SE526831C2 - Heat exchanger plate and plate package - Google Patents

Abstract

The invention refers to a heat exchanger plate ( 1 ) and a plate package for a plate heat exchanger. The heat exchanger plate extends between a primary edge zone ( 11 a) and a secondary edge zone ( 12 a). A centre axis (x) divides the heat exchanger plate in a primary part ( 11 ) and a secondary part ( 12 ). The heat exchanger plate includes a first end area ( 16 ), a second end area ( 17 ), and a central heat transfer area ( 18 ) therebetween. A primary porthole ( 21 ) and a secondary porthole ( 23 ) extend through the plate in the first end area and are surrounded by the respective adjoining edge area ( 25 ). The primary porthole is located on the primary part and the secondary porthole on the secondary part. A distribution area ( 26 ) extends on the first end area and has a base surface ( 27 ) extending from the primary porthole to the central heat transfer area. The base surface is inclined and located at an upper level at an upper plane in the proximity of the edge area of the primary porthole and sinks successively to a lower level in the proximity of a lower plate plane at secondary edge zone.

Description

a first end region, a second end region, a central heat transfer region extending between the primary edge zone and the secondary edge zone from the first end region to the second end region, a primary gate hole and a secondary gate hole; , which extend through the heat exchanger plate in the first end region and which are each surrounded by an adjacent edge region, the primary port hole being on the primary part and the secondary port hole on the secondary part, and a distribution region extending on the first end region and having a base surface extending from the primary port to the central heat transfer area.

In such plate heat exchangers, it is desirable that the main heat transfer takes place via the plates' central heat transfer area. The distribution areas adjacent to the port holes have the task of distributing the media in a uniform manner to the central heat transfer area so that heat transfer takes place evenly over the entire central heat transfer area. It is known to achieve such a distribution by means of special corrugations of the distribution area. These corrugations control the media flow in such a way that it is evenly distributed to the central heat transfer area. A disadvantage of such known distribution patterns is that they also contribute to an excessive pressure drop across the distribution area. Such a pressure drop impairs the efficiency of the plate heat exchanger and contributes to an excessive heat transfer outside the central heat transfer area.

A limitation in this context is the strength of the plate heat exchanger in the distribution area. In plate heat exchangers where the heat exchanger plates are permanently connected to each other, for example by soldering, strong tensile stresses arise in the plate package when media under high pressure are conducted through the plate heat exchanger. In plate heat exchangers which are compressed between a frame plate and a pressure plate, strong compressive stresses arise in the plate package due to the bias voltage. In order to withstand such tensile stresses and compressive stresses in the distribution range 10 15 20 25 30 35 526 831, there must be a certain number of contact points or contact points between adjacent heat exchanger plates. In brazed plate heat exchangers, the heat exchanger plates are connected to each other at these points or places. In order to withstand the different types of voltages, it is also important that these contact points are arranged substantially directly on top of each other, ie. that they form as straight a line as possible throughout the plate package.

SE-B-415 928 discloses a plate heat exchanger with a number of heat exchanger plates, each of which extends parallel to a central distribution plane. Each plate includes a first end region with a primary port hole and a secondary port hole, a second end region with a primary port hole and a secondary port hole, and a central heat transfer region extending from the first end region to the second end region. The port holes for the inlet and the outlet for one and the same fluid are arranged on the same side of the plate. The central heat transfer area has a corrugation which creates a number of passages which are designed in such a way that the passages are narrower at the side of the plate where the inlet and the outlet for the same fluid are located.

WO85 / 02670 discloses a plate heat exchanger with a number of heat exchanger plates, each of which extends parallel to a central distribution plane. Each plate includes a first end region with a primary port hole and a secondary port hole, a second end region with a primary port hole and a secondary port hole, and a central heat transfer region extending from the first end region to the second end region. The port holes for the inlet and the outlet for one and the same fluid are arranged on the same side of the plate. A first distribution area extends to the first end area and a second distribution area extends to the second end area. The distribution areas and the central heat transfer area have corrugations which extend in such directions that the flow resistance in the plate gaps between the distribution areas is less than the flow resistance in the plate gaps between the central heat transfer areas.

