The invention relates to a heat transfer plate and a gasket for such a heat transfer plate.
Plate heat exchangers, PHEs, typically comprises two end plates in between which a number of heat transfer plates are arranged in a stack or pack. The heat transfer plates of a PHE may be of the same or different types and they may be stacked in different ways. In some PHEs, the heat transfer plates are stacked with the front side and the back side of one heat transfer plate facing the back side and the front side, respectively, of other heat transfer plates, and every other heat transfer plate turned upside down in relation to the rest of the heat transfer plates. Typically, this is referred to as the heat transfer plates being “rotated” in relation to each other. In other PHEs, the heat transfer plates are stacked with the front side and the back side of one heat transfer plate facing the front side and back side, respectively, of other heat transfer plates, and every other heat transfer plate turned upside down in relation to the rest of the heat transfer plates. Typically, this is referred to as the heat transfer plates being “flipped” in relation to each other.
In one type of well-known PHEs, the so called gasketed PHEs, gaskets are arranged between the heat transfer plates in gasket grooves pressed in the heat transfer plates. The end plates, and therefore the heat transfer plates, are pressed towards each other by some kind of tightening means, whereby the gaskets seal between the heat transfer plates. Parallel flow channels are formed between the heat transfer plates, one channel between each pair of adjacent heat transfer plates. Two fluids of initially different temperatures, which are fed to/from the PHE through inlets/outlets, can flow alternately through every second channel for transferring heat from one fluid to the other, which fluids enter/exit the channels through inlet/outlet portholes in the heat transfer plates communicating with the inlets/outlets of the PHE.
Typically, a heat transfer plate comprises two end portions and an intermediate heat transfer portion. The end portions comprise the inlet and outlet portholes, distribution areas pressed with a distribution pattern of ridges and valleys, and intermediate adiabatic areas pressed with an adiabatic pattern of ridges and valleys. Similarly, the heat transfer portion comprises a heat transfer area pressed with a heat transfer pattern of ridges and valleys. The ridges and valleys of the distribution, adiabatic and heat transfer patterns of the heat transfer plate are arranged to contact, in contact areas, the ridges and valleys of distribution, adiabatic and heat transfer patterns of adjacent heat transfer plates in a plate heat exchanger. The main task of the adiabatic areas is to convey fluids entering the channels to the distribution areas, and to convey the fluids from the distribution areas out of the channels. The main task of the distribution areas of the heat transfer plates is to spread the fluids across the width of the heat transfer plates before the fluids reach the heat transfer areas, and to collect the fluids after they have passed the heat transfer areas. The main task of the heat transfer areas is heat transfer. Since the adiabatic, distribution and heat transfer areas have different main tasks, the adiabatic, distribution and heat transfer patterns typically differ from each other.
Thus, in a gasketed plate heat exchanger ready for operation, the heat transfer plates are aligned with each other in a plate pack with gaskets arranged between each two adjacent ones of the heat transfer plates. Typically, the gaskets on the opposite sides of one and the same heat transfer plates are aligned with each other along most of their extension. However, to make it possible for two fluids to flow alternately through every second channel of the plate heat exchanger as described above, the gaskets on the opposite sides of one and the same heat transfer plate are not aligned with each other along parts of their extension. Along these parts, there is gasket support on only one side of the heat transfer plate.
For the plate heat exchanger to work properly, the heat transfer plates should contact each other within the above mentioned contact areas to make the plate pack strong, while the heat transfer plates should be separated from each other within other areas to allow the fluids to flow through the plate pack. However, depending on different factors such as the strength of the individual heat transfer plates, the tension between the heat transfer plates and the gaskets, and the fluid pressures inside the channels between the heat transfer plates, the heat transfer plates may suffer from deformation, especially close to areas where there is gasket support only on one side of the heat transfer plates. Such deformation may disturb the desired contact and separation between the plates. In turn, this may result in an impaired capacity or malfunctioning of the plate heat exchanger.
