SE531048C2 - Heat - Google Patents

Description

20 25 30 531 D48 wide to be able to meet tightness and pressure requirements for 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.

The Swedish patent specification SE 521377 shows a heat exchanger for cross-flow heat exchange between two media. The heat exchanger according to SE 521377 comprises two plate types in a plate stack. The plates are permanently connected to each other along edge portions and ports and in contact points, which are located in the heat transfer surface of the plate. The disadvantage of the invention according to SE 521377 is that the edge portion and contact points in the heat transfer surface are in one and the same plane on the plate. This results in the permanent connection of two plates to each other in that the plates are fixed to each other in a common plane. With the fixing in one plane, the plates can turn in said plane. rotation (due to eg high pressures and temperature stresses) in the plane which fixes the plates to each other can thus result in the plates being delaminated.

SUMMARY OF THE INVENTION A recuperator-type heat exchanger comprises a plate stack constructed of two plate types. Each plate includes a heat transfer surface, an edge portion, ports, and a flank portion. The heat transfer surface normally comprises a pattern with peaks and valleys. The peaks and valleys are within a first and a second plane. The plate stack comprises an open channel for receiving a gas, a closed channel for receiving a liquid. The gas passes through the plate stack through the long sides that are open. The liquid passes through the plate stack through the gates and into the closed channel formed by the plates. The media in the two channels have in relation to each other have cross-flow and temperature transfer.

An object of the present invention is to create a heat exchanger of the recuperator type which enables permanent connection between two adjacent plates in two lateral planes separated in the plates. By creating a connection between two plates in at least two planes, adjacent permanently connected plates become more resistant to torsional and bending forces. The above and other objects are achieved according to the invention in that the heat transfer plate initially described has been given the features set forth in claim 1.

Advantages obtained with a heat exchanger of the recuperator type built up of plates, comprising different planes, and where parts of at least the edge portion of at least one plate type are located via a step in a third plane which is separate from the first and the second plane, is that adjacent tiles in the tile stack are connected to each other in different levels. This means that the heat exchanger becomes torsionally rigid and pressure-resistant.

Further advantages are that since the edge in at least one plate type comprises a step which creates a level difference between two planes in the plate, the step functions as a guide member. The step thus helps to position the plates correctly with each other in the plate stack. A further advantage of said step is that the edge portion becomes stiffer with the step, whereby the plate becomes torsionally stiffer and more resistant to bending.

Preferred embodiments of heat transfer plate according to the invention have furthermore been given the features set out in subclaims 2 ~ 13.

According to an embodiment of a heat exchanger according to the invention, each plate comprises an end portion with at least some part located at the respective short side, which end portion comprises a flank which is angled from a lateral plane in the plate in the direction of the first plane. The flank has a width which means that one side of it abuts and thus overlaps the upper flank portion of an adjacent plate. Since the flank overlaps parts of the flank of an adjacent plate, the flank functions as an additional control means for positioning the plates in the plate stack.

According to an embodiment of a heat exchanger according to the invention, the first plane of each plate is placed below the second plane of each plate. Between the said plane, the pattern of the heat transfer surface with peaks and valleys is placed. The valleys are in the first plane. The peaks are in the second plane.

According to an embodiment of a heat exchanger according to the invention, the first plate type comprises a fourth plane, located below the first plane, and in 1023 20 523 523% D48, which fourth plane the ports are located. The fourth plane is located below this first plane via a step in the first plane. The step is located at the end portion of each first plate with a semicircular design around the gate. The ends of the step extend to the edge portion of the end portion, each port in each first plate being enclosed between said step and edge portion. The advantage of having a step which divides the plane and which contributes to the gate area being in a fourth plane separate from the first plane is that the gate area is stiffened through the step. As a result, the postage range becomes more resistant to torsional and bending forces, more pressure-resistant and more resistant to thermal stresses that arise in plates in heat exchangers under temperature influence. A further advantage is that since the door portion in one plate is immersed and when joined fits into the door portion of an adjacent plate. The port portion of the adjacent plate is designed to receive the second port portion. As a result, an improved specification is obtained when joining the door sections, e.g. when soldering.

Thermal stresses in a plate arise when a plate that is prevented from moving is exposed to temperature changes and thus wants to move. An example of this is heat exchangers comprising permanently connected plates. In permanently connected heat exchangers, it is therefore desirable that the construction is such that it can withstand movements in the plates that arise due to thermal stresses.