GB-A-2 054 817 discloses a plate heat exchanger with a number of heat exchanger plates each extending between a left edge and a right edge parallel to a central distribution plane, an upper plate plane and a lower plate plane. The central distribution plane comprises a center axis that divides the plate in the left part and a right part. The plate comprises a first end region, a second end region and a central heat transfer region, which extends between the left edge and the right edge from the first end region to the second end region between. An inlet port hole and an outlet port heel extend through the plate in the first end area and are each surrounded by an adjacent edge area. The inlet port hole is located on the left part and the outlet port hole on the right part. A distribution area extends to the first end area and has a base surface which appears to be parallel to the central plane of extension and which extends from the inlet port hole to the heat transfer area. One or more separate distribution means are attached to this base surface. The distribution means is designed in such a way that it is located at an upper level near the upper plate plane near the edge region of the inlet port and gradually descends to a lower level near the lower plate plane near the left edge.

SUMMARY OF THE INVENTION The object of the present invention is to provide a heat exchanger plate which is intended for a plate package in a plate heat exchanger and which comprises an improved distribution area.

A further object of the present invention is to provide such a heat exchanger plate which contributes to a low flow resistance in the distribution area. A further object of the present invention is to provide such a heat exchanger plate which contributes to a high strength of the plate heat exchanger in the distribution area.

This object is achieved with the initially indicated heat exchanger plate which is characterized in that the base surface is located at an upper level near the upper plate plane near the edge region of the primary port hole and gradually drops to a lower level near the lower plate plane near the secondary plate. edge zones. With such a design of the distribution area, the plate gap between two heat exchanger plates in the plate package can obtain an increasing cross-sectional area with increasing distance from the primary port hole which forms the inlet port of the plate package. More specifically, the height of the plate spacing will be relatively small in an area near the inlet gate and increase gradually in the direction of the opposite secondary edge zone. This design contributes to an even distribution of the medium that enters via the primary gate hole over the entire inlet to, ie. the width of, the central heat transfer area.

According to a further embodiment of the invention, the shape of the distribution area has been achieved by compression molding of the heat exchanger plate. In this way, this advantageous design of the distribution area can also be achieved in a simple manner at low cost. No additional components or elements need to be arranged in the plate package.

According to a further embodiment of the invention, the base surface gradually sinks along a boundary of the central heat transfer area from in the vicinity of the primary edge zone to in the vicinity of the secondary edge zone. In this way, the flow resistance of the medium to the more distant parts of the distribution area, seen from the primary port hole where the medium is intended to flow in, can be reduced so that an even distribution of the medium along the entire central heat transfer area is achieved. According to a further embodiment of the invention, the base surface sinks continuously from the upper level to the lower level.

It should be noted that the term "successive" refers not only to such a continuous lowering of the base surface but also, for example, a stepwise lowering of the base surface in such a way that the base surface forms a number of stepwise lower sections, each of which is substantially parallel to it. central distribution plane. The above-mentioned continuous lowering can be obtained with a substantially flat base surface or a slightly arched base surface.

According to a further embodiment of the invention, the distribution area and the base surface extend over substantially the entire first end area.

According to a further embodiment of the invention, the distribution area comprises a number of elevations and depressions, wherein substantially each elevation extends in a respective direction which runs from the primary port hole towards the central heat transfer area. Such elevations will thus direct the medium flowing from the primary port hole towards the central heat transfer area. Advantageously, substantially every elevation can reach up to the upper plane and substantially every depression can reach down to the lower plane. In this way, the elevations and depressions of adjacent heat exchanger plates in the plate package can form mutual supports against each other in the form of points, lines or areas.

