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Title:
HEAT EXCHANGER
Document Type and Number:
WIPO Patent Application WO/2015/181255
Kind Code:
A1
Abstract:
A plate heat exchanger (100; 200; 300; 400) comprises a stack of heat exchanger plates (102; 202a-202f; 302a-302i; 402a-402i) provided with a pressed pattern of ridges (R) and grooves (G) adapted to keep the plates (102; 202a-202f; 302a- 302i; 402a-402i) in the stack at a distance from one another by providing contact points between ridges (R) of one heat exchanger plate and grooves (G) of a neighbouring plate and vice versa. Interplate flow channels are formed between all neighbouring heat exchanger plates (102; 202a-202f; 302a-302i; 402a-402i) in the stack, wherein four port openings (P1-P4) are arranged to provide for selective communication to the interplate flow channels. A first pair of port openings (P1-P4) communicate with a first set of interplate flow channels and a second pair of port openings (P1-P4) communicate with a second set of interplate flow channels, wherein interplate flow channels with in at least one set of interplate flow channels neighbour one another.

Inventors:
ANDERSSON SVEN (SE)
DAHLBERG TOMAS (SE)
Application Number:
PCT/EP2015/061753
Publication Date:
December 03, 2015
Filing Date:
May 27, 2015
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
SWEP INT AB (SE)
International Classes:
F28D9/00; F28F3/04
Domestic Patent References:
WO2011162659A12011-12-29
Foreign References:
US20070261834A12007-11-15
EP2267391A22010-12-29
Other References:
See also references of EP 3149423A1
Attorney, Agent or Firm:
STRÖM & GULLIKSSON AB (Malmö, SE)
Download PDF:
Claims:
CLAIMS

1. A plate heat exchanger (100; 200; 300; 400; 500) comprising a stack of heat exchanger plates (102a-102j; 202a-202f; 302a-302i; 402a-402i; 502a-502j) provided with a pressed pattern of ridges (R) and grooves (G) adapted to keep the plates (102a- 102j; 202a-202f; 302a-302i; 402a-402i; 502a-502j) in the stack at a distance from one another by providing contact points between ridges (R) of one heat exchanger plate and grooves (G) of a neighbouring plate and vice versa, such that interplate flow channels are formed between all neighbouring heat exchanger plates (102a-102j; 202a-202f; 302a-302i; 402a-402i (502a-502j) in the stack, wherein four port openings (102aa, 102ab, 102ac, 102ad; P1-P4; 402aa-402ad; 502aa-502ad) are arranged to provide for selective communication to the interplate flow channels, the port openings (102aa, 102ab, 102ac, 102ad; P1-P4; 402aa-402ad; 502aa-502ad) being arranged in pairs communicating with the same interplate flow channels, wherein one of the port opening pairs communicates with at least two more interplate flow channels than the other pair, characterised in that the selective communication between the port openings (102aa, 102ab, 102ac, 102ad; P1-P4; 402aa-402ad; 502aa-502ad) at least partly is achieved by providing areas surrounding the port openings of each heat exchanger plate on different levels, such that the areas of neighbouring plates either contact one another or do not contact one another.

2. The plate heat exchanger (100; 200; 300; 400; 500) according to claim 1, wherein the heat exchanger plates (102-102j; 202a-202f; 302a-302i; 402a-402i; 502a- 502j) are brazed to one another to form the heat exchanger (100; 200; 300; 400; 500). 3. The plate heat exchanger (100; 200; 300; 400; 500) according to claim 1 or

2, wherein the heat exchanger plates (102a-102j; 202a-202f; 302a-302i; 402a-402i; 502a-502j) each are provided with a skirt (S) extending in the periphery of the heat exchanger plate (102a-102j; 202a-202f; 302a-302i; 402a-402i; 502a-502j), wherein skirts (S) of neighbouring plates are contacting one another when the heat exchanger plates (102a-102j; 202a-202f; 302a-302i; 402a-402i; 502a-502j) are placed in the stack to form the heat exchanger.

