SE530970C2 - Cross current type heat exchanger - Google Patents

Description

According to a further embodiment of the invention, a divider is arranged, preferably embossed or pressed, in the heat transfer surface in one plate type, preferably the first plate type, which divider extends from the short side where said gate heel is arranged in the direction of the second short side, which divider is shorter than said long sides and arranged between these and arranged parallel between said long sides. An advantage of a divider in a plate type in a heat exchanger is that it stiffens the structure of the plate stack.

According to a further embodiment of the invention, the divider in the plate comprises an ace, or bottom, which lies in the second plane on a side B of the first plate type, the divider being connected to an adjacent second plate type side A, a passage between two plate types being formed between the free end of the divider and the short side of the plate types. Said axis, or bottom, of the divider has a contact surface which is connected to the adjacent second type of plate. The connection between two plate types consists of those already known to those skilled in the art, such as e.g. soldering, welding, gluing, bonding etc.

According to a further embodiment of the invention, the first flow channel is arranged between the respective long side and arranged between two adjacent plate types, which plate types are connected to each other in said first plane.

As mentioned, the divider extends from the first plane in the direction of the second plane on a side B in a first plate type. This means that on side A of the first plate type the divider does not protrude into the surface and has any effect on a flow on that side of the first plate type.

As mentioned, side A of a first plate type is connected to side B of a second plate type, said first flow channel being formed between said plate types. Since the divider ei affects the flow in the first flow channel, the channel can be arranged between respective long sides on said adjacent plate types.

According to a further embodiment of the invention, the second flow channel is arranged in the second plane and extends between said ports, said second flow channel extending from the first short side adjacent to the first port, in the direction of the second short side between the divider and one long side. , through the passage arranged between the free end of the divider and the second short side and in the direction of the first short side between the second side of the divider and the second long side, which first short side also adjoins the second port, said second flow channel thereby extending in a U- shape from the first port around the divider and back on the other side of the divider to the second port. Because the flow channel extends in a U-shape, a longer flow path is created for the medium in the second flow channel.

According to a further embodiment of the invention, a third edge area in the first plate type is arranged in the second plane in the plate type and extends around said plate type partly along the respective long side and partly along the respective short side, which edge areas constitute contact surface against edge areas on the second plate type which on the second plate type are arranged in a corresponding manner and which second plate type is placed below the first plate type in the plate stack. The side B of the first plate type is connected to the side A of the second plate type in a second plane. Through this, the said second flow channel is formed. This channel thus has an inlet through a first gate hole and an outlet through a second gate hole.

According to a further embodiment of the invention, each plate type comprises a board arranged at the respective short side. The board consists of a contact surface which is arranged to be connected to an adjacent plate type in the plate stack.

According to a further embodiment of the invention, a number of channels are arranged in an area where the dimples adjoin an edge area of a door, said channels communicating with the door hole to which the channels lead. The channels help to lead medium out of the gate to areas on each plate type that are difficult to get a medium to distribute to. By making these areas easier to reach for a medium, the total heat transfer surface on each plate type can be better utilized. This is because the medium is caused to spread and distributed over a larger area on the heat transfer surface by the channels leading a part of the medium to hard-to-reach areas on the heat transfer surface.

According to a further embodiment of the invention, a drainage channel is arranged in the board, or in direct proximity to the board, which drainage channel communicates with channel formed between two adjacent plates. The drainage channel consists of a hole arranged through a plate type. The drainage channel communicates with the first flow channel. In the first flow channel, medium can be left in operation at the short end of two connected plate types. This is because part of a medium that flows through the first flow channels between the long sides of the plate types can remain between the plate types, e.g. due to the medium condensing. Therefore, it is necessary to have a drainage channel that can divert excess or standing medium from the heat exchanger.

According to a further embodiment of the invention, the pattern with dowels in the first plate type is designed such that the peaks of two adjacent dowels, which are directed in one and the same direction, are arranged between them and at a level below the peaks, a valley which lies above two other adjacent dowels bottoms, which bottoms are opposite in relation to the direction of the peaks. The dimples contribute to the heat transfer surface being larger compared to if the heat transfer surface was flat.

According to a further embodiment of the invention, the dimples in the second plate type are directed on side A from the second plane in the direction of the first plane. On side Ai of the said second type of plate in the second plane, flat areas are arranged between the dimples.

