CN217931974U - Battery detection device - Google Patents

Abstract

The utility model discloses a battery detection device, which comprises a feeding device, a detection device, a material moving device and a discharging device; detection device is provided with a plurality of detection positions, move the first material mechanism that moves of material device, the second moves material mechanism and third and moves material mechanism synchronous motion under drive arrangement's drive, in order to shift the battery that loading attachment shifted to a plurality of detection positions in proper order, and shift the battery that will accomplish the detection to unloader, first material mechanism that moves, the second moves material mechanism and third and moves material mechanism synchronous actuation and be favorable to improving the efficiency of shifting the battery, detection device can carry out a lot of detection to the battery under the cooperation that moves the material device, battery detection efficiency is high, be favorable to avoiding artifical manual operation difference that detects the battery and calculate and obtain accurate battery testing result.

Description

Battery detection device

Technical Field

The utility model relates to a battery detection area especially relates to a battery detection equipment.

Background

Generally, the performance of the lithium battery needs to be tested for multiple times to obtain multiple sets of lithium battery performance parameters, the average value of the parameters is used as the test result of the lithium battery, and the performance of the lithium battery is judged by analyzing the test result of the lithium battery. The existing method for obtaining multiple groups of lithium battery performance parameters is to manually detect the battery for multiple times, but the efficiency of manually detecting the battery is low, and the operation of manually detecting the battery at each time has differences, which often results in inaccurate detection results of the battery and incapability of judging the performance of the battery.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a battery test equipment is favorable to obtaining accurate battery testing result and improving the efficiency that the battery detected.

In order to achieve the purpose, the utility model discloses a battery detection device, which comprises a feeding device, a detection device, a material moving device and a discharging device; the feeding device comprises a feeding mechanism and a first conveying mechanism, the feeding mechanism is used for transferring the battery to be tested to the first conveying mechanism, and the first conveying mechanism is used for conveying the battery to be tested; the detection device is sequentially provided with a plurality of detection positions and is used for detecting the battery to be detected placed at the detection positions; the material moving device comprises a first material moving mechanism, at least one second material moving mechanism, a third material moving mechanism and at least one driving device which are sequentially arranged, the driving device is used for driving the first material moving mechanism, the second material moving mechanism and the third material moving mechanism to synchronously move, the first material moving mechanism is used for transferring a battery to be detected on the first conveying mechanism to the initial detection position, the second material moving mechanism is used for transferring the battery to be detected which is detected on the previous detection position to the next detection position, and the third material moving mechanism is used for transferring the battery which is detected on the last detection position; the blanking device is used for receiving the battery which is transferred by the third material transferring mechanism and completes detection.

The utility model discloses a detection device detects the battery in order to acquire multiunit battery performance parameter with the cooperation that moves the material device, detection device is provided with a plurality of detection positions, move the first material mechanism that moves that the material device set gradually, the second moves material mechanism and the third moves material mechanism synchronous motion under drive arrangement's drive, in order to shift the battery that the loading attachment shifted to a plurality of detection positions in proper order, and shift the battery that will accomplish the detection to unloader, first material mechanism that moves, the second moves material mechanism and the third moves the efficiency that material mechanism actuates in step and is favorable to improving the transfer battery, detection device can carry out a lot of detection to the battery under the cooperation that moves the material device, battery detection efficiency is high, be favorable to avoiding the operation difference of artifical manual detection battery and calculate and obtain accurate battery test result.

Optionally, the feeding device further includes a shift driving mechanism, the first conveying mechanism is installed at an output end of the shift driving mechanism, a plurality of limiting parts are arranged on the first conveying mechanism at intervals, the limiting parts extend along a conveying direction of the first conveying mechanism, a conveying channel is formed between two adjacent limiting parts, and the shift driving mechanism is used for driving the first conveying mechanism to move so that one of the batteries to be tested conveyed on the conveying channel corresponds to the first material moving mechanism.

