CN211451981U - Plate heat exchanger - Google Patents

Abstract

The application provides a plate heat exchanger, wherein a plate is provided with a main heat exchange area, the plate is provided with a plurality of corrugated structures which are arranged at intervals, the plurality of corrugated structures form a plurality of crest portions and a plurality of trough portions, the crest portions and the trough portions are alternately arranged, two adjacent trough portions have the same or different depths, and the depths of the trough portions are calculated based on the crest portions; along the direction perpendicular to the arrangement direction of the corrugated structure, the corrugated structure comprises at least two straight parts and a bent part; the bending part is positioned between two adjacent straight parts, the two adjacent straight parts and the bending part positioned between the two adjacent straight parts form a herringbone corrugated pattern, and the bending part forms the corner of the herringbone corrugated pattern; at least one of the bent portions is provided with a communication portion which at least partially penetrates through the bent portion in the arrangement direction of the corrugated structure, the communication portion communicates two adjacent wave trough portions, and the sheet is formed with a flow passage through which fluid passes through the wave crest portion. This application is favorable to improving plate heat exchanger's heat transfer performance.

Description

Plate heat exchanger

Technical Field

The utility model relates to a heat exchange technology field especially relates to a plate heat exchanger.

Background

The plate heat exchanger is a well-known high-efficiency and compact liquid cooling heat exchanger and is widely applied to industries such as refrigeration air conditioners, new energy automobiles and the like. In the related art, the plate of the plate heat exchanger is provided with the herringbone wave patterns, when adjacent plates are welded, large welding spots which are not beneficial to fluid flow are easily formed at the sharp-angled positions of the herringbone wave patterns of the plates, the phenomenon that fluid on the plate is distributed unevenly is caused in the plate heat exchanger, the effective heat exchange area of the plate is reduced, and the plate utilization rate of the plate is lower. Thereby affecting the heat exchange performance of the plate heat exchanger.

SUMMERY OF THE UTILITY MODEL

The application provides a plate heat exchanger, which comprises a plurality of plates, wherein the plates comprise a plurality of first plates and a plurality of second plates, the first plates and the second plates are alternately arranged, each plate comprises a front surface and a back surface which are opposite, the front surface of each first plate is opposite to the back surface of each second plate, and the back surface of each first plate is opposite to the front surface of each second plate; each sheet is provided with a main heat exchange area, the sheet is provided with a plurality of corrugated structures which are arranged at intervals along the length direction of the sheet in the main heat exchange area, the plurality of corrugated structures form a plurality of crest portions and a plurality of trough portions along the length direction of the sheet, the crest portions and the trough portions are alternately arranged, two adjacent trough portions have the same or different depths, and the depths of the trough portions are calculated by taking the crest portions as references; the corrugated structure comprises at least two straight portions and one curved portion; the bending part is connected between two adjacent straight parts, and the extension directions of the two adjacent straight parts are intersected, so that the two adjacent straight parts and the bending part positioned between the two adjacent straight parts form a herringbone corrugated pattern, and the bending part forms the corner part of the herringbone corrugated pattern;

wherein, for at least one sheet in the plurality of sheets, at least one of the plurality of bending parts of the plurality of corrugated structures is provided with a communication part which at least partially penetrates through the bending part in the length direction of the sheet, the communication part is communicated with two adjacent wave trough parts separated by the corrugated structures, and the sheet is provided with a flow channel through which fluid passes through the wave crest part between the two adjacent wave trough parts.

The utility model provides a channel structure that plate sheet of plate heat exchanger formed has been improved, at least one flexion of corrugated structure is equipped with the intercommunication portion, the intercommunication portion intercommunication is by two adjacent trough portions that corrugated structure separates for the plate sheet forms the flow channel that can pass the crest portion, also fluid can directly reach another trough portion adjacent with this trough portion from a trough portion through this runner channel, the solder joint that has reduced the flexion influences fluid mobility, fluid's mobility in the middle part of chevron shape ripple pattern has been improved, and then the homogeneity that distributes on plate sheet of plate heat exchanger is improved to the fluid, thereby improve plate heat exchanger's heat transfer performance.

