SE528275C2 - Heat transfer plate with control means and heat exchanger comprising such plates - Google Patents

Abstract

This relates to a heat transfer plate (2) with locating means (8) and adapted to being stacked in a plate stack, and a heat exchanger including such plates (2). The plate (2) has a patterned heat transfer surface, an edge portion, ports, locating means (8) and accommodating means (14). Locating means (8) in the form of nibs (8) is situated on the heat transfer surface of the plate. The nibs (8) are between two planes (10 and 12) situated above the heat transfer surface pattern. In the plate stack, between two mutually adjacent plates (2), the nibs (8) fit into accommodating means (14) on an adjacent plate (2), which accommodating means (14) are disposed in the latter's heat transfer surface. Two mutually adjacent plates (2) in the plate stack together have two nibs (8) and two accommodating means (14) which fit into one another and thereby fix the plates (2) relative to one another so that the plates cannot shear or rotate relative to one another. This means that plates (2) need not have any so-called locating flanges for positioning them in a plate stack.

Description

528 275 to the heat transfer surface. Since the edge portion is to be soldered to the corresponding edge of an adjacent plate, it is required that the edge portion is wide enough to be able to meet the tightness and pressure requirements of the heat exchanger. With today's manufacturing and joining technology, the edge width must be at least about 2 mm from the outer edge into the heat transfer surface.

A further disadvantage of the invention according to the Japanese patent specification JP 09-113170 is that the guide means only prevent movement of the plates across the direction of the edge portion. In the direction of the plate along the edge portions, two plates abutting against each other are not prevented from moving. When soldering the plates, this could mean that the plates are displaced longitudinally relative to each other, whereby the heat exchanger becomes impossible to use.

SUMMARY OF THE INVENTION A heat transfer plate with guide means comprises an edge portion extending around the periphery of the plate and a heat transfer surface enclosed by the edge portion. The heat transfer surface normally comprises a pattern with peaks and valleys. The peaks and valleys are within a first (upper) and a second (lower) plane. The lateral center portion of the heat transfer surface is in a normal plane, located between the first and second planes. The heat transfer plate is stacked on top of a uniform but differently oriented plate in a plate stack in a heat exchanger. Between the plates in the plate stack, flow channels are formed which are receivers of different media. During operation, the media in adjacent channels have a temperature exchange between each other.

An object of the present invention is to create a heat transfer plate for a permanently connected heat exchanger 10 15 20 25 528 275 comprising a plate stack without flanks, which in manufacture can be manufactured without the plate stack having to be supported externally with walls or guide elements to prevent displacement of the stacked plates in relation to each other during the handling in connection with the soldering process.

An object of the present invention is to create a heat transfer plate for a permanently connected heat exchanger comprising a plate stack without flanks where the plates in the plate stack cannot rotate relative to each other during the manufacturing process.

An object of the present invention is to create a heat exchanger which is built up of heat transfer plates stacked on top of each other and which are permanently connected to each other.

A further object of the present invention is to provide a construction which makes it possible to reduce the time required in the manufacture of the heat exchanger's flat stack, whereby the manufacturing process becomes fast and cost-effective.

The above-mentioned and other objects are achieved according to the invention in that the heat transfer plate initially described has been given the features according to claim 1.

Advantages obtained with a heat transfer plate without flanks with guide means according to the characterizing part of claim 1 are that a number of plates can be stacked on top of each other into a plate stack without it having to be supported laterally or longitudinally during soldering. 10 15 20 25 30 528 275 Further advantages are that since the edges do not comprise guide means, the width and thickness of the edges can be minimized. The result is that less material needs to be used in the manufacture of the tiles.

An additional advantage is that the reducing width of the edges results in less solder access when joining the edges of the tiles compared to e.g. with traditional plates where part of the edge width is used to form an angled guide flange.

A further advantage is that a guide flank around the periphery of a plate is not necessary since the guide means in the plate without a flank fulfill the corresponding function as such a guide flank with regard to positioning of a plate stack.

Preferred embodiments of a heat transfer plate according to the invention have furthermore been given the features set out in subclaims 2 to 9.

