EP2588827A2 - Heat exchanger plate, plate heat exchanger provided therewith, and method for manufacturing a plate heat exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger plate (1), to the manufacture thereof and to the use of the heat exchanger plate (1) according to the invention in a plate heat exchanger (100). A plate substrate (10) which is provided is formed at least on its top side (10o) with a flow duct arrangement (20) which has a multiplicity of flow ducts (20k), wherein some or all of the flow ducts (20k) have, over the entire extent thereof or in sections, duct rods (20s) which form duct walls (20w) which delimit a duct channel (20w) of the respective flow duct (20k).

Description

 Heat exchanger plate, thus provided plate heat exchanger and method for producing a plate heat exchanger

FIELD OF THE INVENTION

The present invention relates to a heat exchanger plate, a plate heat exchanger provided therewith and a method for producing a plate heat exchanger. In particular, the present invention also relates to a plate heat exchanger with ceramic plates.

INTERGRUN D OF THE INVENTORY

In heat exchangers or heat exchangers for transferring heat between two fluids or gaseous media which are not allowed to contact and mix, so-called plate heat exchangers or plate heat exchangers are often used in which the heat transfer area between the two media is formed a stapeiförmigen arrangement of so-called heat exchanger plates or heat exchanger plates which lie in the manner of a package to each other or one above the other, with directly adjacent heat exchanger plates form a flow space between them, directly adjacent flow spaces are separated from each other fluidly and each associated with one of the two media. Thus, odd-numbered successive flow spaces in the stack or package are flowed through by a second medium and even-numbered successive flow spaces in the stack or package by a second medium, without any mixing occurring. The heat transfer takes place via the respective flow chambers limiting and separating heat transfer plates, which thus serve as boundary walls of the flow spaces and are sealed against each other by providing appropriate seals. Known heat exchanger plates are formed, for example, metallic, so that their arrangement can be welded or soldered from a plurality of heat exchanger plates, so that the solder seam or weld simultaneously acts as a seal.

Due to the manufacturing costs, their weight and their physicochemical properties, metallic heat exchanger plates are sometimes not advantageous.

SUMMARY OF THE INVENTORY

The invention is based on the object to provide a heat exchanger plate for a plate heat exchanger, a plate heat exchanger itself and a method for producing a heat exchanger plate, in which with a particularly high reliability and mechanical stability in a particularly effective manner heat transfer can be realized.

The object of the invention is based on a heat exchanger plate for a plate heat exchanger according to the invention with the features of independent claim 1, in a plate heat exchanger according to the invention with the features of independent claim 1 7 and in a method for producing a heat exchanger plate for a plate heat exchanger according to the invention with the features of independent claim 18 solved. Advantageous developments are the subject matter of the dependent claims.

One aspect of the present invention is therefore to provide a ceramic material and in particular a SiC material or a silicon carbide material as a material for the heat exchanger plate for a plate heat exchanger instead of a metal material which is normally provided. Another aspect of the present invention is to ensure the mechanical stability of the heat exchanger plate in such a choice of materials that some or all of the intended flow channels of the flow channel arrangement partially or completely channel webs that form completely or partially channel channels delimiting channel walls. These channel lands stabilize the flow channels of the flow channel assembly and thus the plate substrate as a whole in a mechanical manner, particularly when in use and installation in a plate heat exchanger they interact with other heat transfer plates and substantially support a given heat transfer plate on a directly adjacent heat transfer plate allow planar manner, so that imprinted by the flowing media impressions can not lead to plate breaks in the underlying ceramic material.

The following aspects that can be realized according to the invention are pointed out:

The plate substrate and thus the heat transfer plate can have any desired shapes and dimensions, so that in particular an overall height and a total width of the plate substrate and thus of the heat transfer plate according to the invention are not limited.

With regard to flow channels to be provided, in the heat exchanger plates according to the invention, depending on the field of use, a minimum channel depth can be predetermined, e.g. also in the range of about 0.2 mm in so-called micro-heat exchangers or micro-heat exchangers.

When using heat exchanger plates according to the invention in a plate heat exchanger, an arrangement with seals can be used. However, this is not mandatory, because the mutual seal also by direct juxtaposition directly adjacent heat Bertragerplatten can be done, with the heat exchanger plates are mutually supported, namely, for example, by successive plate backs and front panels in the stack touch. Here, webs can be supported on webs, backs on bars, etc.

Due to the geometric configuration of the heat exchanger plate according to the invention and its flow channels as well as the arrangement of a plurality of heat exchanger plates according to the invention in a plate heat exchanger, a deflection of the heat transfer medium or fluids can be realized, e.g. also in the sense of a plate heat exchanger with multiple passage and / or with multiple deflection of the heat transfer fluid or fluids.

The plate substrate may be formed with or from a sintered silicon carbide material or SSiC material. This choice of material has the particular advantage of further mechanical stabilization and increased chemical inertness.

It may be a minimum layer thickness Dmin and / or a mean layer thickness Dm of the disc substrate in the range of about 2 mm to about 4 mm, in particular about 3 mm or less, preferably about 2 mm. Due to the formed channel webs, it is possible to reduce the layer thicknesses of the heat transfer plates accordingly, without causing mechanical destabilization. Without the mechanical stabilization by providing the corresponding webs of the flow channels much higher layer thicknesses for stabilization of the heat exchanger plates would be necessary if they were made of ceramic materials. This would result in a weight and volume increase, so that with the same heat transfer larger equipment needed and higher costs would be the result.

The layer thickness Ds of the plate substrate may be greater than the minimum layer thickness Dmin of the plate substrate in the region of a channel web and / or as the average layer thickness Dm of the disk substrate, such that the relationship

Ds> Dmin or about the relationship

Ds> dm is satisfied.

A local width Bb of the bottom of the channel groove of the flow channel and the local width Bsb of a base of the channel web of the flow channel at the level of the bottom of the channel channel of the flow channel - each measured perpendicular to the local course direction of the channel - can have a ratio Bb: Bsb of approximately 1: 4, so that's about the relationship

Bb: Bsb = 10: 4 is satisfied.

