The invention relates to a heat transfer plate and its design. The invention also relates to a plate pack for a heat exchanger comprising a plurality of such heat transfer plates.
Plate heat exchangers, PHEs, typically consist of 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. 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 port holes in the heat transfer plates communicating with the inlets/outlets of the PHE.
The end plates of a gasketed PHE are often referred to as frame plate and pressure plate. The frame plate is often fixed to a support surface such as the floor while the pressure plate is movable in relation to the frame plate. Often, an upper carrying bar for carrying the heat transfer plates, and possibly also the pressure plate, is fastened to the frame plate and extends from an upper part thereof, past the pressure plate and to a support column. Similarly, a lower guiding bar for guiding the heat transfer plates, and possibly also the pressure plate, is fastened to the frame plate and extends from a lower part thereof, on a distance from the ground, past the pressure plate and to the support column.
For a PHE to work properly, it is important that the heat transfer plates are aligned with each other in the stack since non-aligned heat transfer plates may result in a leaking PHE. Although the carrying and guiding bars of a heat exchanger may provide alignment of, by engagement with, the heat transfer plates, this alignment may be insufficient. Also, some PHEs may lack a carrying bar and/or a guiding bar. In view thereof, some heat transfer plates are provided with guiding sections wherein a guiding section of one heat transfer plate is arranged to engage with a guiding section of another heat transfer plate for alignment of the heat transfer plates. WO 2010/064975 discloses such heat transfer plates arranged in a stack wherein every other heat transfer plate is “rotated” in relation to the other heat transfer plates. Although WO 2010/064975 discloses a guiding solution that works very well, it is limited to alignment of heat transfer plates “rotated” in relation to each other.
An object of the present invention is to provide a heat transfer plate which solves the above mentioned problem. The basic concept of the invention is to provide the heat transfer plate with a guiding solution which is more flexible than known solutions in that it enables alignment of the heat transfer plate and another heat transfer plate irrespective of whether the two heat transfer plates are “rotated” or “flipped” in relation to each other. Another object of the present invention is to provide a plate pack for a heat exchanger comprising a first, a second and a third such heat transfer plate. The heat transfer plate and the plate pack for achieving the objects above are defined in the appended claims and discussed below.
A heat transfer plate according to the present invention has opposing first and second sides, an outer edge and a central extension plane and includes an edge portion comprising corrugations. The corrugations extend between first and second planes which are parallel to the central extension plane, and the central extension plane is arranged between the first and second planes. The corrugations are arranged, at the first side of the heat transfer plate, to abut a first adjacent heat transfer plate, and at the second side of the heat transfer plate, to abut a second adjacent heat transfer plate, when the heat transfer plate is arranged in a plate heat exchanger. Longitudinal and transverse centre axes of the heat transfer plate extending parallel to the central extension plane and perpendicular to each other, define a first, a second, a third and a fourth plate area. The first and second plate areas are arranged on the same side of the transverse centre axis and the first and the third plate areas are arranged on the same side of the longitudinal centre axis. The first, third and fourth plate areas comprise a first, third and fourth guiding section, respectively. The heat transfer plate is characterized in that the first and fourth guiding sections each comprise, as seen from the first side of the heat transfer plate, a male projection projecting beyond the first plane and arranged to engage with the first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate, and, as seen from the second side of the heat transfer plate, a female recess arranged to engage with the second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate. Further, the third guiding section comprises, as seen from the second side of the heat transfer plate, a male projection projecting beyond the second plane and arranged to engage with the second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate, and, as seen from the first side of the heat transfer plate, a female recess arranged to engage with the first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate.
The first and second sides of the heat transfer plate may also be referred to as front and back side.
The central extension plane may be arranged half way between the first and second planes.
The longitudinal centre axis may extend along opposing long sides of the heat transfer plate, while the transverse centre axis may extend along opposing short sides of the heat transfer plate.
