BRPI0808493A2 - TYPE HEAT EXCHANGER CROSSED - Google Patents

Description

Patent Descriptive Report for "CROSS-TYPE HEAT EXCHANGER".

Field of the Invention

The present invention relates to a cross-flow type heat exchanger for heat exchange between different means according to the preamble of claim 1.

Background of the Invention

European Patent Specification EP 0984239 B1 refers to a cross-flow type heat exchanger. The heat exchanger of 10 according to EP 0984239 B1 is composed of two types of plates placed alternately on top of one another to form a plate stack. Ducts are placed between two adjacent plates. The heat exchanger is adapted to receive two means for heat transfer between the two means. The ducts all have substantially the same volume as each other. The fact that media may differ in density makes it impossible to effectively utilize heat exchange between two media when the respective duct has the same volume.

Summary of the Invention

The object of the present invention is to provide a heat exchanger capable of maximum and optimal heat transfer between two means that flow in two ducts and undergo heat transfer through a duct wall.

A further object of the invention is to provide a device and method that is cost effective compared to the state of the art, and whose device is easy to construct, making it possible to optimize cost and time.

The above and other objects are achieved according to the invention by means of the device described in the introduction, which has the characteristics indicated in claim 1.

An advantage achieved with a device according to the

The characterizing part of claim 1 is that optimal heat transfer between two different media of different density becomes possible. Preferred embodiments of the device according to the invention further have the characteristics set forth in subclaims 2-12.

According to one embodiment of the invention, a first edge region in the foreground is placed around respective doors in the first type of plate and constitutes a meeting surface against a second edge region placed around respective doors in the second type of plate. , whose second plate type is placed over the first plate type in the plate stack, whereby side A of the first plate type is connected and adjacent to side B of the second plate type. A first flow duct 10 is thus formed between two adjacent plate types.

According to another embodiment of the invention a divider, preferably stamped or pressed, is placed on the heat transfer surface of a plate type, preferably the first plate type, and extends from the short side where said doors are situated in the towards the other short side, whose divider is shorter than said long sides, and is placed between them and is placed parallel between said long sides. An advantage of a splitter on a plate type in a heat exchanger is that it stiffens the plate stack structure.

According to another embodiment of the invention, the divider in the plate 20 comprises a crest or bottom situated in the background on one side B of the first type of plate, whereby the divider is connected to the side A of an adjacent second type of plate, forming with this between two plate types a passageway between the free end of the divider and a short side of the plate types. Said crest or bottom of the divider has a contact surface 25 which connects to the second type of adjacent plate. The connection between two types of plate is by means of technology already known to one skilled in the art, for example, brazing, welding, adhesive, bonding, etc.

According to another embodiment of the invention the first flow duct is placed between respective long sides and placed between two adjacent plate types which are connected to each other in said foreground. As mentioned above, the divider extends from the foreground to the background on a side B of a first type of plate. This means that on side A of the first type of plate the divider does not protrude from the surface and has no effect on a flow on the side of the first type of plate. As mentioned above, side A of a first type of plate is connected to side B of a second type of plate, thereby forming said first flow duct between said plate types. Since the divider does not affect the flow in the first flow duct, the duct may be placed between respective long sides of said adjacent plate types.

According to another embodiment of the invention the second flow duct is placed in the background and extends between said ports, whereby said second flow duct extends from the first short side adjacent the first door towards the second side. short between the divider and a long side, through the passageway between the free end of the divider and the second short side, and towards the first short side between the second side of the divider and the second long side, whose first short side is also adjacent to the second gate, whereby said second flow duct thus extends in a U-shape from the first gate around the divider back over the second side of the divider to the second gate. The flow duct extending into a U-shape results in a longer flow path to the middle in the second flow duct.

According to another embodiment of the invention the third edge region of the first plate type is placed in the plate type background and extends around said plate type at the same time along each long side and along each side. short side whose edge regions constitute a meeting surface against the edge region of the second plate type which in the second plate type is placed in a corresponding manner, the second plate type of which is placed over the first plate type in the stack of plates. plates. Side B of the first plate type connects to side 30A of the second plate type in a background, thus forming said second flow duct. This duct thus has an entrance through the first door and an outlet through the second door. According to another embodiment of the invention each type of plate has a rim placed on each short side. The rim is a gathering surface adapted to connect to an adjacent plate type in the plate stack.

According to another embodiment of the invention a number of

ducts are placed in a region where the undulations are adjacent to the edge region of a door, whereby said ducts communicate with the door to which the ducts lead. The ducts help to carry medium out of the door to regions of the respective plate type for which it is difficult to distribute a medium. Making these regions easier for a medium to reach may result in better utilization of the total heat exchange surface of the respective plate type by the medium being forced to spread and distributed over a larger area of the heat exchange surface, since the ducts carry part of the middle to regions of the heat exchange surface for which access is difficult.