Drawings

Fig. 1 is a schematic structural diagram of a plate heat exchanger provided in the present application;

FIG. 2 is a schematic structural view of a first plate provided herein;

FIG. 3 is an enlarged view of the front side of the first plate of FIG. 2;

FIG. 4 is a schematic cross-sectional view of a portion of the first plate of FIG. 2 of the present application in the direction A-A;

FIG. 5 is a schematic view of an assembly structure of a first plate and a second plate provided by the present application;

FIG. 6 is an enlarged view of another embodiment of the first plate of FIG. 2 of the present application;

FIG. 7 is a schematic structural view of another first plate provided herein;

FIG. 8 is an enlarged view of the front side of the first plate of FIG. 7;

FIG. 9 is a schematic cross-sectional view of the first plate of FIG. 7 taken along the direction B-B of the present application;

FIG. 10 is a schematic structural view of a second plate provided in accordance with the present application for mating assembly with the first plate of FIG. 7;

FIG. 11 is an enlarged view of the front side of the second plate shown in FIG. 10;

FIG. 12 is a schematic cross-sectional view of the second sheet of FIG. 10 of the present application in the direction C-C;

FIG. 13 is an enlarged view of yet another configuration of the first plate of FIG. 7 of the present application;

fig. 14 is a schematic view of an assembly structure of the first plate illustrated in fig. 7 and the second plate illustrated in fig. 9 of the present application.

Detailed Description

In the prior art, when two plates of a plate heat exchanger are stacked together, welding spots at sharp corners of herringbone waveform patterns are generally large, so that the flow rate of fluid at the sharp corners is low, even no fluid passes through to form a flow dead zone, the flow rate distribution of the fluid on the plates is uneven, and the heat exchange performance of the plate heat exchanger is reduced. The application provides a plate heat exchanger has improved the access structure that corrugated structure formed on the slab, is favorable to reducing the distribution degree of difficulty of fluid when near corrugated structure flexion flows, improves the homogeneity that fluid flows on the slab to improve plate heat exchanger's heat transfer performance.

As shown in fig. 1 to 14, the present invention provides a plate heat exchanger 10, which includes a plurality of plates 100, the plurality of plates 100 are stacked to form a flow channel through which two kinds of fluid that are not communicated flow, the plurality of plates 100 include a plurality of first plates 101 and a plurality of second plates 102, and the plurality of first plates 101 and the plurality of second plates 102 are alternately arranged. Each sheet 100 includes opposing front and back sides 1001, 1002, the front side 1001 of the first sheet 101 opposing the back side 1002 of the second sheet 102, and the back side 1002 of the first sheet 101 opposing the front side 1001 of the second sheet 102

Of course, for the product of the plate heat exchanger 10, it may also include external connection pipes corresponding to two fluids, and the external connection pipes corresponding to two fluids may be located on the same side or different sides of the plate heat exchanger 10 in the thickness direction, and in fig. 1, the external connection pipes are illustrated as being located on different sides of the plate heat exchanger 10.

The plate 100 of the plate heat exchanger 10 provided by the application is provided with a main heat exchange area 1 in the middle of the plate 100, the plate 100 is provided with a plurality of corrugated structures 2 arranged at intervals along the length direction of the plate 100 in the main heat exchange area 1, the plurality of corrugated structures 2 form a plurality of crest portions 21 and a plurality of trough portions 22 along the arrangement direction of the corrugated structures 2, the crest portions 21 and the trough portions 22 are alternately arranged, two adjacent trough portions 22 have the same or different depths, and the depths of the trough portions 22 are calculated based on the crest portions 21.

The corrugated structure 2 comprises at least two straight portions 23 and one curved portion 24. The curved portion 24 is located between two adjacent flat portions 23, and the extending directions of the two adjacent flat portions 23 intersect, so that the two adjacent flat portions 23 and the curved portion 24 located therebetween form a herringbone corrugated pattern, and the curved portion 24 forms a corner of the herringbone corrugated pattern.

Wherein, for at least one sheet of the plurality of sheets 100, for each of the first sheet 101 and the second sheet 102, or one of the plurality of first sheets 101, or one of the plurality of second sheets 102, at least one bent portion 24 of the plurality of corrugated structures 2 is provided with a communication portion 241, at least part of the communication portion 241 penetrates through the bent portion 24 in the arrangement direction of the corrugated structures 2, the communication portion 241 communicates two adjacent wave trough portions 22 separated by the corrugated structures 2, and the sheet 100 is formed with a flow channel 25 through the communication portion 241, through which a fluid passes through the wave trough portion 21 between the two adjacent wave trough portions 22.