4. The plate heat exchanger (200; 300; 400, 500) according to any of the preceding claims 1-3, wherein selective communication between some of the port openings (102aa, 102ab, 102ac, 102ad; P1-P4; 402aa-402ad; 502aa-502ad) and the interplate flow channels is achieved by providing sealing rings (110; SR; 510) between the areas surrounding the port openings on neighbouring plates.

5. The plate heat exchanger (200; 300; 400; 500) according to any of the preceding claims, wherein at least some of the port openings (P1-P4) of at least some heat exchanger plates (202a-202f; 302a-302i) are large enough to allow contact between areas surrounding the port openings of heat exchanger plates being provided on either sides of the heat exchanger plate provided with the large enough port opening.

Description:
HEAT EXCHANGER

FIELD OF THE INVENTION

The present invention relates to a plate heat exchanger comprising a stack of heat exchanger plates provided with a pressed pattern of ridges and grooves adapted to keep the plates in the stack at a distance from one another by providing contact points between ridges of one heat exchanger plate and grooves of a neighbouring plate and vice versa, such that interplate flow channels are formed between all neighbouring heat exchanger plates in the stack, wherein four port openings are arranged to provide for selective communication to the interplate flow channels, the port openings being arranged in pairs communicating with the same interplate flow channels, wherein one of the port opening pairs communicates with at least two more interplate flow channels than the other pair.

PRIOR ART

In the art of heat exchange, plate heat exchangers have gained a considerable market share during the latest decades or so, since plate heat exchangers offer cost effectiveness and an efficient means for exchanging heat between fluids.

A typical plate heat exchanger comprises a number of heat exchanger plates provided with a pressed pattern of ridges and grooves placed in a stack such that interplate flow channels are provided between the heat exchanger plates. Selective communication between port openings and the interplate flow channels may be provided by either providing gaskets in grooves surrounding the port openings or, in the case of brazed heat exchangers, providing the areas surrounding the port openings such that such areas of neighbouring plates either contact one another or do not contact one another - if the areas surrounding the port opening contact one another, there will be no communication between the port opening and the interplate flow channel, whereas if they do not contact one another, there will be communication between the port opening and the interplate flow channel.

In some cases, all heat exchanger plates in a brazed heat exchanger are identical to one another, and the areas surrounding two of the port openings are provided on a high level and the areas surrounding the other two port openings are provided on a low level. When put in a stack to from a heat exchanger, every other plate is turned 180 degrees in its plane, such that a port opening being surrounded by an area at a low level will neighbour port openings provided at a high level. Hence, the port opening will communicate with the plate interspace provided between the two upper plates, while it will not communicate with the plate interspace between the two lower plates.

All heat exchangers designed with identical plates are symmetric, i.e. the plate interspaces between all plate pairs are identical.

However, in most cases, asymmetric heat exchangers are preferred (the only case where a symmetric heat exchanger is the optimal choice is a case wherein two equal flows of equal fluids are supposed to exchange heat with one another).

Asymmetric heat exchangers have hitherto not been manufactured from identical heat exchanger plates.

In order to manufacture an asymmetric heat exchanger, i.e. a heat exchanger having different flow areas for the fluids to exchange heat, many different approaches have been used, all of them concerning manipulation of the pressed pattern of ridges and grooves keeping the plates at a distance from one another. For example, every other ridge may have lower height than its neighbouring ridges, or the ridges between the contact points may have a lower height. In any event, the plates must have different designs.

In US 2007/261834A1, an asymmetric plate heat exchanger comprising a stack of heat exchanger plates provided with a herringbone pattern according to the above is disclosed. However, the areas surrounding the port openings are all at the same height, and selective flow is achieved by providing sealing rings between some of the plates in the area surrounding the port openings. This gives good opportunities to provide different degrees of asymmetry, but the sealing rings may be awkward to handle during manufacturing, and they also constitute a thermal ballast, which may lead to bad brazing characteristics and/or require longer brazing times.

The object of the invention is to provide for a heat exchanger having a large degree of asymmetry while using fewer sealing rings than the heat exchanger of US 2007/261834A1.