These flat areas constitute abutment surface for peaks of the dimples belonging to the first type of plate connected to the second type of plate. On side A of the second plate type, the flat areas are arranged in such a way that the top portion of the divider of a second plate type can be placed against said area and connected to these.

Brief Description of the Drawings A preferred embodiment of the device according to the invention will now be described in more detail with reference to the accompanying schematic drawings, which show only the details necessary for understanding the invention.

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

Fig. 2 shows a view of the plate stack where the included plate types are separated from each other for clarification.

Fig. 3 shows a view of a first plate type.

Fig. 4 shows a section through the first plate type.

Fig. 5 shows a view of a second type of plate.

Fig. 6 shows a section through the second type of plate.

Detailed description of different embodiments of the invention Fig. 1 shows a heat exchanger (1) comprising a plate stack (2). The plate stack (2) is made up of a number of heat transfer plates consisting of a first plate type (3) and a second plate type (4). the heat exchanger (1) according to Fig. 1 is of the cross-current type. The plate types (3, 4) are arranged in such a way in the heat exchanger (1) that its longitudinal slides (5a, b) are open whereby a medium can flow through the heat exchanger (1) from a long side (5a) to a second long side (5b) . Short sides (6a, b) are advantageously connected to each other between adjacent plate types (3, 4).

Fig. 2 shows a view of the plate stack (2) where the plate types (3, 4) are separated from each other to clarify its position and how the respective medium flows between the respective pair of plates. In Fig. 2 it is seen that the plate stack (2) is built up of two plate types (3, 4) which are stacked one on top of the other. Each plate type (3, 4) comprises a first and a second gate hole (7, 8). Said door heels (7, 8) are placed on the respective plate type at one short side (6a). Each plate type (3, 4) comprises a heat transfer surface (9). Said heat transfer surface (9) comprises a pattern (10a, b) comprising a number of dimples (11). The design of the dimples in each plate type (3, 4) differs from each other. This is explained in more detail below. Fig. 2 shows how the flows of each medium take place through the heat exchanger (1). It is clear that the flows cross each other in the heat exchanger (1), hence the name heat exchanger of the cross-current type. Fig. 3 shows a first plate type (3). The pattern (10a) in the first plate type (3) extends between a first plane (12) and a second plane (13). This is illustrated in Fig. 4 which shows a section through the first plate type (3) parallel to the short sides (6a, b) and through the respective gate holes (7, 8). The first plate type has a side A and a side B. In Fig. 3, the side A is the side of the first plate type (3) that a reader sees. Side B consists of the underside of the first plate type (3) in Fig. 3.

Fig. 5 shows a second plate type (4). The pattern (10b) in the second plate type (4) extends in the same way as for the first plate type (3) between a second and a first plane (13, 12). When abutting between two types of plates (3, 4), which form a pair of plates, the planes (12, 13) in a pair of plates coincide with each other. This means that in a pair of plates, e.g. both plate types relate to one of the planes (12, 13). The first and the second plane (12, 13) of the second plate type (4) are illustrated in Fig. 6 which shows a section through the second plate type (4) parallel to the short sides (6a, b) and through the respective gate holes (7, The second plate type has a side A and a side B. In Fig. 5, the side A is the side of the second plate type (3) that a reader sees. Side B consists of the underside of the second plate type (3) in Fig. 5. In the plate stack, side A of the first plate type (3) together with the side of the adjacent second plate type forms the first flow channel (14, see Fig. 2). Side B on the first plate type (3) and the side A of the second plate type together form a second flow channel (15, see Fig. 2). A first medium (16) flows in the first flow channel (14). A second medium (17) flows into the second flow channel (15).

Said first and second medium (16, 17) have heat exchange between each other through the respective plate type (3, 4).

The first plate type (3) has a first edge area (18) arranged around each door hole (see Figs. 3, 4). This first edge area (18) is located in the first plane (12) in the plate type (3). Said first edge area (18) has the function of a plant surface. This is because the first edge area (18) is arranged to be abutted against a second edge area (19). This second edge area (19) is located around the respective gate hole on an adjacent second plate type (4, see Figs. 5, 6) in the plate stack (2). Said second edge region (19) is located in the first plane (12) of the second plate type (4). When abutting between the two plate types (3, 4), said edge areas (18, 19) coincide and adjoin each other in one and the same first plane (12). The short sides (6a, b) of said adjacent plate types (3, 4) are advantageously connected to each other in the first plane (12). Between said adjacent plate types (3, 4) the first flow channel (14) is arranged (see Fig. 2).

