CN220751467U - Self-adaptive floating liquid cooling plate airtight testing mechanism - Google Patents

Abstract

The utility model discloses a self-adaptive floating liquid cooling plate airtight testing mechanism which comprises a first air cylinder, a first supporting plate driven by the first air cylinder to move left and right, an XY floating assembly arranged on the first supporting plate, a second supporting plate arranged at the movable tail end of the XY floating assembly, and a plurality of pairs of inserting sealing pieces fixed on the second supporting plate and inserted with the water gap end of the liquid cooling plate. The utility model can carry out self-adaptive guiding floating with the water gap end of the liquid cooling plate, realizes flexible opposite insertion and accurate opposite insertion, provides conditions for realizing automatic test of air tightness detection, and improves test efficiency.

Description

Self-adaptive floating liquid cooling plate airtight testing mechanism

[ field of technology ]

The utility model belongs to the technical field of airtight detection equipment, and particularly relates to a self-adaptive floating liquid cooling plate airtight test mechanism.

[ background Art ]

The battery module is the power battery of electric automobile, and the battery module adopts the liquid cooling board to cool down to the electric core generally, in order to ensure the reliability of its function, all need to carry out airtight test to it after the liquid cooling board is accomplished to the preparation.

In the prior art, most of airtight detection of the liquid cooling plate adopts manual insertion of an airtight joint to a water gap end of the liquid cooling plate by an operator, so that the operation efficiency is low, and the product is possibly damaged by insertion; the device for high-efficiency airtight detection of the liquid cooling plates can detect the air tightness of a plurality of liquid cooling plates at one time, and the efficiency of the test is improved to a certain extent, but the efficiency of the clamping of the liquid cooling plates is still lower due to manual operation.

Therefore, it is necessary to provide a new adaptive floating liquid-cooled plate airtight testing mechanism to solve the above technical problems.

[ utility model ]

The utility model mainly aims to provide a self-adaptive floating liquid cooling plate airtight testing mechanism which can perform self-adaptive guiding floating with a liquid cooling plate water gap end, realize flexible opposite insertion and accurate opposite insertion, provide conditions for realizing automatic testing of air tightness detection and improve testing efficiency.

The utility model realizes the aim through the following technical scheme: the utility model provides a self-adaptation floating liquid cooling board airtight test mechanism, its includes first cylinder, receives first cylinder drive carries out the first backup pad of horizontal movement, sets up XY floating assembly in the first backup pad, set up the second backup pad that XY floating assembly activity is terminal and fix in the second backup pad and with a plurality of pairs of inserts sealing member of liquid cooling board mouth of a river end butt joint.

Further, the liquid cooling plate comprises a pair of water gaps A with upward openings and a pair of water gaps B with downward openings; the upper butt-inserting assembly for sealing or conducting the water gap A and the lower butt-inserting assembly for sealing or conducting the water gap B are correspondingly arranged on the butt-inserting sealing member.

Further, the upper butt-inserting assembly comprises a second air cylinder fixed on the second supporting plate, a third supporting plate driven by the second air cylinder to move up and down, and a plurality of first sealing heads arranged on the third supporting plate and communicated with the airtight testing instrument.

Further, the lower opposite-plug assembly comprises a third air cylinder fixed on the second supporting plate, a fourth supporting plate driven by the third air cylinder to move up and down, and a plurality of second sealing heads arranged on the fourth supporting plate and communicated with the airtight testing instrument.

Further, an auxiliary positioning block for positioning the water gap on the liquid cooling plate is further arranged on the second supporting plate.

Furthermore, the auxiliary positioning block is inserted between two adjacent water gaps to position the distance between the two adjacent water gaps.

Further, a C-shaped groove for positioning the periphery of the water gap is formed in the auxiliary positioning block.

Further, the XY floating assembly comprises a first floating plate, a first limiting plate, a first elastic piece group, a second floating plate, a centering positioning block, a second elastic piece group and a third elastic piece group, wherein the first floating plate is arranged on the first supporting plate in a left-right sliding mode, the first limiting plate is used for limiting the left side of the first floating plate, the first elastic piece group is positioned on the right side of the first floating plate and is used for propping the first floating plate leftwards, the second floating plate is arranged on the first floating plate in a front-back sliding mode, the centering positioning block is fixed on the lower surface of the middle of the second floating plate, the second elastic piece group and the third elastic piece group are symmetrically arranged on two sides of the centering positioning block and oppositely propped against the two sides of the centering positioning block, the second limiting plate is arranged on the first floating plate, and the other ends of the second elastic piece group and the third elastic piece group are limited by the second limiting plate; the second support plate is disposed on the second floating plate.

Further, an end limiting block for supporting and limiting the water gap end of the liquid cooling plate is further arranged on the second supporting plate.