According to a further embodiment of the invention, substantially each elevation has a length which is substantially shorter than the distance from the primary port hole to the central heat transfer area along the direction of the elevation. Because the elevations are shortened in this way, the medium will not be trapped in channels between the elevations but can flow freely and thus be distributed in a better way over the entire distribution area. Furthermore, the flow resistance can be kept at a low level by means of such short elevations. According to a further embodiment of the invention, substantially each depression extends substantially perpendicular to said respective direction of an adjacent elevation. The immersions have a very small effect on the flow. However, the depressions project into the adjacent plate gap and control the medium flowing there from the secondary part to the primary part with respect to this heat exchanger plate. In this case, essentially each immersion can extend in a respective direction which runs from the secondary port hole towards the central heat transfer area. Even substantially every immersion has the advantage of a length that is significantly shorter than the distance from the secondary port hole to the central heat transfer area along the direction of the immersion.

According to a further embodiment of the invention, each elevation and each depression has two ends and two longitudinal sides, wherein substantially each elevation located on the secondary part with one end extends to one long side of a depression and wherein substantially each down lowering located on the primary part with one end extending to one long side of an elevation. With such a placement of the elevations and depressions, a relatively free flow is achieved for the media flowing through the plate package and at the same time favorable support points are formed between adjacent heat exchanger plates. in particular, it should be mentioned that the guide points or guides are positioned so that they lie almost directly on top of each other throughout the plate package. Such a guide line which extends substantially straight through the entire plate package is particularly advantageous for absorbing the tensile stresses which arise in a plate heat exchanger where the plates are permanently connected to each other by, for example, soldering, or the compressive stresses which arise in a plate heat exchanger. where the plates are pressed against each other. According to a further embodiment of the invention, the heat exchanger plate is symmetrical with respect to the center axis in that most depressions have a shape and position corresponding to the shape and position of an elevation on the other side of the center axis, each immersion being designed to abut an elevation of an adjacent inverted heat exchanger plate in the plate package. The object is also achieved with the initially indicated plate package which is characterized in that the base surface is located at an upper level near the upper plate plane near the edge area of the primary port hole and gradually decreases to a lower level near the lower plate plane near the secondary edge zone. With such a design of the distribution area, the plate gap will have an increasing cross-sectional area with increasing distance from the primary port hole which forms the inlet port of the plate package. More specifically, the height of the plate spacing will be relatively small in an area near the inlet port and gradually increase in the direction of the opposite secondary edge zone. In this way, an even distribution of the medium arriving via the primary gate hole channel over the entire inlet to the central heat transfer area is achieved.

Advantageous embodiments of the plate package are specified in the dependent claims 15 to 26. Advantageously, the heat exchanger plates can then be arranged in an alternating order in such a way that the primary part in the first end region of a first heat exchanger plate adjoins the secondary part of an adjacent second heat exchanger. plate height, whereby the height of the plate gap gradually decreases from in the vicinity of the edge area of the primary port hole with respect to the first heat exchanger plate to in the vicinity of the secondary edge zone with respect to the first heat exchanger plate.

This height can decrease continuously or step by step. Furthermore, it should be mentioned that the heat exchanger plates can be arranged in an alternating order in such a way that the primary part in the first end region of a first heat exchanger plate adjoins the secondary part 10 of an adjacent second heat exchanger plate, wherein substantially each depression of the first heat exchanger plate abuts an elevation of the adjacent second heat exchanger plate. The heat exchanger plates can advantageously be permanently connected to each other.

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

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

Fig. 2 schematically shows a side view of the plate heat exchanger in Fig. 1.

Fig. 3 schematically shows a plan view of a heat exchanger plate of the plate heat exchanger in Fig. 1.

Fig. 4 shows a cross-sectional view through a plate package with heat exchanger plates along the line lV-1V in Fig. 3.

Fig. 5 schematically shows a side view of a plate heat exchanger according to a second embodiment of the invention.