In the first plate type (3) a divider (20) is arranged (see Fig. 3). This divider (20) is advantageously pressed or embossed into the first plate type (3). Alternatively, a separate divider can be mounted firmly against the heat transfer surface (9) on the first plate type (3). 10 15 20 25 30 35 530 570 6 The divider (20) extends from one short side (6a) towards the other short side (6b) between and parallel to the long sides (5a, b) and between the gate holes (7, 8). The divider (20) has a bottom (21). This bottom (21) lies in the second plane (13) in the first plate type (3, see Fig. 4).

Said divider (20) with the bottom (21) on the side B of the first plate type (3) is arranged to abut against a side A of the second plate type (4). When connecting the side B of a first plate type (3) and the side A of a second plate type (4), the bottom (21) of said divider (20) is connected to the side B of said second plate type (4). 5a, b) and short sides (6a, b) are connected to each other advantageously in the second plane (13). The divider (20) is shorter than the longitudinal wires (5a, b). The divider (20) has a free end (22).

Because the divider (20) is shorter than the long sides (5a, b), a passage is arranged between the free end (22) of the divider (20) and the second short side (6a, b) between side B of a first plate type (3) and side A on a second plate type (4). Between said plate types (3, 4) the second flow channel (15) is arranged. The first port hole (7) communicates with the second port hole (8) via medium flowing in the second flow channel (15).

A third edge area (23) extends along the respective longitudinal side (5a, b) and short side (6a, b) of the first and the second plate type (3, 4). This third edge area (23) lies in the second plane (13) in the respective plate type (3, 4). The respective third edge area (23) of the respective plate type (3, 4) is arranged to abut against and be connected to each other.

A board (24) is arranged at the respective short side (6a, b) of the respective plate type (3, 4). The respective boards (24) on the respective adjacent plate types (3, 4) are arranged in such a way that the boards (24) can be abutted and connected to and against each other. In the board (24) belonging to the first plate type (3) along the second short side (Gb), a drainage channel (25) is arranged in the board (see Fig. 3). The drainage channel (25) consists of a hole through the board (24) in the first plate type (3). Through the drainage channel (25) it becomes possible to remove medium which has been left in a pair of plates due to e.g. condensation.

A number of distribution channels (26a-d, see Fig. 5) placed in the second plate type (4) extend from the respective first and second edge areas (14, 15) around the respective gate hole (7, 8) to a number of dimples placed around said gate hole. (7, 8) in the heat transfer surface (9).

The distribution channels (26a-d) lead medium from the port (7, 8) to the parts of the heat transfer surface (9) which are difficult to access in terms of flow. The distribution channels (26a-d) are pressed or embossed in the plate type (4).

The dimples in the first plate type (3) differ in design from the dimples in the second plate type (4). Due to this, in each flow channel (14, 15) an irregularity in the channel surface is obtained which contributes to increased turbulence of a medium flowing through said flow channel (14, 15). 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 (12)

