CN212321669U - Battery test supporting structure and battery test device - Google Patents

Abstract

The utility model is suitable for a battery test field provides a battery test bearing structure and battery testing arrangement. Wherein, battery test bearing structure sets up with the cooperation of platelike battery, includes: the fixing component is provided with a first mounting position and a second mounting position; the battery holder comprises a clamp for clamping the plate-shaped battery and a carrier for supporting the clamp, wherein the carrier is provided with a first connecting part and a second connecting part, any one of the battery holders is selectively connected with one of the first installation position and the second installation position, when the battery holder is connected with the first installation position through the first connecting part, the plate-shaped battery is placed horizontally, and when the battery holder is connected with the second installation position through the second connecting part, the plate-shaped battery is placed vertically. The utility model provides a battery test bearing structure can satisfy the requirement that the plate battery is horizontal state of placing or vertical state of placing and carries out the simulation test to simplify the structure, reduce equipment cost.

Description

Battery test supporting structure and battery test device

Technical Field

The utility model belongs to battery test field especially relates to a battery test bearing structure and battery testing arrangement.

Background

In the production and manufacturing process of the battery, whether the battery meets the requirements or not needs to be tested through the testing procedures of high-temperature, normal-temperature and low-temperature electrical properties. Meanwhile, the capacity, the internal resistance, the self-discharge and other performances of the battery are required to be tested, and the safety and the stability of the battery are tested through voltage, internal resistance, insulation data and the like.

For the plate-shaped batteries, it is necessary to perform simulation tests on a horizontally placed state (the length and width directions thereof are parallel to the horizontal plane, and the height direction thereof is perpendicular to the horizontal plane) and a vertically placed state (the length and height directions thereof are parallel to the horizontal plane, and the width direction thereof is perpendicular to the horizontal plane). The existing battery test supporting structure can only support the plate-shaped battery to be placed horizontally for simulation test, but cannot support the plate-shaped battery to be placed vertically for simulation test.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned prior art not enough, provide a battery test bearing structure and battery testing arrangement, it aims at solving and only supports the plate battery to be horizontal state of placing and simulates the test, can not support the plate battery to be vertical state of placing and simulate the test.

A battery test support structure for supporting plate-shaped batteries, comprising:

the fixing component is provided with at least one first mounting position and at least one second mounting position;

a battery holder having at least one holder including a jig for holding the plate-shaped battery and a carrier for supporting the jig, the carrier having a first connecting portion detachably connectable to the first mounting portion and a second connecting portion detachably connectable to the second mounting portion, any one of the battery holders being selectively connectable to one of the first mounting portion and the second mounting portion, the battery holder being configured to allow the plate-shaped battery to be placed in a horizontal state when connected to the first mounting portion via the first connecting portion, and to allow the plate-shaped battery to be placed in a vertical state when connected to the second mounting portion via the second connecting portion;

the length and the width of the plate-shaped battery are parallel to the horizontal plane and the height of the plate-shaped battery is vertical to the horizontal plane when the plate-shaped battery is placed horizontally, and the length and the height of the plate-shaped battery are parallel to the horizontal plane and the width of the plate-shaped battery is vertical to the horizontal plane when the plate-shaped battery is placed vertically.

Optionally, the carrier is provided with an adjusting groove, and the extending direction of the adjusting groove is parallel to the extending direction of the length of the plate-shaped battery; the clamp comprises a left clamping piece in sliding connection with the adjusting groove, a right clamping piece fixed on the carrier and matched with the left clamping piece to clamp the plate-shaped battery, and a locking piece used for limiting the left clamping piece to move relative to the carrier.

Optionally, the locking piece includes an adjusting screw and an adjusting nut, and the adjusting screw is connected with the left clamp piece and passes through the adjusting groove to be screwed with the adjusting nut.

Optionally, the battery holder further includes a supporting plate connected to the carrier, and the left clamping member, the right clamping member and the supporting plate enclose a fixing space for fixing the plate-shaped battery.