The communicating portion 241 penetrates the bending portion 24 along a substantially bisector direction of an included angle between two adjacent straight portions 23, the communicating portion 241 is a groove depressed from the crest portion 21, and a depth corresponding to the groove is smaller than or equal to a depth of any one of the trough portions 22 of two adjacent trough portions 22. The schematic structure of the first plate 101 described with reference to fig. 2 and the enlarged structure of the main heat exchange area part of the first plate 101 shown in fig. 3 can be considered.

In order to improve the heat exchange performance of the plate heat exchanger, at least a part of the corrugated structures 2 of the plurality of corrugated structures 2 extends to the edge of the plate, for example, the intersection of the first plane part 31 and the flanging of the plate, so that the heat exchange area formed between two adjacent plates is large, fluid can flow at the edge part of the plate, and the uniformity of the fluid flowing on the plate is improved.

In the plate heat exchanger provided in the embodiment of the present application, the plurality of plates 100 includes a plurality of first plates 101 and a plurality of second plates 102, the first plates 101 and the second plates 102 are alternately arranged, and each plate 100 includes opposite front and back surfaces 1001 and 1002. Refer to fig. 5 for illustrating a laminated structure of a first plate 101 and a second plate 102.

In order to reduce the cost, the first plate 101 and the second plate 102 are plates 100 having the same shape and structure, and when stacked, the first plate 101 is rotated 180 ° with respect to the second plate 102 for stacking.

In one embodiment, the depths of two adjacent wave trough portions 22 are substantially equal, the plate 100 further comprises first mating regions 3 located at two sides of the main heat exchange region 1 in the length direction, each first mating region 3 comprises a first plane portion 31, each first plane portion 31 is connected with a wave trough portion 22 at the edge of the main heat exchange region 1, each wave trough portion 22 is flush with the first plane portion 31, each wave crest portion 21 protrudes to one side of the plate 100 relative to the first plane portion 31, and each wave trough portion 22 and each wave trough portion 21 are provided with a plane or a micro-curved surface for welding with the adjacent plate 100.

For convenience of understanding, in the first fitting region 3 of the first plate 101, two corner portions of the first plane portion 31 are formed with two plane corner holes, and the other two corner portions of the first plane portion 31 are respectively formed with boss corner holes protruding from the plate surface by a certain height, the direction in which the boss corner holes protrude from the first plane portion 31 is opposite to the direction in which the flanges protrude from the first plane portion 31, where the side of the first plate 101 having the boss corner holes is defined as a front side 1001 and the other side is defined as a back side 1002.

The corrugated structure 2 is raised relative to the first plane part 31 on the front surface 1001 of each plate 100, the crest part 21 is formed on the top of the corrugated structure 2, correspondingly, the corrugated structure 2 is formed with a groove part relative to the first plane part 31 on the back surface 1002 of each plate, the trough part 22 is formed on the part between two adjacent corrugated structures 2, the front surface 1001 of the first plate 101 is opposite to the back surface 1002 of the second plate 102, the back surface 1002 of the first plate 101 is opposite to the front surface 1001 of the second plate 102, the herringbone corrugated patterns on the corresponding positions of the first plate 101 and the second plate 102 are oppositely arranged, and the crest part 21 of each plate is contacted with the trough part 22 of the adjacent plate to form a welding point.

The individual corrugations 2 are arranged at a distance from one another on the plate, and the pitch of the corrugations 2 may or may not be equal. In the first sheet 101 and the second sheet 102, referring to the sheet cross-sectional view illustrated in fig. 4, the valley portions 22 are formed between adjacent corrugated structures 2, and the peak portions 21 are formed at the tip end portions of the corrugated structures 2.

Due to the existence of the communication portion 241, when the fluid flows from one trough 22 of the front surface 1001 of the plate 100 to another adjacent trough 22 at a position close to the corner of the herringbone waveform pattern, the fluid does not need to completely turn over the crest between two adjacent troughs 22, and can directly reach the other trough 22 through the flow channel 25 formed by the communication portion 241, which is equivalent to opening up a "shortcut" to the next trough 22 in the original flow dead zone, and the flow pressure drop of the flow channel 25 formed by the communication portion 241 is relatively low, so that the limitation of the original flow dead zone is broken, the fluidity of the fluid at the sharp corner of the herringbone waveform pattern is improved, and the distribution of the fluid on the plate surface of the plate is facilitated.