According to another embodiment of the invention a drainage duct is placed in the rim or in the immediate vicinity of the rim, and communicates with ducts formed between two adjacent plates. The drainage duct takes the form of a hole arranged through a type of plate. The drainage duct communicates with the first flow duct. In the first drainage duct, medium may be stationary during operation on the short end of two types of connected plates. This is because part of a medium that flows through the first long side flow ducts of the plate types can remain between the plate types, for example, because the medium condenses. Hence the need for a drainage duct that can drive superfluous or stationary media away from the heat exchanger.

According to another embodiment of the invention the configuration of the ripple design in the first type of plate is such that the peaks of two adjacent ripples pointing in the same direction have placed between them a level below the peaks, a valley higher than the bottoms of the two other adjacent ripples, whose bottoms point in the opposite direction from that of the peaks. The ripples contribute to the heat exchange surface being larger than if it were flat.

According to another embodiment of the invention the undulations of the second type of plate point on the side A of the second plane towards the foreground. On side A of said second plate type in the second plane, flat regions are placed between the undulations. These flat regions constitute a meeting surface for undulation peaks belonging to the first type of plate that connects to the second type of plate. On side A of the second plate type the flat regions are thus placed such that a peak portion of the divider on a second plate type 10 can be placed against and connected to said regions.

Brief Description of the Drawings

A preferred embodiment of the device according to the invention is described below in more detail with reference to the accompanying schematic drawings, which only show the parts necessary for understanding the invention.

Figure 1 outlines a view of a plate stack for a heat exchanger.

Figure 2 outlines a view of the plate stack where the constituent plate types (are) separated from each other for clarity.

Figure 3 outlines a view of a first type of plate.

Figure 4 outlines a section through the first type of plate.

Figure 5 outlines a view of a second type of plate.

Figure 6 outlines a section through the second type of plate. Detailed Description of Various Modes of the Invention Figure 1 outlines a heat exchanger (1) comprising

a stack of plates (2). The plate stack (2) consists of a number of heat transfer plates, some comprising a first plate type (3) and some a second plate type (4).

The heat exchanger (1) according to figure 1 is of the cross flow type. The plate types (3, 4) are so placed in the heat exchanger (1) that their long sides (5a, b) are opened, whereby a means can flow through the heat exchanger (1) from a Ionqo side (5a) to the other long side (5b). The short sides (6a, b) are advantageously connected to each other between adjacent plate types (3, 4).

Figure 2 outlines a view of the plate stack (2) where plate types (3, 4) are separated from each other to clarify their positions and how their means flow between respective plate pairs. Figure 2 shows the plate stack (2) consisting of two types of plate (3, 4) stacked alternately on top of one another. Each type of card (3, 4) has first and second ports (7, 8). Said ports (7, 8) are situated near the short side (6a) of the respective plate type. Each plate type (3, 4) has a heat exchange surface (9). Said heat exchange surface (9) has a design (10a, b) comprising a number of undulations (11). The configuration of the undulations differs between the respective plate types (3, 4). This is explained in more detail below. Figure 2 illustrates how the respective medium flows through the heat exchanger (1). It clearly shows that the flows cross each other in the heat exchanger (1), hence the name cross flow type heat exchanger.

Figure 3 outlines a first type of plate (3). The drawing (10a) of the first plate type (3) extends between a foreground (12) and a second plane (13). This is illustrated in Figure 4 which delineates a section through the first type of plate (3) parallel to the short sides (6a, b), and through the respective ports (7, 8). The first type of card has an A side and a B side. In Figure 3 side A is the side of the first card type (3) that is visible to the reader. Side B is the underside of the first plate type (3) in Figure 3.

Figure 5 outlines a second type of plate (4). The drawing

(10b) of the second plate type (4) extends in a manner corresponding to that of the first plate type (3) between the second and foreground (13, 12). When the two plate types (3, 4) that make up a pair of plates meet, the planes (12, 13) of a pair of plates coincide. This means that in a pair of plates it is possible, for example, that both types of plates relate to either plane (12, 13). Both foreground and background (12, 13) of the second plate type (4) are illustrated in Figure 6 which outlines a section through the second plate type (4), parallel to the short sides (6a, b) and across the respective ports (7, 8). The second type of card has a side A and a side B. In Figure 5 side A is the side of the second card type (4) that is visible to a reader. Side B is the underside of the second plate type (4) in Figure 5.