Optionally, the supporting plate is provided with a first sliding groove, an extending direction of which is parallel to the extending direction of the length of the plate-shaped battery, and the battery holder further includes a connecting rod which penetrates through the first sliding groove and is connected with the carrier.

Optionally, the supporting plate is provided with a first sliding groove, an extending direction of which is parallel to an extending direction of the length of the plate-shaped battery, the carrier is provided with a second sliding groove, an extending direction of which is perpendicular to the first sliding groove, and the battery holder further includes a connecting bolt which penetrates through the first sliding groove and the second sliding groove to connect the supporting plate to the carrier.

Optionally, a baffle plate for limiting the plate-shaped battery to move away from the carrier is connected to the supporting plate along a plate edge facing away from the carrier.

Optionally, the fixing assembly includes at least one first tray, at least one second tray, and a supporting frame for supporting the first tray and the second tray, the first tray has at least one first mounting position, and the second tray has at least one second mounting position.

Optionally, the first tray and the second tray are connected with the supporting frame in a sliding manner.

Optionally, the first mounting positions are multiple and arranged in a row in the horizontal plane, and the second mounting positions are multiple and arranged in a row in the horizontal plane.

A battery test device comprises the battery test support structure.

The application provides a battery test bearing structure's beneficial effect lies in: compared with the prior art, the battery test supporting structure that this application provided can satisfy the requirement that the plate-shaped battery is horizontal placement state or vertical placement state and carries out the simulation test, and in addition, the battery tray realizes the adjustment of plate-shaped battery placement state through the adjustment of battery tray hookup location with the cooperation design of fixed subassembly to simplify the structure, reduce equipment cost.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a general schematic view of a battery test support structure according to an embodiment of the present disclosure;

fig. 2 is a schematic diagram illustrating a connection between a first tray and a battery holder according to a first embodiment of the present disclosure, wherein the battery holder is placed horizontally;

fig. 3 is a schematic diagram illustrating a connection between a second tray and a battery holder according to an embodiment of the present disclosure, wherein the battery holder is placed vertically;

fig. 4 is a schematic view illustrating the battery holder and the plate-shaped battery according to an embodiment of the present disclosure;

fig. 5 is a schematic view of a battery holder according to an embodiment of the present application;

fig. 6 is a top view of a carrier according to an embodiment of the present application.

Wherein, in the figures, the respective reference numerals:

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "height," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," and the like, are used in an orientation or positional relationship indicated based on the orientation or positional relationship shown in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Example one

Referring to fig. 1 to 6, the present embodiment provides a battery test support structure, which is disposed in cooperation with a plate-shaped battery 1. The battery test support structure includes a battery holder 10 for holding the plate-shaped batteries 1 and a fixing assembly 20 for carrying the battery holder 10.

The mounting assembly 20 has at least one first mounting location and has at least one second mounting location.

The battery holder 10 has at least one, including a clamp 11 for clamping the plate-shaped battery 1 and a carrier 12 for supporting the clamp 11, the carrier 12 has a first connecting portion 123 capable of being connected to the first mounting position and a second connecting portion 124 capable of being connected to the second mounting position, any one of the battery holders 10 is selectively connected to one of the first mounting position and the second mounting position, when the battery holder 10 is connected to the first mounting position through the first connecting portion 123, the plate-shaped battery 1 is placed horizontally, and when the battery holder 10 is connected to the second mounting position through the second connecting portion 124, the plate-shaped battery 1 is placed vertically.

The length and width directions of the plate-shaped battery 1 are parallel to the horizontal plane and the height direction thereof is perpendicular to the horizontal plane when the plate-shaped battery 1 is placed horizontally, and the length and height directions thereof are parallel to the horizontal plane and the width direction thereof is perpendicular to the horizontal plane when the plate-shaped battery 1 is placed vertically.