According to an embodiment of a heat exchanger according to the invention, the third plane of the first plate type is located between the first and the second plane of the plate. In this third plane, the edge of the plate (extending around the plate periphery) is placed. The plate thus has at least two planes, planes two and three, at different levels which, when connected to an adjacent second plate, coincide with the two corresponding planes two and three of said second plate. As a result, a connection is made between two plates in two planes at different levels. This results in two plates permanently connected to each other becoming resistant to torsional and bending forces. Additional advantages of such a construction are that the permanently connected plate stack becomes resistant to thermal stresses due to temperature differences in the media through the plate stack. 10 15 20 25 30 531 H48 According to an embodiment of a heat exchanger according to the invention, the second plate type comprises a fourth plane, placed between the first and the second plane, in which fourth plane the gates are located. The plate thus has two planes, planes two and four, in different levels which, when connected to an adjacent first plate, coincide with the two corresponding planes one and four of said first plate. As a result, a connection is made between two plates in two planes at different levels. This results in two plates permanently connected to each other becoming resistant to torsional and bending forces. Additional advantages of such a construction are that the permanently connected plate stack becomes resistant to thermal stresses due to temperature differences in the media through the flat stack.

A further advantage of the construction described above is that the postage ranges, due to the level differences in the connection between the plates, improve the resistance to the effect of pressure. This is important because the door sections are the sections that are normally exposed to high pressures in a heat exchanger.

According to an embodiment of a heat exchanger according to the invention, the third plane of the second plate type is located below the first plane. In this third plane an edge along the respective longitudinal side between the end portions of each second plate type is arranged. The respective said edge is connected to the first plane via a step. The step thus connects the two planes one and three which are arranged in different levels with each other. As a result of the step, a stiffening element is formed in the transition between the heat transfer surface and the edge. The step thus contributes to the plate becoming more resistant to bending and twisting action compared with a traditional plate where instead of the first and third planes there is normally only one common plane.

According to an embodiment of a heat exchanger according to the invention, the first plane of the first plate type is connected to the fourth plane via a step. in that a step is arranged in the transition between the two planes one and four, a stiffening element is obtained in the plate. As previously mentioned, the gates in the plate are arranged in this plane. With the step, the door area is thus stiffened. Since the postage ranges previously mentioned are normally exposed to high pressures in a heat exchanger, it is therefore desirable that they be as pressure-resistant as possible.

According to an embodiment of a heat exchanger according to the invention, all the planes in each plate are laterally parallel to each other. As all the planes are parallel in relation to each other in the plate stack, the manufacturing process is simplified. An example is that you can thus visually check in a simple way if any plate is misplaced in the plate stack. because it would result in the plate stack tilting in that case.

According to an embodiment of a heat exchanger according to the invention, the first channel is arranged between the first and the second plate type, the second plane of the first plate type coinciding with the first plane of the second plate type.

The edges and plate end of a first plate are connected to the edges and plate end of a second plate. The gates communicate with each other via the first channel formed between said plates. Thus, with the first channel, a first medium, usually a liquid, can flow through the heat exchanger.

According to an embodiment of a heat exchanger according to the invention, the second channel is arranged between the second and the first plate type, the second plane of the second plate type adjoining the first plane of the first plate type. As a result, a second channel is formed which has inlets and outlets along two sides of the heat exchanger. In the preferred embodiment, the inlet and the outlet, respectively, are located on opposite longitudinal sides between the end portions between every other plate in the plate stack. Through said second channel, a second medium, usually a gas, can thus flow through the heat exchanger. In the preferred embodiment, the flow path of the first medium thus crosses the flow path of the second medium.

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 heat exchanger (with plate stack) according to the invention. Fig. 2 shows a view of a first plate type according to the invention.

Fig. 3 shows a view of a second plate type according to the invention.

Fig. 4 shows a sectional view of a part of a flat stack according to the invention.

DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS OF THE INVENTION.

Fig. 1 shows a heat exchanger (1) according to the invention of the recuperator type.

The heat exchanger (1) comprises a plate stack (2). The plate stack (2) comprises a first plate type (3) and a second plate type (4), which plates (3 and 4) together form the plate stack (2). In the plate stack (2) between the plates (3 and 4) a first channel (5, see Fig. 4) and a second channel (6) are formed. Each first channel (5, see Fig. 4) thus adjoins every second channel (6) in the plate stack and vice versa.

