CN212606681U - Battery current testing device for new energy automobile production - Google Patents

Abstract

The utility model discloses a new energy automobile production is with battery current testing arrangement, include testing arrangement shell, controlling means, rack, installation piece and accept the board, the laminating has first slider on the testing arrangement shell, and first slider installs on placing the case to place and install the work spring on the case, the rack is installed on placing the case, and rack and gear interconnect to the gear is installed in the axis of rotation, the installation piece is installed on the testing arrangement shell, and installs the axis of rotation on the installation piece, accept the board and push pulley and laminate each other, and accept and install the second slider on the board. This new energy automobile production is with battery current testing arrangement adopts linkage structure, places the case and just begins the downstream after putting into the battery in placing the case, under the effect of rack, realizes promoting the rotation of wheel to be convenient for fix the wire of battery, no longer need too much artifical the participation, effectual reduction accident rate.

Description

Battery current testing device for new energy automobile production

Technical Field

The utility model relates to a battery production technical field specifically is a new energy automobile production is with battery current testing arrangement.

Background

With the development of science and technology, the traveling mode of people is continuously changed, the traveling mode which is the main traveling mode by walking at first is changed into the traveling mode which is the main traveling mode by automobiles, and new energy automobiles also slowly step into the visual field of people, and the automobiles are driven to run by converting electric energy into mechanical energy.

Also there are some problems in the in-process of using the battery to produce new energy automobile, for example, be difficult to fix its wire in the electric current to the battery detects the in-process, need the manual work to press the detection at the in-process that detects, has great potential safety hazard, will cause the damage to the battery when serious.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a new energy automobile production is with battery current testing arrangement to it is difficult to fix the wire to provide in solving above-mentioned background art, needs the manual work to press the problem that has the potential safety hazard.

In order to achieve the above object, the utility model provides a following technical scheme: a new energy automobile production battery current testing device comprises a testing device shell, a control device, a rack, an installation block and a bearing plate, wherein a first sliding block is attached to the testing device shell and is installed on a placing box, a working spring is installed on the placing box, the working spring is installed on the testing device shell, a testing device shell is installed on the control device, a lead is installed on the control device, the rack is installed on the placing box and is connected with a gear, the gear is installed on a rotating shaft, the rotating shaft is connected with the testing device shell, the installation block is installed on the testing device shell, a rotating shaft is installed on the installation block, a pushing wheel is installed on the rotating shaft, the bearing plate and the pushing wheel are attached to each other, a second sliding block is installed on the bearing plate and is attached to the testing device shell, and meanwhile, a limiting device is attached to the second sliding block, the limiting device is attached to the fixed block, the fixed block is installed on the shell of the testing device, and the limiting device is provided with a testing board.

Preferably, the first sliding blocks are symmetrically distributed about the center of the placing box, and the first sliding blocks are in sliding connection with the testing device shell through grooves formed in the testing device shell.

Preferably, the gear and the mounting block form a rotating mechanism through a bearing mounted on the rotating shaft and the mounting block, and the pushing wheel mounted on the rotating shaft is of an eccentric structure.

Preferably, the bearing plate is provided with a through groove, and the inner surface of the groove on the bearing plate is smooth.

Preferably, the limiting device comprises a supporting plate and a functional spring, the supporting plate is mounted on the limiting device, the functional spring is mounted on the supporting plate, and the functional spring is mounted on the supporting plate.

Preferably, the supporting plate is in a shape of a square block with a smooth surface, and the top end of the limiting device connected with the supporting plate is in an inclined shape.

Compared with the prior art, the beneficial effects of the utility model are that: the battery current testing device for the new energy automobile production adopts a linkage structure, after a battery is placed in the placing box, the placing box starts to move downwards, and the pushing wheels rotate under the action of the racks, so that the lead of the battery is conveniently fixed, excessive manual participation is not needed, and the accident rate is effectively reduced;

1. the placing box can be effectively damped through the working spring, so that the placing box is prevented from being greatly collided in the detection process, namely, the battery is prevented from being damaged;

2. drive gear through placing the case and rotate, promote the wheel promptly and begin to rotate to the realization promotes the board of accepting, effectively fixes the wire to the battery, is convenient for follow-up detect the battery through surveying the board.