An object of the present invention is to provide a heat transfer plate and a gasket which at least partly solve the above discussed problem of prior art. The basic concept of the invention is to locally vary a press depth of the heat transfer plate, and a thickness of a body of the gasket, to make the heat transfer plate less prone to deformation. The heat transfer plate, which is also referred to herein as just “plate”, and the gasket for achieving the object above are defined in the appended claims and discussed below.
A heat transfer plate according to the invention comprises an upper end portion, a center portion and a lower end portion arranged in succession along a longitudinal center axis of the heat transfer plate. The upper end portion comprises a first and a second porthole and an upper distribution area provided with an upper distribution corrugation pattern. The lower end portion comprises a third and a fourth porthole and a lower distribution area provided with a lower distribution corrugation pattern. The center portion comprises a heat transfer area provided with a heat transfer corrugation pattern differing from the upper and lower distribution corrugation patterns. The heat transfer plate further comprises, on a front side thereof, a front gasket groove including an annular front groove part extending around the heat transfer area, the upper and lower distribution areas, and the first and third portholes, a second ring groove part enclosing the second porthole and a fourth ring groove part enclosing the fourth porthole. The upper end portion further comprises a second adiabatic area extending between the annular front groove part and the second ring groove part. The lower end portion further comprises a fourth adiabatic area extending between the annular front groove part and the fourth ring groove part. An upper front groove portion of the front gasket groove extends between the second porthole and the upper distribution area and comprises a bottom. A lower front groove portion of the front gasket groove extends between the fourth porthole and the lower distribution area and comprises a bottom. The heat transfer plate is characterized in that the bottom of the upper front groove portion is inclined or tilted such that a depth of the front gasket groove, within the upper front groove portion, increases in a direction towards the second adiabatic area, and the bottom of the lower front groove portion is inclined or tilted such that a depth of the front gasket groove, within the lower front groove portion, increases in a direction towards the fourth adiabatic area.
Here, the depth equals a distance between the bottom of a groove and a reference plane which is parallel to a central extension plane of the heat transfer plate, and the depth is measured perpendicular to the central extension plane.
Thus, the heat transfer plate is characterized in that a depth of the front gasket groove, within the upper and lower front groove portions, increases, from a first smallest depth to a first largest depth, along a transverse extension of the upper and lower front groove portions so as to be the first largest depth closest to the second and fourth adiabatic areas.
Imaginary upper and lower planes may define an extension of the heat transfer plate within the heat transfer area. A bottom of the front gasket groove, may, along more than half of its longitudinal extension, extend in the imaginary lower plane. Such an embodiment may facilitate permanent bonding of the heat transfer plate and an underlaying suitably designed heat transfer plate, possibly another heat transfer plate according to the present invention, into a cassette for use in a so-called semi-welded plate heat exchanger. Alternatively, the bottom of the front gasket groove, may, along more than half of its longitudinal extension, extend between, such as half way between, the imaginary upper and lower planes. Such an embodiment may enable use of the heat transfer plate in a plate heat exchanger with heat transfer plates rotated, as well as flipped, in relation to each other, and may be suitable for so-called asymmetric heat transfer plates.
The front gasket groove is arranged to accommodate a gasket for sealing, and definition of a front fluid channel, between the heat transfer plate and an overlaying suitably designed heat transfer plate, possibly another heat transfer plate according to the present invention. The front fluid channel may allow a fluid flow between the first and the third porthole of the heat transfer plate. The heat transfer plate is further arranged to cooperate with an underlaying suitably designed heat transfer plate, possibly yet another heat transfer plate according to the present invention, for definition of a back fluid channel. The back fluid channel may allow a fluid flow between the second and the fourth porthole of the heat transfer plate, i.e. a fluid flow through passages defined by a backside of the upper and lower front groove portions of the front gasket groove of the heat transfer plate. To achieve the above fluid flows, there should be no gasket on the backside, but only on the front side of the upper and lower front groove portions of the front gasket groove of the heat transfer plate. As above discussed, a heat transfer plate arranged in a plate heat exchanger may be prone to deformation close to areas with one-sided gasket support. By varying the depth of the upper and lower front groove portions of the front gasket groove of the heat transfer plate according to the present invention, undesired deformation of the heat transfer plate close to the upper and lower front groove portions of the front gasket groove may be minimized when the heat transfer plate is arranged in a plate heat exchanger together with gaskets and other heat transfer plates, which may ensure a proper performance of the plate heat exchanger.