10 15 20 25 30 35 530 3170 Patent claims: A cross-flow type heat exchanger (1) for heat exchange between different media comprising a plate stack (2), said plate stack (2) comprising a plurality of heat transfer plates of a first plate type (3) and of a second plate type (4), which plate types (4) 3, 4) are alternately stacked on top of each other in the plate stack (2), which respective plate type (3, 4) comprises: two opposite long sides (5a, b); two opposite short sides (6a, b); a first and a second port hole (7, 8) arranged at one short side (6a); a side A comprising a heat transfer surface (9); a side B comprising the other side of said heat transfer surface (9); which heat transfer surface (9) comprises a pattern (10a, b) comprising a portion of dimples (11), which heat transfer surface (9) is arranged between the long and short sides (5a, b, 6a, b), which heat transfer surface (9) in respective plate type (3,4) is arranged between a first and a second plane (12, 13), wherein side A of a first plate type (3) is connected and adjoins side B of a second plate type (4) in a first plane (12 ) between adjacent plate types (3, 4) forming the first flow channel (14), wherein side B of a first plate type (3) is connected to side A of a second plate type (4) in a second plane (13) between adjacent plate types (3, 4). ) forming a second flow channel (15), characterized in that said first flow channel (14) has a larger volume than said second flow channel (15), the volume of a first medium (16) in said first flow channel (14) being larger than the volume of a second medium (17) in said second flow channel (15), which said medium (16, 17) has heat transfer between them through the heat transfer surface (9) between the channels (14, 15), the pressure failure of medium (16) flowing through the first flow channel (14) being less than the pressure drop of medium (17) flowing through the second flow channel (15). Heat exchanger (1) according to claim 1, characterized in that around each port hole (7, 8) in the first plate type (3) a first edge area (18) is arranged in the first plane (12), which first edge area (18 ) constitutes abutment surface against a second edge area (19) arranged around respective gate holes (7, 8) in the second plate type (4) and which second plate type (4) is arranged on the first plate type (3) in the plate stack (2), the the side A of the first plate type (3) is connected and adjoins the side B of the second plate type (4) Heat exchanger (1) according to claim 1, characterized in that a divider (20) is arranged, preferably embossed, in the heat transfer surface (9) in one plate type (3,4), preferably the first plate type, which divider (20) extends from the short side (6a) where said gate (7, 8) is arranged in the direction of the second short side (6b), which divider (20) is shorter than said long sides (5a, b) and arranged between them and arranged parallel between said long sides (5a, b). 10 15 20 25 30 35 530 5 '? Ü 9 Heat exchanger (1) according to claim 3, characterized in that the divider (20) in the plate type (3) comprises an ace (21), or the bottom (21), which lies in the second plane (13) on a side B in the first plate type (3), the divider (20) being connected to the side A of an adjacent second plate type (4), a passage being formed between two plate types (3, 4) between free end (22) of the divider (20) and short side (6b) of the plate types (3, 4). Heat exchanger (1) according to claim 1, characterized in that the first flow channel (14) is arranged between the respective long side (5a, b) and arranged between two adjacent plate types (3, 4) which plate types (3, 4) are connected with each other in said first plane (12). Heat exchanger (1) according to claim 1, characterized in that the second flow channel (15) is arranged in the second plane (13) and extends between said ports (7, 8), said second flow channel (15) extending from the first short side (6a) adjacent to the first port hole (7), in the direction of the second short side (6b) between the divider (20) and one long side (Sa), through the passage arranged between the free end of the divider (20) (22) ) and the second short side (6b) and in the direction of the first short side (6a) between the second side of the divider (20) and the second long side (5b), which first short side (6a) also adjoins the second port hole (8) said second flow channel (15) thereby extending in a U-shape from the first port hole (7) around the divider (20) and back on the other side of the divider (20) to the second port hole (8). Heat exchanger (1) according to claim 1, characterized in that a third edge region (23) in the first plate type (3) is arranged in the second plane (13) in the plate type (3) and extends around said plate type (3). 3) partly along the respective long side (5a, b) and partly along the respective short side (6a, b), which edge areas (23) constitute abutment surface against edge areas (23) on the second plate type (4) which on the second plate type (4) are arranged in a corresponding manner and which second plate type (4) is located below the first plate type (3) in the plate stack (3). Heat exchanger (1) according to claim 1, characterized in that the respective plate type (3, 4) comprises a board (24) arranged at the respective short side (6a, b). Heat exchanger (1) according to claim 1, characterized in that a number of distribution channels (26a-d) are arranged in an area where the dimples (11) adjoin an edge area (18, 19) of a gate (7, 8), wherein said distribution channels (26a-d) communicate with the respective gate (7, 8) to which the respective distribution channel (26a-d) leads. Heat exchanger (1) according to claim 8, characterized in that a drainage channel (25) is arranged in the board (24), or in direct proximity to the board (24), which drainage channel (25) communicates with a flow channel (14, 15) formed between two adjacent plate types (3, 4). 10 530 H71) 10 Heat exchanger (1) according to claim 1, characterized in that the pattern (10a, b) with dimples (11) in the first plate type (3) has such a design that the peaks of two adjacent dimples (11), which are directed in one and the same direction, between themselves and in the level below the peaks, a valley is arranged, which valley lies above the bottoms of two other adjacent dimplers (11), which bottoms are opposite in relation to the direction of the peaks Heat exchanger (1) according to claim 1, characterized in that the dimples (11) in the second plate type (4) are directed on side A from the second plane (13) in the direction of the first plane (12).