TW202318960A - Connector assembly comprising a shielding cover, a liquid cooling disc, and a thermal coupling module - Google Patents

Abstract

Disclosed is a connector assembly, which comprises a shielding cover, a liquid cooling disc, and a thermal coupling module. The shielding cover is provided with an insertion space and a window connected with the insertion space. The liquid cooling disc is for the cooling liquid to circularly flow in the liquid cooling disc. The thermal coupling module comprises a thermal coupling base and a heat conduction interface material, wherein the thermal coupling base is provided with a thermal coupling part extending into the insertion space through the window, the heat conduction interface material can be compressed and clamped between the liquid cooling disc and the thermal coupling base, so that the thermal coupling base can be connected to the liquid cooling disc in a manner of being far away from or close to the liquid cooling disc.

Description

connector assembly

The present invention relates to a connector assembly, in particular to a connector assembly with a liquid cooling plate.

US Patent Publication No. US7,625,223 discloses a socket assembly, which includes a guide frame, a heat sink and a conductive washer. The guide frame includes a top wall and defines an interior cavity configured to receive a mating connector. The top wall defines an opening communicating with the interior chamber. The heat sink is retained in the interior chamber such that when the mating connector is inserted into the interior chamber, the upper portion of the heat sink passes through the opening and the lower portion engages the mating connector. A conductive gasket is held between the guide frame and the heat sink. The heat sink includes a coupling portion, which provides a heat conduction path for the mating connector when the mating connector is inserted into the internal cavity. The conductive gasket is configured to be compressed between the lead frame and the heat sink such that the conductive gasket provides a conductive path between the heat sink and the lead frame. However, the heat sink disclosed in this prior art is generally a metal heat sink with heat dissipation fins. In the large connector assembly, its heat dissipation performance is slightly insufficient.

Chinese invention patent publication number CN110139534A (corresponding to US invention patent publication number US2019/0246523A1) discloses a cooling device, which includes a manifold and a plurality of bases. The manifold includes a housing enclosing an inner cavity for containing and circulating a cooling liquid. Each base is individually and flexibly coupled to the housing of the manifold through an annular bellows for sealing. Each base is configured to extend outwardly from the bottom surface of the housing of the manifold when fluid pressure is present within the lumen. However, this prior art bellows only provides a flexible connection between the base and the manifold, requiring sufficient force for the base to move from the bottom surface of the housing of the manifold towards the extend outside. First of all, the bellows is used as the connection seal between the base and the manifold. The structure is not only complicated but also difficult to manufacture; , it is easy to cause insufficient protrusion of the base relative to the manifold, so that the pressure of the base in contact with the electrical module is insufficient or even unable to contact the electrical module, thereby reducing the heat dissipation efficiency. Moreover, when multiple electrical modules need to be in contact with the bases on the manifold at the same time, if the outward protrusion of the base relative to the manifold is insufficient and the elastic recovery force of the base relative to the manifold is insufficient, It is easy to prevent each electrical module from contacting each base on the manifold at the same time due to the tolerance problem of each electrical module.

Therefore, an object of the present invention is to provide a connector assembly which can solve at least one problem of the above-mentioned prior art.

Therefore, in some embodiments of the present invention, the connector assembly includes a shielding cover, a liquid cooling plate, and a thermal coupling module. The shielding case has an insertion space and a window communicating with the insertion space. The liquid cooling plate is used for cooling liquid to circulate inside. The thermal coupling module includes a thermal coupling base and a thermal interface material, the thermal coupling base has a thermal coupling part extending into the insertion space through the window, the thermal interface material is compressible and clamps Placed between the liquid cooling plate and the thermal coupling base, the thermal coupling base can be connected to the liquid cooling plate at a distance from or close to the liquid cooling plate.

In some implementation aspects, the thermal coupling module further includes an elastic member disposed between the liquid cooling plate and the thermal coupling base, and the thermal coupling base relatively moves toward the liquid cooling plate When the thermal coupling base presses the elastic member and the thermal interface material; the thermal coupling base and the thermal interface material can move away from the liquid cooling plate through the elastic recovery force of the elastic member. The direction resets elastically.

In some implementation aspects, the thermal coupling module further includes a connecting bolt disposed between the liquid cooling plate and the thermal coupling base, and the connecting bolt causes the thermal interface material to be pre-compressed.

In some implementation aspects, the elastic member is a coil spring, and the elastic member is sleeved on the corresponding connecting bolt.