In the plate stack side A of the first plate type (3) together with side B of the second plate type adjoins a first flow duct (14, see figure 2). Side B of the first plate type (3) and side A of the second plate type together form a second flow duct (15, see Figure 2). A first means (16) flows into the first flow duct (14). A second means (17) flows into the second flow duct (15). Said first and second means (16), (17) are subjected to heat exchange between them through the respective plate types (3, 4).

The first type of plate (3) has around each door a first edge region (18, see figures 3, 4). This first edge region (18) is situated in the foreground (12) of the plate type (3). Said second edge region (18) has the function of an encounter surface. This is because the first edge region (18) is adapted to meet against a second edge region (19). This second edge region (19) is situated around the respective doors of a second type of adjacent plate (4, see figures 5, 6) in the plate stack (2). Said second edge region (19) is situated in the foreground (12) of the second plate type (4). Upon meeting the two types of plate (3, 4) said edge regions (18, 19) coincide and are adjacent to one another in the same foreground (12). The short sides (6a, b) of said adjacent plate types (3, 4) are advantageously connected to one another in the foreground (12). The first flow duct (14) is placed between said adjacent plate types (3, 4 see figure 2).

A divider (20) is placed on the first type of plate (3, see figure 3). This divider 20 is advantageously pressed or stamped on the first type of plate (3). Alternatively, a separate divider may be permanently fitted to the heat exchange surface (9) of the first plate type (3). The divider (20) extends from a short side (6a) towards the other short side (6b) between and parallel to the long sides (5a, b) and between the doors (7, 8). The divider (20) has a bottom (21) situated in the background (13) of the first type of plate (3, see figure 4).

Said divider (20) with its bottom (21) on side B of the first plate type (3) is adapted to meet against side A of the second plate type (4). As mentioned earlier, when in contact between side B of a first type of plate (3) and side A of a second type of plate (4), the bottom (21) of splitter (22) connects to side B of said second type of plate (4). The long sides (5a, b) and short sides (6a, b) of adjacent plate types (3, 4) advantageously connect to each other in the background (13). The divider (20) is shorter than the long sides (5a, b). The divider (20) has a free end (22). The fact that the divider (20) is shorter than the long sides (5a, b) results in a passage between the free end (22) of the divider (20) and another short side 6b between said first b side. plate type (3) and side A of a second plate type (4).

The second flow duct (15) is placed between said plate types (3, 4). The first port (7) communicates with the second port (8) by means of flow in the second flow duct (15).

A third edge region (23) extends along respective long sides (5a, b) and short sides (6a, b) of both first and second plate types (3, 4). This third edge region (23) is situated in the background (13) of the respective plate types (3,4). The respective third edge regions 23 of the respective plate types (3, 4) are adapted to meet and be connected to each other.

A rim (24) is placed on its short sides (6a,

b) the respective plate types (3, 4). The respective rims (24) on respective adjacent plate types (3, 4) are placed so that the rims (24) can meet against and be connected to each other. A drainage duct (25) is placed in the rim (24) along the second short side (6b) 30 of the first type of plate (3, see figure 3). The drainage duct (25) takes the form of a hole through the rim (24) of the first type of plate (3). It is thus possible to remove through the drainage duct 25 any medium remaining in a pair of plates, for example as a result of condensation. In an alternative embodiment (not shown in the figures) the respective short sides between adjacent plates in the plate stack are opened, whereby adjacent rims on the short sides do not seal against each other.

5 A number of distribution ducts (26a-d, see figure 5) place

in the second plate type (4) extend from the respective first and second edge regions (14, 15) around respective doors (7, 8) to a number of undulations about said doors (7, 8) on the heat exchange surface (9). The distribution ducts 26a-d lead half to 10 from the doors 7,8 to the parts of the heat exchange surface 9 which are difficult for the flow to reach. The distribution ducts (26a-d) are pressed or stamped on the second plate type (4).

The undulations of the first plate type (3) differ in configuration from the undulations of the second plate type (4). The result in each flow duct (14, 15) is the surface irregularity of the duct which helps to increase the turbulence of a medium flowing through said flow ducts (14, 15).

The invention is not limited to the above embodiment, but may be varied and modified within the scope of the claims described below as partially described above.