DETAILED DESCRIPTION OF DIFFERENT EMBODIMENTS OF THE INVENTION Figs. 1 and 2 schematically show a plate heat exchanger according to a first embodiment of the invention. The plate heat exchanger comprises a number of heat exchanger plates 1, see Fig. 3, which are arranged next to each other in such a way that they form a plate package 2. In the first embodiment, the heat exchanger plates 1 in the plate package 2 are permanently connected to each other by, for example, soldering in a manner known per se. The plate heat exchanger comprises a first inlet port 4 and a first outlet port 5 for a first medium as well as a second inlet port 6 and a second outlet port 7 for a second medium. Each heat exchanger plate 1 in the embodiment shown has a substantially rectangular basic shape and extends between a primary edge zone 11a and a secondary edge zone 12a parallel to a central extension plane 13, an upper plate plane. 14 and a lower plate 15, see Fig. 4. The central extension plane 13 comprises a longitudinal center axis x which divides the heat exchanger plate 1 into a primary part 11 and a secondary part 12. Each heat exchanger plate 1 further comprises a first end area 16, a second end region 17 and a central heat transfer region 18. The central heat transfer region 18 extends between the primary edge zone 11a and the secondary edge zone 12a and from the first end region 16 to the second end region 17.

Each heat exchanger plate also comprises four gate holes 21, 23 each extending through the heat exchanger plate 1. These four gate holes 21, 23 in the heat exchanger plates 1 in the plate package 2 form the above-mentioned inlet and outlet ports 4-7. The port holes 21, 23 are located in the two end regions 16 and 17, forming a primary port hole 21 on the primary portion 11 of each of the first and second end regions 16, 17 and a secondary port hole 23 on the secondary portion 12 of each of the first and second end areas 16, 17. Each gate hole 21, 23 is surrounded by its respective adjacent edge area 25.

Each of the first end region 16 and the second end region 12 includes a distribution region 26 extending over substantially the entire respective end region 16,17 except for the port holes 21, 23. Each distribution region 26 has a base surface 27 extending over substantially the entire distribution base 26. The base surface 27 of the distribution areas 26 is inclined relative to the central plane of propagation 13 and is located at an upper level in the vicinity of the upper plate plane 14 near the edge region 25 of the primary port hole 21 and gradually decreases to a lower level near the lower the plane 15 in the vicinity of the secondary edge zone 12a. The base area 27 of the distribution areas 26 also extends successively along a boundary of the central heat transfer area 18 from in the vicinity of the primary edge zone 11a to in the vicinity of the secondary edge zone 12a. In the embodiment shown, the base surface 27 of the distribution areas 26 continuously decreases from the upper level to the lower level. It should be noted, however, that the base surface 27 can also sink stepwise between ever lower levels which are substantially parallel to the central plane of propagation 13.

The distribution area 26 of the two end areas 16, 17, see Fig. 3, further comprises a number of elevations 31 which rise from the base 27 to substantially the upper plane 14 and a number of depressions 32 which descend from the base 27 to substantially the lower plane. Substantially each elevation 31 extends in a respective direction extending from the primary port hole 21 towards the central heat transfer area 18. Substantially each elevation 31 has a length which is substantially shorter than the distance from the primary port hole 21 to the central heat transfer area 18 along the in the direction of the elevation 31 in question.

Correspondingly, substantially each depression 32 extends in a respective direction extending from the secondary port hole 23 toward the central heat transfer area 18. Consequently, substantially each depression 32 extends substantially perpendicular to the respective direction of an adjacent elevation 31, i.e. the directions of the elevations 31 and the depressions 32 are substantially orthogonal at the points where these directions meet. Also, substantially each immersion 32 has a length that is substantially shorter than the distance from the secondary port hole 23 to the central heat transfer area 18 along the direction of the immersion 32 in question. Substantially each recess 31 and substantially each recess 32 have two ends and two long sides. The elevations 31 and the depressions 32 are arranged in such a way that essentially each elevation 31 located on the secondary part 12 with one end extends to one long side of a depression 32 and substantially every depression 32 located on the primary part 11 with one end extends to one long side of a ridge 31.

The heat exchanger plate 1 is further symmetrical with respect to the longitudinal center axis x in that most depressions 32 have a shape and position corresponding to the shape and position of a ridge 31 on the other side of the longitudinal center axis x. Thanks to such symmetry and because every other heat exchanger plate 1 in the plate package 2 is rotated 180 °, each depression 32 will abut against an elevation 31 of an adjacent heat exchanger plate 1 in the plate package 2, see Fig. 4. This symmetry also means that the primary port hole 21 of the first end region 16 is located on the same side of the center axis x as the primary port hole 21 of the second end region 17, i.e. both primary port holes 21 are located on the primary part 11 and both secondary port holes are located on the secondary part 12.