Further, in order to prevent the fluid from flowing out toward the outlet on the other side of the plate in a manner of flowing off the straight line through the communication portion 241 at the acute angle position of the herringbone wave pattern, as shown in a partial structure enlarged view of the first plate in fig. 6, the plurality of corrugated structures 2 include a plurality of first corrugated structures 251 and a plurality of second corrugated structures 252, the communication portion 241 is provided at the bent portion 24 of the first corrugated structure 251, the communication portion 241 is not provided at the bent portion 24 of the second corrugated structure 252, and the first corrugated structures 251 and the second corrugated structures 252 are alternately arranged at the main heat exchange area 1 of the plate. The bent portions 24 provided with the communication portions 241 are alternately provided with the bent portions 24 not provided with the communication portions 241. This facilitates the flow of fluid over the plates in a relatively serpentine flow pattern, as can be seen in the direction of fluid flow indicated by the black line with arrows in fig. 6. The heat exchange coefficient of the fluid can be effectively improved, and the heat exchange performance of the plate heat exchanger is favorably improved.

In another embodiment of the present application, there is also provided a plate heat exchanger of a plate type having an asymmetric waveform structure, and for the asymmetric waveform structure, referring to a schematic structural diagram of the first plate 101 shown in fig. 7 and an enlarged schematic partial structural diagram of the first plate 101 shown in fig. 8, the plurality of wave trough portions 22 include a plurality of first wave trough portions 221 and a plurality of second wave trough portions 222. The first wave trough parts 221 and the second wave trough parts 222 are alternately arranged, the depth of the first wave trough parts 221 is larger than that of the second wave trough parts 222, and the wave peak parts 21 and the first wave trough parts 221 are provided with planes or micro-curved surfaces for welding with adjacent plates.

Accordingly, the depth of the groove corresponding to the communication portion 241 is substantially equal to the depth of the second trough 222, and the depth of the groove accounts for 15% to 75% of the depth of the first trough 221.

Referring to fig. 7 to 14, in an embodiment of the present application, there is provided a plate heat exchanger including a plurality of first plates 101 and second plates 102 mated with the first plates 101, the first plates 101 and the second plates 102 being alternately arranged, each of the first plates 101 and the second plates 102 including opposing front and back surfaces 1001 and 1002, the front surface 1001 of the first plate 101 opposing the back surface 1002 of the second plate 102 and the back surface 1002 of the first plate 101 opposing the front surface 1001 of the second plate 102 when assembled.

The first plate 101 comprises second matching areas 4 which are positioned at two sides of the main heat exchange area 1 in the length direction, the second matching areas 4 comprise second flat surface parts 41, the second flat surface parts 41 are connected with first wave trough parts 221 at the edges of the main heat exchange area 1 of the first plate 101, the first wave trough parts 221 at the edges of the main heat exchange area 1 of the first plate 101 are flush with the second flat surface parts 41, the wave crest parts 21 are higher than the second flat surface parts 41 at the front surfaces 1001 of the first plate 101 in the thickness direction of the first plate 101, and the second wave trough parts 222 are higher than the second flat surface parts 41 at the front surfaces 1001 of the first plate 101. Referring to fig. 9, on the first sheet 101, the first trough 221 is flush with the second flat surface 41, the second trough 222 is higher than the second flat surface 41 on the front surface 1001 of the third sheet, and the first trough 221 and the second trough 222 form an M-like structure with respect to the second flat surface 41.

The second plate 102 is similar in structure to the main heat exchange area of the first plate 101, and the plurality of wave trough portions 22 of the second plate 102 also include a plurality of first wave trough portions 221 and a plurality of second wave trough portions 222. The first wave trough parts 221 and the second wave trough parts 222 are alternately arranged, the depth of the first wave trough parts 221 is larger than that of the second wave trough parts 222, and the wave peak parts 21 and the first wave trough parts 221 are provided with planes or micro-curved surfaces for welding with adjacent plates. The second plate piece 102 comprises third matching areas 5 which are positioned at two sides of the main heat transfer area 1 in the length direction, the third matching areas 5 comprise third plane parts 51, the third plane parts 51 are connected with the crest part 21 at the edge of the main heat transfer area 1 of the second plate piece 102, the crest part 21 at the edge of the main heat transfer area 1 of the second plate piece 102 is flush with the third plane parts 51, and the first wave trough part 221 and the second wave trough part 222 are raised relative to the third plane parts 51 at the front surface 1001 of the second plate piece 102. Referring to fig. 12, on the second plate piece 102, the crest portions 21 are flush with the third flat surface portion 51, the first trough portions 221 and the second trough portions 222 are raised relative to the third flat surface portion 51 at the front surface 1001 of the second plate piece 102, the first trough portions 221 and the second trough portions 222 are higher than the front surface 1001 of the second plate piece 102, and the first trough portions 221 and the second trough portions 222 form a W-like structure relative to the third flat surface portion 51.