Referring to fig. 4, a rectangular coordinate system is established in a state where the plate-shaped battery 1 is horizontally placed, in which the length of the plate-shaped battery 1 extends in the Y-axis direction, the width of the plate-shaped battery 1 extends in the X-axis direction, and the height of the plate-shaped battery 1 extends in the Z-axis direction. For convenience of description, a face of the battery holder 10 perpendicular to the Z axis and in the positive direction of the Z axis is referred to as an upper face, a face perpendicular to the Z axis and in the negative direction of the Z axis is referred to as a lower face, a face perpendicular to the X axis and in the positive direction of the X axis is referred to as a front face, a face perpendicular to the X axis and in the negative direction of the X axis is referred to as a front face, a face perpendicular to the Y axis and in the positive direction of the Y axis is referred to as a left face, and a face perpendicular to the Y axis and in the positive direction of the Y axis is referred.

Referring to fig. 2 and 4, the carrier 12 of the battery holder 10 is substantially square, and when the upper surface of the carrier 12 is placed on the fixing member 20 in an upward direction, the plate-shaped battery 1 is placed in a horizontal state. In the illustrated structure, the first connection portion 123 is disposed on the lower surface of the carrier 12, and the fixing assembly 20 is connected to the first connection portion 123 at the first installation position by a detachable connection manner such as a screw connection, a clamping connection, a magnetic connection, or a fixed connection manner such as a welding connection.

Referring to fig. 2 and 4, the rear surface of the carrier 12 is a second connecting portion 124, and when the second connecting portion 124 is connected to the fixing member 20, the plate-shaped battery 1 is placed in a vertical state. The fixing component 20 and the second connecting portion 124 are detachably connected or fixedly connected.

The plate-shaped battery 1 is held and fixed to a battery holder 10 by a jig 11, and the battery holder 10 can be selectively attached to a first attachment position and a second attachment position. When the plate-shaped battery 1 needs to be placed horizontally for testing, the first connection part 123 (the lower surface of the carrier 12) of the battery holder 10 holding the plate-shaped battery 1 is connected to the first mounting site, and when the plate-shaped battery 1 needs to be placed vertically for testing, the second connection part 124 (the rear surface of the carrier 12) of the battery holder 10 holding the plate-shaped battery 1 is connected to the second mounting site. The horizontal placement and the vertical placement of the plate-shaped battery 1 are realized through the selection of the horizontal placement and the vertical placement of the battery holder 10, and the horizontal placement or the vertical placement of the battery holder 10 is realized through the selection of different connection parts of the battery holder 10. The first mounting position is connected with the first connecting portion 123 to realize horizontal placement of the battery holder 10, and the second mounting position is connected with the second connecting portion 124 to realize vertical placement of the battery holder 10.

It should be noted that the first mounting position and the second mounting position may be the same position, and in this case, the connecting assembly can be alternatively connected to the first connecting portion 123 and the second connecting portion 124 of the battery holder 10 at this position. Under this design, because first installation position can be connected with first connecting portion 123, also can be connected with second connecting portion 124 for the structure of first installation position is comparatively complicated. In this embodiment, the first mounting position can be connected to the first connecting portion 123 only, and the second mounting position can be connected to the second connecting portion 124 only, so as to simplify the design of the connecting structure.

In summary, the battery test support structure provided by this embodiment can satisfy the requirement that the plate-shaped battery 1 is placed horizontally or placed vertically to perform the simulation test, and in addition, the adjustment of the placement state of the plate-shaped battery 1 is realized through the adjustment of the connection position of the battery holder 10 by the matching design of the battery holder 10 and the fixing component 20, so as to simplify the structure and reduce the equipment cost.

It can be understood by those skilled in the art that when it is required to perform a simulation test on the plate-shaped battery 1 in a vertical placement state (the width and height directions of the plate-shaped battery 1 are parallel to the horizontal plane, and the height direction thereof is perpendicular to the horizontal plane), the battery holder 10 is provided with a third connecting portion capable of being connected to the fixing member 20, the fixing member 20 is provided with a third installation position connected to the third connecting portion, and when the third connecting portion is connected to the third installation position, the plate-shaped battery 1 is in a vertical placement state.

