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CN-224230798-U - Integrated component

CN224230798UCN 224230798 UCN224230798 UCN 224230798UCN-224230798-U

Abstract

The application provides an integrated component, which comprises a runner plate component, wherein the runner plate component comprises a runner part and a gas collecting part, the runner part is provided with a runner cavity, the gas collecting part is provided with a gas collecting cavity, the gas collecting cavity comprises a first opening and a second opening, the first opening is communicated with the runner cavity, the second opening is formed on the outer wall part of the runner plate component, the runner plate component comprises a liquid supplementing part, the liquid supplementing part comprises a liquid supplementing cavity, the liquid supplementing cavity is communicated with the runner cavity, the liquid supplementing cavity comprises a liquid supplementing opening, the liquid supplementing opening is formed on the outer wall part of the runner plate component, and the liquid supplementing opening and the second opening are arranged at intervals. In this way, the exhaust efficiency of the integrated assembly is advantageously improved.

Inventors

  • Request for anonymity
  • Request for anonymity
  • Request for anonymity

Assignees

  • 浙江三花汽车零部件有限公司

Dates

Publication Date
20260512
Application Date
20241231

Claims (14)

  1. 1. An integrated assembly (100) is characterized in that the integrated assembly (100) comprises a runner plate assembly (11), the runner plate assembly (11) comprises a runner part (111) and a gas collecting part (115), the runner part (111) is provided with a runner cavity (112), the gas collecting part (115) is provided with a gas collecting cavity (1153), the gas collecting cavity (1153) comprises a first opening (1151) and a second opening (1152), the first opening (1151) is communicated with the runner cavity (112), the second opening (1152) is formed in the outer wall part of the runner plate assembly (11), the runner plate assembly (11) comprises a fluid supplementing part (120), the fluid supplementing part (120) comprises a fluid supplementing cavity (1201), the fluid supplementing cavity (1201) is communicated with the runner cavity (112), the fluid supplementing cavity (1201) comprises a fluid supplementing port (1202), the fluid supplementing port (1202) is formed in the outer wall part of the runner plate assembly (11), and the fluid supplementing port (1202) is spaced from the second opening (1152).
  2. 2. The integrated assembly (100) of claim 1, wherein the flow field plate assembly (11) comprises an expansion kettle (13), the expansion kettle (13) having a fluid reservoir (135), the second opening (1152) being in communication with the fluid reservoir (135), the fluid reservoir (1202) being in communication with the fluid reservoir (135), the expansion kettle (13) comprising a degassing structure (136), the degassing structure (136) having a degassing channel (1361), the degassing channel (1361) comprising a first port (1361 a) and a second port (1361 b), the first port (1361 a) being in communication with the second opening (1152), the second port (1361 b) being in communication with the fluid reservoir (1202), the degassing structure (136) comprising a first partition (1362) and a second partition (1363) along a length of the expansion kettle (13), the first partition (1362) and the second partition (1363) being located at least partially opposite the first port (1361 a) and the second port (1361 b) forming a projection to the first port (1361 a) of the wall (1361), the projection of the wall corresponding to the first port (1361 a) does not coincide with the projection of the wall corresponding to the second port (1361 b).
  3. 3. The integrated assembly (100) of claim 1 or 2, wherein the flow channel cavity (112) includes an inlet end (1122) and an outlet end (1123), the first opening (1151) being proximate to the inlet end (1122) relative to the outlet end (1123), the first opening (1151) having a cross-sectional area for flow therethrough that is greater than a cross-sectional area for flow therethrough of the second opening (1152).
  4. 4. The integrated assembly (100) according to claim 1 or 2, wherein the flow channel plate assembly (11) comprises an expansion kettle (13), the second opening (1152) is close to the expansion kettle (13) relative to the first opening (1151) along the height direction of the expansion kettle (13), the wall portion corresponding to the air collecting chamber (1153) comprises a first blocking portion (118) and a second blocking portion (119), and the distance between the first blocking portion (118) and the second blocking portion (119) tends to decrease along the direction from the first opening (1151) to the second opening (1152).
  5. 5. The integrated component (100) according to claim 3, wherein the runner plate assembly (11) comprises an expansion kettle (13), the second opening (1152) is close to the expansion kettle (13) relative to the first opening (1151) along the height direction of the expansion kettle (13), the wall portion corresponding to the air collecting chamber (1153) comprises a first blocking portion (118) and a second blocking portion (119), and the distance between the first blocking portion (118) and the second blocking portion (119) tends to decrease along the direction from the first opening (1151) to the second opening (1152).