According to an embodiment of a heat transfer plate according to the invention, a second guide means is arranged between a fourth plane, placed laterally parallel below the second plane of the heat transfer surface, and the second plane. in that a second guide means is arranged on the heat transfer surface, the plate is rotationally fixed / rotation between the plates is prevented. With only one guide member between two plates, on the other hand, the plates can rotate around the guide member.

According to a further embodiment of a heat transfer plate according to the invention, a control means is arranged on the heat transfer surface.

The control means are advantageously placed in areas which are not exposed to high pressures. Since the number of contact points is reduced locally in an area where control means are located, it causes a local weakening between adjacent plates. Therefore, the control means are advantageously not located in door areas where the contact and solder points of adjacent plates are exposed to high pressures in the heat exchanger. instead, the control means are located at a distance from the port areas on the heat transfer surface so that the total pressure resistance of the heat exchanger is not affected.

According to a further embodiment of a heat transfer plate according to the invention, the control means in a first plate is arranged to fit into a first receiving device for the control means arranged on an adjacent second plate. At the same time, the second guide means in an adjacent second plate is arranged to fit into a second receiving device for the guide means arranged on the adjacent first plate in the plate stack, the plates being fixed to each other in their lateral directions. Because the guide means in each plate fit into the receiving devices of the adjacent plates, the plates are locked to each other. This against both shear and rotation between the plates.

According to a further embodiment of a heat transfer plate according to the invention, the heat transfer plate adjoins a second heat transfer plate, these together comprising at least two control means, which effectively counteracts rotation between two adjacent plates by the two points fixing the plates to each other.

According to a further embodiment of a heat transfer plate according to the invention, the control means consist of lugs. In the preferred embodiment, lugs are used for the control means. When pressing the heat transfer surface, small elevations and depressions in the form of studs are introduced into the surface. The lugs are located in the area between the first and third planes and in the area between the second and fourth planes. Since cams are used as control means, the area of the heat transfer surface that needs to be used for them is minimized. This is because it is desirable to have as large a heat transfer surface (with maximum heat transfer) as possible.

According to a further embodiment of a heat transfer plate according to the invention, the guide means consist of grooves. By designing the control means as grooves, a heat exchanger with such plates can be exposed to high pressures. This is because the control means thereby also function as stiffening elements in the heat exchanger. The heat exchanger thus becomes strong and can be exposed to high pressure stresses.

According to a further embodiment of a heat transfer plate according to the invention, the guide means are located on or in the immediate vicinity of the edge portion. By enlarging the edge locally at individual portions of the edge area, guide means can be placed on or in the immediate vicinity of the edge portion.

The local enlargement of the area of the guide member is obtained by widening the edge in that area whereby a guide member can be placed there.

BRIEF DESCRIPTION OF THE DRAWINGS Preferred embodiments of the device according to the invention will now be described in more detail with reference to the accompanying schematic drawings, which only show the details necessary for understanding the invention.

Fig. 1 shows a plate stack for a heat exchanger.

Fig. 2 shows a view of a heat transfer plate according to the invention.

Fig. 3 shows a side view in section of a number of heat transfer plates according to the invention in a plate stack. DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS OF THE INVENTION Fig. 1 shows a heat exchanger with a plate stack (1) comprising heat transfer plates without flank stacked on top of each other. In the following text, the word heat transfer plate will be synonymous with plate. Fig. 2 shows a plate (2). The plate comprises an edge portion (3) which extends around the beading of the plate (2). In the front edge portion »(3) a heat transfer surface (4) is located. In each corner of the plate a port (5a-d) is arranged for inflow and outflow of medium. In the preferred embodiment, the heat transfer surface (4) comprises a pattern (6) for optimizing the heat transfer in the heat exchanger. The pattern (6) comprises peaks and valleys, which at adjacent plates point point against each other so that contact points are formed, which are used in a known manner to connect the plates to each other in connection with the soldering of the heat exchanger. In a plate stack (1) with a number of plates (2) stacked on top of each other, flow channels (7 are formed between the adjacent plates (2), see Fig. 3). The adjacent flow channels (7) are receivers for different media which have temperature exchange with each other through the heat transfer surfaces (4) of the plates - the plate according to Fig. 2 comprises on the heat transfer surface a number of lugs (8a-d). The function of the lugs (8a-d) is to fit into the receiving means of an adjacent plate (2) in order in this way to prevent the plates (2) from moving laterally in relation to each other. Plates comprising receiving means have a corresponding position on the plate as the lugs (8a-d), are not shown in the figure. Fig. 3 shows how the plates (2) with lugs (8) are fixed to each other in a plate stack (1). The heat transfer surface of a first plate (2a) comprises a normal plane (9), located in the lateral "middle plane" of the plate. Above the normal plane (9) there is a first plane (10). Below the normal plane (9) there is a second plane (11). Between the first plane (10) and the second plane (11) the heat transfer surface (4) with its peaks and valleys is arranged.