In some implementation aspects, it also includes an elastic buckle disposed on the shielding cover, the elastic buckle is pressed against the thermal coupling base, and the elastic buckle has a pressure direction away from the liquid cooling plate. resist the corresponding elastic pressure part of the thermal coupling base.

Therefore, in some embodiments of the present invention, the connector assembly includes a shielding cover, a liquid cooling plate, and a plurality of thermal coupling modules. The shielding case has a plurality of insertion spaces, and a plurality of windows respectively corresponding to communicate with the plurality of insertion spaces. The liquid cooling plate is used for cooling liquid to circulate inside. The plurality of thermal coupling modules respectively correspond to the plurality of insertion spaces and are independently operated and connected to the same liquid cooling plate. Each of the thermal coupling modules includes a thermal coupling base and a thermal interface material. The thermal coupling base has a thermal coupling portion extending into the insertion space through the window, and the thermal interface material is compressible and sandwiched between the liquid cooling plate and the thermal coupling base, so The thermal coupling base can be connected to the liquid cooling plate far away from or close to the liquid cooling plate.

In some implementation aspects, the thermal coupling module further includes an elastic member disposed between the liquid cooling plate and the thermal coupling base, and the thermal coupling base relatively moves toward the liquid cooling plate When the thermal coupling base presses the elastic member and the thermal interface material; the thermal coupling base and the thermal interface material can move away from the liquid cooling plate through the elastic recovery force of the elastic member. The direction resets elastically.

In some implementation aspects, the thermal coupling module further includes a connecting bolt disposed between the liquid cooling plate and the thermal coupling base, and the connecting bolt causes the thermal interface material to be pre-compressed.

In some implementation aspects, the elastic member is a coil spring, and the elastic member is sleeved on the corresponding connecting bolt.

In some implementation aspects, it also includes a plurality of elastic buckles arranged on the shielding cover, and the elastic buckles are pressed against the thermal coupling base in a manner that one elastic buckle corresponds to one thermal coupling base. The coupling base, the elastic buckle has an elastic pressing part that presses against the corresponding thermal coupling base in a direction away from the liquid cooling plate.

In some implementation aspects, it also includes an elastic buckle disposed on the shielding cover, and the elastic buckle has a plurality of corresponding thermal coupling bases that are pressed against the corresponding plurality of thermal coupling bases in a direction away from the liquid cooling plate. an elastic pressure-applying portion.

The liquid cooling plate in the connector assembly of the present invention has better heat dissipation performance than ordinary radiators, and the heat-conducting interface material is sandwiched between the liquid cooling plate and the thermal coupling base through the connection bolts and is pre-compressed, thereby The heat conduction interface material can be completely contacted between the liquid cooling plate and the thermal coupling base, so as to increase the heat transfer effect of the heat conduction interface material and improve the heat dissipation and cooling effect of the liquid cooling plate. In addition, because the thermal interface material is pre-compressed, it is not necessary to increase the deformation stroke of the thermal interface material to ensure complete contact between the components, so that a thinner thermal interface material can be selected to reduce the thermal interface material. Thermal resistance to maximize the heat transfer effect and improve the cooling effect of the liquid cooling plate. Furthermore, the compressibility and elasticity of the thermal coupling modules can be improved by the connection pins and the elastic members, and the tolerance of different pluggable modules inserted into the shield can be absorbed by the independent operation of the respective thermal coupling modules. , so that each pluggable module can have a good contact with the corresponding thermal coupling module, thereby further improving the heat dissipation performance.

Before the present invention is described in detail, it should be noted that in the following description, similar elements are denoted by the same numerals.

Referring to FIG. 1 to FIG. 4 , a first embodiment of the connector assembly 100 of the present invention is suitable for covering a plurality of receptacle connectors 200 and suitable for plugging with a pluggable module 300 . The connector assembly 100 includes a shielding case 1 , a liquid cooling plate 2 , and a plurality of thermal coupling modules 3 . It should be noted that, in this embodiment, the shield 1 has a plurality of shields 11 assembled side by side, and each shield 11 corresponds to one of the receptacle connectors 200, but in other implementations, the shield The cover 1 can also have only one cover body 11 , and the number of socket connectors 200 can also be adjusted correspondingly according to requirements.