In another embodiment of the present application, referring to fig. 1 to 3, the fixing assembly 20 includes at least one first tray 21, at least one second tray 22, and a supporting frame 23 for supporting the first tray 21 and the second tray 22, where the first tray 21 has at least one first mounting position, and the second tray 22 has at least one second mounting position.

In the illustrated structure, the supporting frame 23 has a layered structure, and a plurality of tray mounting positions are formed in a stacked manner in the height direction, and the first tray 21 and the second tray 22 are correspondingly disposed on the tray mounting positions. In another embodiment, the support frame 23 may be a rack structure, and the tray mounting positions may be arranged in order in the horizontal direction.

In this embodiment, the supporting frame 23 is provided with one tray mounting position for mounting one first tray 21 or one second tray 22 per layer, and in other embodiments, the supporting frame 23 may also be provided with more than two tray mounting positions per layer, which is not limited herein.

The first tray 21 is provided with at least one first mounting position, and each first mounting position is used for fixing the battery holder 10. The first mounting positions are arranged in rows and columns on a horizontal plane, so that the arrangement of flat cables electrically connected with the plate-shaped batteries 1 is facilitated. Similarly, the second tray 22 is provided with at least one second mounting position, and each second mounting position is arranged in a row and a column, so as to facilitate the arrangement of the cables electrically connected with the plate-shaped batteries 1. In the illustrated structure, the first tray 21 is provided with four first mounting positions, and the four first mounting positions are arranged at equal intervals in the front-rear direction. The second tray 22 is provided with four second mounting positions, which are arranged at equal intervals in the front-rear direction.

The first tray 21 and the second tray 22 are selectively connected to the battery holder 10, and when the battery holder 10 is connected to the first tray 21, the first connection part 123 is connected to the first mounting position to horizontally place the plate-shaped battery 1 (see fig. 2), and when the battery holder 10 is connected to the second tray 22, the second connection part 124 is connected to the second mounting position to vertically place the plate-shaped battery 1 (see fig. 3).

The plate-shaped battery 1 is held and fixed to a battery holder 10 by a jig 11, and the battery holder 10 can be alternatively attached to a first tray 21 and a second tray 22. When the plate-shaped battery 1 needs to be placed horizontally for testing, the battery holder 10 holding the plate-shaped battery 1 is fitted to the first tray 21 (the first connecting portion 123 is connected to the first mounting site), and when the plate-shaped battery 1 needs to be placed vertically for testing, the battery holder 10 holding the plate-shaped battery 1 is fitted to the second tray 22 (the second connecting portion 124 is connected to the second mounting site). The operation of the operator is facilitated.

In practice, a plurality of battery holders 10 are fixedly connected to the first tray 21 and the second tray 22 to form an integral structure. When the plate-shaped battery 1 is required to be tested, the plate-shaped battery 1 is placed in one of the battery holders 10 according to a desired placement state of the plate-shaped battery 1. When the plate-shaped battery 1 needs to be tested in a horizontally placed state, the plate-shaped battery 1 is placed in one of the battery seats 10 on the first tray 21, and when the plate-shaped battery 1 needs to be tested in a vertically placed state, the plate-shaped battery 1 is placed in one of the battery seats 10 on the second tray 22, which is convenient to operate.

In another embodiment of the present application, referring to fig. 1, the first tray 21 and the second tray 22 are slidably connected to the supporting frame 23. The first tray 21 and the support 23, and the second tray 22 and the support 23 may be connected by drawer slide rails, which may be roller slide rails, steel ball slide rails, gear slide rails, or damping slide rails. When the plate-shaped battery 1 needs to be taken in and out, the first tray 21/the second tray 22 are pulled out, and the first tray 21/the second tray 22 are pushed back after the plate-shaped battery 1 is put in/out. The first tray 21 and the second tray 22 are slidably connected to the support frame 23, so that the plate-shaped battery 1 can be conveniently taken and placed.

In another embodiment of the present application, referring to fig. 3, the carrier 12 is provided with an adjusting groove 121, an extending direction of which is parallel to a length extending direction of the plate-shaped battery 1; the clamp 11 includes a left clamping member 111 slidably connected to the adjustment groove 121, a right clamping member 112 fixed to the carrier 12 and cooperating with the left clamping member 111 to clamp the plate-shaped battery 1, and a locking member 113 for limiting the movement of the left clamping member 111 relative to the carrier 12.