In line with the above, the heat transfer plate may further comprise, on a back side thereof, a back gasket groove including an annular back groove part extending around the heat transfer area, the upper and lower distribution areas and the second and fourth portholes, a first ring groove part enclosing the first porthole and a third ring groove part enclosing the third porthole. Further, the upper end portion may comprise a first adiabatic area extending between the annular back groove part and the first ring groove part, and the lower end portion may comprise a third adiabatic area extending between the annular back groove part and the third ring groove part. An upper back groove portion of the back gasket groove may extend between the first porthole and the upper distribution area and comprise a bottom. A lower back groove portion of the back gasket groove may extend between the third porthole and the lower distribution area and comprise a bottom. The bottom of the upper back groove portion may be inclined or tilted such that a depth of the back gasket groove, within the upper back groove portion, increases in a direction towards the first adiabatic area. Further, the bottom of the lower back groove portion may be inclined or tilted such that a depth of the back gasket groove, within the lower back groove portion, increases in a direction towards the third adiabatic area.
Herein, “annular” does not necessarily means a circular extension, but could mean any enclosing extension, such as an oval or polygonal extension. Accordingly, the annular front and back groove parts of the front and back gasket grooves need not be circular but may have any form suitable for the heat transfer plate. Similarly, the second and fourth ring groove parts of the front gasket groove, and the first and third ring groove parts of the back gasket groove, need not be circular but may have any form suitable for the heat transfer plate, and especially the portholes thereof.
The first, second, third and fourth adiabatic areas may be provided with a first adiabatic corrugation pattern, a second adiabatic corrugation pattern, a third adiabatic corrugation pattern and a fourth adiabatic corrugation pattern, respectively, which first, second, third and fourth adiabatic corrugation patterns may differ from the upper and lower distribution corrugation patterns and the heat transfer corrugation pattern.
The depth of the front gasket groove, within the upper front groove portion and the lower front groove portion, and possibly the depth of the back gasket groove, within the upper back groove portion and the lower back groove portion, may be gradually increasing along the transverse extension of the upper and lower front groove portions of the front gasket groove, and along a transverse extension of the upper and lower back groove portions of the back gasket groove, respectively. For example, the gradual increase may be step-wise or wavelike. As another example, the depth may be linearly increasing in which case the bottom of the upper front groove portion and the bottom of the lower front groove portion, and possibly the bottom of the upper back groove portion and the bottom of the lower back groove portion, may be plane. This configuration may enable a relatively straight forward design of the heat transfer plate.
The heat transfer plate may be so designed that the upper front groove portion of the front gasket groove is comprised in an upper diagonal portion of the annular front groove part of the front gasket groove, which upper diagonal portion extends between the second adiabatic area and the upper distribution area. Further, said lower front groove portion of the front gasket groove may be comprised in a lower diagonal portion of the annular front groove part of the front gasket groove, which lower diagonal portion extends between the fourth adiabatic area and the lower distribution area. Thereby, the depth of the upper and lower front groove portions of the front gasket groove will increase in a direction towards the second and fourth portholes. Such an embodiment may strengthen the heat transfer plate close to the upper and lower diagonal portions. Consequently, deformation, by fluid pressure, of the heat transfer plate close to the upper and lower diagonal portions may be prevented when the heat transfer plate is arranged in a plate heat exchanger. In turn, this may ensure that the desired contact between the heat transfer plate and adjacent heat transfer plates in the plate heat exchanger is achieved.