The edge portion may be an outer peripheral edge portion of the heat transfer plate or an inner edge portion such as an edge portion defining a port hole of the heat transfer plate. Further, the complete edge portion, or only one or more portions thereof, may comprise corrugations. The corrugations may be evenly or unevenly distributed along the edge portion, and they may, or may not, all look the same. The edge portion may comprise further corrugations extending within or outside the first and second planes.
The corrugations define ridges and valleys which may give the edge portion a wave-like design. As seen from the first side of the plate, when the heat transfer plate is arranged in a plate heat exchanger, the ridges are arranged to abut the first adjacent plate while the valleys are arranged to abut the second adjacent heat transfer plate.
The heat transfer plate may be essentially rectangular, and the longitudinal and transverse centre axes essentially perpendicular to each other so as to define four essentially rectangular plate areas.
“As seen from the first side of the heat transfer plate” means when the first side of the heat transfer plate is viewed at a distance. Similarly, “as seen from the second side of the heat transfer plate” means when the second side of the heat transfer plate is viewed at a distance.
The heat transfer plate and the first and second adjacent heat transfer plates may all be of the same type. Alternatively, the heat transfer plate and the first and second adjacent heat transfer plates may be of different types. For example, the heat transfer plate and the first and second adjacent heat transfer plates may all comprise guiding sections as defined in the claims but otherwise be differently designed.
The above configuration of the guiding sections may enable alignment of the heat transfer plate and an adjacent heat transfer plate irrespective of whether the adjacent heat transfer plate is rotated or flipped with respect to the heat transfer plate. Further, alignment of the heat transfer plate and the adjacent heat transfer plate by means of at least two of the guiding sections of the heat transfer plate may be enabled, which improves the alignment. Moreover, alignment of the heat transfer plate and two adjacent heat transfer plates, e.g. the first and second adjacent heat transfer plates referred to above, by means of each of said at least two of the guiding sections of the heat transfer plate may be enabled, which improves the alignment. The alignment enablement is naturally dependent on the design of the adjacent heat transfer plate(s).
The second plate area may comprise a second guiding section comprising, as seen from the second side of the heat transfer plate, a male projection projecting beyond the second plane and arranged to engage with the second adjacent heat transfer plate for alignment of the heat transfer plate and the second adjacent heat transfer plate, and, as seen from the first side of the heat transfer plate, a female recess arranged to engage with the first adjacent heat transfer plate for alignment of the heat transfer plate and the first adjacent heat transfer plate. Thereby, alignment of the heat transfer plate and the adjacent heat transfer plate by means of all of the guiding sections of the heat transfer plate may be enabled, which improves the alignment. Moreover, alignment of the heat transfer plate and two adjacent heat transfer plates, e.g. the first and second adjacent heat transfer plates referred to above, by means of each of all the guiding sections of the heat transfer plate may be enabled, which improves the alignment. Again, the alignment enablement is naturally dependent on the design of the adjacent heat transfer plate(s).
A respective top of the male projections of the first and second guiding sections may extend from a distance ML1 to a distance ML2 from the transverse centre axis and from a distance MW1 to a distance MW2 from the longitudinal centre axis, and a respective opening or root of the female recesses of the third and fourth guiding sections may extend from a distance FL1 to a distance FL2 from the transverse centre axis and from a distance FW1 to a distance FW2 from the longitudinal centre axis, wherein FL1<ML1<ML2<FL2 and FW1<MW1<MW2<FW2. Further, (each of) the male projections of the first and second guiding sections may fit into (each of) the female recesses of the third and fourth guiding sections. By “fit” is meant that the male projections at least partly could be received in the female recesses. For example, the male projections could have outer circumferences which are smaller than inner circumferences of the female recesses and/or outer surfaces of the male projections could define volumes which are smaller than volumes defined by inner surfaces of the female recesses. Naturally, reception of the male projections of a heat transfer plate in the female recesses of the same heat transfer plate is not relevant and impossible without deforming or cutting the heat transfer plate. However, this embodiment may enable alignment of the heat transfer plate and first and second adjacent heat transfer plates of the same type as the heat transfer plate, or at least comprising guiding sections as above defined, by insertion of the male projections of the first and second guiding sections of the heat transfer plate in the female recesses of the third and fourth guiding sections of the first and second adjacent heat transfer plates, and reception, of the male projections of the first and second guiding sections of the first and second adjacent heat transfer plates, by the female recesses of the third and fourth guiding sections of the heat transfer plate.
