thereby the upper outlet can extend Vsig 'from the inlet duct to the gas duct and the closed duct inlet. len can extend from the gas channel.

According to yet another embodiment of the invention, the plate heat exchanger comprises a first tube extending through the first port holes of substantially each heat exchanger plate and forming the inlet duct. According to this embodiment, the plate heat exchanger can be provided with ordinary heat exchanger plates in the tube exchanger. The upper passage and the lower outlet can advantageously extend through the first pipe, the primary passage extending around at least a part of the first pipe. The primary passage will thus extend in the relatively narrow gap formed between the inlet duct and the outside of the first pipe. According to a further embodiment of the invention, the plate heat exchanger comprises a dividing plate arranged at an angle of inclination in the first pipe and extending along substantially the entire length of the inlet duct, upper the outlet is located above the delni the dividing plate and the lower outlet are located below the dividing plate and the dividing plate in a lower region has an opening for the liquid phase. Liquid can thus accumulate in a lower region of the first tube; especially in an area below the divider plate. According to a further embodiment of the invention, the plate heat exchanger comprises a second pipe extending into the first pipe along substantially the entire opening of such the inlet duct, whereby it is 10 '531 267 - In length, the second tube comprising at least one opening for discharging the gas phase and the liquid phase into the front. According to a further embodiment of the invention, the plate heat exchanger comprises a first end plate and a second end plate, between which the heat exchanger plates are arranged. Furthermore, substantially each heat exchanger plate may comprise a third port hole and a fourth port hole, the third H. the port holes form an inlet channel for said fluid to the "second plate gaps" and the fourth port holes form an outlet channel for said fluid from the second plate gaps thereby extending through the first end plate. The heat exchanger plates but. the outlet ducts can the inlet ducts and A can also be permanently connected to each other in pairs, each pair enclosing one of the first plate gaps. The object is also achieved with the initially indicated plate module which is characterized in that it comprises at least one primary passage for guiding the gas phase from the inlet duct to the plate gap and at least one secondary passage for guiding the liquid phase from the inlet duct to the secondary gap BRIEF DESCRIPTION OF THE DRAWINGS The present invention will now be explained in more detail by means of a description of various embodiments shown by way of example and with reference to the accompanying drawings.

Fig. 1 schematically shows a side view of a plate heat exchanger according to a first embodiment of the invention; Fig. 2 schematically shows a front view of the plate heat exchanger in Fig. 1. "s" schematically shows a plan view of a heat exchanger plate of the plate heat exchanger in FIG. 1.Wvf A _ I lg _, Fig._4 schematically shows a plan view of an area around _ a gate hole of the heat exchanger plate in Fig. 3. Q .Fig. 5 schematically shows a section through a number of heat? _ _ changer plates along the line V-V in Fig. 4. gFig. 6 ¿schematically shows a plan view of an area around a V-port hole of a heat exchanger plate according to a second embodiment of the invention, W _. _, _.

Fig. 7 schematically shows a plan view of an area around a gate hole of a heat exchanger plate according to a third embodiment of the invention.

DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS OF THE INVENTION Eigl_1 to 5 show a first embodiment of a plate heater according to the invention. The plate heat exchanger comprises a plate package P comprising a number of molded heat exchanger plates 1 arranged next to each other. The heat exchanger plates 1 are arranged in such a way that a first plate gap 3 is formed for a refrigerant between every second pair of adjacent heat exchanger plates 1 and a second plate gap 4 for a fluid between the other pairs of adjacent heat exchanger plates 1 and the second plate gaps are thus separated from each other and arranged next to each other in an alternating order in the plate package P ..

The plate heat exchanger further comprises a first end plate 5 and a second end plate 6, between which the heat exchanger plates 1 '1 are arranged. In the first embodiment shown in Figs. 1 and 2, the first end plate 5 is a so-called pressure plate and the second end plate 6 is a so-called frame plate;

The plate package P is held together in the first embodiment by means of a number of tension bolts 7 which extend outside the first heat plate spaces 1 but through the end plates 5 and 6. The plate package P is compressed by means of nuts 8. which are threaded on the draw bolts 7.