Fig. 2 shows a first plate type (3). The plate (3) comprises a first edge portion (7a), a first port area (8a), a first heat transfer surface (9a), a first step (10a). The edge portion (7a) extends around the periphery of the plate (3) and encloses the heat transfer surface (9a). At each plate end, a first door (1 ta) is located within the door area (8a). The heat transfer surface (9a) comprises a pattern (12), arranged according to a previously known method.

Fig. 3 shows a second plate type (4). The plate (4) comprises a second edge portion (7b), a second port area (8b), a second heat transfer surface (9b), a second step (10b). The edge portion (7b) extends around the plate (3) and encloses the heat transfer surface (9b). At each plate end, a second port (11b) is located within the gate area (Bb). The heat transfer surface (9b) comprises a pattern (12), e.g. an arrow-shaped corrugation pattern, arranged according to a previously known method.

Fig. 4 shows in cross section a plate stack (2) according to the invention seen in a section through the plate stack (2) in the direction between the end portions of the plates (4 and 5) and through a center line (14) present in each door channel (13). A first plate type (3) is connected to a second plate type (4). The plates (3 and 4) comprise a flank (15) at the respective end portion of each plate (3 and 4). Each plate (3 and 4) comprises a heat transfer surface (9a and 9b) with pattern (12) with peaks (16) and valleys (17). The heat transfer surface (9a and 9b) for each plate (3 and 4) is located within a first plane (18) and a second plane (19), which planes (18 and 10) are laterally parallel to a in each plate (3 and 4) placed normal plane (not shown in figure). Each flank (15) of the plates (3 and 4) in the plate stack (2) is angled from the normal plane (not shown in the figure) in the plates (3 and 4) in the direction of the first plane (18) of the respective plate (3 and 4).

For understanding, the reference numerals in Fig. 4 for the plane (18 - 21) belonging to the first plate type (3) are located to the right of the plate stack (2) in Fig. 4. Correspondingly, the reference numerals in Fig. 4 for the plane (18 - 21) 21) belonging to the second plate type (4) located at the left side of the plate stack (2).

In the plate stack (2), all the plate types (3 and 4) are oriented in such a way that all the flanks (15) on the plates (3 and 4) are jointly directed in the same direction (downwards in Fig. 4).

The plate stack (2) is built in that a second plate type (4) is placed on a first plate type (3), the second plane (19) of the first plate type (3) coinciding with the first plane (18) of the second plate type (4). A first plate type (3) is placed on the second plate type (4), the second plane (19) of the second plate type (4) coinciding with the first plane (18) of the first plate type (3) placed on top.

Furthermore, the first and the second plate types (3 and 4) are permanently connected to each other via a third plane (20) placed in each plate (3 and 4).

The first plate (3) comprises, as mentioned above, a second plane (19) which abuts against the first plane (18) of the second plate (4). Furthermore, the first plate (3) comprises a third plane (20), placed between the first and the second plane (18 and 19) in the plate (3). In this third plane (20) the first edge portion (7a) is arranged. The edge portion (7a) extends around the periphery of the plate (3) (see Fig. 2). The second plate (4) also comprises a third plane (20), which third plane (20) is located on a level below the first plane (18) in the second plate (4). In this third plane (20) the first edge portion (7b) is arranged. The edge portion (7b) extends around the periphery of the plate (4) (see Fig. 3).

The edge portion (7b) of the second plate (4) is located in the third plane (20) of the plate (4) at a level below the first plane (18) via the second stage (1 Ob, 10 15 20 25 30 531 D48 see Fig. 3). in that the edge (7b) is connected to the first plane (18) in a step (1 Ob, see Fig. 3), a stiffening element is formed in the edge portion.

At the connection between two plate types (3 and 4) where the second plane (19) of the first plate type (3) coincides with the first plane (18) of the second plate type (4), the edges (7a and 7b) are laid on the respective plate (3 and 4) against each other. This is because the third planes (20) of the plates (3 and 4) respectively coincide with each other in the plate stack. Between the plates (3 and 4) a first channel (5) is thus formed for receiving a first medium, preferably a liquid, through the heat exchanger (t, see Fig. 1). The gates (11a and 11b, see Figs. 2 and 3) in the plate stack (2) communicate with each other through said formed first channel (5).