A respective top of the male projections of the third and fourth guiding sections may extend from a distance ML3 to a distance ML4 from the transverse centre axis and from a distance MW3 to a distance MW4 from the longitudinal centre axis, and a respective opening or root of the female recesses of the first and second guiding sections may extend from a distance FL3 to a distance FL4 from the transverse centre axis and from a distance FW3 to a distance FW4 from the longitudinal centre axis, wherein FL3<ML3<ML4<FL4 and FW3<MW3<MW4<FW4. Further, (each of) the male projections of the third and fourth guiding sections may fit into (each of) the female recesses of the first and second guiding sections. The meaning of “fit” is as defined above. This embodiment may enable alignment of the heat transfer plate and first and second adjacent heat transfer plates of the same type as the heat transfer plate, or at least comprising guiding sections as above defined, by insertion of the male projections of the third and fourth guiding sections of the heat transfer plate in the female recesses of the first and second guiding sections of the first and second adjacent heat transfer plates, and reception, of the male projections of the third and fourth guiding sections of the first and second adjacent heat transfer plates, by the female recesses of the first and second guiding sections of the heat transfer plate.
The first and fourth guiding sections may each comprise a first plane portion extending between the outer edge of the heat transfer plate and the male projection, or even surrounding the male projection, and extending parallel to the central extension plane. Further, the second and third guiding sections may each comprise a second plane portion extending between the outer edge of the heat transfer plate and the male projection, or even surrounding the male projection, and extending parallel to the central extension plane. This embodiment excludes arrangement of the male projections immediately at an outer edge portion of the heat transfer plate which may improve the stability of the guiding sections.
Similarly, the first and fourth guiding sections may each comprise a second plane portion extending between the outer edge of the heat transfer plate and the female recess, or even surrounding the female recess, and extending parallel to the central extension plane, and the second and third guiding sections may each comprise a first plane portion extending between the outer edge of the heat transfer plate and the female recess, or even surrounding the female recess, and extending parallel to the central extension plane. This embodiment excludes arrangement of the female recesses immediately at an outer edge portion of the heat transfer plate which may improve the stability of the guiding sections.
The first and second plane portions referred to above may extend in different planes. For example, they may extend in the first and the second plane, respectively, of the heat transfer plate. The first and second plane portions may then be arranged to abut the first and the second adjacent heat transfer plate, respectively, which may improve the stability of the guiding sections.
Each of the first plane portions of the first, second, third and fourth guiding sections may “branch” towards the outer edge of the heat transfer plate so as to define and at least partly enclose a respective third plane portion extending in the second plane.
The heat transfer plate may be such that, as seen from the first side of the heat transfer plate, two reinforcement recesses, in relation to the first plane portions, are arranged on opposite sides of each of the first plane portions, and two reinforcement projections, in relation to the second plane portions, are arranged on opposite sides of each of the second plane portions. The reinforcement recesses and projections may be arranged in succession along the outer edge of the heat transfer plate. As implied by the names, the reinforcement recesses and projections are arranged to reinforce and stiffen the heat transfer plate so as to reduce the risk of deformation of the guiding sections of the heat transfer plate when this engages with the first and second adjacent heat transfer plates, which could affect the alignment of the three heat transfer plates negatively. Bottoms of the reinforcement recesses may extend in the second plane while tops of the reinforcement projections may extend in the first plane. The reinforcement recesses and projections may then be arranged to abut the first and the second adjacent heat transfer plate, respectively, which may improve the stability of the guiding sections. For example, one or more of the reinforcement recesses and projections could comprise a respective one of the corrugations of the edge portion of the heat transfer plates.
