DE102005010341A1 - Plate type heat exchanger has short ridges and grooves to ensure non impeded flow without fluid trapped in pockets - Google Patents

Abstract

A plate type heat exchanger with improved flow has a pattern of ridges (31) and grooves (32) between the central heat exchanger area (18) and the primary (21) and secondary (23) connections. The length of the grooves and ridges is less than the spacing between the primary/secondary connections and the central area with the grooves at right angles to the ridges. The ridges reach to the top wall of the plate while the grooves reach to the bottom wall of the plate. The short ridges and grooves are set at right angles to each other to ensure a good mixing of the flow.

Description

BACKGROUND OF THE INVENTION AND PRIOR ART

The The present invention relates to a heat exchanger plate for a plate pack for one Plate heat exchanger, which heat exchanger plate between a primary and a secondary one Edge zone parallel to a central plane of extent, an upper and a lower plate plane, wherein the central extension plane having a central axis, the heat exchanger plate to a primary and a secondary one Part divided, and the heat exchanger plate a first end portion, a second end portion, a central one Heat transfer area, the between the primary and the secondary Edge zone from the first and the second end region runs, a primary and a secondary one Connection port, which run through the heat exchanger plate in the first end region and each surrounded by an adjacent edge region, wherein the primary port opening in the primary and the secondary port opening in the secondary Lie part, as well as a distribution range, which is on the first end portion extends and a number of projections and Contains depressions, wherein substantially each projection along a respective associated path from the primary port opening to the central heat transfer area runs.

The Invention also relates to a plate pack for a plate heat exchanger, the at least two heat exchanger plates having a gap between them, each heat exchanger plate between a primary and a secondary one Edge zone parallel to a central plane of extension, one upper plate level and a lower plate level, the central extension plane has a central axis, which is the heat exchanger plate to a primary and a secondary one Part divided and each heat exchanger plate a first end portion, a second end portion, a central one Heat transfer area, the between the primary and the secondary Edge zone extends from the first to the second end, a primary and a secondary one port opening in the heat exchange plate in the first end region, by an associated adjacent edge region are surrounded, the primary port opening in the primary section and the secondary port opening in the secondary Lie part, and has a distribution area, which is on the first end portion extends and a number of projections and Recesses having substantially all the projections itself along an associated, from the primary port opening to the central heat transfer area extend extending path.

at such heat exchanger plates is desired that the main heat transfer in the central heat transfer area he follows. The to the connection openings adjacent distribution areas have the function, the mean evenly on the central heat transfer area so to distribute that the heat transfer distributed evenly throughout the distribution area. It is known, such distribution by means of special corrugations in To create distribution area. These curls lead the flow so that they spread evenly over the central heat transfer area distributed. A disadvantage of such known distribution ranges is Also, they cause too high a pressure drop across the distribution area contribute. Such a pressure drop degrades the efficiency of the plate heat exchanger and contributes too much heat transfer outside the central heat transfer area at.

A restriction in this context, the strength of the plate heat exchanger in the distribution area. In plate heat exchangers, their heat transfer plates permanently joined together - eg. brazed - are, arise in the plate pack high tensile stresses when heat exchange medium be passed under high pressure through the plate heat exchanger. In plate heat exchangers, which are compressed between a frame and a printing plate, arise in the plate pack as a result of bias high compressive stresses. In order to withstand these tensile and compressive stresses in the distribution area, must be determined between adjacent heat transfer plates one Number of contact points or points. In brazed heat exchangers are the heat transfer plates on soldered to these points or points. To resist the various tensions, so too important that these contact points are essentially one on top of the other, i.e. on a straight line, lying through the entire plate package line.

SE-B-415 928 discloses a plate heat exchanger having heat exchanger plates each extending parallel to a central plane of extent. Each plate has a first end portion having a primary and a secondary port, a second end portion having a primary and a secondary port, and a central heat transfer region extending from the first to the second end portion. The connection openings for the inlet and outlet of one and the same heat exchange medium are on the same side of the plate. The central heat transfer area has corrugations that produce a number of passages designed to be connected to the inlet and outlet sides of the plate Drain are thinner for one and the same heat exchange medium.