In the connection between two plate types (3 and 4) where the second plane (19) of the second plate type (4) coincides with the first plane (18) of the first plate type (3), the door portions (8a and 8b) are arranged on the respective plate (3 and 4) against each other. This is because the fourth planes (21) of the plates (3 and 4) respectively coincide with each other in the plate stack; Between the plates (3 and 4) a second channel (6) is thus formed for receiving a second medium, preferably a gas, through the heat exchanger (1). The channel (6, see Fig. 1) extends between every other plate (3 and 4) between the respective long sides of the plate stack (2).

The long sides between each other plate (3 and 4) are open, the respective open long sides communicating with each other via the channel (6, see Fig. 1). As a result, the flow path of the first medium crosses the flow path of the second medium, whereby a cross-flow heat exchanger (1) is thereby formed.

Because the plates (3 and 4) in the plate stack (2) are connected to each other in different planes (18 - 21) between adjacent plates (3 and 4), the plates are fixed to each other in several planes, which thus improves the rigidity of the heat exchanger (1). . This also results in the resistance of the heat exchanger (1) to pressure and thermal stresses being improved. In the preferred embodiment of the invention it is described that the heat exchanger is permanently connected. By this is meant all the joining processes such as e.g. soldering, welding, gluing, bonding etc. which contributes to two surfaces being permanently connected to each other. The invention is not limited to the embodiment shown but can be varied and modified within the scope of the appended claims, which have been partly described above.

Claims (12)

10 15 20 25 531 043 11 PATENT REQUIREMENTS Heat exchangers (1), preferably of the recuperator type, comprising heat transfer plates (3 and 4) of a first plate type (3) and of a second plate type (4), which together form a first channel (5) in a plate stack (2) and a second channel (6), the respective plate (3 and 4) comprising two short sides, two long sides, two port holes (11a-b), an edge portion (7a-b) located along the periphery of the plate (3 and 4), a heat transfer surface ( 9a-b) comprising a pattern (12) with peaks (16) and valleys (17), the heat transfer surface (9a-b) being located within a first and a second plane (18 and 19), which edge portion (7a-b) ), via a step (10a-b), is located in a third plane (20), which third plane (20) is separate from the first and the second plane (18 and 19), characterized in that, the first plate type (3) and the second plate type (4) each comprise a fourth plane (21), in which fourth plane (21) the gate holes (11a-b) are located, which adjacent plate types (3 and 4) are connected to each other. strip in at least two of said planes at different levels in each plate (3 and 4), which said planes in each plate (3 and 4) are all parallel to each other. Heat exchanger (1) according to claim 1, characterized in that each plate (3 and 4) comprises an end portion with at least some part located at each short side, which end portion comprises an fl ankle (15) which is angled from one in the plate ( 3 and 4) lateral plane in the direction of the first plane (18). Heat exchanger (1) according to claim 1, characterized in that the first plane (18) of each plate (3 and 4) is located below the second plane (19) of each plate. 10 15 20 25 53'l G48 12 Heat exchanger (1) according to claim 1, characterized in that the first plate type (3) comprises a fourth plane (21), located below the first plane (18), in which the fourth plane (21) is the portal hole (11a) placed. Heat exchanger (1) according to claim 3, characterized in that the third plane (20) of the first plate type (3) is located between the first and the second plane of the plate (18 and 19). Heat exchanger (1) according to claim 1, characterized in that the second plate type (4) comprises a fourth plane (21), located between the first and the second plane (18 and 19), in which fourth plane (21) the gate holes (1 1 b) are located. Heat exchanger (1) according to claim 3, characterized in that the third plane (20) of the second plate type (4) is located below the first plane (18). Heat exchanger (1) according to claim 4, characterized in that the first plane (18) of the first plate type (3) is connected to the fourth plane (21) via a step (10a). Heat exchanger (1) according to claim 1, characterized in that the first channel (5) is arranged between the first and the second plate type (3 and 4), the second plane (19) of the first plate type (3) being adjacent to the first plane (18) of the second plate type (4). Heat exchanger (1) according to claim 1, characterized in that the second channel (6) is arranged between the second and the first plate type (4 and 3), wherein the second plane of the second plate type (4) ( 19) adjoins the first plane (18) of the first plate type (3). Heat exchanger (1) according to claim 9, characterized in that the second duct (6) has an inlet along one side, preferably long side, of the heat exchanger (1). Heat exchanger (1) according to claim 9, characterized in that the second duct (6) has an outlet along one side, preferably long side, of the heat exchanger (1).