The first, second, third and fourth guiding sections may be arranged at a respective one of four corners of the heat transfer plate. Then, the guiding sections may be arranged as far from each other as is possible and suitable which may result in an optimized alignment between the heat transfer plate and the first and second adjacent heat transfer plates.
The heat transfer plate may comprise two opposing long sides extending parallel to the longitudinal centre axis and two opposing short sides extending parallel to the transverse centre axis. Within each of the first, second, third and fourth guiding sections, the female recess and the male projection may be arranged on opposite sides of an imaginary straight line extending with an angle of 45 degrees in relation to one of the long sides and one of the short sides of the heat transfer plate. This may result in an optimized alignment between the heat transfer plate and the first and second adjacent heat transfer plates.
The heat transfer plate may be so designed that a depth of the female recesses of the third and fourth guiding sections is a ≥height of the male projections of the first and second guiding sections, and a depth of the female recesses of the first and second guiding sections is a ≥height of the male projections of the third and fourth guiding sections. Such an embodiment may enable that the complete male projections of the heat transfer plate may be received in recesses of first and second adjacent heat transfer plates of the same type as the heat transfer plate, or at least comprising guiding sections as above defined, and that the female recesses of the heat transfer plate completely may receive male projections of the first and second adjacent heat transfer plates. In turn, this enables an optimized alignment of the heat transfer plate and the first and second adjacent heat transfer plates.
At least one of the male projections of the first and second guiding sections and at least one of the female recesses of the third and fourth guiding sections may have an at least partly uniform cross section parallel to the central extension plane. Similarly, at least one of the female recesses of the first and second guiding sections and at least one of the male projections of the third and fourth guiding sections may have an at least partly uniform cross section parallel to the central extension plane. Thereby, a good fit between the male projections and the female recesses of the heat transfer plate and first and second adjacent heat transfer plates of the same type as the heat transfer plate, or at least comprising guiding sections as above defined, may be enabled.
At least one of the male projections of the first and second guiding sections and at least one of the female recesses of the third and fourth guiding sections may have a cross section parallel to the central extension plane comprising two perpendicular portions, i.e. two portions that are perpendicular to each other, each. Similarly, at least one of the female recesses of the first and second guiding sections and at least one of the male projections of the third and fourth guiding sections may have a cross section parallel to the central extension plane comprising two perpendicular portions each. Thereby, alignment, in two perpendicular directions, i.e. optimum alignment, of the heat transfer plate and first and second adjacent heat transfer plates of the same type as the heat transfer plate, or at least comprising guiding sections as above defined, may be enabled.
A plate pack for a heat exchanger according to the invention comprises a first, a second and a third heat transfer plate as described above, which heat transfer plates may or may not be similar. The second heat transfer plate is arranged between the first and third heat transfer plates. When the first and second sides of the second heat transfer plate abut the second side of the first heat transfer plate and the first side of the third heat transfer plate, respectively, and the second heat transfer plate is rotated 180 degrees in relation to the first and third heat transfer plates about an axis extending parallel to a normal of the central extension plane, and through a cross point between the longitudinal and transverse centre axes, of the second heat transfer plate, i.e. when the heat transfer plates are rotated in relation to each other with the above definition,
Further, when the first and second sides of the second heat transfer plate abut the first side of the first heat transfer plate and the second side of the third heat transfer plate, respectively, and the second heat transfer plate is rotated 180 degrees in relation to the first and third heat transfer plates about an axis coinciding with the transverse centre axis of the second heat transfer plate, i.e. when the heat transfer plates are flipped in relation to each other with the above definition,
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 4a will now be further described with reference to
The heat transfer plate further has a longitudinal centre axis 20 extending parallel to, and half way between, the long sides 10, and a transverse centre axis 22 extending parallel to, and half way between, the short sides 12, and thus perpendicular to the longitudinal centre axis 20 (
The heat transfer plate 4a comprises four port holes 32 arranged at a respective one of four corners 34, 36, 38 and 40 of the heat transfer plate, and recesses 42 extending from a respective one of the short sides 12 of the heat transfer plate 4a and arranged to receive carrying and guiding bars of the plate heat exchanger.