The local width Bb of the bottom of the channel channels of the flow channel and the local width Bsp of a plateau of a channel web of a flow channel on the side facing away from the bottom of the channel channel of the flow channel - each measured perpendicular to the local course direction of the flow channel - a ratio Bb: Bsp in the range of have about 1 0: 3, so about the relationship

10: 4 <Bb: Ex <10: 2 or preferably about the relationship Bb: Bsp = 10: 3 is satisfied.

The local width Bsb of the base of the channel web of the flow channel at the level of the bottom of the channel channel of the flow channel and the local width Bsp of the plateau of the channel web of the flow channel on the side remote from the bottom of the channel channel of the flow channel - each measured perpendicular to the local direction of the flow channel have a ratio Bsb: Bsp in the range of about 1: 1 to about 4: 2, preferably about 4: 3, so that about the relationship

4: 2 <Bsb: Ex <1: 1 or preferably about the relationship

Bsb: Bsp = 4: 3

is satisfied.

The channel walls of a flow channel with the normal to the bottom of the channel groove of the flow channel include an angle α which is in the range of more than 0 ° and less than 30 °, preferably about 1 5 °, so that about the relationship

0 ° <a <30 ° or preferably about the relationship a = 15 °

is satisfied. The local width Bb of the bottom of the channel channel of the flow channel - measured perpendicular to the local direction of the flow channel - and the depth t of the channel channel of the flow channel - measured perpendicular to the bottom of the channel channel of the flow channel - a ratio Bb: t in the range of about 10: 1 0th to about 10: 4, preferably about 10: 4, so that about the relationship

10: 10 <Bb: t <10: 4 or preferably about the relationship

Bb: t = 10: 4 is satisfied.

The last-described measures realize various geometric arrangements in the embodiment of the heat exchanger plate according to the invention with respect to the channel geometry in relation to the plate thickness, whereby particularly favorable mechanical properties are achieved with comparatively low volume and / or weight.

The sheet substrate may be provided with top and bottom penetrating supply and discharge ports for supplying a first heat transfer fluid F1 to and from the top of the disk substrate, the flow channel assembly configured to transport the first heat transfer fluid F1 from the supply port to the discharge port ,

Flow channels of the flow channel arrangement can have completely or in sections a multiple undulated course. The undulation direction U can run in a surface or plane defined by the plate substrate and / or perpendicular to the flow direction locally and / or in the middle defined by the respective flow channel.

The shape of the undulation of a respective flow channel may be one of a group of shapes including sawtooth shapes, alternating step shapes, waveforms, sine shapes, and combinations thereof. On the back or bottom of the disk substrate may be formed a second flow channel arrangement for a second heat transfer fluid F2 having a plurality of corresponding flow channels.

The plate substrate may be provided with top and bottom penetrating second supply and discharge ports for supplying the second heat transfer fluid F2 to and from the back or bottom of the disc substrate, and the second flow channel assembly for transporting the second heat transfer fluid F2 from the second Feed opening is formed to the second discharge opening.

The heat exchanger plate according to the invention may be rotationally symmetrical with respect to the front or top side and the back or bottom side by 180 ° with respect to an axis of symmetry S. extending in the plate substrate.

The plate substrate may have a substantially rectangular shape.

In this case, supply and / or discharge openings can be formed in the area at opposite first, preferably shorter, sides of the rectangular shape, in particular in regions of the corners.

The flow directions of first and / or second heat transfer fluids F1, F2 and / or main directions of flow of flow channels can be essentially along the extension directions of opposite second - preferably longer - sides of the rectangular shape may be formed.

By the measures described above, different flow geometries in the interaction, ie. in the stack-like or packet-like juxtaposition of a plurality of inventive heat exchanger plate, realized.

According to another aspect of the present invention, there is also provided a plate heat exchanger as such having a plurality of heat transfer plates according to the invention, the heat transfer plates being constructed and arranged so that the back or bottom of the plate substrate is a respective preceding heat transfer plate. 1 of the front or top side of the disk substrate directly opposite each j + 1 with j = 1, n-1 directly and in particular with a seal arrangement therebetween abuts that by the sequence of heat transfer plates j = 1, n and / or in particular by the formation of the seal assembly directly successive flow-separated flow spaces R1, Rn + 1 are formed or are that directly adjacent flow spaces Rj, Rj + 1, j = 1, n are separated in pairs in terms of flow, and that j In each case, adjacent flow-through spaces Rj, Rj + 2, j = 1, n-1 are connected in pairs in terms of flow, each assigned to a heat transfer fluid F1, F2 and designed to flow through respectively associated heat transfer fluid F1, F2 from the respective supply opening to the respective discharge opening.

According to another aspect of the present invention, there is also provided a method of manufacturing a heat transfer plate for a plate heat exchanger, comprising the steps of providing or forming a plate substrate with or made of a ceramic, SiC material or a silicon carbide material having a front or top surface and a return or terseite, forming a flow channel arrangement having a plurality of flow channels on the front or top of the disk substrate, wherein a part or all of the flow channels of the flow channel arrangement are formed completely or in sections with channel channels defining channel walls forming channel webs.

The plate substrate may be formed with or from a sintered silicon carbide material or SSiC material.

Flow channels of the flow channel arrangement can be formed completely or in sections with a multiple undulated course.

The undulation direction U can be formed to extend in a surface or plane defined by the plate substrate and / or perpendicular to the flow direction locally or in the middle defined flow direction.

The shape of the undulation may be a shape of the group of shapes including sawtooth shapes, alternating step shapes, waveforms, sine shapes, and combinations thereof.

These and other aspects will be explained on the basis of the attached drawings.

KU DESCRIPTION OF THE FIGURES

Fig. 1A is a schematic plan view of the front side of an embodiment of the heat exchanger plate according to the invention.