SUMMARY OF THE INVENTION

According to the present invention, these and other objects are achieved by plate heat exchangers of the type mentioned above, wherein selective communication between the port openings at least partly is achieved by providing areas surrounding the port openings of each heat exchanger plate on different levels, such that the areas of neighbouring plates either contact one another or do not contact one another.

Preferably, the heat exchanger plates comprised in the heat exchanger are brazed to one another to form the heat exchanger.

In order to seal the interplate flow channels, the heat exchanger plates may each be provided with a skirt extending in the periphery of the heat exchanger plate, wherein skirts of neighbouring plates are contacting one another when the heat exchanger plates are placed in the stack to form the heat exchanger.

According to one embodiment of the invention, selective communication between some of the port openings and the interplate flow channels is achieved by providing sealing rings between the areas surrounding the port openings on

neighbouring plates.

In another embodiment of the invention, the selective communication is achieved by at least some of the port openings of at least some heat exchanger plates being large enough to allow contact between areas surrounding the port openings of heat exchanger plates being provided on either sides of the heat exchanger plate provided with the large enough port opening.

BRIEF DESCRIPTION OF THE DRAWINGS

Hereinafter, the invention will be described with reference to the appended drawings, wherein:

Figs, la, lb and lc are an exploded view, a section view and a plan view respectively, of a plate heat exchanger according to a first embodiment of the present invention;

Figs. 2a, 2b and 2c are an exploded view, a section view and a plan view respectively, of a plate heat exchanger according to a second embodiment of the present invention;

Figs. 3a, 3b and 3c are an exploded view, a section view and a plan view respectively, of a plate heat exchanger according to a third embodiment of the present invention;

Figs. 4a, 4b and 4c are an exploded view, a section view and a plan view, respectively, of a plate heat exchanger according to a fourth embodiment of the present invention; Figs. 5a, 5b and 5c are an exploded view, a section view and a plan view, respectively, of a plate heat exchanger according to a fifth embodiment of the present invention; and

Figs. 6a, 6b and 6c are an exploded view, a section view and a plan view, respectively, of a heat exchanger according to a sixth embodiment of the present invention.

DESCRIPTION OF EMBODIMENTS

With reference to Figs, la, lb and lc, a heat exchanger 100 according to a first embodiment of the invention comprises a number of heat exchanger plates 102a- 102j, each being provided with a pressed pattern of ridges R and grooves G and being placed in a stack to form the heat exchanger. A skirt S surrounds each plate, the skirt S being adapted to contact skirts of neighbouring plates and form a seal for a plate interspace formed by the plates, the formation of the plate interspace being elaborated on further below. The ridges R and grooves G are preferably arranged in a herringbone pattern, such that contact points between crossing ridges and grooves of neighbouring plates are formed when the plates are put in a stack wherein every other plate is turned 180 degrees in its plane with respect to its neighbouring plates.

Moreover, the heat exchanger plates are provided with port openings 102aa- 102ad, 102ba- 102bd ...102j a- 102j d, wherein the areas surrounding the port openings 102aa, 102ab. 102ba, 102bb, 102ca, 102cb, 102da, 102db, 102ha, 102hb, 102ia, 102ib, 102ja, 102 jb, 102dc, 102dd, 102ec, 102ed, 102fc and 102fd are provided on a high level and wherein the remaining port openings are provided on a low level. When the heat exchanger plates are stacked in a stack, every other plate is turned 180 degrees in the plane as compared to its neighbouring plates. As a result of this, there will be a selective communication between the ports and the interplate flow channels - however, due to the arrangement of high and low ports, some of the interplate flow channels will communicate with all four port openings. This would lead to mixing of the fluids to exchange heat, which of course is highly unsuitable. To avoid this, sealing rings 110 are placed between the areas surrounding the port openings 102da and 102ed, 102db and 102ec, 102ga and 102hd and 102gb and 102gc.