The heat transfer plate 4a is pressed, in a conventional manner, in a pressing tool, to be given a desired structure, more particularly different corrugation patterns within different portions of the heat transfer plate. The corrugation patterns are optimized for the specific functions of the respective plate portions. Accordingly, the heat transfer plate 4a comprises two distribution areas 44 which each is provided with a distribution pattern adapted for optimized fluid distribution across the heat transfer plate. Further, the heat transfer plate 4a comprises a heat transfer area 46 arranged between the distribution areas 44 and provided with a heat transfer pattern adapted for optimized heat transfer between two fluids flowing on opposite sides of the heat transfer plate. Moreover, the heat transfer plate 4a comprises inner edge portions 48 surrounding the port holes 32 and an outer edge portion 50 extending along an outer edge 51 of the heat transfer plate 4a. The inner and outer edge portions 48 and 50 comprises corrugations 52 which make the inner and outer edge portions stiffer and, thus, the heat transfer plate 4a more resistant to deformation. Further, the corrugations 52 form a support structure in that they are arranged to abut adjacent heat transfer plates when the heat transfer plate 4a is arranged in the plate heat exchanger. Depending on the design of the distribution and heat transfer patterns, the heat transfer plate 4a may also be arranged to abut adjacent heat transfer plates within the distribution and heat transfer areas 44 and 46, respectively, when the heat transfer plate is arranged in the plate heat exchanger. However, this is not further discussed herein. Also, the heat transfer plate 4a comprises a groove 53 arranged to receive a gasket.
With reference especially to
The first, second, third and fourth plate areas 24, 26, 28 and 30 comprise a first, second, third and fourth guiding section 60, 62, 64 and 66, respectively, arranged at a respective one of the four corners 34, 36, 38 and 40 of the heat transfer plate 4a. With reference especially to
Similarly, with reference especially to
Naturally, the male projections as seen from one side of the heat transfer plate forms female recesses as seen from the other side of the plate, and vice versa.
Thus, as is clear from
The male projections 68, 70, 88 and 90 and the female recesses 78, 80, 98 and 100 all have, parallel to the central extension plane 58, an essentially uniform rectangular cross section, with a cross section of the female recesses being larger than the cross section of the male projections. All the female recesses have essentially the same cross section while all the male projections have essentially the same cross section. Thus, the male projections fit into the female recesses. Further, all the female recesses have essentially the same depth d while all the male projections have essentially the same height h, and d is essentially equal to h. The depth d and height h of the female recess 78 and the male projection 68 of the first guiding section 60 is illustrated in
As is clear from
With reference especially to
Further, the fourth guiding section 66 of the second heat transfer plate 4b engages with the first guiding sections 60 of the first and third heat transfer plates 4a and 4c (
Further, the third guiding section 64 of the second heat transfer plate 4b engages with the second guiding sections 62 of the first and third heat transfer plates 4a and 4c (
Further, the second guiding section 62 of the second heat transfer plate 4b engages with the third guiding sections 64 of the first and third heat transfer plates 4a and 4c (
Further, the first guiding section 60 of the second heat transfer plate 4b engages with the fourth guiding sections 66 of the first and third heat transfer plates 4a and 4c (
Thereby, in the plate pack 2, the second heat transfer plate 4b engages, at all four of its guiding sections 60, 62, 64 and 66, with both the first and the third heat transfer plate 4a, 4c, which results in a reliable and effective alignment of the first, second and third heat transfer plates.