The shielding case 1 can be made of metal, for example. The cover body 11 of the shielding cover 1 extends along a front-to-back direction D1 and has a top wall 111, a bottom wall 112 spaced opposite to the top wall 111 along a vertical direction D2, and spaced apart from each other along a left-right direction D3. The two side walls 113 connected to the two sides of the top wall 111 and the bottom wall 112, and extending downward from the side walls 113 and suitable for being fixed on a circuit board (not shown) and/or connected to ground traces Multiple pins 115. The cover body 11 of the shielding cover 1 also has an insertion space 116 which is defined by the top wall 111, the bottom wall 112 and the two side walls 113 and is located inside, and a front end which is located at the front end and communicates with the insertion space 116. The opening 116 a , a window 116 b formed on the top wall 111 and communicating with the insertion space 116 , and a bottom opening 116 c located at the rear side of the bottom wall 112 and communicating with the insertion space 116 . Because the shielding case 1 has a plurality of housings 11 , the shielding case 1 has a plurality of insertion spaces 116 , and a plurality of windows 116 b respectively corresponding to the insertion spaces 116 . It should be noted that, in a variant embodiment, the shielding case 1 can also be constructed in one piece, but a plurality of insertion spaces 116 are separated by a plurality of partition walls (not shown in the figure). Each receptacle connector 200 is arranged in the rear section of the insertion space 116 of the corresponding cover body 11. The receptacle connector 200 has an insulating housing 201 and a plurality of terminals 202. The housing 201 has an opening 116a towards the front end. And the two insertion slots 201a for docking with the pluggable module 300, the terminals 202 are located in the insertion slots 201a and electrically and mechanically connected to the aforementioned circuit board, in detail, the The receptacle connector 200 is mechanically and electrically arranged on the circuit board, and is covered with the cover body 11 of the shielding case 1 through the bottom opening 116c, so that the receptacle connector 200 is arranged in the insertion space 116 , but not limited thereto, for example, each terminal 202 of the receptacle connector 200 may not be connected to a circuit board, and each terminal 202 may also be connected to a cable.

The two insertion slots 201a of the receptacle connector 200 are spaced side by side along the up-down direction D2, and the insertion space 116 of the cover body 11 of the shielding case 1 is provided with a partition member 117 (only the partition member is shown in the figure 117, a ground pad 117a), the partition member 117 divides the insertion space 116 into a first module channel 116d and a second module channel 116e arranged along the vertical direction D2, the first module channel 116d The second module channel 116e corresponds to the two insertion slots 201a of the socket connector 200, when the pluggable module 300 is inserted into the first module channel 116d and the second module through the front opening 116a. The circuit board 302 provided at the end of the docking portion 301 of the pluggable module 300 can be inserted into the corresponding slot 201a to dock with the socket connector 200 . Wherein, the first module channel 116d located above communicates with the window 116b. It should be noted that, in other embodiments, the shield body 11 of the shield 1 may not be provided with the partition member 117, It is not limited by this first embodiment.

The liquid cooling plate 2 is used for cooling liquid to circulate inside, and the liquid cooling plate 2 includes a shell 21 for cooling liquid to flow inside. The cooling liquid can be, for example, water or other cooling liquids. The housing 21 is, for example, made of metal (such as copper, aluminum) and also has a first inlet 211 and a first flow at the rear end for the cooling liquid to flow in or out. The outlet 212 , and a channel (not shown) located inside and connected between the inlet 211 and the outlet 212 . The liquid cooling plate 2 can be used in conjunction with other components of the liquid cooling system (not shown), so that the cooling liquid can absorb heat from the liquid cooling plate 2 and then dissipate heat through the components. The components are, for example, Fluid conduits, radiators, cooling fans, pumps, water tanks, etc., the above-mentioned components can be arranged outside the shielding case 1 . For example, the liquid cooling plate 2 can be fixed on an equipment frame (not shown in the figure), so that the liquid cooling plate 2 is fixed on the shielding case 1 without moving relative to the shielding case 1 .

Referring to Fig. 2 and Fig. 4 to Fig. 7, the thermal coupling modules 3 respectively correspond to the insertion spaces 116 of the housings 11 of the shielding case 1, and the thermal coupling modules 3 are connected to the same liquid Cold cuts2. Each thermal coupling module 3 includes a thermal coupling base 31 , a thermal interface material 32 (Thermal Interface Material, TIM), a plurality of connecting bolts 33 , and a plurality of elastic members 34 . The thermal coupling base 31 is, for example, made of metal (such as copper, aluminum), and it is generally plate-shaped in the first embodiment. The thermal coupling base 31 has a downward protrusion and passes through a corresponding window 116b extends into a thermal coupling portion 311 of the first module channel 116d corresponding to the insertion space 116 . The thermal interface material 32 can be selected from composite materials with high thermal conductivity, high flexibility, compressibility, elasticity, insulation, wear resistance, etc., and it is generally in the form of a sheet in the first embodiment. . The thermal interface material 32 can be compressed and sandwiched between the liquid cooling plate 2 and the thermal coupling base 31 .