This leads to a heat exchanger wherein the port opening 102aa and its corresponding port openings of the other plates will communicate with the port opening 102ab and its corresponding port openings of the other plates via the interplate flow channels between heat exchanger plates 102b and 102c, 102e and 102f and 102h and 102i. The port opening 102ac and its corresponding port opening of the other plates will communicate with the port opening 102ad and its corresponding port openings of the neighbouring plates via the plate interspaces between the plates 102a and 102b, 102c and 102d, 102d and 102e, 102f and 102g and 102g and 102h. Consequently, the port openings 102aa and 102ab will communicate via three interplate flow channels, while the port openings 102ac and 102ad will communicate via six interplate flow channels, hence giving an asymmetry ratio of 1 :2.

Optionally, the heat exchanger 100 according to the first embodiment may be provided with either a start plate 104 or an end plate 106, or both. In case it is desired to use a start- or end plate having its ports provided at the same level, sealing rings 110 may be placed between the start-or end plate and the areas surrounding the port openings being provided on a level giving a gap between the start- or end plate and the area surrounding the port opening.

In another embodiment of the invention, all port openings are provided with skirts adapted to contact one another and hence provide a seal between the port opening and the interplate flow channels. Communication can then be arranged by cutting openings in the skirts where communication between the port opening and the interplate flow channel is desired. This embodiment of the invention is advantageous in that identical plates may be used, the only difference between the plates being that openings are pierced, cut or drilled into the skirts

In Figs. 2a-2c, a second embodiment of the invention is shown. In Figs 2a-2c, a heat exchanger 200 comprises a number of heat exchanger plates 202a-202f, all of which being provided with port openings P1-P4. All the heat exchanger plates exhibit a pressed pattern of ridges and grooves adapted to keep the plates on a distance from one another under formation of interplate flow channels, just like in the first embodiment. Some of the port openings are surrounded by areas provided on a high level or a low level, while some of the heat exchanger plates (202b and 202e) are provided with port openings where the port openings are significantly larger than the port openings of the other heat exchanger plates. In the following, the interplate flow channels will be denoted a-b for the flow channel between the plates 202a and 202b, b-c between the plates 202 b and 202c, and so on. The port openings PI and P3 of each plate are identical, which also is the case for port openings P2 and P4.

With reference to Fig. 2c, the port opening PI of heat exchanger plate 202a is surrounded by an area provided on a low level, while the port opening P2 of the same plate is surrounded by an area provided on a high level; by "low" and "high" is meant that the area is located far from or close to the end plate 206, respectively. Moreover, a "low" level means that the level is lower then the level of the grooves, and a "high" level is higher than the level of the ridges, such that the areas surrounding the port openings may contact one another although a plate with a large port opening is placed between the heat exchanger plates provided with said high and low areas surrounding the port openings. In the shown, exemplary embodiment, the heat exchanger plate 202b is provided with large port openings, and the area surrounding the port openings of the plate 202c are located oppositely as compared to the areas surrounding the port openings, i.e. the port opening PI of this plate is located on a high level, and the port opening P2 is located on a low level. The port openings of the plate 202e are located oppositely compared to the plate 202d.

This has the result that the area surrounding the port opening PI of the plate 202a will contact the area surrounding the port opening PI of the plate 202c, while the areas surrounding the port opening PI of the plates 202c and 202d will not contact one another. Regarding the port opening P2, the areas surrounding this port opening of plates 202a and 202c will not contact one another, while the areas surrounding the port opening P2 of plates 202c and 202d will.

Hence, the port opening PI will communicate with interplate channel c-d , while the port opening P2 will communicate with the interplate channels a-b, b-c, d-e and e-f.

It should be noted that the embodiment of Figs. 2a-2c is exemplary only; it has an asymmetry ratio of 1 to 5. However, if the stack would comprise more heat exchanger plates according to what is shown in Figs. 2a-2c, the asymmetry ratio would approach a value of two. Moreover, a skilled person would realise that it is possible to provide a "single" channel at the first and last plate interspaces, such as shown in the first embodiment.