Fig. 1 B shows a schematic plan view of the back side of FIG. 1 illustrated embodiment of the heat exchanger plate according to the invention. show analogous to FIGS. 1 and 2 another embodiment of the heat exchanger plate according to the invention, in which the Hauptfl ießkanäle have a different geometry. show schematic plan views of the front of two

Embodiments of inventive heat transfer plates, which are similar to those of FIGS. 1 A and 2A are constructed, but wherein the channel webs of the feed channels have a different geometry. show cross-sectional views of inventive heat exchanger plates to illustrate the cross sections of the channel geometries. is an exploded view of a stack of heat exchanger plates according to the invention, as they may be provided in a plate heat exchanger. show schematic side views of the in Fig. 7 illustrated stack or package inventive heat exchanger plates, the flow conditions of two proposed flow media are illustrated. shows a schematic side view of an embodiment of a plate heat exchanger according to the invention, which has a stack or a package according to the invention heat transfer plates. show in plan view and in a cross-sectional view in a schematic manner another embodiment of a heat exchanger plate according to the invention. DETAILED DESCRIPTION OF THE EMBODIMENTS

Hereinafter, embodiments of the present invention will be described. All embodiments of the invention and also their technical features and properties can be isolated individually or combined randomly combined with each other arbitrarily and without restriction.

Structurally and / or functionally identical, similar or identically acting features or elements are referred to below in connection with the figures with the same reference numerals. Not in any case, a detailed description of these features or elements is repeated.

First of all, reference is made to the drawings in general.

In particular, the present invention also relates to a plate heat exchanger 100 or plate heat exchanger 100 with a plurality of heat exchanger plates 1 according to the invention.

In this case, in particular monolithically constructed, ceramic materials for the design of the heat exchanger plates 1 according to the invention are provided.

Monolithic ceramic materials are highly sensitive to bending loads. Therefore heretofore her use for the design of heat exchanger plates 1 in plate heat exchangers 100 largely forbids, since different design concepts of flow chambers in ceramic heat exchanger plates and in particular SSiC heat exchanger plates 1 have no support over large areas of the heat exchanger plates 1. This has previously led to plate fractures due to bending stresses caused by the internal pressure loads when pressurizing the respective flow chambers with fluid pressure. According to the invention, this is counteracted in that the flow channels 20k are formed with so-called channel webs 20s, which form channel walls 20w, which for their part delimit the channel channels 20r of the flow channels 20k of the flow channel arrangement 20 completely or in sections.

It is precisely the channel webs 20s which inherently stabilize the structure of the heat exchanger plate 1 made of a ceramic material and in particular of a SiC or SSiC material, and in particular also by supporting an arrangement of a plurality of inventive heat exchanger plates 1 in a plate heat exchanger 1 00 serve each other.

Now, reference will be made in detail to the drawings.

Fig. 1 shows a schematic plan view of a first embodiment of the heat exchanger plate 1 or heat exchanger plate 1 according to the invention.

This consists essentially of a plate substrate 1 0, which is also referred to simply as the substrate 1 0 for the heat exchanger plate 1 and with or at least one ceramic material 1 0 ', preferably a SiC material or Siliziumcarbidmaterial 1 0' and more preferably with or is formed of at least one sintered silicon carbide 1 0 'or SSiC material 1 0'.

The substrate 1 0 for the heat exchanger plate 1 has a plate structure with a front or top 1 0o and a back or bottom 1 0u; however, these may be particularly equal, especially with respect to a particular application, and they may also be structured in a similar or even identical manner.

Hereinafter, the so-called front side or upper side 10o of the substrate of the heat exchanger plate 1 according to the invention will first be described. Provided are first a feed opening 2 for a first fluid F1, a discharge opening 3 for the first fluid F1, a feed opening 2 'for a second fluid F2 and a discharge opening 3' for the second fluid F2. All openings 2, 2 ', 3, 3' are formed at the edge or corner regions of the disk substrate 1 0.

The feed opening 2 for the first fluid F1 is shown in the view of FIG. 1 A formed in the upper, left corner. The discharge opening 3 for the first fluid F1 is formed in the lower left corner. However, it may also be the discharge opening 3 for the first fluid F1 of the feed opening 2 for the first fluid F1 are formed diagonally opposite one another, ie in the in FIG. 1 A given view in the lower right corner.

In the embodiment of FIG. 1 A, the supply opening 2 'for the second fluid F2 is formed in the region of the upper, right-hand corner, while the discharge opening 3' for the second fluid F2 is formed in the region of the lower, right-hand corner. However, the discharge opening 3 'for the second fluid may also be formed diagonally opposite the feed opening 2' for the second fluid, that is to say in the embodiment shown in FIG. 1 A view in the lower left corner.

The respective supply openings and discharge openings for a respective fluid are in relation to the longitudinal orientation of the disk substrate 1 0 each opposite. In the in Fig. Moreover, they are both arranged on the left side or on the right side of the disk substrate 10 with respect to the short edge k, respectively. In addition, the two feed openings 2, 2 'on the one hand and the two discharge openings 3, 3' on the other hand with respect to the longitudinal edge I or long edge I of the disk substrate 1 0, so that in particular when combining a plurality of inventive heat exchanger plates 1 0 in a plate heat - exchanger 1 00, a countercurrent process is implemented; this will be further clarified below.

The feed opening 2 and the discharge opening 3 for the first fluid are surrounded or framed on the upper side 10a of the disk substrate 10 by a main seal 6 for the front side 10o and for the first fluid F1, so that outside the main seal 6 for the upper side 1 0o the supply port 2 'and the discharge opening 3' for the second fluid F2 lie.