The connection bolts 33 are arranged between the liquid cooling plate 2 and the thermal coupling base 31, so that the thermal coupling base 31 can be connected to the liquid cooling plate 2 by the connection bolts 33 away from or close to the liquid cooling plate 2. The cold plate 2, and the thermal interface material 32 is subjected to pre-compression. In detail, in this first embodiment, the housing 21 of the liquid cooling plate 2 is formed with a plurality of first connection holes 213, and the thermal coupling base 31 is formed with a plurality of second connection holes 312, and each connection bolt 33 pierces through the corresponding first connection hole 213 and the corresponding second connection hole 312, and each connection bolt 33 has a first limit block 331 and a second limit block 332, the first limit block 331 The second limiting block 332 is used to abut against the surroundings of the corresponding first connecting hole 213 of the liquid cooling plate 2 and the surrounding of the corresponding second connecting hole 312 of the thermal coupling base 31 to limit the heat. The maximum distance between the coupling base 3 and the liquid cooling plate 2 allows the thermal coupling base 3 to move toward the liquid cooling plate 2 and pre-compresses the thermal interface material 32 . That is to say, the connecting bolt 33 limits the distance between the thermal coupling base 31 and the liquid cooling plate 2 , and keeps the distance less than the thickness of the thermal interface material 32 . In addition, the cross-section of the bottom of the second limiting block 332 is semicircular and each connecting pin 33 is formed with a slit 333 extending upward from the bottom of the second limiting block 332, so that the second limiting block 332 The block 332 easily passes through the second connection hole 312 downward.

The elastic members 34 are disposed between the liquid cooling plate 2 and the thermal coupling base 31 , and are used to drive the thermal coupling base 31 to move away from the liquid cooling plate 2 . In this first embodiment, the elastic members 34 are coil springs, and the elastic members 34 are sleeved on the corresponding connecting bolts 33, but the elastic members 34 can also be other types of elastic elements, such as springs sheet, and its setting position may not need to be covered with the connecting bolt 33 , for example, sandwiched between the liquid cooling plate 2 and the thermal coupling base 31 .

1 to 2 and 6 to 7, when the pluggable module 300 is inserted into the first module channel 116d of the insertion space 116 of the cover 11, the thermal coupling base 31 is subjected to the The plug-in module 300 is pushed to move relatively towards the direction of the liquid cooling plate 2. At this time, the thermal coupling base 31 presses the elastic members 34 and the thermal interface material 32. When the plug-in module 300 is pulled out , the thermal coupling base 31 and the heat-conducting interface material 32 can be elastically reset in a direction away from the liquid cooling plate 2 through the elastic restoring force of the elastic members 34 . Further, the thermal interface material 32 can also be elastic at the same time, so as to jointly provide the elastic force for restoring the thermal coupling base 31 together with the elastic members 34 . The liquid cooling plate 2 in the connector assembly 100 of the present invention has better heat dissipation performance than ordinary radiators, and the thermally conductive interface material 32 is sandwiched between the liquid cooling plate 2 and the thermal coupling base by being pre-compressed through the connecting bolt 33 31, so that the thermal interface material 32 can completely contact between the liquid cooling plate 2 and the thermal coupling base 31, so as to increase the heat transfer effect of the thermal interface material 32 and improve the cooling effect of the liquid cooling plate 2. In addition, since the heat conduction interface material 32 is pre-compressed, it is not necessary to increase the deformation stroke of the heat conduction interface material 32 to ensure complete contact between the components, so that a thinner heat conduction interface material 32 can be selected to reduce The thermal resistance of the heat-conducting interface material 32 itself is used to exert a greater heat transfer effect and improve the heat dissipation and cooling effect of the liquid cooling plate 2 . Furthermore, the compressibility and elasticity of each thermal coupling module 3 can be improved by the connection bolt 33 and the elastic member 34, and the independent operation of each thermal coupling module 3 can absorb the difference in the insertion of the shielding case 1. The tolerance of the pluggable modules 300 enables each pluggable module 300 to have a good contact with the corresponding thermal coupling module 3 , thereby further improving the heat dissipation performance.