The crest portion 21 and the first trough portion 221 of each sheet 100 are provided with a plane or a micro-curved surface for welding with the adjacent sheet 100, the crest portion 21 of the front surface 1001 of the first sheet 101 is in contact with the crest portion 21 of the back surface 1002 of the adjacent second sheet 102 to form a welding point, and the first trough portion 221 of the back surface 1002 of the first sheet 101 is in contact with the first trough portion 221 of the front surface 1001 of the adjacent second sheet 102 to form a welding point.

The depth of the communication portion 241 is substantially equivalent to that of the second trough portion 222, and referring to a schematic diagram of stacking the first plate 101 and the second plate 102 illustrated in fig. 14, when a fluid flows on the front surface 1001 of the first plate 101, and the fluid flows on the first trough portion 221 of the front surface 1001 of the first plate 101 to the adjacent second trough portion 222 due to the existence of the communication portion 241, the fluid does not need to completely turn over the crest portion 21 between the first trough portion 221 and the second trough portion 222, and can directly reach the second trough portion 222 through the flow channel 25 formed by the communication portion 241, which is equivalent to opening up a "shortcut" to the second trough portion 222 in the original flow dead zone, the flow pressure drop of the flow channel 25 formed by the communication portion 241 is relatively low, so as to facilitate breaking the restriction of the original flow dead zone, so that the fluid improves the fluidity at the sharp corner position of the herringbone wave pattern, thereby facilitating distribution of fluid over the plate surface.

Likewise, in order to avoid the fluid from exiting at the pointed corners of the herringbone wavy pattern through the communicating portions 241 toward the other side of the plate in a manner of flowing off straight, as shown in fig. 13, in the primary heat exchange area 1 of each plate, the plurality of corrugated structures 2 include a plurality of third corrugated structures 261 and a plurality of fourth corrugated structures 262, wherein the third corrugated structures 261 alternate with the fourth corrugated structures 262 in the primary heat exchange area 1 of the plate 100. A third corrugated structure 261 and an adjacent fourth corrugated structure 262 form a corrugated unit 26, a second wave trough 222 is formed between the third corrugated structure 261 and the fourth corrugated structure 262 of each corrugated unit 26, and a first wave trough 221 is formed between two adjacent corrugated units 26. In the corrugated unit 26, the communicating portion 241 is provided at the bent portion 24 on the farther side in the pointed direction of the pointed corners of the herringbone corrugated pattern in the third corrugated structure 261 and the fourth corrugated structure 262. In fig. 13, the bent portion 24 on the far side is the bent portion 24 on the upper side in the bellows unit 26. The third corrugated structures 261 and the fourth corrugated structures 262 are alternately arranged in the primary heat exchange area 1 of the plate 100 such that the bent portions 24 provided with the communicating portions 241 are alternately arranged with the bent portions 24 not provided with the communicating portions 241. This facilitates the flow of fluid over the plates in a relatively serpentine flow pattern, as can be seen in the direction of fluid flow indicated by the black line with arrows in fig. 13. The heat exchange coefficient of the fluid can be effectively improved, and the heat exchange performance of the plate heat exchanger is favorably improved.

The bent portion 24 plate structure provided with the communication portion 241 provided in the present application may be applied to a refrigerant-side flow channel, such as the front surface 1001 of the first plate 101 and/or the back surface 1002 of the second plate 102, so as to optimize the refrigerant-side channel structure and facilitate the uniformity of refrigerant fluid distribution on the plates.