Alternatively/additionally, the heat transfer plate may be so designed that the upper front groove portion of the front gasket groove is comprised in an inner portion of the second ring groove part of the front gasket groove, which inner portion extends between the second porthole and the second adiabatic area. Further, the lower front groove portion of the front gasket groove may be comprised in an inner portion of the fourth ring groove part of the front gasket groove, which inner portion extends between the fourth porthole and the fourth adiabatic area. Thereby, the depth of the upper and lower front groove portions of the front gasket groove will increase in a direction away from the second and fourth portholes. The inner portion of the second ring groove part may be 25-65% of the second ring groove part. Similarly, the inner portion of the fourth ring groove part may be 25-65% of the fourth ring groove part. This embodiment may strengthen the heat transfer plate close to the upper and lower diagonal portions. Consequently, deformation, by fluid pressure, of the heat transfer plate close to the inner portions of the second and fourth ring groove parts may be prevented when the heat transfer plate is arranged in a plate heat exchanger. In turn, this may ensure that the desired contact between the heat transfer plate and adjacent heat transfer plates in the plate heat exchanger is achieved
The portholes of the heat transfer plate are defined by inner plate edges which may, or may not, be corrugated. The heat transfer plate may be so designed that a bottom of the second ring groove part comprises an annular second inner edge defining the second porthole, while a bottom of the fourth ring groove comprises an annular fourth inner edge defining the fourth porthole. According to this embodiment, the second and fourth ring groove parts extend all the way to the second and fourth portholes, respectively. If the bottoms of the second and fourth ring groove parts are plane, this embodiment means that the second and fourth portholes of the heat transfer plate are defined by plane, i.e. not corrugated, inner plate edges. By omitting the corrugation around the second and fourth portholes, the hygiene of the heat transfer plate may be improved, and the plate surface available for heat transfer may be increased. By varying, in accordance with the present invention, the depth of the front gasket groove within the inner portions of the second and fourth ring groove parts on a heat transfer plate without corrugations around the portholes, the heat transfer plate may be “pre-deformed” in one direction. When the heat transfer plate is arranged in a plate heat exchanger, an overlying heat transfer plate and an intermediate gasket accommodated in the second and fourth ring groove parts of the heat transfer plate will deform the heat transfer plate in the opposite direction. This will result in a reset of the “pre-deformation” and inner plate edges extending, at least along part of their extension, essentially parallel to the central extension plane of the heat transfer plate, i.e. the desired separation between the heat transfer plate and the adjacent heat transfer plates in the plate heat exchanger. In turn, this will decrease a pressure drop for a fluid entering a channel defined by the back side of the heat transfer plate.
The heat transfer plate may be so designed that the first and third portholes are arranged on one side of the longitudinal center axis of the heat transfer plate, and the second and fourth portholes are arranged on another opposite side of the longitudinal center axis. Thereby, the heat transfer plate may be suitable for use in a plate heat exchanger of so-called parallel flow type. Such a parallel-flow heat exchanger may comprise only one plate type. If instead the first and fourth portholes are arranged on one and the same side, and the second and third porthole are arranged on the same and the other side, of the longitudinal center axis, which is also possible according to the invention, the plate may be suitable for use in a plate heat exchanger of so-called diagonal flow type. Such a diagonal flow heat exchanger may typically comprise more than one plate type.
The heat transfer plate may be so designed that the upper front groove portion of the front gasket groove is a mirroring, parallel to a transverse center axis of the heat transfer plate, of the lower front groove portion of the front gasket groove. This may enable a plate pack containing only heat transfer plates according to the present invention.
Naturally, different designs of the back gasket groove corresponding to the above discussed different designs of the front gasket groove are conceivable.
A gasket for a plate heat exchanger according to the invention comprises an annular gasket part, an annular second ring gasket part and an annular fourth ring gasket part. The second and fourth ring gasket parts are arranged outside, and on opposite sides of, the annular gasket part. The second ring gasket part and the annular gasket part are separated by a second intermediate space and the fourth ring gasket part and the annular gasket part are separated by a fourth intermediate space. An upper gasket portion of the gasket limits, defines or extends along the second intermediate space. A lower gasket portion of the gasket limits, defines or extends along the fourth intermediate space. The gasket comprises a body extending along the complete annular gasket part and second and fourth ring gasket parts and comprising an upper side and an opposing lower side. The upper and lower sides of the gasket body define a thickness of the body. The gasket is characterized in that the thickness of the body of the gasket, within the upper gasket portion, increases in a direction towards the second intermediate space and, within the lower gasket portion, increases in a direction towards the fourth intermediate space.