Optionally, feed mechanism includes material loading support, horizontal actuating mechanism, vertical actuating mechanism and one at least gets the material subassembly, horizontal actuating mechanism installs the material loading support, vertical actuating mechanism installs horizontal actuating mechanism's output, vertical actuating mechanism installs vertical actuating mechanism's output, it installs to get the material subassembly vertical actuating mechanism's output, it is used for picking up the battery that awaits measuring to get the material subassembly, it is in to get the material subassembly horizontal actuating mechanism vertical actuating mechanism with the battery that awaits measuring that will pick up shifts under vertical actuating mechanism's the drive.

Optionally, get the material subassembly and include the clamping jaw driver and install first clamping jaw and the second clamping jaw of the output of centre gripping driver, the clamping jaw driver is used for the drive first clamping jaw with the second clamping jaw removes in opposite directions is in order to the centre gripping battery that awaits measuring.

Optionally, the driving device includes a driving support frame, a lateral moving driving mechanism and a vertical moving driving mechanism, the lateral moving driving mechanism is installed on the driving support frame, the vertical moving driving mechanism is installed at an output end of the lateral moving driving mechanism, the first material moving mechanism, the second material moving mechanism and the third material moving mechanism are vacuum material absorbers and are installed at an output end of the vertical moving driving mechanism, and the first material moving mechanism, the second material moving mechanism and the third material moving mechanism are used for absorbing corresponding batteries and synchronously moving under the driving of the lateral moving driving mechanism and the vertical moving driving mechanism to transfer the absorbed batteries.

Optionally, the detection device includes a supporting table and a plurality of detectors, the detectors include two detection probes, the detection position is set up on the supporting table, two the detection probes are with place anodal and the negative pole electric connection of the battery that awaits measuring on the detection position, the detection probes are used for detecting the performance parameter of the battery that awaits measuring.

Optionally, the detection device is provided with a pressing mechanism corresponding to the detection position, and when the detection device detects the battery to be detected, the pressing mechanism is used for pressing and fixing the battery to be detected on the detection position.

Optionally, the pressing mechanism includes a pressing bracket, two pressing slide rails and a vertical driver mounted on the pressing bracket, two pressing sliders and two pressing pieces respectively mounted on the pressing sliders, the two pressing slide rails are arranged in a V shape, and the two pressing sliders are respectively slidably disposed on the two pressing slide rails; the inner sides of the two pressing sliding blocks are provided with boosting inclined planes which are arranged in an inverted V shape, and the output end of the vertical driver is connected with a pushing block positioned between the boosting inclined planes on the two sides; when the vertical driver drives the pushing block upwards, the pushing block pushes the two boosting inclined planes, the two pressing sliding blocks slide outwards and upwards to drive the two pressing pieces to be far away from the pressed battery under the constraint of the two pressing slide rails, and when the vertical driver drives the pushing block downwards, the two pressing sliding blocks slide inwards and downwards under the action of self gravity to drive the two pressing pieces to press the battery to be tested.

Optionally, the blanking device includes a second conveying mechanism, the second conveying mechanism is used for receiving and conveying the battery that the third material moving mechanism transferred, the first conveying mechanism with the second conveying mechanism includes respectively conveying actuating mechanism, and drive roll, driving roller that with conveying actuating mechanism's output is connected and around locating the drive roll with conveyer belt between the driving roller, the conveyer belt is in circulation transmission under conveying actuating mechanism's the drive.

Optionally, the blanking device is provided with a counting sensor, and the counting sensor is used for sensing the batteries received by the blanking device so as to count the number of the batteries.

Drawings

Fig. 1 is a three-dimensional structure diagram of the battery detection device according to the embodiment of the present invention.

Fig. 2 is a perspective view of the first conveying mechanism and the displacement driving mechanism according to the embodiment of the present invention.

Fig. 3 is a three-dimensional structure diagram of the feeding mechanism in the embodiment of the present invention.