Claims (13)

1. Cross-flow type heat exchanger (1) for heat exchange between different media comprising a plate stack (2) which itself comprises a number of the heat transfer plates of a first plate type (3) ) and a second type of plate (4), whose plate types (3, 4) are stacked alternately on top of each other in the plate stack (2), and each has two opposite long sides (5a, b), two opposite short sides (6a, b), first and second doors (7, 8) placed next to a short side (6a), one side A having a heat exchange surface (9), one side B comprising a another side of said heat exchange surface (9) whose heat exchange surface (9) has a design (10a, b) comprising a wavy portion (11) and is placed between the long and short sides (5a, b, 6a, b) whose heat exchange surface (9) of each type of plate (3, 4) is placed between foreground and background (12, 13), whereby side A of a first The plate type (3) is connected and adjacent to side B of a second plate type (4) in the foreground (12) and between adjacent plate types (3, 4) that form a first flow duct (14). ) and side B of a first plate type (3) is connected to side A of a second plate type (4) in a background 13 between adjacent plate types (3, 4) forming the second flow duct. (15), characterized in that said first flow duct (14) has a larger volume than said second detachment duct (15), whereby the volume of a first medium (16) in said first flow duct (14) ) be greater than the volume of the second medium (17) in said second flow duct (15), said means (16, 17) being subjected to heat transfer between them via the heat exchange surface (9) between the ducts (14, 15), the pressure drop of the medium (16) flowing through the first flow duct (14) is less than the pressure drop of the medium (17) q which flows through the second flow duct (15). Heat exchanger (1) according to claim 1, characterized in that around each door (7, 8) in the first plate type (3) a first edge region (18) is placed in the foreground ( 12) and constitute a meeting surface against a second edge region (19) placed around each door (7, 8) of the second plate type (4), whose second plate type (4) is placed over the first type. plate (3) on the plate stack (2), whereby side A of the first plate type (3) is connected and adjacent to side B of the second plate type (4). Heat exchanger (1) according to Claim 1, characterized in that a divider (20) preferably stamped is placed on the heat exchange surface (9) of a plate type (3,4) preferably the first type. extending from the short side (6a) where said doors (7, 8) are situated towards the second short side (6b) whose divider (20) is shorter than said long sides (5a, b ), be placed between them and be placed parallel between said long sides (5a, b). Heat exchanger (1) according to Claim 3, characterized in that the divider (20) of the first type of plate (3) comprises a ridge (21) or bottom (21) situated in the second plane (13). over side B of the first plate type (3), whereby the divider (20) is connected to side A of a second adjacent plate type (4) thereby forming between two types of plate (3, 4) a passage between a free end (22) of the divider (20) and a short side (6b) of the plate types (3, 4). Heat exchanger (1) according to Claim 1, characterized in that the first flow duct (14) is arranged between respective long sides (5a, b) and between two adjacent plate types (3, 4). which are connected to each other in said foreground (12). Heat exchanger (1) according to claim 1, characterized in that the second flow duct (15) is placed in the second plane (13) and extends between said doors (7, 8) for which reason. The second flow duct (15) extends from the first short side (6a) adjacent the first door (7) towards the second short side (6b) between the divider (20) and a long side (5a) through the passage between the free end (22) of the divider (20) and the second short side (6b) towards the first short side (6a) between the second side of the divider (20) and the other long side (5b), first The short side (6a) is also adjacent to the second port (8), whereby said second flow duct (15) thus extends in a U-shape from the first port (7) around the divider (20) and from turn on the other side of the divider (20) to the second door (8). Heat exchanger (1) according to Claim 1, characterized in that a third edge region (23) of the first plate type (3) is placed in the second plane (13) of the first plate type (3). and extending around said plate type (3) at the same time along each long side (5a, b) and along each short side (6a, b), whose edge regions (23) constitute a surface of against the edge regions (23) of the second plate type (4) which are placed on the second plate type (4) in a corresponding manner, whose second plate type (4) is placed under the first plate type (4). 3) on the plate stack (2). Heat exchanger (1) according to Claim 1, characterized in that each type of plate (3, 4) has a ring (24) placed on each short side (6a, b). Heat exchanger (1) according to claim 1, characterized in that a number of distribution ducts (26a-d) are placed in a region where the undulations (11) are adjacent to the edge region (18, 19 ) of a door (7, 8), whereby said distribution ducts (26a-d) communicate with the respective ports (7, 8) to which the respective distribution ducts (26a-d) lead. Heat exchanger (1) according to claim 8, characterized in that a drainage duct (25) is placed in the rim (24) or in the immediate vicinity of the rim (24) and communicates with flow ducts (14). , 15) formed between two adjacent plate types (3, 4). Heat exchanger (1) according to claim 1, characterized in that the configuration of the undulation design (10a, b) of the first type of plate (3) is such that the peaks of two adjacent undulations (11) which point in the same direction have been placed between them at a level below the peaks, a valley higher than the bottoms of two other adjacent ripples (11), whose bottoms point in the opposite direction from that of the peaks. 12 Heat exchanger (1) according to Claim 1, characterized in that the undulations (11) of the second plate type (4) point on the side from the second plane (13) towards the foreground (12). .