According to the first embodiment, the heat exchanger plates 1 are permanently permanently connected in pairs. The two heat exchanger plates 1 in each pair can thus be welded to each other by means of a weld joint 9, see Fig. 3. The heat exchanger plates 1 in a pair can also be soldered to each other, or permanently connected in another way. Such a permanently connected pair forms a plate module 10, see Fig. 5. The two heat exchanger plates 1. in the plate module 10 enclose between them one of the first plate gaps 3. In the plate package 3 the second plate gaps 4 are enclosed by the adjacent plate modules 10. In sealed by means of of gaskets 11 in a manner known per se. The other plate spacers 10 may be noted that the invention is also applicable to flat heat exchangers where each plate spacer 3, 4 "is sealed by gaskets, or plate heat exchangers where all heat exchanger plates 1 are soldered to a permanently connected plate. ket.

Substantially each heat exchanger plate 1 comprises a first gate hole 12, a second gate hole 12, a third gate hole 12 and a fourth gate hole 12, see Fig. 3. The first gate holes 12 enclose an inlet duct 13 for the refrigerant to the first plate gaps 3. The second the port holes 12 enclose an outlet duct 14 for the refrigerant from the first plate gaps 3. The third port holes 12 enclose an inlet channel 15 'for said fluid to the second plate gaps 4. The fourth port holes 12 enclose an outlet duct 16 for said fluid from the other plate gaps 4. In a central cmÄ "area" of 'each heat exchanger plate .A, “B xnellan. the port holes 12 ¿_ »“ Jfinns 'an -active -heat transfer area 18' sonx.are provided fi with a corrugation of ridges and valleys in a manner known per se. In V the embodiment scm shown in Pig »3 extends corrugated- '10 15 20 25 '30 35 531 26? the rings in a herringbone-like pattern, the corrugations of the adjacent heat exchanger plates 1 pointing in opposite directions. The heat transfer area 18 can, of course, have other types of patterns, cf. Fig. 4.

Each heat exchanger plate 1 has a downward center axis x, see Pig. 2 and 3. The heat exchanger plates 1 and the plate heat exchanger are in all the embodiments shown adapted to be arranged in such a way that the center axis x extends substantially vertically. The refrigerant inlet duct 13 and the fluid outlet outlet duct 16 will then be located near a lower end of the plate heat exchanger while the refrigerant outlet duct 14 and the fluid inlet duct 15 will be located near an upper end of the plate - the heat exchanger. In an evaporator application, the refrigerant preferably flows upwards through the plate heat exchanger. In the embodiments shown, the plate heat exchanger is formed in; a nwt-A power configuration. However, the invention is also applicable to a co-current configuration.

The refrigerant supplied to an evaporator is * normally a mixture of a gas and a liquid. In accordance with this invention, the gas must first be separated from the liquid {For this purpose, the inlet duct 13 is arranged to allow separation of the refrigerant entering the inlet duct 13 into a main gas phase and a main liquid phase. Thereafter, the gas phase and the liquid phase are to be led separated from each other to an area 19 in each of the first plate gaps 3. In the area 19, the liquid phase and the gas phase meet and remix with each other. In this way it is possible to control in particular the supply of liquid to different parts of the inlet duct V. and thus to ensure that the liquid is distributed evenly between each of the first plate gaps 3. The plate heat exchanger inside. ¿_Covers ~ for this purpose. at least one primary passage for directing the gas phase from the inlet channel 13 to the first plate gaps 3 'and at least one secondary passage for directing the liquid phase 13 from the inlet duct 13 to the first plate passages 13' to the first plate gaps 13 '. : meet in said area 19 in the vicinity of the first plate intermediate drums 3 for remixing the liquid phase into the gas phase. The primary passage is designed to increase the velocity of the gas phase and lead the gas phase to and past the liquid phase at a relatively high velocity in such a way that liquid is remixed in the gas phase by means of ejector action in said area 19. In particular with reference to Figs. 4 and 5, the first embodiment will be described in more detail. In these figures, the area around the inlet duct 13 is shown in more detail. According to. In the first embodiment, the primary passage, the secondary passage and the lower area 19 have been provided by compression molding of the heat exchanger plates 1. The primary passage comprises in substantially each of the first plate gaps 3 an upper outlet 20 formed as a channel extending from The primary passage further comprises in each of the first plate gaps 3 two substantially closed channels 21 extending from the upper outlet 20 around each half of the inlet channel 13 to said area 19 which is located below the inlet channel 13. The secondary passage comprises substantially each of the first plate gaps 3 a lower outlet 22 formed as a channel extending from the inlet channel 13 to said area 19 below the inlet channel 13; When the gas phase has been remixed with the liquid phase, liquid being supplied to the gas passing through the ejector action, the mixture leaves the lower region 19 and is discharged into the heat transfer region 18 in the first plate gap 3 via an annular channel 24 extending around the inlet channel 13 and the two closed channels 21 in each of the first plate gaps 3. The annular channel 24 has also been provided by the compression molding of the heat exchanger plates 1; Each heat exchanger plate 1 forms, on the side facing away from the ring-shaped primary passage and the secondary passage, a receiving area for the above-mentioned! gasket 11; see Fig. 5. The lower outlet 22 is dimensioned in such a way that it allows liquid from the liquid phase to accumulate in a lower area of the inlet channel 13 upstream of the lower outlet 13; The secondary passage then has in the lower outlet 22 a minimum flow area which is relatively small and smaller than a nun staff flow area of the primary passage. As shown above, the primary passage in the first embodiment divides into two primary sections extending from an area at an upper part of the inlet duct 13 in each direction - around the inlet duct 13. The two primary sections meet substantially immediately downstream of the lower outlet 22. However, it is also possible to provide two upper outlets in the inlet duct 13, one for each such primary section. In this case, there are thus two primary passages in each of the first plate gaps 3.