The WO 85/02670 discloses a plate heat exchanger with heat transfer plates, each extending parallel to a central plane of extent. The plates each have a first end portion with a primary and a secondary port, a second end portion with a primary and a secondary port as well a central heat transfer area on, which extends from the first to the second end region. The connection openings for the Inlet and outflow of the same heat exchange agent are on the same plate side. A first distribution area extends in the first and a second distribution area in the second end area. The Distribution areas and the central heat transfer area have corrugations on, which run so that the flow resistance in the space between the distribution areas of the plates is lower than in the space between the central heat transfer areas.

The GB-A-2 054 817 teaches a plate heat exchanger with heat exchanger plates, each parallel between a left and a right edge to a central extent level as well as an upper and a lower plate level. The central extension level has a central axis connecting the plate to a left and a right part divided. The plate has a first and a second end as well a central heat transfer area, which is between the left and the right edge from the first to the second end portion extends. An inlet and a drain port extend in the first end area through the plate and are from an adjacent one Surrounded edge area. The inlet connection opening is in the left part, the drain connection opening in the right part. A distribution area extends in the first end area and has a footprint, which seems to lie parallel to the central plane of extent and itself from the inlet connection opening to the heat transfer area extends. At this base are one or more separate distribution elements attached. The distribution element is designed to be close to the top plate level near the edge portion of the inlet connection opening is at an upper level and nearby the lower plate level near the left edge successively to a lower altitude decreases.

SUMMARY OF THE INVENTION

aim The present invention is a heat exchanger plate for a Plate pack in a plate heat exchanger, which has an improved distribution range.

One Another object of the present invention is such a heat exchanger plate, which leads to a low flow resistance contributes in the distribution area.

additional The aim of the present invention is such a heat exchanger plate, resulting in a high strength of the plate heat exchanger in the distribution area contributes.

This The aim is achieved in the heat exchanger plate specified above, that at least in a central part of the distribution area essentially every projection has a length that is significantly shorter as the distance between the primary port and the central heat transfer area in the direction of the projection.

M.a.W. let yourself say that the protrusions, in the prior art from the primary port to the central heat transfer area run to shorter projections have been split. By such projections that from the primary port to central heat exchange area flowing Heat transfer medium out. There the projections shortened in this way, comes the heat transfer medium in the passages between the projections not to stop, but can flow freely over the distribute the entire distribution area. Furthermore, it is possible with such shorter ones projections the flow resistance keep lower.

To an embodiment of the invention reach at least in a central part of the distribution area essentially all the projections the upper and substantially all wells the lower plate plane. That way you can the projections and depressions of adjacent heat exchange plates in the plate pack mutual supports in point, line or surface form.

According to a further embodiment of the invention, substantially all depressions extend substantially perpendicular to the direction of an adjacent projection. The depressions hardly affect the flow. However, they protrude into the adjacent plate interspace and carry the medium flowing therefrom from the secondary to the primary part with respect to this heat exchanger plate. Substantially all wells may then pass along an associated path from the secondary port to the central heat transfer region. Also, in a middle part of the distribution area, each recess advantageously has a length that is much shorter as the distance from the secondary port to the central heat transfer area toward the well. According to a further embodiment of the invention, each projection and recess has two ends and two long sides, with substantially each projection lying in the secondary part extending with one of the ends to one of the long sides of the recess and substantially each recess, which lies in the primary part, extends with one end to one of the long sides of a projection. In such an arrangement of the projections and depressions to achieve a relatively free flow of the fluid in the plate pack; At the same time advantageously support points between adjacent heat exchanger plates form. In particular, it should be noted that the support points or lines are so that they lie through the entire plate package through almost straight above the other. Such a support line, which runs substantially straight through the entire plate package, is particularly advantageous for absorbing the tensile stresses that occur in a plate heat exchanger when the plates are permanently joined together - for example. Brazed - are, or the compressive stresses in a plate heat exchanger Pressing on the plates occur.