Further, in a plurality of the above-described schematic views provided by the present application, the number of the bent portions 24 of each corrugated structure 2 in the width direction of the sheet 100 is 2 or more. That is, in the width direction of the sheet 100, the corrugated structure 2 is formed with a structure of multiple herringbone corrugated patterns. Of course, the plate 100 of the plate heat exchanger provided by the present application is suitable for a corrugated structure of a single letter wave, or a V-shaped corrugated structure, having one curved portion 24 and two straight portions 23; but also to a corrugated structure of multiple chevron with more bends 24 and more flats 23, such as a W-shaped or double chevron corrugated structure of 3 bends 24 and 4 flats 23. Especially for multiple herringbone waves, the wave tip angle of the herringbone waveform structure occupies a certain specific gravity in the width direction of the plate, so that the application is greatly helpful for improving the performance of the product.

The fluid flow uniformity on the plate can be effectively improved, and the fluid flow resistance is obviously reduced. The product performance is effectively improved.

The plate heat exchanger provided by the present application is described in detail above. The principles and embodiments of the present invention have been explained herein using specific examples, and the above descriptions of the embodiments are only used to help understand the core concepts of the present invention. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.

Claims (10)

1. A plate heat exchanger comprising a plurality of plates (100), the plurality of plates (100) comprising a plurality of first plates (101) and a plurality of second plates (102), the plurality of first plates (101) and the plurality of second plates (102) being alternately arranged, each plate (100) comprising opposing front (1001) and back (1002) faces, the front (1001) of the first plate (101) opposing the back (1002) of the second plate (102), the back (1002) of the first plate (101) opposing the front (1001) of the second plate (102); each sheet (100) is provided with a main heat exchange area (1), the sheet (100) is provided with a plurality of corrugated structures (2) which are arranged at intervals along the length direction of the sheet (100) in the main heat exchange area (1), the plurality of corrugated structures (2) form a plurality of crest portions (21) and a plurality of trough portions (22) along the length direction of the sheet (100), the plurality of crest portions (21) and the plurality of trough portions (22) are alternately arranged, two adjacent trough portions (22) have the same or different depths, and the depths of the trough portions (22) are calculated by taking the crest portions (21) as a reference; the corrugated structure (2) comprises at least two straight portions (23) and one curved portion (24); the bending part (24) is connected between two adjacent straight parts (23), the extending directions of two adjacent straight parts (23) are crossed, so that two adjacent straight parts (23) and the bending part (24) positioned between the two adjacent straight parts form a herringbone corrugated pattern, and the bending part (24) forms the corner of the herringbone corrugated pattern;

wherein, for at least one sheet in the plurality of sheets (100), at least one curved part (24) in the plurality of curved parts (24) of the corrugated structures (2) is provided with a communication part (241), the communication part (241) at least partially penetrates through the curved part (24) in the length direction of the sheet, the communication part (241) is communicated with two adjacent wave trough parts (22) separated by the corrugated structures (2), and the sheet (100) is provided with a flow channel (25) for a fluid to pass through a wave crest part (21) between the two adjacent wave trough parts (22) through the communication part (241).

2. A plate heat exchanger according to claim 1, wherein the communication portion (241) extends through the curved portion (24) in a direction substantially perpendicular to a bisector of an angle between the directions of extension of two adjacent flat portions (23), the communication portion (241) being a groove sunken from the crest portion (21) and corresponding to a depth smaller than or equal to a depth of any one (22) of two adjacent trough portions (22).

3. A plate heat exchanger according to claim 2, wherein for each plate sheet (100) the depth of two adjacent wave trough portions (22) is substantially equal, each plate sheet (100) further comprises first mating zones (3) located lengthwise on both sides of the main heat transfer zone (1), the first mating zones (3) comprising first plane portions (31), the first plane portions (31) being connected with the wave trough portions (22) at the edges of the main heat transfer zone (1), and the wave trough portions (22) being flush with the first plane portions (31), the corrugated structure (2) being convex with respect to the first plane portions (31) at the front face (1001) of each plate sheet (100), the tops of the corrugated structures (2) forming wave crest portions (21); the corrugated structure (2) forms a groove with respect to the first plane portion (31) on the reverse side (1002) of each sheet (100); the part between two adjacent corrugated structures (2) forms a wave trough part (22).