In the above described plate pack 2, the heat transfer plates are “rotated” in relation to each other. In an alternative plate pack according to the invention, the heat transfer plates are instead “flipped” in relation to each other. Accordingly, the second heat transfer plate 4b is arranged between the first and third heat transfer plates 4a and 4c. Further, the first and third heat transfer plates 4a and 4b are both rotated 180 degrees about their respective transverse centre axis 22, in relation to the second heat transfer plate 4b. Thereby, the first and second sides 6 and 8 of the second heat transfer plate 4b abut the first side 6 of the first heat transfer plate 4a and the second side 8 of the third heat transfer plate 4c, respectively. More particularly, portions of the second heat transfer plate 4b extending in the first plane 54 contact opposing portions of the first heat transfer plate 4a extending in the first plane 54, and portions of the second heat transfer plate 4b extending in the second plane 56 contact opposing portions of the third heat transfer plate 4c extending in the second plane 56. For example, as schematically illustrated in
Further, the third guiding section 64 of the second heat transfer plate 4b engages with the first guiding sections 60 of the first and third heat transfer plates 4a and 4c (
Further, the fourth guiding section 66 of the second heat transfer plate 4b engages with the second guiding sections 62 of the first and third heat transfer plates 4a and 4c (
Further, the first guiding section 60 of the second heat transfer plate 4b engages with the third guiding sections 64 of the first and third heat transfer plates 4a and 4c (
Further, the second guiding section 62 of the second heat transfer plate 4b engages with the fourth guiding sections 66 of the first and third heat transfer plates 4a and 4c (
Thereby, in the plate pack above, the second heat transfer plate 4b engages, at all four of its guiding sections 60, 62, 64 and 66, with both the first and the third heat transfer plate 4a, 4c, which results in a reliable and effective alignment of the first, second and third heat transfer plates.
Thus, due to the inventive construction of the first, second, third and fourth guiding sections 60, 62, 64 and 66, the heat transfer plates 4a, 4b and 4c are properly aligned with each other in a plate pack irrespective of whether they are rotated or flipped in relation to each other. Due to the design, and location on the heat transfer plates, of the female recesses and male projections, the actual alignment of the heat transfer plates is performed by means of outer portions of the female recesses and the male projections, i.e. portions of the female recesses and the male projections facing the respective outer edges 51 of the heat transfer plates. Thus, when the heat transfer plates are aligned, the outer portions of the female recesses and the male projections of one heat transfer plate engage with the outer portions of the male projections and the female recesses, respectively, of the adjacent plates. Inner portions of the female recesses and the male projections, i.e. portions of the female recesses and the male projections facing away from the respective outer edges 51 of the heat transfer plates, do not engage with each other.
In that the first and second plane portions 72, 74, 102, 104 and 82, 84, 92 and 94 extend in the first and second planes 54 and 56, and the depth of the female recesses 78, 80, 98 and 100 is equal to the height of the male projections 68, 70, 88 and 90, the first and second plate portions, just like inside bottom surfaces of the female recesses and outside top surfaces of the male projections, will abut each other in the plate pack and so make the plate pack more stable.
The above described embodiments of the present invention should only be seen as an example. 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.
For example, the female recesses and the male projections need not have a rectangular cross section. As an example, they may have a round, triangular or pentagonal cross section, such as the cross section illustrated in
Further, the female recesses need not all have the same cross section and the same depth. Similarly, the male projections need not all have the same cross section and the same height. Also, the depth of the female recesses need not be equal to the height of the male projections but could be larger or even smaller. Also, one or more of the first plane portions of the guiding sections may extend in a plane different from the first plane. Similarly, one or more of the second plane portions of the guiding sections may extend in a plane different from the second plane.
Also, the alignment function need not reside solely within the outer portions of the female recesses and the male projections but could instead reside solely within the inner portions of the female recesses and the male projections, or within one or more of the outer portions and/or one or more of the inner portions of the female recesses and the male projections.
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 heat transfer plate need not be made of stainless steel but could be of other materials, such as titanium or aluminium.
The guiding sections of the heat transfer plate need not be arranged at a respective corner of the heat transfer plate but could be arranged closer to the longitudinal centre axis and/or closer to the transverse centre axis. Also, within each of the guiding sections, the female recess and the male projection need not be arranged on opposite sides, but could instead be arranged on the same side, of the imaginary straight line 108 illustrated in
The plate packs described above comprises one plate type only. Naturally, the plate packs could instead comprise two or more different types of alternately arranged heat transfer plates, for example heat transfer plates with different heat transfer patterns and/or guiding sections as long as the heat transfer patterns and/or the guiding sections are compatible with each other.