To a further embodiment The invention is the heat exchanger plate in terms of the central axis symmetrical, in such a way that most wells have a shape and position that the shape and position of a projection on the other side correspond to the central axis, with the depressions so executed are that they each have a projection on an adjacent one turned heat exchanger plate abut in the plate pack.

To a further embodiment According to the invention, the distribution area has a base area from the primary port opening to the central heat transfer area extends as well as nearby the edge area of the primary port opening on an upper level near the upper level is located and nearby the second edge zone successively to a lower level in the Near the lower plate level drops. With such an execution of Distribution area can be the space between two heat transfer plates in the plate pack with increasing distance from the primary port, which forms the inlet connection of the plate pack, increase in cross-section. In particular, the height the plate gap in a region at the inlet connection port relative be small and opposite secondary Edge zone gradually increase. This construction contributes to one even distribution of the primary port opening introduced fluid over the entire Feed, i. the width contributes to the central heat transfer area.

To a further embodiment the invention decreases the base area along a boundary to the heat transfer area from near the primary until near the secondary Edge zone down. In this way, the flow resistance of the fluid to more distant parts of the distribution area - seen from the primary connection opening, where the fluid to be initiated - reduced, so that you have a uniform distribution of the fluid over the entire central heat transfer area receives.

To a further embodiment the invention decreases the base area from the upper to the lower level steadily. It should be noted that the term "successive" is not just one steady decrease of the base area, but also, for example, a gradual decrease of the same denote should be such that the footprint a lot of lower paragraphs forms, each substantially parallel to the central plane of extent run. The mentioned steady lowering reach with a substantially flat or slightly curved base.

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

To a further embodiment The invention achieves the shape of the distribution area Printing forms of the heat exchanger plate. That way this advantageous structure of the distribution area also on simple way and inexpensive to reach. In the plate package do not need other components or elements to be provided.

The set goal also achieve this with the disk package defined above that essentially all projections have a length at least in a middle part of the distribution area, the much shorter is the distance between the primary port and the central heat transfer area in the direction of the projection. From such projections and depressions is the in the plate gap from the pri mary connection opening to central heat transfer area flowing Fluid guided. There the projections shortened are, that becomes fluid in the passages between the projections not stopped, but can flow freely, so that it is about spread the entire distribution area better. Furthermore, it is possible by means of such short projections the flow resistance keep it low.

advantageous embodiments of the plate pack are given in the subclaims 14 to 24. With Advantage let the heat exchanger plates themselves alternately arrange so that the primary part in the first end area a first heat exchanger plate at the secondary Part of an adjacent secondary heat exchanger plate is, wherein substantially all the wells of the first heat exchanger plate abut a projection of the adjacent secondary heat exchanger plate. The heat exchanger plates can be permanently joined together with advantage.

BRIEF DESCRIPTION OF THE DRAWINGS

The The present invention will now be described by way of various examples embodiments and the attached Drawings in more detail described.

1 shows a perspective elevation of a plate heat exchanger according to the invention;

2 shows the plate heat exchanger the 1 as a perspective side view;

3 shows a heat exchanger plate of the plate heat exchanger of 1 as a perspective elevation;

4 shows a section through a plate pack of heat exchanger plates in the plane IV-IV of 3 ; and

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

DETAILED DESCRIPTION DIFFERENT EMBODIMENTS THE INVENTION

The 1 and 2 show diagrammatically a plate heat exchanger according to a first embodiment of the invention. The plate heat exchanger has a number of heat exchanger plates 1 (Comp. 3 ), side by side to a plate pack 2 are arranged. In the first embodiment, the heat exchanger plates 1 in the record package 2 in a known manner permanently connected to each other - for example. Hard soldered. The plate heat exchanger has a first inlet connection 4 and a first drain port 5 for a first heat exchange medium and a second inlet connection 6 and a second drain port 7 for a second heat exchange medium.