It should be noted that a few elevations 33 and depressions 34 along the center axis x deviate from this symmetry in that these elevations and depressions 34 have been divided into two shorter elevations 33 and depressions 34 extending from two directions to a respective depression 32 and elevation. 31.

Essentially all the heat exchanger plates 1 in the plate package 2 are thus identical. In the first embodiment, the heat exchanger plates 1 are further permanently connected to each other by any suitable method such as soldering. Each elevation 31 is then permanently connected to a depression 32 of an adjacent heat exchanger plate 1. The heat exchanger plates 1 have been manufactured by compression molding in a heat exchanger plate 1 the zone 'IQ u I ø vc 13. steps of substantially flat plates. Preferably after the compression molding, the door holes 21-24 have been punched out of the heat exchanger plates 1. The distribution area 26 of the end areas 16, 17 has thus obtained its shape by said compression molding. In the same compression step, the central heat transfer area 18 has also obtained the shape shown with two corrugations 36 and 37 of ridges and valleys, see Fig. 3. The corrugation 36 adjoins the first end region 16 and the corrugation 37 adjoins the second end region 17. The corrugation 36 includes ridges and valleys forming channels 38 extending obliquely across the central heat transfer region 18 from the secondary edge zone 12a to the primary edge zone 11a with an angle of inclination approximately 45 ° with respect to the longitudinal center axis x. The channels 38 have a decreasing width. in such a way that the channels 38 are wider in the vicinity of the secondary edge zone 12a and taper gradually as the channels 38 approach the primary edge zone 11. Similarly, the corrugation 37 includes ridges and valleys forming channels 39 extending obliquely across the central heat transfer area. from the primary edge zone 11a to the secondary edge zone 12a with an angle of inclination approximately 45 ° relative to l the longitudinal center axis x, i.e. approximately perpendicular to the direction of the channels 38. Furthermore, the channels 39 also have an increasing width in such a way that the channels 39 are narrower in the vicinity of the primary edge zone 11a and become successively wider as the channels 39 approach the secondary edge zone 11.

Fig. 4 shows a section through the plate package 2. As can be seen, a plate gap 40 is formed between each adjacent pair of heat exchanger plates 1. The heat exchanger plates 1 are arranged in an alternating order such that the primary part 11 in the first end region of a first heat exchanger plate 1 adjoins the secondary part 12 of an adjacent second heat exchanger plate 1. Thus, the height of the plate gap 40 will gradually decrease from the edge area 25 of the primary port housing 21, 22 with respect to the first heat exchanger plate 1, or the secondary port hole 23, 24 n! 0 0 0100 II 0 n 00 00 0 OI g 0 0 0 0 000 0 UU 'g 0 0 0 I 9 .5 00 0000 I' 10 15 20 25 30 526 851 14 edge area 25 with respect to the second heat exchanger plate 1, to the secondary edge zone 12a with respect to the first heat exchanger plate 1, or to the primary edge zone 11a with respect to the second heat exchanger plate 1. In the embodiment shown, the height of the plate gap 40 decreases continuously.

Thus, in the illustrated embodiment, one medium will flow into the primary port hole 21 of the first end region 16 to the plate gap 40 in question and be distributed evenly over the entire width of the plate gap at the transition to the central heat transfer region 18. Thanks to the tapered channels 38 and thereafter the expanding channels 39 ensure an evenly distributed flow over the entire central heat transfer area 18. At the second end area 17, the elevations 31 of the distribution area 26 will lead the medium towards the primary port hole 21 where the medium leaves the plate gap 40.

Fig. 5 shows a plate heat exchanger according to a second embodiment which differs from the first embodiment in that the heat exchanger plates 1 are pressed against each other between a frame plate 50 and a pressure plate 51 by means of tension curves 52 in a manner known per se. The heat exchanger plates 1 have the same design as in the first embodiment with respect to the end areas 16 and 17 and the central heat transfer area 18.