Within the main seal 6 for the front side 10o, an arrangement 20 for flow channels 20k is provided next to the feed opening 2 and the discharge opening 3 for the first fluid F1, which is also referred to as channel arrangement 20 or flow channel arrangement 20. The plurality of flow channels 20k provided in this channel arrangement 20 extend on the surface or upper side 10o of the substrate 10, namely, the individual channels 20k in a plurality of reliefs on the upper side 10o of the plate substrate 10 within the main seal 6 for the upper side 10o form. The channels 20k extend substantially between the feed opening 2 and the discharge opening 3 for the first fluid F1.

The entire channel assembly 20 is divided into a main channel assembly 21 or main heat transfer channel assembly 21, which is located in the middle between the supply port 2 and the discharge opening 3 for the first fluid and a little spaced therefrom and of main channels 21 k or main heat transfer channels 21 k is formed. Directly adjacent to the feed opening 2 and to the discharge opening 3 for the first fluid F1 and directly connected to and / or adjacent to the main channel arrangement 21 are a feed or distribution channel arrangement 22 with distribution channels 22k or distribution channels 22k or a bundling, merging or discharge channel arrangement 23 with a plurality of bundling, merging, or discharge channels 23k. Inn operation is supplied via the supply port 2, the first fluid F1 and practically introduced to the top 10 of the disk substrate 1 0 and distributed there. The distribution is taken over by the distribution channels 22k of the feed and distribution channel arrangement 22 adjoining the feed opening 2 for the first fluid F1.

The distribution channels 22k of the supply and distribution channel arrangement 22 transfer the first fluid F1 into the main channels 21k or main heat transfer channels 21k of the main channel arrangement 21 or main heat transfer channel arrangement 21. The main channels 21 k and the main channel arrangement 21 are formed comparatively longer than the supply and distribution channel arrangement 22, so that there is a longer residence time of flowing in the channels 20 k first fluid F1 and thus sets a stronger heat transfer to the plate substrate 1 0.

The main channels 21 k then lead into the so-called bundling channels 23 k, which can also be referred to as discharge channels 23 k or 23k merging channels and receive the first fluid F1 from the main channels 21 k and the discharge opening 3 for the first fluid F1 supply, through which then the first fluid F1 after flowing through the channels 20k of the entire channel assembly 20, starting from the feed opening 2 for the first fluid F1, the channel assembly 20 and thus the top 10o of the substrate 1 0 leaves the heat exchanger plate 1 according to the invention again.

Due to the main seal 6 for the first fluid F1 and for the upper side 10o, the first fluid F1, when flowing from the feed opening 2 to the discharge opening 3, reaches the outside area outside the main seal 6 and thus the areas of the feed opening 2 'and the discharge opening 3' for the first second fl uid F2 not. In addition, the feed opening 2 'and the discharge opening 3' for the second fluid on first and two side seals 4-1 and 4-2, which the feed opening 2 'and the discharge opening 3' for the second fluid F2 for themselves once again by closing the feed opening 2 'and the lead opening 3 'for the second fluid F2 in the edge region surrounded from the outside. Overall, therefore, the feed opening 2 and the discharge opening 3 for the first fluid F1 and the feed opening 2 'and the discharge opening 3' for the second fluid F2 are fluidly separated from each other or isolated, so that the first and the second fluid F1 or Do not mix F2 on top 1 0o of the plate substrate 1 0.

The supply port 2 for the first fluid F1 and the supply and distribution channel assembly 22 with the distribution channels 22k or supply channels 22k together form the supply or distribution region 7 for the front side 10o of the substrate 10 or for the first fluid F1.

The main channel arrangement 21 or main heat transfer channel arrangement 21 with its main channels 21 k or main heat transfer channels 21 k forms the main heat transfer area or main heat exchange area 9 on the upper side 10o of the plate substrate 10 or of the first fluid F1 of the heat transfer plate 1 according to the invention.

Correspondingly, the discharge opening 3 for the first fluid F1 and the bundling and discharge channel arrangement with their bundling channels 23k, merging channels 23k or discharge channels 23k form the so-called bundling and discharge region 8 for the front side 10o of the plate substrate 10 of the heat transfer plate according to the invention 1 or the first fluid.

The arrangement shown in plan view of FIG. 1 A is strictly axisymmetric with respect to the indicated symmetry axis x. With regard to the symmetry axis y, which is also drawn, at least the feed opening 2 for the first fluid F1 and the discharge opening 3 'for the second fluid F2 on the one hand and the discharge opening 3 for the first fluid F1 and the supply opening 2' for the second fluid F2 are strictly axially symmetrical arranged. The outer shape of the substrate 10 is strictly axially symmetrical with respect to both axes x and y and has substantially the shape of one in the length drawn rectangles with rounded corners and an aspect ratio for the long edge I and the short edge k in the range of about 2: 1.

In the in Fig. 1A, the feed channels 22k or distribution channels 22k directly transition into the main channels 21k in a 1-to-1 arrangement or assignment, and these in turn in a 1-to-1 arrangement into the trunking channels 23k or discharge channels 23k. In the figure, the channel cavities 20r or channel grooves 20r are shown white or light, whereas the channel lands 20s forming the channel walls 20w are shown in black or dark.

The channels 20k in total are in the arrangement of FIG. 1 A thus formed by a respective feed channel 22k, a directly associated main channel 21k and a directly associated discharge channel 23k. The main channels 21 k here have the shape of a sawtooth or a zigzag line with triangular basic pattern. However, other embodiments are also conceivable.

Decisive is in the arrangement of FIG. 1 A, that the channel assembly 20 in total and the channels 20k in particular with so-called channel webs 20s, which form the channel walls 20w of the channel groove 20r, are formed. These channel webs 20s lead to the special mechanical stability, especially in hydrodynamic or fluidodynamic H in the area of the feed openings 2 for the first fluid F1.