In the illustrated structure, the left and right clip members 111 and 112 are spaced apart from each other in the left-right direction, and the adjustment groove 121 extends in the left-right direction. The left grip member 111 can be moved closer to or farther from the right grip member 112 along the adjustment groove 121 to facilitate the taking and placing of the plate-shaped battery 1. When the left and right clips 111 and 112 abut against both side surfaces of the plate-shaped battery 1, respectively, the left clip 111 is locked, and the clamping of the plate-shaped battery 1 by the clamp 11 is achieved. As will be understood by those skilled in the art, when the plate-shaped battery 1 is taken out, the lock member 113 releases the movement restriction of the left grip member 111, and the left grip member 111 moves away from the right grip member 112 to release the plate-shaped battery 1, so that the plate-shaped battery 1 can be taken out.

When the adjustment groove 121 has a certain length, the jig 11 can be attached to the plate-shaped battery 1 of various sizes. The plate-shaped battery 1 of two dimensions is applied to the jig 11 as an example. The adjusting groove 121 has a starting position, a first limiting position and a second limiting position which are arranged at intervals left and right, and the left clamping piece 111 can move left and right along the adjusting groove 121 and is limited to move relative to the carrier 12 at the first limiting position or the second limiting position by the locking piece 113. The first and second limit positions are set in conformity with the sizes of the two plate-shaped batteries 1. When the left grip member 111 moves rightward from the initial position to reach the first restriction position, the locking member 113 locks the left grip member 111, and at this time, the left grip member 111 and the right grip member 112 can grip the plate-shaped battery 1 of the first size. When the left clamping piece 111 moves to the second limiting position, the locking piece 113 locks the left clamping piece 111, and it can be understood by those skilled in the art that when more than three plate-shaped batteries 1 are required to be applied, a third limiting position and a fourth limiting position are correspondingly arranged.

In another embodiment of the present application, the locking member 113 includes an adjusting screw and an adjusting nut, and the adjusting screw is connected to the left clamping member 111 and threaded with the adjusting nut through the adjusting slot 121. The left clamping member 111 is provided with a connecting hole for passing an adjusting screw (in other embodiments, the left clamping member 111 may also be fixedly connected with the adjusting screw), and the adjusting screw passes through the connecting hole and the adjusting groove 121 to be screwed with the adjusting nut. And when the adjusting nut is screwed with the adjusting screw, the left clamping piece 111 is locked, and when the adjusting nut and the adjusting screw are unscrewed, the left clamping piece 111 is unlocked. The locking piece 113 adopts a bolt structure, has a simple structure and is beneficial to reducing the equipment cost. In other embodiments, the locking member 113 can also be electromagnetically connected or can be used to lock and unlock the left clamping member 111, which is not limited herein. In the illustrated structure, there are three adjustment grooves 121 arranged in parallel, and correspondingly, there are three locking members 113. The battery holder 10 further includes a connecting plate, the connecting plate is provided with a limiting hole for each screw to pass through, and the adjusting screw passes through the connecting hole, the adjusting groove 121 and the limiting hole to be connected with the adjusting nut. The connecting plate is arranged to simultaneously bear the clamping force of each adjusting nut, so that the stress concentration of the structure is reduced.