In Figs 3a-3c, still another embodiment of a heat exchanger according to the invention is shown. In Figs. 3a-3c, a heat exchanger 300, comprising nine heat exchanger plates 302a-302i is shown, all of which comprising port openings P1-P4 and a pressed pattern of ridges R and grooves G, just like the heat exchanger plates of the previously disclosed embodiments. Plate interspaces between the heat exchanger plates will be denoted a-b, b-c and so forth.

The port openings of the heat exchanger plates 302a-302i are surrounded by areas provided on various levels on different diameters in a way to be explained later. In the embodiment shown in Figs. 3a-3c, the port opening PI is closed from communication with the plate interspace a-b by contacting areas surrounding the port openings of plates 302a and 302b on a large diameter. The port opening PI is also closed from communication with plate interspace b-c, by cooperation between areas surrounding the port opening on a small diameter. Moreover, port opening PI will communicate with plate interspaces c-d and f-g, and it will be closed from

communication to plate interspaces d-e, e-f, g-h and h-i by cooperation between areas surrounding the port opening on small, large, large and small diameters, respectively.

The port opening P2, on the other hand, will communicate with the plate interspaces a-b, b-c, d-e, e-f, g-h and h-i, whereas it will be closed from communication with plate interspaces c-d and f-g. The selective communication between the plate interspaces and port opening P2 is achieved by contacting or non-contacting surfaces surrounding the port opening P2, wherein all such surfaces are provided on the same diameter.

In Figs. 4a-4c, one further embodiment of the invention is shown. This embodiment is primarily useful in case a low flow resistance and a low ratio of heat exchange is desired, which e.g. might be interesting if the heat exchanger is used as a so-called suction gas heat exchanger, i.e. a heat exchanger used for exchanging heat between refrigerant about to enter a compressor and compressed refrigerant leaving the compressor. In theory, it does not matter if the heat exchange between the incoming and outgoing media is efficient, but in practice, the compressor might be overheated if the heat exchange is too effective.

In the figs. 4a-4c, a heat exchanger 400 according to the present invention is shown. The heat exchanger 400 comprises a number of heat exchanger plates 402a- 40 li, each bein identical to the heat exchanger plates being disclosed in conjunction with figs la-lc. Moreover, the heat exchanger 400 comprises a number of sealing rings SR, the provision of which will be disclosed below.

As mentioned above, the heat exchanger 400 is designed to give a bad heat exchange. This may be achieved in two ways: either by decreasing the heat exchange surface, or by decreasing the heat exchange over the surface. In the heat exchanger 400, the sealing rings SR are arranged such that there will be flow channels from the port opening PI to e.g. the port opening P3 that neighbour one another. In fig. 4b, it is shown that there are sealing rings SR provided to block flow from the port opening PI to the interplate flow channels between heat exchanger plates 402a, 402b and 402c, whereas the port opening PI will communicate with the interplate flow channels between the heat exchanger plates 402c, 402d and 402e. The port opening P2 will communicate with the interplate flow channels between plates 402a, 402b and 402c and be closed from communication with the interplate flow channels between heat exchanger plates 402c, 402d and 402e.

With reference to Figs. 5a, 5b and 5c, a heat exchanger 500 according to a fifth embodiment of the invention comprises a number of heat exchanger plates 502a-502j, each being provided with a pressed pattern of ridges R and grooves G and being placed in a stack to form the heat exchanger. A skirt S surrounds each plate, the skirt S being adapted to contact skirts of neighbouring plates and form a seal for a plate interspace formed by the plates, the formation of the plate interspace being elaborated on further below. The ridges R and grooves G are preferably arranged in a herringbone pattern, such that contact points between crossing ridges and grooves of neighbouring plates are formed when the plates are put in a stack wherein every other plate is turned 180 degrees in its plane with respect to its neighbouring plates.