8 to 10, a second embodiment of the connector assembly of the present invention is different from the first embodiment in that, in this second embodiment, the connector assembly also includes the shielding cover 1 A plurality of elastic fasteners 4 of the cover body 11, the elastic fasteners 4 are fastened to the corresponding shielding cover 1 in such a way that two elastic fasteners 4 correspond to a cover body 11 and a thermal coupling base 31. The cover body 11 is pressed against the corresponding thermal coupling base 31 . It should be noted that, in a variant embodiment, the two elastic buckles 4 corresponding to the same cover body 11 and the same thermal coupling base 31 may not be two-piece but integrally constructed single-piece, In another variant embodiment, there may be more than three corresponding to the same cover body 11 and the same thermal coupling base 31. In other words, the elastic buckle 4 is at least one elastic buckle 4 corresponding to one The thermal coupling base 31 is pressed against the thermal coupling base 31 .

In detail, in the second embodiment, two elastic buckles 4 corresponding to the same cover body 11 and the same thermal coupling base 31 are spaced and arranged side by side in the front-rear direction D1, and each elastic buckle 4 has a The left-right direction D3 extends and presses against the elastic pressure part 41 of the corresponding thermal coupling base 31 in a direction away from the liquid cooling plate 2, and from both ends of the elastic pressure part 41 in the left-right direction D3 toward The buckling portion 42 extends downward and is used to fasten to the side wall 113 (see FIG. 1 ) of the corresponding shield body 11 of the shielding case 1 . Two accommodating grooves 313 correspondingly accommodating the elastic pressing portion 41 are formed on the top surface of each thermal coupling base 31 , and the two accommodating grooves 313 extend along the left-right direction D3 and along the front-rear direction D1 are spaced side by side. The elastic force for resetting the thermal coupling bases 31 away from the liquid cooling plate 2 can be increased by the elastic fasteners 4 .

11 to 12, the third embodiment of the connector assembly of the present invention is different from the second embodiment in that, in this third embodiment, the elastic buckle provided on the cover body 11 of the shielding cover 1 The number of tool 4 is only one, and the elastic buckle 4 has a plurality of elastic pressing parts 41 respectively pressed against the thermal coupling bases 31 in a direction away from the liquid cooling plate 2 (see FIG. 1 ), connected to the A plurality of connecting portions 43 between the elastic pressing portions 41 and used to be arranged on the top of the shield 1 extend downward from the outer sides of the elastic pressing portions 41 located on both sides in the left-right direction D3 and are used for It is fastened to the two fastening portions 44 on the outer side walls 113 (see FIG. 1 ) of the shielding case 1 .

But what is described above is only an embodiment of the present invention, and should not limit the scope of the present invention. All simple equivalent changes and modifications made according to the patent scope of the present invention and the content of the patent specification are still within the scope of the present invention. Within the scope covered by the patent of the present invention.

1: shielding cover 11: Cover body 111: top wall 112: bottom wall 113: side wall 115: pin 116: insert space 116a: front opening 116b: open window 116c: Bottom opening 116d: first module channel 116e: Second module channel 117:Separation member 117a: Ground pad 2: Liquid cooling plate 21: shell 211: Inflow port 212: outflow port 213: the first connection hole 3: thermal coupling module 31: Thermal coupling base 311: thermal coupling part 312: the second connection hole 313: accommodating groove 32: Thermal interface material 33: Connecting bolt 331: the first limit block 332: the second limit block 333: Slit 34: Elastic member 4: elastic buckle 41: Elastic pressure applying part 42: Fastening part 43: Connecting part 44: Fastening part 100:Connector assembly 200: socket connector 201: shell 201a: socket slot 202: terminal 300: pluggable module 301: docking part 302: circuit board D1: Front and rear direction D2: up and down direction D3: left and right directions

Other features and effects of the present invention will be clearly presented in the implementation manner with reference to the drawings, wherein: 1 is a perspective view of a first embodiment of a connector assembly of the present invention, a socket connector and a pluggable module; Fig. 2 is a sectional view of Fig. 1, in which the pluggable module is omitted; Fig. 3 is a three-dimensional exploded view of Fig. 1, in which the socket connector is omitted; Fig. 4 is a perspective view viewed from the bottom of the liquid cooling plate and the thermal coupling module of the first embodiment; Fig. 5 is a top view of the liquid cooling plate and the thermal coupling module of the first embodiment; Fig. 6 is a sectional view taken along line A-A in Fig. 5; 7 is a partial perspective exploded view of the liquid cooling plate and the thermal coupling module of the first embodiment; 8 is a partial bottom view of the liquid cooling plate, the thermal coupling module and the elastic buckle of a second embodiment of the connector assembly of the present invention; Fig. 9 is a partial sectional view taken along line B-B in Fig. 8; 10 is a three-dimensional exploded view of the thermal coupling module and the elastic buckle of a second embodiment of the connector assembly of the present invention; 11 is a perspective view of the thermal coupling base and the elastic buckle of the thermal coupling module of a third embodiment of the connector assembly of the present invention; and FIG. 12 is an exploded perspective view of FIG. 11 .