In the disclosed embodiment, each heat exchanger plate 1 a substantially rectangular basic shape and it extends between a primary edge zone 11a and a secondary edge zone 12a parallel to a central extension plane 13 , an upper plate level 14 and a lower panel level 15 (Comp. 4 ). The central extension plane 13 has a longitudinal central axis x, which is the plate heat exchanger 1 to a primary part 11 and a secondary part 12 divided. Furthermore, each heat exchanger plate has 1 a first end area 16 , a second end area 17 and a central heat transfer area 18 , The central heat transfer area 18 extends between the primary and secondary edge zones 11a . 12a and from the first to the second end region 16 . 17 ,

Each heat exchanger plate also contains four connection openings 21 . 23 , respectively through the heat exchanger plates 1 run. The four connection openings 21 . 23 in the heat exchanger plates 1 of the disk pack 2 form the mentioned inlet and outlet connections 4 - 7 , The connection openings 21 . 23 lie in the two end areas 16 . 17 and form a primary port 21 in the primary part 11 the first and the second end region 16 . 17 and a second connection opening 23 in the secondary part 12 each first and second end region 16 . 17 , The connection openings 21 . 23 are each from an adjacent edge area 25 surround.

The first and the second end area 16 . 12 also has a distribution area 26 on, extending over substantially the entire associated end region 16 . 17 - with the exception of the connection openings 21 . 23 - extends. Each distribution area 26 has a floor space 27 which runs over substantially the entire distribution area. The base area 27 of the distribution area 26 lies obliquely with respect to the central plane of extent 13 ; it lies on the edge area 25 the primary connection opening 21 at an upper level near the upper plate level 14 and gradually decreases to a lower level near the lower plate level 15 at the second edge zone 12a from. The base area 27 of the distribution area 26 also drops along a boundary to the central heat transfer area 18 from the primary edge zone 11a to the secondary edge zone 12a down. In the illustrated embodiment, the base area decreases 27 of the distribution area steadily from the upper to the lower level. It should be noted, however, that the footprint 27 can gradually drop over several lower levels, which are substantially parallel to the central plane of extent 13 run.

The distribution area 26 both end areas 16 . 17 (Comp. 3 ) contains a plurality of protrusions 31 which is essentially up to the top board plane 14 from the base 27 protrude, as well as a variety of wells 32 that of the base area 27 essentially to the lower plate level 15 protrude downwards. Essentially all projections 31 extend along an associated path from the primary port 21 to the central heat transfer area 18 , Essentially all projections 31 have - at least in a middle part of the distribution area - a length that is substantially shorter than the distance from the primary connection opening 21 to the central heat transfer area 18 in the direction of the respective projection 31 ,

Accordingly, essentially all depressions extend 32 along an associated path from the secondary port 23 to the central heat transfer area 18 , Consequently, essentially all depressions lie 32 substantially perpendicular to each adjacent projection 31 ie the projections 31 and the depressions 32 Where they intersect, they are essentially at right angles to each other. Also have all the wells 32 at least in a central part of the distribution area a length which is considerably shorter than the distance from the secondary connection opening 23 to the central heat transfer area 18 in the direction of the respective depression 32 , The paths of the projections 31 and the wells 32 can be rectilinear or light - for example, approximately S-shaped - curved.

Essentially all projections 31 and depressions 32 have two ends and two long sides. The projections 31 and depressions 32 are arranged so that essentially every projection 31 on the second part 12 with one of the ends to a long side of a recess 32 towards and essentially every depression on the primary part 11 with one end to a long side of a projection 31 goes.

Furthermore, the heat exchanger plate 1 symmetrical with respect to the longitudinal central axis x, in such a way that most depressions 32 a shape and position according to the shape and position of a projection 31 on the other side of the longitudinal central axis x have. Thanks to this symmetry and every second heat exchanger plate 1 in the record package 2 rotated by 180 °, touches each depression 32 a lead 31 an adjacent heat exchange plate 1 in the record package 2 (Comp. 2 ). The symmetry also means that the primary connection opening 21 in the first end area 16 on the same side of the central axis x as the primary connection opening 21 of the second end region 17 lies, ie both primary connection openings 21 lie in the primary part 11 and both secondary ports in the secondary part 12 ,

It should be noted that a small number of protrusions 33 and depressions 34 along the central axis x deviate from this symmetry, since these projections 33 and depressions 34 to two shorter protrusions 33 and depressions 34 are divided from two directions to a depression 32 or a lead 31 to go.