  6. 6. The assembly (100) of claim 4, wherein the first blocking portion (118) comprises a first sub-blocking portion (1181) and a second sub-blocking portion (1182), the first sub-blocking portion (1181) is connected with the second sub-blocking portion (1182), the second sub-blocking portion (1182) is close to the second opening (1152) relative to the first sub-blocking portion (1181), the first sub-blocking portion (1181) and the second sub-blocking portion (1182) are projected forward to a plane perpendicular to the first blocking portion (118), the projected structure of the first sub-blocking portion (1181) is an arc structure, the structure of the second sub-blocking portion (1182) is a straight line structure, and the arc structure is concavely arranged from the inside of the air cavity to the outside of the air cavity (1153).
  7. 7. The assembly (100) of claim 5, wherein the first blocking portion (118) comprises a first sub-blocking portion (1181) and a second sub-blocking portion (1182), the first sub-blocking portion (1181) is connected with the second sub-blocking portion (1182), the second sub-blocking portion (1182) is close to the second opening (1152) relative to the first sub-blocking portion (1181), the first sub-blocking portion (1181) and the second sub-blocking portion (1182) are projected forward to a plane perpendicular to the first blocking portion (118), the projected structure of the first sub-blocking portion (1181) is an arc structure, the structure of the second sub-blocking portion (1182) is a straight line structure, and the arc structure is concavely arranged from the inside of the air cavity to the outside of the air cavity (1153).
  8. 8. The assembly (100) of claim 6, wherein the first stop (118) comprises a first end (1183) and a second end (1184), the first end (1183) is formed at the first sub-stop (1181), the second end (1184) is formed at the second sub-stop (1182), the second end (1184) is fixedly connected to the expansion kettle (13), the second stop (119) comprises a third end (1191) and a fourth end (1192), the third end (1191) is fixedly connected to the expansion kettle (13), the wall corresponding to the first opening (1151) comprises the first end (1183) and the fourth end (1192), and the fourth end (1192) is adjacent to the expansion kettle (13) relative to the first end (1183) along the first direction (101).
  9. 9. The assembly (100) of claim 7, wherein the first stop (118) comprises a first end (1183) and a second end (1184), the first end (1183) is formed at the first sub-stop (1181), the second end (1184) is formed at the second sub-stop (1182), the second end (1184) is fixedly connected to the expansion kettle (13), the second stop (119) comprises a third end (1191) and a fourth end (1192), the third end (1191) is fixedly connected to the expansion kettle (13), the wall corresponding to the first opening (1151) comprises the first end (1183) and the fourth end (1192), and the fourth end (1192) is adjacent to the expansion kettle (13) relative to the first end (1183) along the first direction (101).
  10. 10. The integrated component (100) according to claim 4, wherein the flow channel plate assembly (11) comprises a base (116) and a cover (117), the base (116) comprises a base (1161), the first blocking portion (118) and the second blocking portion (119) are fixedly connected with the base (116) or the first blocking portion (118) and the second blocking portion (119) are integrally formed with the base (116), and the cover (117) is fixedly connected with the base (116).
  11. 11. The integrated assembly (100) of claim 1 or 2, wherein the flow channel cavity (112) includes an outlet end (1123), the flow channel plate assembly (11) includes at least one mounting portion (121), the mounting portion (121) having a mounting cavity (1211), the outlet end (1123) being in communication with the mounting cavity (1211), the fluid-refill port (1202) being proximate the outlet end (1123) relative to the second opening (1152), the second opening (1152) being located upstream of the fluid-refill port (1202).
  12. 12. The integrated assembly (100) according to claim 2, wherein the expansion kettle (13) has a liquid storage chamber (135), the wall portion corresponding to the liquid storage chamber (135) comprises a bottom (131), the expansion kettle (13) comprises a communication port (132), the communication port (132) is arranged through the bottom (131), and the communication port (132) is communicated with the second opening (1152).
  13. 13. The integrated assembly (100) according to claim 12, wherein the expansion kettle (13) comprises an extending portion (133), the extending portion (133) is fixedly connected with the bottom (131), the extending portion (133) comprises an extending channel (1331), the communication port (132) is formed at one end of the extending channel (1331), and the other end of the extending channel (1331) is communicated with the liquid storage cavity (135).
  14. 14. The integrated assembly (100) according to claim 13, wherein the expansion kettle (13) has a partition plate portion (134), the partition plate portion (134) being disposed parallel to the bottom portion (131), a wall portion of the partition plate portion (134) corresponding to the liquid storage chamber (135) being fixedly connected, and an end of the partition plate portion (134) being spaced apart from an end of the penetration portion (133) by a predetermined distance along the first direction (101).