Moreover, the heat exchanger plates are provided with port openings 502aa-

502ad, 502ba-502bd...502ja-502jd, wherein the areas surrounding the port openings 502aa, 502ab. 502ba, 502bb, 502ca, 502cb, 502da, 502db, 502ec, 502ed, 502fa, 502f , 502ga, 502 gb, 502ha, 502hb, 502ia, 502ib, 502ja and 502jb are provided on a low level and wherein the remaining port openings are provided on a high level. When the heat exchanger plates are stacked in a stack, every other plate is turned 180 degrees in the plane as compared to its neighbouring plates. As a result of this, there will be a selective communication between the ports and the interplate flow channels - however, due to the arrangement of high and low ports, some of the interplate flow channels will communicate with all four port openings. This would lead to mixing of the fluids to exchange heat, which of course is highly unsuitable. To avoid this, sealing rings 510 are placed between the areas surrounding the port openings 502dd and 502ea, 502ea and 502fd, 502fd and 502ga and 502ga and 502hd. Also, sealing rings 110 (however not shown) are placed between ports 502dc and 502eb, 502eb and 502fc, 502fc and 502gb and 502gb and 502hc.

This leads to a heat exchanger wherein the port opening 502aa and its corresponding port openings of the other plates will communicate with the port opening 502ab and its corresponding port openings of the other plates via the interplate flow channels between heat exchanger plates 502b and 502c and between 502h and. The port opening 502ac and its corresponding port opening of the other plates will communicate with the port opening 502ad and its corresponding port openings of the neighbouring plates via the plate interspaces between the plates502a and 502b, 502c and 502d, 502d and 502e, 502e and 502f, 502f and 502g, 502g and 502h, and between 502i and 502j. Consequently, the port openings 502aa and 502ab will communicate via two interplate flow channels, while the port openings 502ac and 502ad will communicate via seven interplate flow channels, hence giving an asymmetry ratio of 2:7. However, by providing further heat exchanger plates in the stack, arranged in the same manner as the heat exchanger plates 502a-502j, a ratio going towards the ratio 1 :5 may be achieved by this arrangement.

Optionally, the heat exchanger 500 according to the fifth embodiment may be provided with either a start plate 504 or an end plate 506, or both. In case it is desired to use a start- or end plate having its ports provided at the same level, sealing rings 510 may be placed between the start-or end plate and the areas surrounding the port openings being provided on a level giving a gap between the start- or end plate and the area surrounding the port opening.

In still another embodiment, not shown in the drawings, the heat exchanger comprises a number of identical plates, wherein every other plate is turned 180 degrees in its plane compared to its neighbouring plates. The plates are providd with a herringbone pattern of ridges and grooves adapted to keep the plates on a distance from one another such that interplate flow channels are formed between neighbouring plates. Selective communication between the interplate flow channels and port openings is provided by arranging areas surrounding the port openings such that such areas surrounding port openings of neighbouring plates alternatingly will contact one another, hence sealing the port opening from communication with the interplate channel limited by the plates belonging to the port openings in question or not contact one another, hence allowing for a communication between the por opening and the interplate flow channel limited by the plates.

Until now, it has only been possible to manufacture symmetrical heat exchangers from identical heat exchanger plates, but according to this embodiment, it is possible to achieve asymmetry ratios of 3: 1, 3:3, 5,: 1, 5:3, or any uneven number divided by any other uneven number.

This is achieved by providing a sealing ring extending from an area

surrounding a port opening of one plate to another area surrounding a port opening of another plate. By the provision of such a sealing ring, the communication that would have been present between the port opening and the interplate flow channel is blocked. In order to provide for communication between the interplate flow channel that has been shut off from communication with the previous port opening to another port opening, it is possible to drill e.g. a hole to open the inteplate flow channel to communication with the other port. It is also possible to cut a larger port opening, such that the areas surrounding the port opening and would have come into contact with one another do not contact one another any more, hence providing for communication between the other port opening and the interplate flow channel having been blocked from communication with the previous port opening by the sealing ring.

Moreover, the heat exchanger plates may be brazed to one another in order to form the heat exchanger - the brazing material may be any brazing material known to persons skilled in the art, e.g. copper, nickel or iron based brazing materials comprising a melting point depressant.