Consequently, substantially all heat exchanger plates 1 in the record package 2 identical. In the first embodiment, the heat exchanger plates 1 also in a suitable manner - for example, by brazing - permanently joined together. Every lead 31 is then permanent with a depression 32 an adjacent heat exchanger plate 1 connected.

The heat exchanger plates 1 were made by compression molding in one step from substantially flat sheets. Preferably, after molding, the connection openings 21 . 24 from the plates 1 punched. The distribution area 26 the end areas 16 . 17 So received his form by the molding. In the same molding step also receives the central heat transfer area 18 the given shape with two corrugations 36 . 37 from ribs and valleys (cf. 3 ). The curl 36 adjoins the first end area 16 , the curl 37 to the second end area 17 , The curl 36 has ridges and valleys, the canals 38 form, with an inclination angle of about 45 ° to the longitudinal central axis x of the secondary to the primary edge zone 12a respectively. 11a diagonally across the central heat transfer area 18 run. The channels have a decreasing width in such a way that the channels 38 near the secondary edge zone 12a are wider and become the primary edge zone 11a to progressively rejuvenate. The corrugation points in the same way 37 Ridges and valleys on the channels 39 form, with an inclination angle of about 45 ° to the longitudinal central axis x, ie approximately perpendicular to the direction of the channels 38 obliquely across the central heat transfer area from the primary to the secondary edge zone 11a respectively. 12a run. Continue to have the Knäle 39 an increasing width such that they are near the primary edge zone 11a are thinner and with the approach to the secondary edge zone 12 get wider.

The 4 shows a section through the plate pack 2 , As can be seen, each form two adjacent heat exchanger plates 1 between them a plate gap 40 , The heat exchanger plates are alternately arranged so that the primary part 11 in the first end region of a first heat exchanger plate 1 on the second part 12 an adjacent heat exchanger plate 1 is applied. Consequently, the height of the plate gap decreases 40 successively from the edge area 25 the pri mary connection opening 21 . 22 with respect to the first heat exchanger plate 1 - or from the edge area 25 the secondary connection opening 23 . 24 with respect to the second heat exchanger plate 1 - to the secondary edge area 12a with respect to the first heat exchanger plate 1 - or to the primary edge area 11a with respect to the second heat exchanger plate 1 , In the illustrated embodiment, the height of the plate gap steadily decreases.

Thus, in the disclosed embodiment, one of the fluids flows into the primary port 21 of the first end region 16 to the corresponding plate gap 40 and is distributed there at the transition to the central heat transfer area over its entire width. Thanks to the rejuvenated channels 38 and the subsequently expanded channels 39 is a uniformly distributed flow over the entire central heat transfer area 18 guaranteed. In the second end area 17 lead the projections 31 of the distribution area 26 the fluid to the primary port 21 where there is the plate gap 40 leaves.

The 5 shows a plate heat exchanger according to a second embodiment, which differs from the first in that the heat exchanger plates 1 between a frame plate 50 and a printing plate 51 by means of draw bolts 52 be pressed in a known manner to each other. The heat exchanger plates 1 are in terms of end areas 16 . 17 and the central heat transfer area 18 constructed identically with the preceding embodiment.

The The invention is not limited to the disclosed embodiments, but rather let yourself within the scope of the following claims vary and modify.