On the one hand, the mechanical stability of the sheet-like substrate 1 0, which is formed in a planar manner, is stabilized per se by the sequence of depression or groove 20r and web 20s per se. In addition, however, results in the interaction of a plurality of plate substrates 1 0 arranged in a stack heat exchanger plates 1 according to the invention in a plate heat exchanger 1 00 an effect of mutual support directly adjacent substrates 1 0 on the areas of the channel webs 20s. Because of this pelten mechanical stabilization or reinforcement, it is possible according to the invention to use under Biegebelastungen little strong loadable ceramic substrate material 1 0 'of the disc substrates 1 0, in particular in the form of so-called Sil iziumcarbidmaterial or SiC ma- materials and sintered in particular in the form Silicon carbide ien or SSIC material ien, without an increase in the plate thickness or thickness DS of the disk substart 1 0 of the heat exchanger plate 1 according to the invention would be necessary, since by the web structure, ie. the sequence of depressions of the 20k of the channels 20k and the webs 20s of the channels 20k and the mutual support by Aufl the webs 20s of the channels 20k directly in the plate stack adjacent heat exchanger plates 1 a higher stiffening and stabilization against each other are achieved, so that also when introducing the first fluid F1 through the feed opening 2 for the first fluid F1 and the associated high pressures, the bending stress of the plate substrate 1 0 of the heat exchanger plate 1 according to the invention does not exceed the maximum possible.

The Fig. 1B shows from the direction of view from the upper side 110o of the substrate 110 from the arrangement of FIG. 1 A from - quasi in review - the structure of the back 1 0u or bottom 10u of the same substrate 1 0. All structures are therefore shown dotted or dashed lines.

The arrangement of the here provided main seal 6 'for the second fluid F2 for the back 1 0u and the first and second side seals 4-1' and 4-2 'for the supply port 2 and for the discharge opening 3 for the first fluid F1 in relation on the back 10u is strictly axis or mirror symmetry to the axis of symmetry x and appears in comparison to the in Fig. 1 A shown corresponding arrangement with respect to the main seal 6 for the first fluid F1 and the secondary seals 4-1 and 4-2 for the second fluid with respect to the front 1 0o to the symmetry axis y strictly axis or mirror symmetry. Here, the main seal 6 'surrounds the supply port 2' and the second fluid discharge port 3 ', fluidically outwardly separates the supply port 2 and the first fluid discharge port 3 with the corresponding first and second side seals 4-1' and 4-2 'and has in its interior the channel arrangement 20' or flow channel arrangement 20 'for the second fluid F2 on the back 1 0u of the plate substrate 1 0 of the heat exchanger plate 1 according to the invention.

Thus, the in Fig. 1B for the rear side 10u or lower side 10u of the disk substrate 10 essentially the one for the front side 10o of the disk substrate 10, which is shown in FIG. 1 A is shown.

Accordingly, a supply portion 7 'or distribution portion 7', a bundling portion 8 'or discharge portion 8' and a main heat transfer portion 9 'or main heat exchange portion 9' are formed for the back 10u or second fluid F2 by cooperation of the supply port 2 'for the second fluid F2 and the supply channel arrangement 22 'or distribution channel arrangement 22' with the supply channels 22k 'or distribution channels 22k' for the second fluid F2, through the main channel arrangement 21 'or main heat transfer channel arrangement 21' with the main channels 21k 'or main heat transfer channels 21k' for the second fluid F2 or by cooperation of the discharge opening 3 'for the second fluid F2 with the bundling channel arrangement 23', Zusammenführkanalanordnung 22 'or Abführkanalanordnung 23' with the bundling, Zusammenführ- or Abführkanälen 23k 'for the second fluid F2 on the back 1 0u of the disk substrate 10 of the erf heat exchanger plate 1 according to the invention.

Otherwise, this applies to the front side 1 0o shown in FIG. 1 A said in a similar way.

The in Figs. 2A and 2B arrangements correspond to those of FIGS. 1 A and 1 B, except that in Figs. 1 A and 1 B the main channels 21 k for the first fluid F1 and 21 k 'for the second fluid F2 and the respective webs 20s, 20s' have a sawtooth shape or a zigzag shape, whereas in the embodiment according to FIGS. 2A and 2B is a waveform, in particular in the manner of a sinusoidal course.

In principle, all channel types are conceivable, i. e.g. with any lateral, d .h. Undulation with undulation direction U in the XY plane of the front side 10o and / or the back side 10u of the disk substrate 10 of the heat exchanger plate 1 according to the invention.

The undulation itself leads in each case to a longer dwell time of the fluid F1, F2 flowing or flowing in the channel 20k, 20k 'and thus to a more intimate heat exchange with the material 10' of the substrate 10.

The Fig. 3 and 4 show plan views of upper sides 10o of substrates 10 of two other embodiments for the heat exchanger plate 1 according to the invention. In this case, the main channels 21k, 21k 'of the channels 20k, 20k' essentially correspond in their structure to the channels of the arrangements of FIGS. 1A, B on the one hand and FIGS. 2A, B on the other hand, ie. they have a sawtooth, a waveform.

In contrast to the arrangements of FIG. 1A to 2B show the arrangements of FIG. 3 and 4 supply channels 22k, 22k 'and discharge channels 23k, 23k', which are no longer in 1-to-1 correspondence with the main channels 21k, 21k '. Rather, here are the channel webs 20s, 20s' - in particular 22s, 22s', 23s, 23s' - formed greatly widened, so that a total of the number of feed channels 22k, 22k 'and the discharge channels 23k, 23k' is less than the number of main channels 21 k, 21 k '. Due to the widening of the webs 20s, 20s' 22s, 22s', 23s, 23s', however, here the mechanical stability in the region of the feed opening 2 and the discharge opening 3 for the first medium - and accordingly Chend for the feed opening 2 'and 3' for the second medium on the back 1 0u - further increased.

The Fig. FIGS. 5 and 6 show partial sectional views through a substrate 10 of two embodiments of the heat exchanger plate 1 according to the invention, namely, when the arrangements of FIGS. 1 A to 4 - viewed in the direction Y

From the in Fig. 5 and 6, the various configuration possibilities of the cross section of the channels 20k, 20k ', in particular of the main heat transfer channel arrangement 21, 21', ie the main channels 21k, 21k ', can be seen.