4. A plate heat exchanger according to claim 3, wherein the crest portion (21) is provided with a flat or micro-curved surface for welding with an adjacent plate (100), and the trough portion (22) is provided with a flat or micro-curved surface for welding with an adjacent plate (100);

the herringbone corrugated patterns of the corresponding positions of the first plate (101) and the second plate (102) are arranged in an opposite direction, and the wave crest part (21) of each plate (100) is in contact with the wave trough part (22) of the adjacent plate (100) to form welding points.

5. A plate heat exchanger according to claim 4, wherein the plurality of corrugations (2) comprises a plurality of first corrugations (251) and a plurality of second corrugations (252), wherein the connections (241) are provided at the bends (24) of the first corrugations (251), wherein the bends (24) of the second corrugations (252) are not provided with connections (241), and wherein the first corrugations (251) alternate with the second corrugations (252) in the main heat transfer area (1) of the plate sheet (100).

6. A plate heat exchanger according to claim 2, wherein the plurality of wave trough portions (22) comprises a plurality of first wave trough portions (221) and a plurality of second wave trough portions (222); the depth of the first wave-shaped trough portion (221) is larger than that of the second wave-shaped trough portion (222), the first wave-shaped trough portion (221) and the second wave-shaped trough portion (222) are arranged alternately, the wave-shaped peak portion (21) is provided with a plane or a micro-curved surface used for being welded with an adjacent plate piece, and the first wave-shaped trough portion (221) is provided with a plane or a micro-curved surface used for being welded with an adjacent plate piece.

7. A plate heat exchanger according to claim 6, wherein the depth of the groove is substantially equal to the depth of the second wave trough (222), and the depth of the groove amounts to 15-75% of the depth of the first wave trough (221).

8. A plate heat exchanger according to claim 6, wherein the first plate sheet (101) comprises second mating zones (4) at both sides of the main heat transfer zone (1) in the length direction, the second mating zones (4) comprising second flat portions (41), the second flat portions (41) being connected to first trough portions (221) at the edges of the main heat transfer zone (1) of the first plate sheet (101), and the first trough portions (221) of the main heat transfer zone (1) of the first plate sheet (101) being flush with the second flat portions (41); the crest portion (21) and the second trough portion (222) are higher than the second plane portion (41) on the front surface (1001) of the first sheet (101) in the thickness direction of the first sheet (101);

the second plate piece (102) comprises third matching areas (5) which are positioned at two sides of the main heat exchange area (1) in the length direction, the third matching areas (5) comprise third plane parts (51), the third plane parts (51) are connected with wave crest parts (21) at the edges of the main heat exchange area (1) of the second plate piece (102), and the wave crest parts (21) of the second plate piece (102) are flush with the third plane parts (51); the first wave trough (221) and the second wave trough (222) are raised relative to a third planar portion (51) on a front face (1001) of the second plate (102);

the wave crest part (21) of each sheet of plate is provided with a plane or a micro-curved surface for welding with the adjacent plate, and the first wave trough part (221) of each sheet of plate is provided with a plane or a micro-curved surface for welding with the adjacent plate; the wave crest portions (21) of the front surface (1001) of the first plate (101) are in contact with the wave crest portions (21) of the back surface (1002) of the adjacent second plate (102) to form welding spots, and the first wave trough portions (221) of the back surface (1002) of the first plate (101) are in contact with the first wave trough portions (221) of the front surface (1001) of the adjacent second plate (102) to form welding spots.

9. A plate heat exchanger according to claim 8, wherein the plurality of corrugations (2) comprises a plurality of third corrugations (261) and a plurality of fourth corrugations (262), wherein the third corrugations (261) alternate with the fourth corrugations (262) in the main heat transfer zone (1) of the plate; a third corrugated structure (261) and a fourth corrugated structure (262) form a corrugated unit, the second wave trough portion (222) is formed between the third corrugated structure (261) and the fourth corrugated structure (262) of each corrugated unit (26), and the first wave trough portion (221) is formed between two adjacent corrugated units (26); in the corrugated unit (26), the communication portion (241) is provided at a bending portion (24) on the far side in the pointing direction of the chevron pattern sharp angle of the third corrugated structure (261) and the fourth corrugated structure (262).

10. A plate heat exchanger according to any one of claims 1-9, wherein the number of the bent portions (24) of at least part of the corrugated structure (2) in the width direction of the plate (100) is greater than or equal to 2, said at least part of the corrugated structure (2) forming a multiple herringbone corrugation pattern in the width direction of the plate (100).

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