Drawings

FIG. 1 is a schematic view of the cross-sectional structure of the test device of the present invention;

FIG. 2 is a schematic view of the sectional structure of the rack of the present invention;

FIG. 3 is a schematic view of the cross-sectional structure of the testing device of the present invention;

FIG. 4 is a side view of the pushing wheel of the present invention;

fig. 5 is an enlarged schematic view of a portion a in fig. 3 according to the present invention.

In the figure: 1. a test device housing; 2. a first slider; 3. placing a box; 4. a working spring; 5. a control device; 6. a wire; 7. a rack; 8. a gear; 9. a rotating shaft; 10. mounting blocks; 11. a push wheel; 12. a bearing plate; 13. a second slider; 14. a limiting device; 1401. a support plate; 1402. a functional spring; 15. a fixed block; 16. and (6) testing the board.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a new energy automobile production battery current testing device comprises a testing device shell 1, a first sliding block 2, a placing box 3, a working spring 4, a control device 5, a lead 6, a rack 7, a gear 8, a rotating shaft 9, an installation block 10, a pushing wheel 11, a bearing plate 12, a second sliding block 13, a limiting device 14, a supporting plate 1401, a functional spring 1402, a fixed block 15 and a testing plate 16, wherein the first sliding block 2 is attached to the testing device shell 1, the first sliding block 2 is installed on the placing box 3, the working spring 4 is installed on the testing device shell 1, the testing device shell 1 is installed on the control device 5, the lead 6 is installed on the control device 5, the rack 7 is installed on the placing box 3, the rack 7 is connected with the gear 8, the gear 8 is installed on the rotating shaft 9, and the rotating shaft 9 is connected with the testing device shell 1, installation piece 10 is installed on testing arrangement shell 1, and install axis of rotation 9 on the installation piece 10, and install pushing wheel 11 on the axis of rotation 9, accept board 12 and pushing wheel 11 and laminate each other, and accept and install second slider 13 on the board 12, and second slider 13 and testing arrangement shell 1 laminate each other, laminate stop device 14 on the second slider 13 simultaneously, stop device 14 and fixed block 15 laminate each other, and fixed block 15 installs on testing arrangement shell 1, and stop device 14 is last to install and to survey test panel 16.

In the embodiment, the first sliding blocks 2 are symmetrically distributed about the center of the placing box 3, the first sliding blocks 2 are in sliding connection with the testing device shell 1 through grooves formed in the testing device shell 1, so that the position of the placing box 3 can be changed conveniently through the first sliding blocks 2, and the first sliding blocks 2 are in sliding connection with the testing device shell 1 through grooves formed in the testing device shell 1, so that the limitation on the movement range of the placing box 3 can be realized conveniently;

the gear 8 and the mounting block 10 form a rotating mechanism through a bearing mounted on the rotating shaft 9 and the mounting block 10, a pushing wheel 11 mounted on the rotating shaft 9 is of an eccentric structure, the rotation of the gear 8 is not influenced while the gear 8 is supported, and the pushing wheel 11 mounted on the rotating shaft 9 is of an eccentric structure, so that the bearing plate 12 is pushed conveniently;

the bearing plate 12 is provided with a through groove, the inner surface of the groove formed in the bearing plate 12 is smooth, the bearing plate 12 is provided with a through groove, the limiting device 14 is conveniently placed in the through groove, the inner surface of the groove formed in the bearing plate 12 is smooth, and friction between the bearing plate 12 and the limiting device 14 is conveniently reduced;

the limiting device 14 comprises a supporting plate 1401 and a functional spring 1402, the supporting plate 1401 is installed on the limiting device 14, the functional spring 1402 is installed on the supporting plate 1401, and the functional spring 1402 is installed on the bearing plate 12, so that the movement range of the limiting device 14 is limited conveniently through the structure, and the current of the battery is detected;

the supporting plate 1401 is arranged to be in a square block shape with a smooth surface, the top end of the limiting device 14 connected with the supporting plate 1401 is arranged to be in an inclined shape, the supporting plate 1401 is arranged to be in a square block shape with a smooth surface, the limiting device 14 is convenient to limit, the top end of the limiting device 14 connected with the supporting plate 1401 is arranged to be in an inclined shape, and the supporting plate is convenient to be better attached to the fixing block 15 and moves.