The thickness of the body of the gasket may, within the upper gasket portion and the lower gasket portion, be gradually, possibly linearly, increasing along a transverse extension of the upper and lower gasket portions of the gasket.
The upper and lower sides of the gasket body may be essentially plane.
The upper gasket portion of the gasket may be comprised in an upper diagonal portion of the annular gasket part of the gasket, which upper diagonal portion extends on an inside of the second ring gasket part of the gasket. The lower gasket portion of the gasket may be comprised in a lower diagonal portion of the annular gasket part of the gasket, which lower diagonal portion extends on an inside of the fourth ring gasket part of the gasket.
Alternatively/additionally, the upper gasket portion of the gasket may be comprised in an inner portion of the second ring gasket part of the gasket, which inner portion extends between an outer portion of the second ring gasket part of the gasket and an upper diagonal portion of the annular gasket part of the gasket, which upper diagonal portion extends on an inside of the second ring gasket part of the gasket. Further, the lower gasket portion of the gasket may be comprised in an inner portion of the fourth ring gasket part of the gasket, which inner portion extends between an outer portion of the fourth ring gasket part of the gasket and a lower diagonal portion of the annular gasket part of the gasket, which lower diagonal portion extends on an inside of the fourth ring gasket part of the gasket.
The gasket may further comprise at least one elongate projection projecting from one of the upper side and the lower side of the body and extending along at least the upper and lower gasket portions of the gasket. Such a projection may improve the sealing capability of the gasket.
The at least one elongate projection may be arranged offset from a second center plane of the body. Thereby, the sealing features of the gasket may be optimized.
The gasket may be so configured that the second center plane of the body of the gasket is arranged between the at least one projection and the second intermediate space within the upper gasket portion, and between the at least one projection and the fourth intermediate space within the lower gasket portion. Such an arrangement may position the projection relatively close to a fluid when the gasket is arranged between two heat transfer plates in a plate heat exchanger, which in turn may enable early prevention of fluid leakage.
The gasket may have such a design that the second and fourth ring gasket parts of the gasket are arranged on one and the same side of a longitudinal center axis of the gasket.
The upper gasket portion of the gasket may be a mirroring, parallel to a transverse center axis of the gasket, of the lower gasket portion of the gasket.
The heat transfer plate and the gasket according to the invention are adapted to be used together, and the design of the gasket is adapted to the design of the heat transfer plate, and vice versa. Thus, the above different embodiments of the gasket according to the invention correspond to the above different embodiments of the heat transfer plate according to the invention. Accordingly, the advantages of the above different embodiments of the heat transfer plate are transferable to the above different embodiments of the gasket. Naturally, these advantages appear first when the heat transfer plate and the gasket cooperate with each other and other suitably designed heat transfer plates and gaskets in a plate heat exchanger.
Still other objectives, features, aspects and advantages of the invention will appear from the following detailed description as well as from the drawings.