In another embodiment of the present application, referring to fig. 5, the battery holder 10 further includes a supporting plate 13 connected to the carrier 12, and the left clamping member 111, the right clamping member 112 and the supporting plate 13 enclose to form a fixing space for fixing the plate-shaped battery 1. The battery holder 10 in fig. 5 is taken as an example of the placement state. Before assembly, the distance between the left clamping piece 111 and the right clamping piece 112 is larger than the length of the plate-shaped battery 1 in the left-right direction, and the left clamping piece 111, the right clamping piece 112 and the supporting plate 13 enclose to form an accommodating space for the plate-shaped battery 1 to enter. The plate-shaped battery 1 enters the housing space from the front (positive X-axis direction) and is restricted from moving backward by the tray 13, and at this time, the position of the plate-shaped battery 1 in the front-rear direction is relatively fixed. Then, the left clamping member 111 moves rightward to clamp and fix the plate-shaped battery 1 in the left-right direction, and at this time, the left clamping member 111, the right clamping member 112, and the support plate 13 enclose a fixing space for fixing the plate-shaped battery 1, and three surfaces of the plate-shaped battery 1 abut against the left clamping member 111, the right clamping member 112, and the support plate 13, respectively. Therefore, the arrangement of the pallet 13 provides an initial positioning function for the placement of the plate-shaped batteries 1.

In another embodiment of the present application, the supporting plate 13 is provided with a first sliding slot 131, an extending direction of which is parallel to a length extending direction of the plate-shaped battery 1, and the battery holder 10 further includes a connecting rod passing through the first sliding slot 131 and connecting to the carrier 12. This arrangement enables the pallet 13 to move left and right relative to the carrier 12 along the first slide groove 131 to adjust the position of the plate-shaped battery 1 according to different dimensions.

In another embodiment of the present application, referring to fig. 5 and 6, the supporting plate 13 is provided with a first sliding slot 131 extending in a direction parallel to a length extending direction of the plate-shaped battery 1, the carrier 12 is provided with a second sliding slot 122 extending in a direction perpendicular to the first sliding slot 131, and the battery holder 10 further includes a connecting bolt 14 penetrating through the first sliding slot 131 and the second sliding slot 122 to connect the supporting plate 13 to the carrier 12. This arrangement enables the pallet 13 to move relative to the carrier 12 in two degrees of freedom perpendicular to each other. In the illustrated structure, the first slide groove 131 extends left and right, the second slide groove 122 extends forward and backward, and the connecting bolt 14 passes through both the first slide groove 131 and the second slide groove 122. The supporting plate 13 can move left and right relative to the connecting bolt 14 to realize left and right movement of the supporting plate 13 relative to the carrier 12, and the connecting bolt 14 and the supporting plate 13 can move back and forth relative to the second sliding groove 122 to realize front and back movement of the supporting plate 13 relative to the carrier 12. In other embodiments, the first sliding slot 131 may be disposed on the carrier 12 and communicated with the second sliding slot 122, in which the connecting bolt 14 and the supporting plate 13 are fixed in position relatively, and the connecting bolt 14 can move along the first sliding slot 131 and the second sliding slot 122 to drive the supporting plate 13 to move relative to the carrier 12. In other embodiments, the second chute 122 may be opened on the supporting plate 13 and communicated with the first chute 131, in this arrangement, the position of the connecting bolt 14 and the carrier 12 is fixed relatively, and the connecting bolt 14 can move along the first chute 131 and the second chute 122 to move the supporting plate 13 relative to the carrier 12. In the illustrated structure, the screw of the connecting bolt 14 is a butterfly screw, and this arrangement can facilitate manual operation.

In another embodiment of the present application, referring to fig. 4 or 5, a baffle 15 for limiting the movement of the plate-shaped battery 1 away from the carrier 12 is connected to the supporting plate 13 along a plate facing away from the carrier 12. When the plate-shaped battery 1 is clamped by the clamp 11, the left clamping piece 111 and the right clamping piece 112 respectively abut against the left side and the right side of the plate-shaped battery 1, the rear surface of the plate-shaped battery 1 is abutted by the supporting plate 13, and the baffle 15 is positioned above the plate-shaped battery 1 to limit the plate-shaped battery 1 to be separated from the upper side. Note that the baffle 15 and the pallet 13 are integrally provided. The baffle 15 and the support plate 13 together can achieve the effect of facilitating assembly. Particularly, when the plate-shaped battery 1 is placed vertically, please refer to fig. 5, the plate-shaped battery 1 enters the accommodating space enclosed by the left clamping piece 111, the right clamping piece 112 and the supporting plate 13 along the negative X-axis direction, at this time, the plate-shaped battery 1 is limited by the supporting plate 13 to move towards the negative X-axis direction and balance with gravity, and is limited by the baffle 15 and the carrier 12 to move towards the Z-axis direction and prevent the plate-shaped battery 1 from tilting towards the Z-axis direction, so that the plate-shaped battery 1 is in a relatively static state where no external force acts on the plate-shaped battery and the plate-shaped battery does not move, that is, in this case, no manual fixation is needed, and thus an operator is free to perform a clamping.