The working principle is as follows: the battery is placed in the placing box 3 in fig. 1, the placing box 3 starts to move downwards under the action of the first sliding blocks 2 arranged at the two ends, the working spring 4 is compressed and deformed along with the downward movement of the placing box 3, because the rack 7 is arranged on the placing box 3 in fig. 2, as the placing box 3 in fig. 3 moves downwards, the gear 8 starts to rotate anticlockwise, because the gear 8 is arranged on the rotating shaft 9, the rotating shaft 9 starts to rotate anticlockwise, when the rotating shaft 9 rotates anticlockwise in fig. 5, the pushing wheel 11 arranged on the rotating shaft 9 starts to rotate anticlockwise, under the supporting and limiting action of the second sliding block 13, the bearing plate 12 starts to move away from the rotating shaft 9, at the moment, the position in fig. 5 is reached, when the bearing plates 12 in fig. 4 move towards the mutually approaching direction, the fixed block 15 starts to press the limiting device 14, namely, the limiting device 14 starts to move downwards, the test plate 16 mounted on the spacing device 14 comes into abutment with the battery lead 6 placed at the lower end and is detected by the control device 5 in fig. 1.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a new energy automobile production is with battery current testing arrangement, includes testing arrangement shell (1), controlling means (5), rack (7), installation piece (10) and accepts board (12), its characterized in that: the testing device is characterized in that a first slider (2) is attached to a testing device shell (1), the first slider (2) is installed on a placing box (3), a working spring (4) is installed on the placing box (3), the working spring (4) is installed on the testing device shell (1) at the same time, the testing device shell (1) is installed on a control device (5), a lead (6) is installed on the control device (5), a rack (7) is installed on the placing box (3), the rack (7) is connected with a gear (8) mutually, the gear (8) is installed on a rotating shaft (9), the rotating shaft (9) is connected with the testing device shell (1) at the same time, an installing block (10) is installed on the testing device shell (1), the rotating shaft (9) is installed on the installing block (10), and a pushing wheel (11) is installed on the rotating shaft (9), bear board (12) and push wheel (11) and laminate each other, and bear and install second slider (13) on board (12) to second slider (13) and testing arrangement shell (1) laminate each other, have closing device (14) on second slider (13) simultaneously, closing device (14) and fixed block (15) laminate each other, and fixed block (15) install on testing arrangement shell (1) to install on closing device (14) and survey test panel (16).

2. The new energy automobile production battery current testing device according to claim 1, characterized in that: the first sliding blocks (2) are symmetrically distributed about the center of the placing box (3), and the first sliding blocks (2) are in sliding connection with the testing device shell (1) through grooves formed in the testing device shell (1).

3. The new energy automobile production battery current testing device according to claim 1, characterized in that: the gear (8) and the mounting block (10) form a rotating mechanism through a bearing arranged on the rotating shaft (9) and the mounting block (10), and a pushing wheel (11) arranged on the rotating shaft (9) is of an eccentric structure.

4. The new energy automobile production battery current testing device according to claim 1, characterized in that: the bearing plate (12) is provided with a through groove, and the inner surface of the groove arranged on the bearing plate (12) is smooth.

5. The new energy automobile production battery current testing device according to claim 1, characterized in that: the limiting device (14) comprises a supporting plate (1401) and a functional spring (1402), the supporting plate (1401) is installed on the limiting device (14), the functional spring (1402) is installed on the supporting plate (1401), and meanwhile the functional spring (1402) is installed on the bearing plate (12).

6. The new energy automobile production battery current testing device according to claim 5, characterized in that: the supporting plate (1401) is arranged to be a square block with a smooth surface, and the top end of a limiting device (14) connected with the supporting plate (1401) is arranged to be inclined.

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