Above the first plane (10) there is a third plane (12). Below the »second plane (11) there is a fourth plane (13). All planes (9 - ~ 13) are parallel to each other. In order to clarify in the figure how the plane relates to a plate, the plate with the associated described planes is drawn in black in the figure. in the area between the first plane (10) and the third plane (12), cams (8) are arranged. Correspondingly, in the area between the second plane (11) and the fourth plane (13), cams (8) are arranged. In the area between the first and the second plane (10 and 11) receiving means (14) are arranged. The receiving means (14) are adapted to receive the lugs (8 in an adjacent plate (2) and thereby fixedly fix the plates (2) in a lateral plane to each other. this means that every other plate faces 180. This means that the first plane (10) of each plate (2) abuts against the first plane (10) of an adjacent plate. In the preferred embodiment according to the invention, a first and a fourth plate (2a, d, see Fig. 1) comprise a cam (8) placed on the heat transfer surface (4, see Fig. 2) in In the area between the first plane (10) and the second plane (11), three receiving means (14) are arranged, not shown in the area between the second plane (11) and the fourth plane (13). Figure 2. Two of the receiving means (14) have an opening towards the first plane (10) and the third has an opening towards the second plane (11). the preferred embodiment according to the invention comprises a second and a third plate (2b, c, see Fig. 1) two lugs (8) placed in the area between the first plane (10) and the third plane (12). A cam (8) is located in the area between the second plane (11) and the fourth plane (13). A receiving means (14) is arranged between the first plane (10) and the second plane (11), opening towards the second plane (11).

On the first plate (2a, see Fig. 1) the second plate (2b, see Fig. 1) is placed, the first planes (10) on the respective plate (2a, b) abutting each other. The two bosses (8), in the area of the second plate (2b) between the first and the third plane (10, 12), fit into the receiving means (14) of the first plate (2a), placed between the first and the second plane (10, 11), with their openings to the first plane (10), are not shown in FIG.

On the second plate (2b, see Fig. 1) the third plate (2c, see Fig. 1) is placed, the second planes (11) on the respective plate (2b, c) abutting each other. The cam (8) on the second plate (2b), located in the area between the second and the fourth plane (11, 13), fits into the receiving means (14) in the third plate (2c) which has an opening to the second plane. At the same time, the cam (8) on the third plate (2c), located in the area between the second and the fourth plane (11, 13), fits into the receiving means (14) on the second plate (2b), which has an opening to the second plane, is not shown in the figure.

On the third plate (2c, see Fig. 1) the fourth plate (2d, see Fig. 1) is placed, the first planes (10) on the respective plate (2c, d) abutting 10 15 20 25 30 528 275 10 against each other. The two bosses (8) in the area of the third plate (2c) between the first and the third plane (10, 12), fit into the receiving means (14) of the fourth plate (2d), placed between the first and the second plane ( 10, 11), with their openings to the second plane (10), are not shown in FIG.