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

Claims (26)

10 15 20 25 30 35 526 831 u c Q o o ø n; 15 Patent claims A heat exchanger plate for a plate package (2) for a plate heat exchanger, the heat exchanger plate (1) extending between a primary edge zone (11a) and a secondary edge zone (12a) parallel to a central spreading plane (13), an upper plate plane (14) and a lower plate plane (15), the central expansion plane comprising a center axis (x) dividing the heat exchanger plate (1) into a primary part (11) and a secondary part (12), and the heat exchanger plate comprising a first end region (16), a second end region (17), a central heat transfer region (18) extending between the primary edge zone (11a) and the secondary edge zone (12a) from the first end region (16) to the second end region (17), a primary port hole (21) and a secondary port hole ( 23), which extend through the heat exchanger plate (1) in the first end region (16) and which are surrounded by their respective adjacent edge region (25), the primary port hole (21) being located on the primary part (11) and the secondary port hole (23) on the secondary part (12), and a distribution area (26) extending on the first end area (16) and having a base surface (27) extending from the primary port hole (21) to the central heat transfer area (18), characterized in that the base surface (27) is located at a upper level in the vicinity of the upper plate plane (14) in the vicinity of the edge region (25) of the primary port hole (21) and gradually descends to a lower level in the vicinity of the lower plate plane (15) in the vicinity of the secondary edge zone (12a). Heat exchanger plate according to claim 1, characterized in that the shape of the distribution area (26) has been achieved by compression molding of the heat exchanger plate (1). Heat exchanger plate according to one of Claims 1 and 2, characterized in that the base surface (27) sinks successively along a boundary 10 to 20 20 25 30 35 526 851 - oouooo Q ao 16 to the central heat transfer area (18) from in the vicinity of the primary edge zone (11a) to in the vicinity of the secondary edge zone (12a). Heat exchanger plate according to one of Claims 1 to 3, characterized in that the base surface (27) sinks continuously from the upper level to the lower level. Heat exchanger plate according to one of the preceding claims, characterized in that the distribution area (26) and the base surface (27) extend over substantially the entire first end area (16). Heat exchanger plate according to any one of the preceding claims, characterized in that the distribution area (26) comprises a number of elevations (31) and depressions (32), wherein substantially each elevation (31) extends in a respective direction extending from the primary port hole (21). towards the central heat transfer area (18). Heat exchanger plate according to claim 6, characterized in that substantially each elevation (31) reaches up to the upper plate plane (14) and that substantially each depression (32) reaches down to the lower plate plane (15). Heat exchanger plate according to one of Claims 6 and 7, characterized in that substantially each elevation (31) has a length which is substantially shorter than the distance from the primary port hole (21) to the central heat transfer area (18) along the elevation (31). direction. Heat exchanger plate according to any one of claims 7 and 8, characterized in that substantially each depression (32) extends substantially perpendicular to said respective direction of an adjacent elevation (31). o I c oc: I O O I I 1 o nu I: o 10 15 20 25 30 35 526 831 c »o ø ou o I o Q o ø | oo 17 Heat exchanger plate according to one of Claims 6 to 9, characterized in that substantially each immersion (32) extends in a respective direction extending from the secondary port hole (23) towards the central heat transfer area (18). Heat exchanger plate according to one of Claims 9 and 10, characterized in that substantially each immersion (32) has a length which is substantially shorter than the distance from the secondary port hole (23) to the central heat transfer area (18) along the direction of the immersion (32). . Heat exchanger plate according to any one of claims 6 to 11, characterized in that each ridge (31) and each depression (32) has two ends and two long sides, wherein substantially each ridge (31) located on the secondary part (12) with one end extends to one long side of a depression (32) and wherein substantially each depression (32) located on the primary portion (11) with one end extends to one long side of a ridge (31). ). Heat exchanger plate according to one of Claims 6 to 12, characterized in that the heat exchanger plate (1) is symmetrical with respect to the center axis (x) in such a way that substantially each depression (32) has a shape and position corresponding to the shape and position of an elevation (31) on the other side of the center axis (x), each depression (32) being designed to abut an elevation (31) of an adjacent inverted heat exchanger plate (1) in the plate package ( 2). A plate