Further, a sensor for detecting whether the product exists or not is further arranged on the end limiting block.

Compared with the prior art, the self-adaptive floating liquid cooling plate airtight testing mechanism has the beneficial effects that: through setting up XY floating assembly, will set up on XY floating assembly with the sealing member that the liquid cooling board mouth of a river was inserted, can carry out self-adaptation direction with the liquid cooling board mouth of a river end and float, realize flexible to inserting and accurate to inserting, provide the condition for realizing the automatic test that the gas tightness detected, improve efficiency of software testing.

[ description of the drawings ]

FIG. 1 is a schematic perspective view of an embodiment of the present utility model;

FIG. 2 is a schematic view of another embodiment of the present utility model;

FIG. 3 is a schematic diagram of the structure of an end stop block and an auxiliary positioning block according to an embodiment of the present utility model;

FIG. 4 is a schematic perspective view of an XY floating assembly according to an embodiment of the present utility model;

FIG. 5 is a schematic side view of an XY floating assembly according to an embodiment of the present utility model;

the figures represent the numbers:

100-an adaptive floating liquid cooling plate airtight testing mechanism;

200-liquid cooling plate water gap end;

1-first cylinder, 2-first backup pad, 3-XY floating assembly, 31-first floating plate, 32-first limiting plate, 33-first elastic member set, 34-second floating plate, 35-centering locating piece, 36-second elastic member set, 37-third elastic member set, 38-second limiting plate, 4-second backup pad, 5-insert seal, 51-upper insert assembly, 511-second cylinder, 512-third backup pad, 513-first seal head, 52-lower insert assembly, 521-third cylinder, 522-fourth backup pad, 523-second seal head, 6-auxiliary locating piece, 7-end stop, 8-sensor.

[ detailed description ] of the utility model

Embodiment one:

referring to fig. 1-5, the present embodiment is a self-adaptive floating liquid cooling plate airtight testing mechanism 100, which includes a first cylinder 1, a first support plate 2 driven by the first cylinder 1 to move left and right, an XY floating assembly 3 disposed on the first support plate 2, a second support plate 4 disposed at the movable end of the XY floating assembly 3, and a plurality of pairs of inserting seals 5 fixed on the second support plate 4 and inserted with the water gap end of the liquid cooling plate.

In this embodiment, the liquid cooling plate includes a pair of nozzles a with upward openings and a pair of nozzles B with downward openings. The insert seal 5 is provided with an upper insert assembly 51 and a lower insert assembly 52, respectively. The upper insert assembly 51 is used for sealing or conducting the water gap A; the lower insert assembly 52 is used to seal or conduct the nozzle B.

The upper counter insert assembly 51 includes a second cylinder 511 fixed to the second support plate 4, a third support plate 512 driven to move up and down by the second cylinder 511, and a plurality of first sealing heads 513 provided on the third support plate 512.

The lower counter insert assembly 52 includes a third cylinder 521 fixed to the second support plate 4, a fourth support plate 522 driven to move up and down by the third cylinder 521, and a plurality of second sealing heads 523 provided on the fourth support plate 521.

The first sealing head 513 and the second sealing head 523 are respectively connected to an input end and an output end of the air tightness testing instrument, and air tightness detection is performed on the cooling channel inside the liquid cooling plate.

In other embodiments, if there is a horizontally open nozzle on the liquid cooling plate 200, a sealing head that moves horizontally may be provided correspondingly.

In order to improve the accuracy of butt joint of the sealing head and the water gap end of the liquid cooling plate, an auxiliary positioning block 6 for positioning the water gap on the liquid cooling plate is further arranged on the second supporting plate 4.

In this embodiment, the auxiliary positioning block 6 is inserted between two adjacent water gaps A, B, so that the distance between the two water gaps is well controlled, and the first sealing head 513 and the second sealing head 523 can be aligned for insertion. In other embodiments, the auxiliary positioning block 6 may also be used for positioning the periphery of the nozzle by forming a C-shaped groove.

In order to further improve the accuracy and safety of the insertion of the first and second sealing heads 513 and 523 into the nozzle, the nozzle is prevented from being damaged by insertion. The XY floating assembly 3 is arranged in the embodiment, the floating function of the first sealing head 513 and the second sealing head 523 in the X, Y direction is achieved through the XY floating assembly 3, when the water gap is inserted, the self-adaptive adjustment can be achieved through taper guiding of the periphery or the inner ring of the water gap, and the phenomenon that a liquid cooling plate is damaged due to hard insertion is effectively avoided. Specifically, the XY floating assembly 3 includes a first floating plate 31 slidably disposed on the first supporting plate 2 from side to side, a first stopper plate 32 defining a left side position of the first floating plate 31, a first elastic member group 33 disposed on a right side of the first floating plate 31 and holding the first floating plate 31 to the left, a second floating plate 34 slidably disposed on the first floating plate 31 from front to back, a centering positioning block 35 fixed on a lower surface of a middle portion of the second floating plate 34, a second elastic member group 36 and a third elastic member group 37 symmetrically disposed on both sides of the centering positioning block 35 and oppositely holding both side surfaces of the centering positioning block 35, a second stopper plate 38 disposed on the first floating plate 31, and the other ends of the second elastic member group 36 and the third elastic member group 37 being limited by the second stopper plate 38. The second support plate 4 is provided on the second floating plate 34.