The second embodiment will now be described in more detail with reference to Fig. 6. According to the second embodiment, heat exchanger plates 1 are also used which are molded and punched in such a way that the primary passage and the secondary passage are provided. Each heat exchanger plate 1 is then molded and punched in such a way that it has the first port hole 12. Also in the second embodiment they form the first pmçté). the holes 12 inlet channel 13. Each heat exchanger plate also has a lower opening 30 which is below the first port hole 12. The lower opening 30 is delimited from the first door hole 12 by means of a: first dividing section 31. The lower openings 30 form a liquid channel 32 which extends substantially through the entire plate package 11. parallel to the inlet duct 13. The first dividing section 31 is designed to allow at least the liquid phase to be led »from the inlet duct '13 over dividing section 31 down to 220; 25 _30. The lower outlet 22 extends from the liquid channel 32 and more specifically through an axis 33 which defines the liquid channel 32 downwards; Each heat exchanger plate 1 is further molded and punched in such a way that it has an upper opening 34 which is delimited from the first door holder by means of a second dividing section ¿35. The upper openings 35 form a gas passage 36 which extends through substantially the entire plate package P substantially parallel to the inlet passage 13; the upper outlet 20 extends from the inlet passage 13 to the upper opening 35 and the gas passage 36 via the second dividing section 35 and more specifically around an upper ridge 37 which delimits the inlet channel 13 upwards and towards the gas channel 36. From the gas channel 36 and the upper outlet 20 the closed channel 21 extends to the area 19 where the gas phase, but below it the lower outlet 22. The mixture of the gas phase 'and the liquid phase is then transported from the area 19 to the heat transfer area 18 via an outlet channel 38 in each of the first plate gaps 3.

The third embodiment will now be described in more detail with reference to Fig. 7. According to the third embodiment, heat exchanger plates 1 are used which are arranged to drive. vda the first plate gaps 3 between each other pair of adjacent plates 1 and the second. plate gaps' 4 between other pairs of adjacent plates 1. The plates 1 can be connected to each other in all possible ways, for example pressed against each other between two end plates 5 and 6; According to the third embodiment, the plate heat exchanger comprises a first tube 40 which extends through the first ones transported through the closed channel 21, wears the liquid phase from the lower outlet. The area 19 is also according to the second embodiment of the first plate gaps 3,531,257 to the port holes 12 of substantially each heat exchanger plate 1. The first tube 40 forms the inlet duct 13. The upper outlet 20 and the lower outlet 22 extends through the tube 40, the primary passage extending around at least a portion of said tube. Preferably, an upper outlet 20 in the form of a hole is provided through the first tube 40 for each shape of a hole through the first tube 40 for each of the first plate gaps 3. Furthermore, a dividing plate 41 is provided in the first tube. The dividing plate 41 has an angle of inclination relative to the center axis x. The dividing plate 41 extends along substantially the entire length of the first tube 40 and the inlet channel 13. The upper outlet 20 is located above the dividing plate 41 and the lower outlet 22 is below the dividing plate 41. Furthermore, in a lower region, the dividing plate 41 has an opening 42 through which the liquid phase can pass. According to the third embodiment, the plate heat exchanger also comprises a second pipe 43 for supplying the refrigerant to the plate heat exchanger. The second pipe 43 extends into the first pipe 40 along substantially the entire length of the inlet duct 13. The second pipe 43 comprises at least one opening 44 for discharging the refrigerant, i.e. the gas phase and the liquid phase, into the first tube 40 above the dividing plate 41. The gas phase will thus be discharged through the upper outlets 20 and then pass through the primary passage along the outside of the first tube 40 down to said area 19 which is located From the area 19, mixture is transported out into the heat transfer area in each case below the lower outlet 22. and one of the first plate gaps 3.