The present invention could be used in connection with other types of plate heat exchangers than gasketed ones, such as brazed, all-welded and semi-welded (heat transfer plates pairwise welded to each other in cassettes, which cassettes are separated by gaskets) plate heat exchangers. The present invention could also be used with plate heat exchangers lacking carrying and guiding bars, i.e. for heat transfer plates lacking recesses for receiving such carrying and guiding bars.
The locations of the first, second, central extension, third, fourth, fifth and sixth planes 54, 56, 58, 76, 86, 96 and 106 need not be as above defined but could vary. As an example, with reference to
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 |
---|---|---|---|
17194863 | Oct 2017 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2018/074380 | 9/11/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/068426 | 4/11/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5056590 | Bohn | Oct 1991 | A |
5392849 | Matsunaga et al. | Feb 1995 | A |
5967227 | Jensen et al. | Oct 1999 | A |
20040226704 | Sella | Nov 2004 | A1 |
20070089872 | Hou | Apr 2007 | A1 |
20110240273 | Blomgren et al. | Oct 2011 | A1 |
20160040943 | Han | Feb 2016 | A1 |
20160313071 | Andersson | Oct 2016 | A1 |
20210293484 | Sanchez | Sep 2021 | A1 |
Number | Date | Country |
---|---|---|
1815123 | Aug 2006 | CN |
203464823 | Mar 2014 | CN |
103791756 | May 2014 | CN |
204188044 | Mar 2015 | CN |
205279836 | Jun 2016 | CN |
106197094 | Dec 2016 | CN |
1010928 | Jan 2001 | EP |
1 688 692 | Aug 2006 | EP |
2728293 | May 2014 | EP |
3 101 376 | Jun 2019 | EP |
1 963 771 | Jul 2019 | EP |
1298240 | Nov 1972 | GB |
H08-233481 | Sep 1996 | JP |
11248392 | Sep 1998 | JP |
H11-506533 | Jun 1999 | JP |
2000320986 | Nov 2000 | JP |
3675475 | May 2005 | JP |
2012-510606 | May 2012 | JP |
2014-055772 | Mar 2014 | JP |
64 333 | Jun 2007 | RU |
2 411 436 | Feb 2011 | RU |
2 623 346 | Jun 2017 | RU |
2 643 999 | Feb 2018 | RU |
9419657 | Sep 1994 | WO |
9639605 | Dec 1996 | WO |
9949271 | Sep 1999 | WO |
2010064975 | Jun 2010 | WO |
Entry |
---|
Office Action dated Dec. 15, 2020, by the National Intellectual Property Administration, P. R China in corresponding Chinese Patent Application No. 201880064956.4. (5 pages). |
Office Action (Notice of Reasons for Rejection) dated Jan. 25, 2021, by the Japanese Patent Office in corresponding Japanese Patent Application No. 2020-519384 and an English Translation of the Office Action. (7 pages). |
International Search Report (PCT/ISA/210) dated Nov. 19, 2018, by the European Patent Office as the International Searching Authority for International Application No. PCT/EP2018/074380. |
Written Opinion (PCT/ISA/237) dated Nov. 19, by the European Patent Office as the International Searching Authority for International Application No. PCT/EP2018/074380. |
An English Translation of the Office Action (Decision to Grant) dated Sep. 29, 2020, by the Federal Service for Intellectual Property (Rospatent) in corresponding Russian Patent Application No. 2020114747/(024457). (10 pages). |
Notice of Allowance dated Feb. 3, 2022 in corresponding Korean Patent Application No. 10-2020-7012335, with English language translation (4 pages). |
Number | Date | Country | |
---|---|---|---|
20200278158 A1 | Sep 2020 | US |