The second supporting plate 4 is also provided with an end limiting block 7 for limiting the water gap end 200 of the liquid cooling plate. The position of the second supporting plate 4 moving leftwards is limited, the elastic floating function of the XY floating assembly 3 is matched, the auxiliary positioning block 6 can be prevented from excessively pressing the water gap leftwards, the end part of the liquid cooling plate can be positioned through the end limiting block 7, a relative position reference is provided through the end limiting block 7, and the position accuracy of the sealing head is guaranteed.

The end limiting block 7 is also provided with a sensor 8 for detecting whether the product exists or not. The sensor 8 senses the distance between the water gap end 200 and the end of the liquid cooling plate, and if a signal is sensed, the liquid cooling plate is placed on the station to be detected.

What has been described above is merely some embodiments of the present utility model. It will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the spirit of the utility model.

Claims (10)

1. The utility model provides a self-adaptation floating liquid cooling board airtight test mechanism which characterized in that: the device comprises a first air cylinder, a first supporting plate driven by the first air cylinder to move left and right, an XY floating assembly arranged on the first supporting plate, a second supporting plate arranged at the movable tail end of the XY floating assembly, and a plurality of pairs of inserting sealing pieces fixed on the second supporting plate and inserted with the water gap end of the liquid cooling plate.

2. The adaptive floating liquid-cooled panel airtight testing mechanism of claim 1, wherein: the liquid cooling plate comprises a pair of water gaps A with upward openings and a pair of water gaps B with downward openings; the upper butt-inserting assembly for sealing or conducting the water gap A and the lower butt-inserting assembly for sealing or conducting the water gap B are correspondingly arranged on the butt-inserting sealing member.

3. The self-adaptive floating liquid-cooled panel airtight testing mechanism according to claim 2, wherein: the upper opposite-plug assembly comprises a second air cylinder fixed on the second support plate, a third support plate driven by the second air cylinder to move up and down, and a plurality of first sealing heads arranged on the third support plate and communicated with the airtight test instrument.

4. The self-adaptive floating liquid-cooled panel airtight testing mechanism according to claim 2, wherein: the lower opposite-plug assembly comprises a third air cylinder fixed on the second supporting plate, a fourth supporting plate driven by the third air cylinder to move up and down, and a plurality of second sealing heads arranged on the fourth supporting plate and communicated with the airtight testing instrument.

5. The adaptive floating liquid-cooled panel airtight testing mechanism of claim 1, wherein: and an auxiliary positioning block for positioning the water gap on the liquid cooling plate is further arranged on the second supporting plate.

6. The adaptive floating liquid-cooled panel airtight testing mechanism of claim 5, wherein: the auxiliary positioning block is inserted between two adjacent water gaps to position the distance between the two adjacent water gaps.

7. The adaptive floating liquid-cooled panel airtight testing mechanism of claim 5, wherein: and the auxiliary positioning block is provided with a C-shaped groove for positioning the periphery of the water gap.

8. The adaptive floating liquid-cooled panel airtight testing mechanism of claim 1, wherein: the XY floating assembly comprises a first floating plate, a first limiting plate, a first elastic piece group, a second floating plate, a centering positioning block, a second elastic piece group and a third elastic piece group, wherein the first floating plate is arranged on the first supporting plate in a left-right sliding mode, the first limiting plate is used for limiting the left side of the first floating plate, the first elastic piece group is positioned on the right side of the first floating plate and used for propping the first floating plate leftwards, the second floating plate is arranged on the first floating plate in a front-back sliding mode, the centering positioning block is fixed on the lower surface of the middle of the second floating plate, the second elastic piece group and the third elastic piece group are symmetrically arranged on two sides of the centering positioning block and oppositely propped against the two side surfaces of the centering positioning block, the second limiting plate is arranged on the first floating plate, and the other ends of the second elastic piece group and the third elastic piece group are limited by the second limiting plate; the second support plate is disposed on the second floating plate.

9. The adaptive floating liquid-cooled panel airtight testing mechanism of claim 8, wherein: and an end limiting block for supporting and limiting the water gap end of the liquid cooling plate is further arranged on the second supporting plate.

10. The adaptive floating liquid cooled panel air tightness test mechanism of claim 9, wherein: and a sensor for detecting whether the product exists or not is further arranged on the end limiting block.