The invention is not limited to the embodiments shown, but may be varied and modified within the scope of the appended claims. and a lower outlet 22 i_

Claims (22)

10 15 20 25 30 35 531 267 15 Patent claims A plate heat exchanger comprising a plate package (P) comprises a number of heat exchanger plates (1) arranged so next to each other that a first plate space (3) is formed for a refrigerant between every second pair of adjacent heat exchanger plates (1) and a second plate gap (4) for a fluid between the other pairs of adjacent heat exchanger plates (1), S If (3) and the second plate gaps (4) are separated from each other and arranged. the first plate gaps are located next to each other in an alternating order in the plate package (P), substantially each heat exchanger plate (1) having at least a first gate hole (12) and a second gate hole (12), the first gate holes (12) enclosing a the inlet duct (13) for the refrigerant to the first plate gaps (3) and the second port holes (12) (14) for the refrigerant from the first plate gaps (3), (13) are arranged to allow separation of the refrigerant in a main gas phase and a main liquid phase, enclosing an outlet channel, the inlet channel wherein the plate heat exchanger comprises at least one pri- (13) and at least one center passage for guiding the inlet duct to the first plate gaps (3) customer passage for 13) to the first plate gaps (3) and wherein the primary passage and the secondary passage meet in an area (19) transport of this mixture further into the first plate gaps (3), to the additional passage is designed to increase the velocity of the gas phase and lead the gas phase to and past the liquid phase in such a way that liquid is remixed in the gas phase by ejector action, that the primary passage has a total minimum flow area and for remixing the liquid phase into the gas phase characterized by 16 that the secondary passage has a total minimum flow area, wherein the minimum flow area of the secondary passage is smaller than the minimum flow area of the primary passage. Plate heat exchanger according to claim 1, characterized in that the inlet duct (13) is connected to at least one upper outlet (20) which forms an inlet to the primary passage and at least one lower outlet (22) which forms an inlet to the secondary passage . Plate heat exchanger according to claim 2, characterized in that the primary passage extends to the secondary passage. Plate heat exchanger according to one of Claims 2 and 3, characterized in that the plate heat exchanger is adapted to be arranged in such a way that the lower outlet (22) is located below (20), (22) is dimensioned in such a way that it allows: liquid from the liquid phase accumulates upstream of the lower outlet (22). the upper outlet with the lower outlet Plate heat exchanger according to any one of the preceding claims, characterized in that the heat exchanger plates (1) are molded in such a way that a substantially closed channel (21) is formed which extends around at least a part of the inlet channel (13) in substantially each of the first plate gaps (3), these closed channels (21) being included by the primary passage. Plate heat exchanger according to claims 2 and 5, characterized in that the heat exchanger plates (1) extend the upper outlet (20) from the inlet duct (13) to the substantially closed duct (21) in substantially each of the first plate intermediate spaces ( 3). are molded in such a way as to be designed as a channel extending 10 15 20 25 30 35 531 267 17 Plate heat exchanger according to claim 6, characterized in that the heat exchanger plates lower outlet (22) from the inlet duct (1) are molded in such a way that it is formed as a duct extending (13) in substantially each of the first plate gaps (3) . A plate heat exchanger according to any one of claims 2 to 7, may: characterized in that the primary passage comprises two primary sections extending from an area at an upper part of the inlet duct (13) in different directions around the inlet duct (13), the two the primary sections meet substantially immediately downstream of the lower outlet (22). Plate heat exchanger according to claim 8, characterized in that the primary passage divides substantially immediately downstream of the upper outlet (20) into the two primary sections. Plate heat exchanger according to one of Claims 1 to 5, characterized in that each substantially heat exchanger plate (1) is designed in such a way that it has a lower opening (30) which is located below the first door hole (12) and which is delimited from the first gate holder (12) by means of a first (31), the first dividing section being designed to allow at least said liquid phase (31) a liquid channel dividing section (31) passing