Example two

The embodiment provides a plate-shaped battery testing device which comprises a battery testing supporting structure and a circuit system, wherein the circuit system is arranged on the battery testing supporting structure and is used for testing a plate-shaped battery. Please refer to the first embodiment for a specific structure of the battery testing support structure. Since the battery testing apparatus provided in this embodiment adopts all the technical solutions of all the embodiments one, all the beneficial effects brought by the technical solutions of the embodiments are also achieved, and are not described in detail herein.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modification, equivalent replacement or improvement made within the spirit and principle of the present invention should be included in the present invention.

Claims (10)

1. A battery test support structure for supporting a plate-shaped battery, comprising:

the fixing component is provided with at least one first mounting position and at least one second mounting position;

a battery holder including at least one clamp for holding the plate-shaped battery and a carrier for supporting the clamp, the carrier having a first connecting portion connectable to the first mounting position and a second connecting portion connectable to the second mounting position, any one of the battery holders being selectively connectable to one of the first mounting position and the second mounting position, the battery holder being configured to allow the plate-shaped battery to be placed in a horizontal position when connected to the first mounting position via the first connecting portion, and to allow the plate-shaped battery to be placed in a vertical position when connected to the second mounting position via the second connecting portion;

the length and the width of the plate-shaped battery are parallel to the horizontal plane and the height of the plate-shaped battery is vertical to the horizontal plane when the plate-shaped battery is placed horizontally, and the length and the height of the plate-shaped battery are parallel to the horizontal plane and the width of the plate-shaped battery is vertical to the horizontal plane when the plate-shaped battery is placed vertically.

2. The battery test support structure of claim 1, wherein the carrier is provided with an adjustment groove extending in a direction parallel to the extension direction of the length of the plate-shaped battery; the clamp comprises a left clamping piece in sliding connection with the adjusting groove, a right clamping piece fixed on the carrier and matched with the left clamping piece to clamp the plate-shaped battery, and a locking piece used for limiting the left clamping piece to move relative to the carrier.

3. The battery test support structure of claim 2, wherein the locking member comprises an adjustment screw and an adjustment nut, the adjustment screw connecting the left clamp piece and passing through the adjustment slot to be threadedly coupled with the adjustment nut.

4. The battery test support structure of claim 2, wherein the battery holder further comprises a support plate connected to the carrier, and the left clamp, the right clamp and the support plate enclose a fixing space for fixing the plate-shaped battery.

5. The battery testing support structure of claim 4, wherein the support plate defines a first sliding slot extending in a direction parallel to a length of the plate-shaped battery, the carrier defines a second sliding slot extending in a direction perpendicular to the first sliding slot, and the battery holder further comprises a connecting bolt passing through the first sliding slot and the second sliding slot to connect the support plate to the carrier.

6. The battery test support structure of claim 4, wherein the pallet has attached to a plate facing away from the carrier a stop for limiting movement of the plate-like batteries away from the carrier.

7. The battery test support structure of any one of claims 1 to 6, wherein said fixture assembly comprises at least one first tray having at least one said first mounting location, at least one second tray having at least one said second mounting location, and a support frame for supporting said first tray and said second tray.

8. The battery test support structure of claim 7, wherein the first tray and the second tray are each slidably connected to the support frame.

9. The battery test support structure of claim 8, wherein the first mounting locations are plural and arranged in a row in a horizontal plane, and the second mounting locations are plural and arranged in a row in a horizontal plane.

10. A battery test apparatus comprising a battery test support structure according to any one of claims 1 to 9.

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