Claims (24)

Heat exchanger plate for a plate pack ( 2 ) for a plate heat exchanger located between a primary edge zone ( 11a ) and a secondary edge zone ( 12a ) parallel to a central extension plane ( 13 ), an upper disk level ( 14 ) and a lower panel level ( 15 ), wherein the central plane of extent has a central axis (x), the heat exchanger plate ( 1 ) to a primary part ( 11 ) and a secondary part ( 12 ), and wherein the heat exchanger plate comprises: a first end region ( 16 ); a second end region ( 17 ); a central heat transfer area ( 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 ) extends; a primary port ( 21 ) and a secondary port ( 23 ), which in the first end region ( 16 ) through the heat exchanger plate ( 1 ) and from an associated adjacent edge region ( 25 ), wherein the primary port ( 21 ) in the primary part ( 11 ) and the secondary port ( 23 ) in the secondary part ( 12 ) lie; and a distribution area ( 26 ), which in the first end region ( 15 ) and a number of protrusions ( 31 ) and depressions ( 32 ), wherein essentially each projection ( 31 ) along an associated path extending from the primary port ( 21 ) to the central heat transfer area ( 18 ), characterized in that substantially each projection ( 31 ) has a length at least in a central part of the distribution area that is significantly shorter than the distance from the primary connection opening ( 21 ) to the central heat transfer area ( 18 ) in the direction of the projection ( 31 ). Heat exchanger plate according to claim 1, characterized in that essentially all projections ( 31 ) the upper plate level ( 14 ) and essentially all depressions ( 32 ) the lower plate level ( 15 ) to reach. Heat exchanger plate according to one of claims 1 and 2, characterized in that substantially all depressions ( 32 ) substantially perpendicular to the direction of a respective adjacent projection ( 31 ). Heat exchanger plate according to one of claims 1 to 3, characterized in that substantially all depressions ( 32 ) along a respectively associated path extending from the secondary port ( 23 ) to the central heat transfer area ( 18 ). Heat exchanger plate according to one of claims 3 and 4, characterized in that substantially each depression ( 32 ) has a length at least in a central part of the distribution area that is significantly shorter than the distance from the secondary connection opening ( 23 ) to the central heat transfer area ( 18 ) in the direction of the depression ( 32 ). Heat exchanger plate according to one of the preceding claims, characterized in that all the projections ( 31 ) and depressions ( 32 ) each have two ends and two long sides and that essentially all the projections ( 31 ) in the secondary part ( 12 ) with one of the ends to one of the long sides of a depression ( 32 ) and essentially all depressions ( 32 ) in the primary part ( 11 ) with one of the ends to one of the long sides of a projection ( 31 ). Heat exchanger plate according to one of the pre Henden claims, characterized in that the heat exchanger plate ( 1 ) is symmetrical with respect to the central axis (x) such that substantially all depressions have a shape and a position corresponding to the shape or position of a projection ( 31 ) on the other side of the central axis (x), each depression ( 32 ) is constructed so that it is at a projection ( 31 ) of an adjacent turned heat exchanger plate ( 1 ) in the disk pack ( 2 ) is present. Heat exchanger plate according to one of the preceding claims, characterized in that the distribution area ( 26 ) a base area ( 27 ), which extends from the primary port ( 21 ) to the central heat transfer area ( 17 ), at the edge region ( 25 ) of the primary port ( 21 ) at an upper level near the upper disk plane ( 14 ) and at the secondary edge zone ( 12a ) successively to a lower level near the lower plate level ( 15 ) decreases. Heat exchanger plate according to claim 8, characterized in that the base area ( 27 ) along a boundary to the central heat transfer area ( 18 ) from proximity to the primary edge zone ( 11a ) to the secondary edge zone ( 12a ) decreases successively. Heat exchanger plate according to one of claims 8 and 9, characterized in that the base surface ( 27 ) decreases steadily from the upper to the lower level. Heat exchanger plate according to one of claims 8 to 10, characterized in that the distribution area ( 26 ) and the base area ( 27 ) over substantially the entire first end region ( 16 ). Heat exchanger plate according to one of the preceding claims, characterized in that the shape of the distribution area ( 26 ) by molding the heat exchanger plate ( 1 ) is achieved. Plate package for a plate heat exchanger with at least two heat exchanger