package for a plate heat exchanger comprising at least two heat exchanger plates (1) with a plate gap (40) therebetween, each heat exchanger plate (1) extending between a primary edge zone (11a) and a secondary edge zone (12a) parallel to a central distribution plane (13), an upper plate (14) and a lower plate (15), the central spreading plane (13) comprising a center axis (x) dividing the heat exchanger plate 10 (20) in a primary part (11) and a secondary part (12), and wherein each heat exchanger plate (1) comprises a first end region (16), a second end region (17), a central heat transfer region (18) extending between the primary edge zone (11a) and the secondary edge zone (12a) from the first end region (16) to the second end region (17), a primary port hole (21) and a secondary port hole (23), which extend through the heat wax plate (1) in the first end region (16) and which are each surrounded by adjacent edge area (25), wherein pri the gate port (21) is located on the primary portion (11) and the secondary port hole (23) on the secondary portion, and a distribution area (26) extending on the first end region (16) and having a base surface (27) extending from the primary port hole (21) to the central heat transfer area (18). characterized in that the base surface (27) is located at an upper level in the vicinity of the upper plate plane (14) in the vicinity of the edge region (25) of the primary port hole (21) and gradually descends to a lower level in the vicinity of the lower plate plane (14). 15) in the vicinity of the secondary edge zone (12a). Plate package according to claim 14, characterized in that the heat exchanger plates (1) are arranged in an alternating order such that the primary part (11) in the first end region (16) of a first heat exchanger plate (1) adjoins the secondary part of an adjacent second heat exchanger plate (1), the height of the plate gap (40) gradually decreasing from in the vicinity of the edge region (25) of the primary port hole (21) with respect to the first heat exchanger plate (1) to in the vicinity of the secondary edge zone (12a) with respect to on the first heat exchanger plate (1). Plate package according to Claim 15, characterized in that the height of the plate space (40) decreases continuously. 10 15 20 25 30 35 (_37 Ä) CB CS CA! ... x I ~ no | ou ': | qq ven. 19 Plate package according to any one of claims 14 to 16, characterized in that the distribution area (26) comprises a number of elevations (31) and depressions (32), wherein substantially each elevation (31) extends in a respective direction extending from the primary port hole. (21) towards the central heat transfer area (18). Plate package according to claim 17, characterized in that substantially each elevation (31) reaches up to the upper plate plane (14) and that substantially each depression (32) reaches down to the lower plate plane (15). Plate package according to one of Claims 17 and 18, characterized in that substantially each elevation (31) has a length which is substantially shorter than the distance from the primary port hole (21) to the central heat transfer area (18) along the direction of the elevation (31). Plate package according to any one of claims 17 to 19, characterized in that substantially each depression (32) extends substantially perpendicular to said respective direction of an adjacent elevation (31). Plate package according to one of Claims 17 to 20, characterized in that substantially each depression (32) extends in a respective direction extending from the secondary port hole (23) towards the central heat transfer area (18). Plate package according to one of Claims 20 and 21, characterized in that substantially each immersion (32) has a length which is substantially shorter than the distance from the primary port hole (21) to the central heat transfer area (18) along the direction of the immersion (32). Plate package according to one of Claims 17 to 22, characterized in that each elevation (31) and each immersion (32) has two gyms; æxæs. = ";": f_ f; 20 ends and two long sides, substantially each elevation (31) located on the secondary part (12) with one end extending to one long side of a depression (32) and wherein substantially each depression (32) located extends on the primary part (11) with one end extending to one long side of a ridge (31). Plate package according to one of Claims 17 to 23, characterized in that the heat exchanger plates (1) are arranged in an alternating order in such a way that the primary part (11) in the first end region (16) of a first heat exchanger plate (1) adjoins the secondary the part (12) of an adjacent second heat exchanger plate (1), wherein substantially each depression (32) of the first heat exchanger plate (1) abuts a ridge (31) of the adjacent second heat exchanger plate (1). Plate package according to one of Claims 14 to 24, characterized in that substantially all of the heat exchanger plates (1) are identical. Plate package according to one of Claims 14 to 25, characterized in that the heat exchanger plates (1) are permanently connected to one another.