2: Liquid cooling plate

21: shell

213: the first connection hole

3: thermal coupling module

31: Thermal coupling base

311: thermal coupling part

312: the second connection hole

32: Thermal interface material

33: Connecting bolt

331: the first limit block

332: the second limit block

333: Slit

34: Elastic member

100:Connector assembly

D1: Front and rear direction

D2: up and down direction

D3: left and right directions

Claims (11)

A connector assembly comprising: The shielding case has an insertion space and a window communicating with the insertion space; a liquid cooling plate for circulating a cooling liquid therein; and The thermal coupling module includes a thermal coupling base and a thermal interface material, the thermal coupling base has a thermal coupling part extending into the insertion space through the window, the thermal interface material is compressible and sandwiched Between the liquid cooling plate and the thermal coupling base, the thermal coupling base can be connected to the liquid cooling plate at a distance from or close to the liquid cooling plate. The connector assembly according to claim 1, wherein the thermal coupling module further includes an elastic member disposed between the liquid cooling plate and the thermal coupling base, and the thermal coupling base faces toward the When moving in the direction of the liquid cooling plate, the thermal coupling base presses the elastic member and the thermal interface material; the thermal coupling base and the thermal interface material can move toward Elastically reset in a direction away from the liquid cooling plate. The connector assembly according to claim 2, wherein the thermal coupling module further includes a connecting pin arranged between the liquid cooling plate and the thermal coupling base, and the connecting pin makes the thermal interface material subject to preload. The connector assembly according to claim 3, wherein the elastic member is a coil spring, and the elastic member is sheathed on the corresponding connecting pin. The connector assembly according to claim 1, further comprising an elastic buckle disposed on the shield, the elastic buckle is pressed against the thermal coupling base, and the elastic buckle has a direction away from the liquid The direction of the cold plate is pressed against the corresponding elastic pressing portion of the thermal coupling base. A connector assembly comprising: The shielding case has a plurality of insertion spaces, and a plurality of windows respectively corresponding to the plurality of insertion spaces; a liquid cooling plate for circulating a cooling liquid therein; and A plurality of thermal coupling modules are respectively corresponding to the plurality of insertion spaces and are independently operated and connected to the same liquid cooling plate. Each of the thermal coupling modules includes a thermal coupling base and a thermal interface material. The thermal coupling base has a thermal coupling portion extending into the insertion space through the window, the heat-conducting interface material is compressible and interposed between the liquid cooling plate and the thermal coupling base, the The thermal coupling base can be connected to the liquid cooling plate far away from or close to the liquid cooling plate. The connector assembly according to claim 6, wherein the thermal coupling module further includes an elastic member disposed between the liquid cooling plate and the thermal coupling base, and the thermal coupling base faces toward the When moving in the direction of the liquid cooling plate, the thermal coupling base presses the elastic member and the thermal interface material; the thermal coupling base and the thermal interface material can move toward Elastically reset in a direction away from the liquid cooling plate. The connector assembly according to claim 7, wherein the thermal coupling module further includes a connecting pin arranged between the liquid cooling plate and the thermal coupling base, and the connecting pin makes the thermal interface material subject to preload. The connector assembly according to claim 8, wherein the elastic member is a coil spring, and the elastic member is sleeved on the corresponding connecting pin. The connector assembly according to claim 6, further comprising a plurality of elastic buckles arranged on the shielding cover, and the elastic buckles are pressed against each other in such a way that one elastic buckle corresponds to one thermal coupling base On the thermal coupling base, the elastic buckle has an elastic pressing portion that presses against the corresponding thermal coupling base in a direction away from the liquid cooling plate. The connector assembly according to claim 6, further comprising an elastic buckle disposed on the shield, and the elastic buckle is pressed against the corresponding plurality of thermal couplers in a direction away from the liquid cooling plate. A plurality of elastic pressure-applying parts of the base.

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