The invention will now be described in more detail with reference to the appended schematic drawings, in which
With reference to
The heat transfer plate 1 is pressed, in a conventional manner, in a pressing tool, to be given a desired structure, such as different corrugation patterns within different portions of the heat transfer plate. As was discussed by way of introduction, the corrugation patterns are optimized for the specific functions of the respective plate portions. Accordingly, the upper and lower distribution areas 13 and 25 are provided with a distribution pattern of chocolate type while the heat transfer area 33 is provided with a heat transfer pattern of herringbone type. The first, second, third and fourth adiabatic areas 15, 17, 27 and 29 comprise corrugations adapted to transfer a fluid with minimized heat transfer. Further, the outer edge portion 35 comprises corrugations 41 which make the outer edge portion 35 stiffer and, thus, the heat transfer plate 1 more resistant to deformation. Further, the corrugations 41 form a support structure in that they are arranged to abut corrugations within outer edge portions of adjacent heat transfer plates in a plate pack of a heat exchanger. The corrugations 41 extend between and in imaginary lower and upper planes P1 and P2 (
With reference to
With reference to
With reference to
With reference to
As said above, in a gasketed plate heat exchanger, a plurality of heat transfer plates like the heat transfer plate 1 are aligned in a plate pack, here “rotated” in relation to each other. Between each two adjacent ones of the heat transfer plates, a rubber gasket 2 as illustrated in
With reference to
The design of the gasket 2 is adapted to the design of the plate 1, and vice versa. Accordingly, the upper and lower sides 18 and 20 of the gasket body 16 extend parallel to each other, and to a first center plane C1 of the gasket body 16, along essentially the complete extension of the annular gasket part 4. Thereby, along essentially the complete extension of the annular gasket part 4, the thickness of the gasket body 16 is essentially constant along a transverse extension of the gasket body 16, even if the thickness may vary within different longitudinal sections of the annular gasket part 4. As an example, the thickness of the gasket body 16 along the portions of annular gasket part 4 arranged to extend along the two opposite long sides of the heat transfer plate 1 may differ from the thickness of the gasket body 16 along upper and lower diagonal portions 22 and 24 of the annular gasket part 4 extending on an inside of the second and fourth ring gasket parts 6 and 8. Further, along an upper gasket portion 26 defining the second intermediate space 10, here an inner portion 28 of the second ring gasket part 6 (bold reference numerals in
Besides for the body 16, the gasket 2 further comprises an elongate upper projection 42 projecting from the upper side 18 of the body 16 and an elongate lower projection 44 projecting from the lower side 20 of the body 16. The upper projection 42 extends along the annular gasket part 4, the second ring gasket part 6 and the fourth ring gasket part 8, while the lower projection 44 extends along the inner portions 28 and 36 of the second and fourth ring gasket parts 6, 8 only. The opposing upper and lower projections 42 and 44 are arranged offset from a second center plane C2, which is orthogonal to the first center plane C1. Within the annular gasket part 4 of the gasket 2, the upper projection 42 is displaced towards an inner periphery 46 of the annular gasket part 4, within the second ring gasket part 6 of the gasket 2 the upper and lower projections 42 and 44 are displaced towards an inner periphery 48 of the second ring gasket part 6, and within the fourth ring gasket part 8 of the gasket 2 the upper and lower projections 42 and 44 are displaced towards an inner periphery 50 of the fourth ring gasket part 8.
While the gasket 2 illustrated in
Along an inner portion 58 of the first ring gasket part 54, the lower side 20 of the gasket body 16 is inclined an angle, here 2 degrees, in relation to the upper side 18 of the gasket body 16. Thereby, the thickness of the gasket body 16, within the inner portion 58 of the first ring gasket part 54 is linearly gradually increasing in a direction towards an outer portion 60 of the first ring gasket part 54. Within the outer portion 60 of the first ring gasket part 54, the upper and lower sides 18 and 20 of the gasket body 16 extend parallel to each other, so as to give the gasket body 16 an essentially constant thickness along a transverse extension of the gasket body 16. Further, along an inner portion 62 of the third ring gasket part 56, the lower side 20 of the gasket body 16 is inclined an angle, here 2 degrees, in relation to the upper side 18 of the gasket body 16. Thereby, the thickness of the gasket body 16, within the inner portion 62 of the third ring gasket part 56 is linearly gradually increasing in a direction towards an outer portion 64 of the third ring gasket part 56. Within the outer portion 64 of the third ring gasket part 56, the upper and lower sides 18 and 20 of the gasket body 16 extend parallel to each other, so as to give the gasket body 16 an essentially constant thickness along a transverse extension of the gasket body 16. The upper projection 42 extends, inwards offset, along the first and third ring gasket parts 54 and 56, while the lower projection 44 extends, inwards offset, along the inner portions 58 and 62 of the first and third ring gasket parts 54 and 56.