Description

Integrated component Technical Field The application relates to the technical field of thermal management, in particular to an integrated assembly for a vehicle thermal management system. Background The integrated component comprises a runner cavity, a working medium flows through the runner cavity, and under certain working conditions, the working medium can generate certain bubbles, and the working medium mixed with the bubbles can influence the heat exchange efficiency. The current integrated assembly has low exhaust efficiency. Disclosure of utility model The application aims to provide an integrated assembly, which is beneficial to improving the exhaust efficiency of the integrated assembly. In order to achieve the purpose, the integrated assembly comprises a runner plate assembly, the runner plate assembly comprises a runner part and a gas collecting part, the runner part is provided with a runner cavity, the gas collecting part is provided with a gas collecting cavity, the gas collecting cavity comprises a first opening and a second opening, the first opening is communicated with the runner cavity, the second opening is formed in the outer wall part of the runner plate assembly, the runner plate assembly comprises a liquid supplementing part, the liquid supplementing part comprises a liquid supplementing cavity, the liquid supplementing cavity is communicated with the runner cavity, the liquid supplementing cavity comprises a liquid supplementing opening, the liquid supplementing opening is formed in the outer wall part of the runner plate assembly, and the liquid supplementing opening and the second opening are arranged at intervals. According to the technical scheme, the gas collection cavity comprises a first opening and a second opening, the first opening is communicated with the flow channel cavity, the second opening is formed in the outer wall of the flow channel plate assembly, the flow channel plate assembly comprises a liquid supplementing part, the liquid supplementing part comprises a liquid supplementing cavity, the liquid supplementing cavity is communicated with the flow channel cavity, the liquid supplementing cavity comprises a liquid supplementing opening, the liquid supplementing opening is formed in the outer wall of the flow channel plate assembly, and the liquid supplementing opening and the second opening are arranged at intervals. Therefore, the method is beneficial to laying a certain foundation for arranging other structures (such as a degassing structure) between the liquid supplementing opening and the second opening, further, bubbles discharged from the second opening can be fully degassed, a working medium after full degassing enters the flow channel cavity from the liquid supplementing opening, and compared with the technical scheme that the liquid supplementing opening and the second opening are arranged next to each other, the method is beneficial to reducing that bubbles discharged from the second opening do not fully degasify and enter the liquid supplementing opening, and therefore, the method is beneficial to improving the exhaust efficiency of the integrated assembly. Drawings Fig. 1 is a schematic perspective view of a first embodiment of an integrated assembly of the present application in one orientation. Fig. 2 is a schematic diagram of the explosive structure of the integrated assembly of fig. 1. Fig. 3 is a schematic diagram of the front view of the integrated assembly of fig. 1 along direction C. Fig. 4 is a schematic view of the structure of fig. 3 along the section A-A. Fig. 5 is an enlarged schematic view of the structure at I in fig. 4. Fig. 6 is a schematic perspective view of the base in fig. 1 in one direction. Fig. 7 is a schematic perspective view of the lower kettle body in fig. 1 in another direction. Fig. 8 is a schematic front view of the lower kettle body in fig. 7 along the direction D. Fig. 9 is a schematic view of the structure of the lower kettle body along the section B-B in fig. 8. In the accompanying drawings: 100. An integrated assembly, 11, a flow channel plate assembly, 111, a flow channel part, 112, a flow channel cavity, 1122, an inlet end, 1123, an outlet end, 113, an interface part, 1131, an interface cavity, 114, a fluid management device, 1141, an electric pump, 1141a, a pump inlet, 1141b, a pump outlet, 1142, an electric valve; 115. 1151, a first opening, 1152, a second opening, 1153, and an air collecting cavity; 116. 1161, a base; 117. a cover portion; 118. First baffle part, 1181, first sub baffle part, 1182, second sub baffle part, 1183, first end part, 1184, second end part; 119. a second stop 1191, a third end 1192, a fourth end; 120. Liquid supplementing part 1201, liquid supplementing cavity 1202, liquid supplementing port 121, mounting part 1211, mounting cavity; 13. the expansion kettle comprises 131, a bottom, 132, a communication port, 133, an extending part, 1331, an extending channel, 134, a baffle plate part, 1