In the in Fig. 5, the respective channel groove 20r, 20r 'and the respective channel web 20s, 20s' of the respective channel 20k, 20k' have approximately a rectangular or square shape and are substantially equal to one another. The respective channel bottom 20b, 20b 'forms e.g. The level of the minimum layer thickness Dmin of the underlying substrate 1 is set thereon. The webs or channel webs 20s, 20s 'having a height which forms the depth t of the channel channel 20r, 20r', which corresponds to the width Bb of the bottom 20b, 20b 'the channel groove 20r of the flow channel 20k, 20k' but also the width Bsb of the channel web 20s, 20s 'at the level of the bottom 20b, 20b' and also the local width Bsp of the plateau 20sp, 20sp 'of the web 20s, 20s' corresponds.

Due to the geometry of the channels 20I, 20K ', the channel walls 20W, 20W' are formed vertically. The base of the respective channel web 20s, 20s' and the plateau 20sp, 20sp 'of the channel web 20s, 20s' are chosen to be equal in width, Bsp = Bsb.

In the embodiment according to FIG. 6, in contrast, the base of the channel web 20s, 20s' and the plateaus 20sp, 20sp 'of the channel webs 20s, 20s' such chosen that the channel webs 20s, 20s' to the channel bottom 20b, 20b 'side facing away from a tapered course results, wherein the inclination angle α of the respective channel wall 20w, 20w' is different from 0 °, it is therefore: Bsb> Ex.

The Fig. 7 shows, in a schematic and perspective exploded view, an arrangement 1 00 'for a plate heat exchanger 100 having a plurality of inventive heat exchanger plates 1 or 1 j, j = 1, n, which are arranged congruently in the manner of a stack 1 1 0 and alternately flow spaces R1 , R3, R5, ... for the first fluid F1, R2, R4, R6, ... and the second fluid F2, respectively. Also indicated is the assignment of the spaces or flow spaces R1, R2, R3,... Directly adjacent inventive heat exchanger plates 1 or 1j, j = 1, n to the corresponding first and second fluids F1, F2. The arrows indicate the flow conditions with respect to the outward and return flow, that is to say from inflow and outflow. The respective seals 6, 4-1, 4-2 and the various channel arrangements 20, 20 'are not indicated in this illustration.

The Fig. FIGS. 8A to 8D show, in sectional side and plan views, the schematic arrangement shown in the arrangement 100 'of FIG. 7 present flow conditions with respect to the first and second fluids F1 and F2. Here, only the first and second secondary seals 4-1, 4-2, 4-1 ', 4-2' for the first and second fluids F1, F2 are shown.

From the information to Figs. 7 to 8D it follows that the juxtaposition and interconnection of a plurality of inventive heat exchanger plates 1 or 1j, j = 1, n provides a sequence of alternating flow spaces for the first and second fluids F1 and F2, successive odd-numbered spaces R1, R3, R5 , ... between directly successive heat exchanger plates 1 or 1j, j = 1, n flow spaces R1, R3, R5, ... for the first fluid F1 and even-numbered spaces R2, R4, R6, ... successive heat exchanger plates 1 or 1j, j = 1, n flow spaces R2, R4, R4, ... for the second fluid F2 form.

The illustrations of FIG. 8A to 8D are not to scale here because the main seals 6, 6 'and the side seals 4-1, 4-2, 4-1', 4-2 'are designed too strong in strength; However, this serves to clarify the geometric and flow conditions.

Fig. 9 shows, in a schematic and partially sectioned side view, a more realistic representation of the arrangement 100 'of a plate heat exchanger 100 according to the invention with a plurality of heat transfer plates 1 or 1j, j = 1, n, combined to form a stack 11.

In this case, the stack 1 10 of the plurality of inventive heat exchanger plates 1 or 1 j, j = 1, n clamped between two clamping plates 120 or clamping devices 120 via a corresponding screw 1 30, so that a total of the interaction of the individual heat exchanger plates according to the invention 1 or 1 j, j = 1, n set the ratios described in the preceding figures.

The Fig. 10A and 10B describe another embodiment of the heat exchanger plate 1 according to the invention with or consisting of a ceramic substrate 10.

Here, the heat exchanger plate 1 according to the invention also has a substantially rectangular configuration, but with an edge ratio of the long and short edges I and k of about 4: 1. Otherwise, in connection with FIGS. 2A, 2B and 4 and 6 described before. That is, the actual main heat transfer channels 21k, 21k 'are approximately undulating, with no 1-to-1 correspondence or allocation between the supply and discharge channels 22k, 22k', 23k, 23k 'on the one hand and the main heat transfer channels 21 k, 21 k 'is present and that the webs 20s, 20s' - in particular 22s, 22s ', 23s, 23s' - the underlying flow channels 20k, 20k 'in cross-section have a trapezoidal shape, with the respective channel bottom 20b, 20b' facing away from tapering Course.

LIST OF REFERENCE NUMBERS

1 heat exchanger plate according to the invention, warning exchanger plate 1j heat exchanger plate according to the invention, heat exchanger plate in an arrangement of a plurality of j = 1, n heat exchanger plates according to the invention, heat exchanger plates

2 feed opening (first fluid F1)

2 'supply port (second fluid F2)

 3 discharge opening (first fluid F1)

3 'discharge opening (second fluid F2)

 4-1 first secondary seal (front 1 0o / for supply port second fluid F2)

 4-1 'first side seal (back 1 0u / for feed opening first

 Fluid F1)

 4-2 second secondary seal (front 1 0o / for discharge opening second fluid F2)

 4-2 'second side seal (back 10u / for discharge opening first

 Fluid F1)

 6 main seal (front 1 0o / first fluid F1)

6 'main seal (back 1 0u / second fluid F2)

 7 Feed area / distribution area (front 1 0o / first fluid

 F1)