On the fourth plate (2d, see Fig. 1) the first plate (2a, see Fig. 1) is placed, the second planes (11) on the respective plate (2d, a) abutting each other. The cam (8) on the fourth plate (2d), located in the area between the second and the fourth plane (11, 13), fits into the receiving means (14) in the first plate (2a), with opening to the second plane . At the same time, the cam (8) on the first plate (2a), located in the area between the second and the fourth plane (11, 13), fits into the receiving means (14) on the fourth plate (2d) which has an opening to the second plane .

When the lugs (8) and the receiving means (14) fit into each other, the plates (2) are fixed in their lateral planes with each other. By fixing at least two points between adjacent plates (2), the plates (2) are also prevented from rotating in relation to each other.

With guide means according to the preferred embodiment, no support fixture is needed for the plate stack (1) during soldering to counteract displacement between the plates (2). This is because the plates (2) are prevented from moving laterally by the guide means (2) and the receiving means (14) in the plates.

When the plates (2) are stacked and the guide means (8) have fitted into the receiving means (14), it is advantageous if a weight is applied to the plate package (1) at the soldering line (not shown in figure). This is so that intermediate solder can make the plate package (1) a little unstable. Since there is a weight between each plate (2), a weight counteracts that there are areas where the plates (2) are not soldered to each other due to of the plates (2) e.g. are slightly bent.

An alternative design of the invention is that the guide means instead of studs consist of beams or that they have the shape of an X, Y, Z or other design which prevents movement in the lateral plane between two plates.

The advantage of such an alternative guide means is that only one guide means is needed to fix the plates to each other. The disadvantage is that such control means need to be made larger than a cam. The surface available for heat transfer thus becomes smaller, which leads to poorer heat transfer capacity.

The invention is not limited to the embodiment shown but can be varied and modified within the scope of the appended claims, which has been partly described above.

Claims (1)

10 15 20 25 30 523 275 12 PATENTKFlAV Heat transfer plate (2) with guide means (8) arranged to be stacked in a permanently connected plate stack (1), which heat transfer plate (2) comprises an edge portion (3) extending around the periphery of the plate (2) and gate areas with gates and a heat transfer surface. (4) which years are located within the periphery of the plate (2), which heat transfer surface (4) preferably comprises a pattern (6) with peaks and valleys and is located within a first (upper) and a second (lower) plane (10 and 11) which are laterally parallel to the heat transfer plate (2) normal plane (9), said guide means (8) being arranged partly between a third plane (12), placed laterally parallel above the first plane (10) of the heat transfer surface (4), and the first plane ( 10), partly between a fourth plane (13), placed laterally parallel below the second plane (11) of the heat transfer surface (4), and the second plane (11), characterized in that a receiving means (14) is arranged between the first and the second planet ( 10 and 11), and that the guide means (8) in said heat transfer plate is arranged to fit into a receiving means (14) arranged on an adjacent uniform second plate (2b), the guide means (8) being arranged at a distance from the gate areas and on the heat transfer surface (4). . Heat transfer plate (2) according to claim 1, characterized in that the control means (8) in a first plate (2a) is arranged to fit into a first receiving device (14) for the control means (8) arranged on an adjacent second plate (2b). 10 15 20 25 528 275 13. Heat transfer plate according to claim 2, characterized in that the second guide means (8) in a second plate (2b) is arranged to fit into a second receiving device (14) for the guide means (8) arranged on an adjacent first plate (2a) in the plate stack (1) wherein the plates (2) are fixed to each other in lateral directions. Heat transfer plate (2) according to claim 1, characterized in that the heat transfer plate (2) adjoins a second heat transfer plate (2b), these together comprising at least two control means (8). . Heat transfer plate (2) according to claim 1, characterized in that the control means (8) consist of cams. . Heat transfer plate (2) according to claim 1, characterized in that the control means (8) consist of grooves. . Heat transfer plate (2) according to claim 1, characterized in that the guide means (8) are located in direct proximity to the edge portion (3). . Heat transfer plate (2) according to claim 1, characterized in that the guide means (8) are placed on the edge portion (3). . A heat exchanger comprising a plate stack (1) built up of heat transfer plates (2) according to any one of the preceding claims, which heat transfer plates (2) are permanently connected to each other.