the first dividing section (30) forming extending through the plate package (P) ( 13). and wherein the (32) substantially parallel lower openings as with the inlet channel 11. ll. Plate heat exchanger according to claims 2 and 10, in that the lower outlet (22) is smooth (32). characteristic extends from the liquid Plate heat exchanger according to one of Claims 10 and 11, characterized in that each heat exchanger plate (1) is designed in such a way that it has an upper opening (34) which is delimited from the first door holder. (12) by means of a second dividing section (35), the upper openings (34) forming a gas channel (36) extending through the plate package (P) parallel to the inlet channel (13). Plate heat exchanger according to claims 2 and 12, characterized in that the upper outlet (20) extends from the inlet duct (13) to the gas duct (6). Plate heat exchanger according to claims 5 and 13, in that the closed channel (36). characterized (21) extends from the gas duct Plate heat exchanger according to any one of claims 1 to 4, characterized in that the plate heat exchanger comprises a first sensing tube (40) extending through the first port holes (12) of substantially each heat exchanger plate (1) and forming the inlet duct (13) . A plate heat exchanger according to claims 2 and 15, (20) extends through said pipe characterized (22), the primary passage of the upper outlet and the lower outlet (40) extending around at least a part of said pipe (40). Plate heat exchanger according to claim 16, characterized in that the plate heat exchanger comprises a pitch plate (41) arranged at an angle of inclination in the first tube (40) and extending along substantially the entire length of the inlet duct (13), the upper outlet (20) is located above (41) and the lower outlet (22) is below the dividing plate (41) and wherein the dividing plate is located (41) in a lower region has an opening (42) for the liquid phase. Plate heat exchanger according to claim 17, characterized in that the plate heat exchanger comprises a second tube (43) extending into the first tube (40) along substantially the entire inward and extension direction. The flue channel (13) (43) comprises at least one opening (44) for discharging the gas phase and the liquid phase into the first pipe (41). length, the second tube Plate heat exchanger according to one of the preceding claims, characterized in that the plate heat exchanger comprises a first end plate (5) and a second end plate (6), the co-exchanger plates (1) are arranged. between which values Plate heat exchanger according to any one of the preceding claims, characterized in that substantially each heat exchanger plate (1) comprises a third port hole (12) and a fourth port hole (12), the third port holes (12) forming an inlet channel (15) for said fluid to the second plate gaps (4) and the fourth port holes (12) form an outlet channel (16) for said fluid from the second plate gaps (4). Plate heat exchanger according to one of the preceding claims, characterized in that the heat exchanger plates (1) are permanently connected in pairs to one another, one of the first plate gaps (3). each pair enclosing Plate module (10) exchanger, for a plate package (P) in a plate heater, wherein the plate module (10) (1) which are arranged next to each other so as to form a plate gap (3), the plates (1), comprise two heat exchanger plates for a refrigerant between heat exchangers, wherein substantially each heat exchanger plate (1) has at least a first port hole (12) and a second port hole (12), the first port holes (12) forming an inlet duct (13) for the refrigerant to the plate gap (3) and the second port holes (12) (14) for the refrigerant from the plate gap form an outlet duct (3), the inlet duct (13) being designed to allow separation of the refrigerant in one. main gas phase and a main liquid phase, the plate module (10) comprising at least one primary passage for guiding the gas phase from, the inlet channel (13) to the plate gap (3) and at least one secondary passage for leading the liquid phase from the inlet channel (13) to the plate gap (3) and wherein the primary passage and the secondary passage meet in an area (19) port of this mixture further into the plate gap (3), characterized by for remixing the liquid phase in the gas phase for trans- that the primary passage is designed to increase the gas phase velocity and lead the gas phase to and bypassing the liquid phase in such a way that liquid is remixed in the gas phase by ejector action, that the primary passage has a total minimum flow area and that the secondary passage has a total minimum flow area, the secondary passage minimum flow area being less than the primary passage minimum flow area.