 7 'feed area / distribution area (back 10u / second fluid

 F2)

 8 bundling area / discharge area (front 1 0o / first fluid

 F1)

 8 'bundling area / discharge area (rear 1 0u / second Fl uid

 F2)

 9 main heat transfer area / main heat exchange area

 (Front 1 0o / first fluid F1)

 9 'main heat transfer area / main heat exchange area

(Back 1 0u / second fluid F2) Substrate of the heat exchanger plate 1 0, plate substrate

'Material of the disk substrate, ceramic material, SiC or

 SSiC material

o top / front of the substrate 1 0

u bottom / back of the substrate 1 0

 Channel arrangement / flow channel arrangement (front 10o / first fluid F1)

'Channel arrangement / flow channel arrangement (back 1 0u / second

 Fluid F2)

b, 20b 'channel bottom

k, 20k 'flow channel, channel, heat transfer channel

p, 20p 'canal plateau

r, 20r 'sewer

s, 20s' canal dock

w, 20w 'canal wall

, 21 'main heat transfer duct assembly, main duct assembly b, 21b' duct bottom

k, 21 k 'main heat transmission channel, main channel

p, 21 p 'channel plateau

r, 21 r 'sewer

s, 21 s' canal dock

w, 21 w 'duct wall

, 22 'Feed Channel Assembly / Distribution Channel Assembly

b, 22b 'channel bottom

k, 22k 'distribution channel

p, 22p 'canal plateau

r, 22r 'sewer

s, 22s' canal dock

w, 22w 'canal wall

, 23 'bundling arrangement / discharge channel arrangement

b, 23b 'channel bottom

k, 23k 'bundling channel, merging channel, discharge channel 23p, 23p 'canal plateau

23r, 23r 'gutter

23s, 23s' canal dock

23w, 23w 'canal wall

1 00 inventive plate heat exchanger or plate heat exchanger

 1 00 'arrangement for a plate heat exchanger 100 or plate heat exchanger 1 00 according to the invention

 1 1 0 Stack of a plurality of inventive heat exchanger plates 1 or heat exchanger plates. 1

 1 20 clamping plate, clamping device

 1 30 Screwing device, screw connection, clamping screw

F1 first fluid, first heat transfer fluid

 F2 second fluid, second heat transfer fluid

k short edge of the disk substrate 10

 I long edge of the disk substrate 1 0

Depth of channel 20k, 20k 'or channel groove 20r, 20r'

 U undulation direction

Claims

1 . Heat exchanger plate (1) for a plate heat exchanger (1 00),

 with a plate substrate (10) which is formed with or consists of a SiC material (10 ') or a silicon carbide material (10') and which has a front or top side (10o) and a rear or underside ( 1 0u),

 wherein at least the front or top side (10o) of the disk substrate (10) is formed with a flow channel arrangement (20) having a plurality of flow channels (20k), and

 wherein a part or all of the flow channels (20k) of the flow channel arrangement (20) have channel webs (20s) which form channel channels (20r) which delimit channel channels (20r) completely or in sections.

2. Heat exchanger plate (1) according to claim 1,

 wherein the plate substrate (10) with or from a sintered silicon carbide material (1 0 ') or SSiC material (1 0) is formed.

3. Heat exchanger plate (1) according to one of the preceding claims, wherein a minimum layer thickness Dmin and / or a mean layer thickness Dm of the plate substrate (1 0) in the range of about 2 mm to about 4 mm, in particular about 3 mm or less, preferably at about

2 mm.

4. Heat exchanger plate (1) according to one of the preceding claims, wherein the layer thickness Ds of the plate substrate (1 0) in the region of

Duct web (20s) is greater than the minimum layer thickness Dmin of the disk substrate (1 0) and / or as the average layer thickness Dm of the disk substrate (1 0),

 so that's about the relationship

Ds> Dmin or about the relationship

 Ds> Dm

is satisfied.

5. Heat exchanger plate (1) according to one of the preceding claims, wherein a local width Bb of the bottom (20b) of the channel groove (20w) of the

Flow channel (20k) and the local width Bsb a base of the channel web (20s) of the flow channel (20k) at the level of the bottom (20b) of the channel groove (20r) of the flow channel (20k) - each measured perpendicular to the local direction of the flow channel (20k ) - have a ratio Bb: Bsb of about 1: 4,

 so that's about the relationship

Bb: Bsb = 10: 4

is satisfied.

6. Heat exchanger plate (1) according to any one of the preceding claims, wherein the local width Bb of the bottom (20b) of the channel grooves (20r) of the

Flow channel (20k) and the local width Bsp of a plateau (20sp) of a channel web (20s) of a flow channel (20k) on the bottom (20b) of the channel groove (20r) of the Fließkanal (20k) facing away - each measured perpendicular to the local Extending direction of the flow channel (20k) - have a ratio Bb: Bsp in the range of about 1 0: 3,

 so that's about the relationship

10: 4 <Bb: Ex <10: 2 or preferably about the relationship

Bb: Bsp = 10: 3

is satisfied.

7. heat exchanger plate (1) according to one of the preceding claims, wherein the local width Bsb of the base (20sb) of the channel web (20s) of the flow channel (20k) at the level of the bottom (20b) of the channel channel (20r) of the flow channel (20k) and the local width Bsp of the plateau (20sp) of the channel web (20s) of the flow channel (20k) on the side facing away from the bottom (20b) of the channel groove (20r) of the flow channel (20k) - each measured perpendicular to the local direction of the flow channel (20k) - a ratio Bsb: Ex in the range of from about 1: 1 to about 4: 2, preferably about 4: 3, such that about the relationship

4: 2 <Bsb: Ex <1: 1 or preferably about the relationship

Bsb: Bsp = 4: 3

is satisfied.