plates ( 1 ) with a plate gap ( 40 ) between them, each heat exchanger plate ( 1 ) between a primary edge zone ( 11a ) and a secondary edge zone ( 12a ) parallel to a central extension plane ( 13 ), an upper disk level ( 14 ) and a lower panel level ( 15 ) and the central extent ( 13 ) has a central axis (x), the heat exchanger plate ( 1 ) to a primary part ( 11 ) and a secondary part ( 12 ), and wherein each heat exchanger plate ( 1 ) has: a first end region ( 16 ); a second end region ( 17 ); a central heat transfer area ( 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 ) extends; a primary port ( 21 ) and a secondary port ( 23 ), which in the first end region ( 16 ) through the heat exchanger plate ( 1 ) and from an associated adjacent edge region ( 25 ), wherein the primary port ( 21 ) in the primary part ( 11 ) and the secondary port ( 23 ) in the secondary part ( 12 ) lie; and a distribution area ( 26 ), which in the first end region ( 15 ) and a number of protrusions ( 31 ) and depressions ( 32 ), wherein essentially each projection ( 31 ) along an associated path extending from the primary port ( 21 ) to the central heat transfer area ( 18 ), characterized in that substantially each projection ( 31 ) has a length at least in a central part of the distribution area that is significantly shorter than the distance from the primary connection opening ( 21 ) to the central heat transfer area ( 18 ) in the direction of the projection ( 31 ). Plate package according to claim 13, characterized in that substantially all the projections ( 31 ) the upper plate level ( 14 ) and essentially all wells ( 32 ) down to the lower board level ( 15 ). Heat exchanger plate according to one of claims 13 and 14, characterized in that substantially all depressions ( 32 ) substantially perpendicular to the direction of an adjacent projection ( 31 ). Heat exchanger plate according to one of claims 13 to 15, characterized in that substantially all depressions ( 32 ) extend along an associated path extending from the secondary port ( 23 ) to the central heat transfer area ( 18 ) runs. Plate pack according to one of Claims 15 and 16, characterized in that essentially all depressions ( 32 ) have a length at least in a central part of the distribution area that is significantly shorter than the distance from the secondary connection opening ( 23 ) to the central heat transfer area ( 18 ) in the direction of the depression ( 32 ). Plate pack according to one of the preceding claims, characterized in that all the projections ( 31 ) and all wells ( 32 ) have two ends and two long sides and that essentially all the projections ( 31 ) in the secondary part ( 12 ) with one of the ends to one of the long sides of a Deepening ( 32 ) and essentially all depressions ( 32 ) in the primary part ( 11 ) with one of the ends to one of the long sides of a projection ( 31 ). Plate pack according to one of claims 13 to 18, characterized in that the heat exchanger plates are arranged in alternating order such that the primary part ( 11 ) in the first end region ( 16 ) a first heat exchanger plate ( 1 ) at the secondary part ( 12 ) of an adjacent second heat exchanger plate ( 1 ) is applied, wherein substantially all depressions ( 32 ) of the first heat exchanger plate ( 1 ) at a respective projection ( 31 ) of the adjacent second heat exchanger plate ( 1 ) issue. Plate pack according to one of claims 13 and 19, characterized in that the distribution area ( 26 ) a base area ( 27 ) from the primary port ( 21 ) to the central heat transfer area ( 18 ), at the edge area ( 25 ) of the primary port at an upper level near the upper disk plane ( 14 ) and successively to a lower level near the lower plate level ( 15 ) at the secondary edge zone ( 12a ) decreases. Plate pack according to claim 20, characterized in that the heat exchanger plates ( 1 ) are arranged alternately so that the primary part ( 11 ) in the first end region ( 16 ) a first heat exchanger plate ( 1 ) on the second part of an adjacent second heat exchanger plate ( 1 ), wherein the height of the plate gap ( 40 ) from the proximity to the edge region ( 25 ) of the primary port ( 21 ) with respect to the first heat exchanger plate ( 1 ) to the second edge area ( 12a ) with respect to the first heat exchanger plate ( 1 ) decreases successively. Plate package according to claim 20, characterized in that the height of the plate gap ( 40 ) decreases steadily. Plate pack according to one of claims 13 to 22, characterized in that substantially all heat exchanger plates ( 1 ) are identical. Plate pack according to one of claims 13 to 23, characterized in that the heat exchanger plates ( 1 ) are permanently connected to each other.