Above, the pressing depth of the heat transfer plate is varied around the portholes such as to achieve ring groove parts having partly inclined bottoms. Further, the design of the gasket is varied such as to achieve a partly radially tapered ring gasket body. Instead of, or in addition to, varying the ring groove part pressing depth and the ring gasket body thickness, the pressing depth and the gasket body thickness may, according to the invention, be varied within other plate areas and gasket areas, respectively. Hereinafter, a heat transfer plate 1 and a gasket 2 according to an alternative embodiment of the invention will be described. This plate and this gasket, which essentially are designed as illustrated in
Besides for the body 16, the gasket 2 according to the alternative embodiment further comprises three elongate upper projections 42a, 42b and 42c projecting from the upper side 18 of the body 16, and no projection projecting from the lower side 20 of the body 16. The upper projections 42a, 42b and 42c extend along each other and along the complete extension of body 16. One of the upper projections 42b is arranged aligned with a second center plane C2 of the gasket body 16, while the remaining two upper projections 42a and 42c are arranged on opposite sides of the upper projection 42b.
The above described embodiments of the present invention should only be seen as examples. A person skilled in the art realizes that the embodiments discussed can be varied and combined in a number of ways without deviating from the inventive conception.
In the above described embodiments, the upper and lower sides 18 and 20 of the gasket body 16 are both inclined within the upper and lower gasket portions 26 and 34 of the gasket 2 to achieve the varying thickness of the gasket body 16. Naturally, a varying body thickness may instead be achieved by having only one of the upper and lower sides 18 and 20 inclined.
Further, in the above described embodiments, the upper and lower sides of the gasket body are inclined with the same angle/angles within the upper and lower gasket portions of the gasket. This need not be the case in alternative embodiments.
In the above described embodiments, the bottoms of the upper and lower front groove portions and the bottoms of the upper and lower back groove portions are all inclined to achieve a varying groove depth. According to an alternative embodiment, only the bottoms of either the upper and lower front groove portions or the upper and lower back groove portions are inclined.
Further, in the above described embodiments, the bottoms of the upper and lower front groove portions and the bottoms of the upper and lower back groove portions are all inclined with the same angle. This need not be the case in alternative embodiments.
The imaginary plane P3 used above to define gasket groove depth may or may not be arranged half way between the planes P1 and P2. According to alternative embodiments, the plane P3 may also coincide with the imaginary lower plane P1.
The borders of the upper and lower front groove portions, the upper and lower back groove portions and the upper and lower gasket portions may be endlessly varied so as to reposition, reduce or expand the areas within which the groove depth and the gasket body thickness are varied. As an example, the groove depth and the gasket body thickness could be varied within the complete ring groove parts and ring gasket parts, respectively.
The number, extension, design and/or positioning of upper and lower projections of the gasket could be varied endlessly.
In the above described embodiments, the heat transfer plates of the plate pack and the gaskets between the heat transfer plates are all similar, but this is not mandatory. As an example, in an alternative plate pack, plates of different types may be combined, such as plates having differently configurated heat transfer patterns.
The heat transfer plate need not be rectangular but may have other shapes, such as essentially rectangular with rounded corners instead of right corners, circular or oval. The portholes of the plates may have other forms than illustrated in the drawings, such as a circular form. The heat transfer plate need not be made of stainless steel but could be of other materials, such as titanium or aluminium. Similarly, the gaskets need not be made of rubber.
The inventive heat transfer plate could be used in connection with other types of plate heat exchangers than gasketed ones, for example semi-welded plate heat exchangers. Further, the plates in the plate pack could be “flipped” instead of “rotated” in relation to each other.
The heat transfer plate need not be provided with a heat transfer pattern of herringbone type and distribution patterns of chocolate type but could be provided with other patterns, both symmetric and asymmetric patterns.
It should be stressed that the attributes front, back, upper, lower, first, second, third, etc. is used herein just to distinguish between details and not to express any kind of orientation or mutual order between the details.
Further, it should be stressed that a description of details not relevant to the present invention has been omitted and that the figures are just schematic and not drawn according to scale. It should also be said that some of the figures have been more simplified than others. Therefore, some components may be illustrated in one figure but left out on another figure.
Number | Date | Country | Kind |
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21170710.4 | Apr 2021 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/058769 | 4/1/2022 | WO |