8. heat transfer plate (1) according to one of the preceding claims 1 to 6,

 wherein the channel walls (20w) of a flow channel (20k) with the normal to the bottom (20b) of the channel groove (20r) of the flow channel (20k) enclose an angle α in the range of more than 0 ° and less than 30 °, preferably at about 15 ° L,

 so that's about the relationship

0 ° <a <30 ° or preferably about the relationship a = 15 °

is satisfied.

9. heat transfer plate (1) according to one of the preceding claims, wherein the local width Bb of the bottom (20b) of the channel groove (20r) of the flow channel (20k) measured perpendicular to the local direction of the flow channel (20k) and the depth t of the channel groove (20r) of the flow channel (20k) measured perpendicular to Bottom (20b) of the channel groove (20r) of the flow channel (20k) - a ratio Bb: t ranging from about 10:10 to about 10: 4, preferably about 10: 4,

 so that's about the relationship

10:10 <Bb: t <10: 4 or preferably the relationship

Bb: t = 10: 4

is satisfied.

10. Heat exchanger plate (1) according to one of the preceding claims, wherein the plate substrate (10) from the top (10o) to the bottom (10u) penetrating supply and discharge openings (2, 3) for supplying or discharging a first heat transfer fluid (F1) to the top surface (10o) of the disc substrate (10), and wherein the flow channel assembly (20) is configured to transport the first heat transfer fluid (F1) from the supply port (2) to the discharge port (3).

11. Heat exchanger plate (1) according to one of the preceding claims, wherein flow channels (20k) of the flow channel arrangement (20) completely or partially have a multiple undulated course and wherein the Undulationsrichtung (U) in a plane defined by the plate substrate (10) surface or / and or perpendicular to the respective flow channel (20k) locally and / or in the middle defined flow direction.

1 2. Heat exchanger plate (1) according to claim 1 1,

 wherein the shape of the undulation of a respective flow channel (20k) is a shape of the group of shapes having sawtooth shapes, alternating step shapes, waveforms, sine shapes, and combinations thereof.

3. Heat exchanger plate (1) according to one of the preceding claims, wherein on the rear or underside (1 u) of the plate substrate (1) a second flow channel arrangement (20 ') for a second heat transfer fluid (F2) having a plurality of corresponding flow channels ( 20k ') is formed.

14. Heat exchanger plate (1) according to claim 1 3,

 wherein the plate substrate (10) penetrates second feed and discharge openings (2 ', 3') from the upper side (10o) to the lower side (1 0u) for feeding or discharging the second heat transfer fluid (F2) to and from the rear or bottom (10 u) of the disk substrate (1 0) are provided and

 wherein the second flow channel arrangement (20 ') is designed to transport the second heat transfer fluid (F2) from the second supply opening (2') to the second discharge opening (3 ').

1 5. Heat exchanger plate (1) according to one of the preceding claims, which is rotationally symmetrical with respect to the front or top (1 0o) and the rear or underside (1 0u) by 1 80 ° relative to a in the plate substrate (1 0) extending symmetry axis (S).

1 6. heat transfer plate (1) according to one of the preceding claims, wherein the plate substrate (1 0) has a substantially rectangular shape,

wherein supply and / or Abführöffnungen (2, 2 ', 3, 3') are formed in the region on opposite first - preferably shorter - sides of the rectangular shape and wherein flow directions of first and / or second heat transfer fluids (F1, F2) and / or main extension directions of flow channels (20k, 20k ') are formed substantially along extension directions of opposite second, preferably longer, sides of the rectangular shape. 7. plate heat exchanger (1 00),

 with a plurality of heat exchanger plates (1; 1j, j = 1, n) according to one of claims 1 to 1 6,

 wherein the heat exchanger plates (1; 1j, j = 1, n) are designed and arranged in such a way:

 in that the rear or underside (10 u) of the plate substrate (1) of a respective preceding heat exchanger plate (1; 1 j, j = 1, n-1) of the front or top side (1 oo) of the plate substrate (1) each directly following Heat transfer plate (1; 1j + 1, j = 1, n-1) is directly opposite and directly to or with a seal assembly (6, 4-1, 4-2) is applied to this,

 by the sequence of the heat exchanger plates (1, 1j, j = 1, n) and / or in particular by the formation of the seal arrangement (6, 4-1, 4-2) from each other directly successive flow separated flow chambers (R1, Rn + 1 ) are formed,

 directly adjacent throughflow spaces (Rj, Rj + 1, j = 1, n) are separated in pairs in terms of flow, and

in each case adjacent throughflow spaces (Rj, Rj + 2, j = 1, n-1) are connected in pairs in terms of flow, in each case assigned to a heat transfer fluid (F1, F2) and for flowing through respectively assigned heat transfer fluid (F1, F2) from the respective supply opening ( 2, 2 ') to the respective discharge opening (3, 3') are formed out.

1 8. Method for producing a heat exchanger plate (1) for a plate heat exchanger (100),

 with the steps:

 Providing or forming a disk substrate (1 0) with or from a SiC material (1 0 ') or a Siliziumcarbidmaterial (1 0') having a front or top (1 0o) and a back or bottom (1 0u), Forming a flow channel arrangement (20) with a plurality of flow channels (20k) on the front or top side (10o) of the plate substrate (10),

 wherein a part or all of the flow channels (20k) of the flow channel arrangement (20) are formed completely or in sections with channel channels (20r) delimiting channel walls (20w) forming channel webs (20s).

1 9. The method of claim 1 8,

 wherein the disk substrate (10) is formed with or made of a sintered silicon carbide material (10) or SSiC material (10 ').

20. The method according to any one of the preceding claims 1 8 or 19,

 wherein flow channels (20k) of the flow channel arrangement (20) are formed completely or in sections with a multi-undulated course,

 wherein the Undulationsrichtung (U) in a plane defined by the plate substrate (1 0) surface or plane and / or perpendicular to the flow channel (20k) locally or in the middle defined flow direction is formed running and

 in particular, the shape of the undulation is one of the group of shapes having sawtooth shapes, alternating step shapes, waveforms, sine shapes, and combinations thereof.