Fig. 4 is a three-dimensional structure diagram of the material moving device in the embodiment of the present invention.

Fig. 5 is a perspective view of the embodiment of the present invention after a part of the pressing mechanism is hidden in the detecting device.

Fig. 6 is a perspective structural view of the pressing mechanism in the embodiment of the present invention.

Fig. 7 is a perspective view of a second transfer mechanism according to an embodiment of the present invention.

Detailed Description

In order to explain technical contents, structural features, and objects and effects of the present invention in detail, the following description is given in conjunction with the embodiments and the accompanying drawings.

Referring to fig. 1 to 7, the present invention discloses a battery testing apparatus, which includes a feeding device 1, a testing device 2, a moving device 3 and a discharging device 4; the feeding device 1 comprises a feeding mechanism 11 and a first conveying mechanism 12, wherein the feeding mechanism 11 is used for transferring the battery 10 to be tested to the first conveying mechanism 12, and the first conveying mechanism 12 is used for conveying the battery 10 to be tested; the detection device 2 is sequentially provided with a plurality of detection positions 20, and the detection device 2 is used for detecting the battery 10 to be detected placed at the detection positions 20; the material moving device 3 comprises a first material moving mechanism 31, at least one second material moving mechanism 32, a third material moving mechanism 33 and at least one driving device 34 which are sequentially arranged, wherein the driving device 34 is used for driving the first material moving mechanism 31, the second material moving mechanism 32 and the third material moving mechanism 33 to synchronously move, the first material moving mechanism 31 is used for transferring the battery 10 to be detected on the first conveying mechanism 12 to the initial detection position 20, the second material moving mechanism 32 is used for transferring the battery 10 to be detected on the previous detection position 20 to the next detection position 20, and the third material moving mechanism 33 is used for transferring the battery 10 to be detected on the last detection position 20; the blanking device 4 is used for receiving the detected batteries 10 transferred by the third material transferring mechanism 33.

The utility model discloses a detection device 2 and the cooperation that moves material device 3 detect battery 10 in order to acquire multiunit battery 10 performance parameter, detection device 2 is provided with a plurality of detection position 20, move the first material mechanism 31 that moves that material device 3 set gradually, the second moves material mechanism 32 and the third moves material mechanism 33 synchronous motion under drive arrangement 34's drive, in order to shift battery 10 that loading attachment 1 shifted to a plurality of detection position 20 in proper order, and the battery 10 that will accomplish the detection shifts unloader 4, first material mechanism 31 that moves, the second moves material mechanism 32 and the third moves material mechanism 33 synchronous motion and is favorable to improving the efficiency that shifts battery 10, detection device 2 can carry out a lot of detections to battery 10 under the cooperation that moves material device 3, battery 10 detection efficiency is high, be favorable to avoiding artifical manual detection battery 10's operation difference and calculate and obtain accurate battery 10 testing result.

Referring to fig. 1 and fig. 2, the feeding device 1 further includes a displacement driving mechanism 13, a first conveying mechanism 12 is installed at an output end of the displacement driving mechanism 13, a plurality of limiting members 121 are arranged on the first conveying mechanism 12 at intervals, the limiting members 121 extend along a conveying direction of the first conveying mechanism 12, a conveying channel 122 is formed between two adjacent limiting members 121, and the displacement driving mechanism 13 is configured to drive the first conveying mechanism 12 to move so that the battery 10 to be tested conveyed on one conveying channel 122 corresponds to the first material moving mechanism 31, which is beneficial to matching between the first conveying mechanism 12 and the first material moving mechanism 31.

Specifically, in the present embodiment, the displacement driving mechanism 13 includes a displacement support frame 131, a longitudinal displacement driving mechanism 132 disposed on the displacement support frame 131, a displacement slide rail 133 extending along the longitudinal direction, and a longitudinal displacement connecting member 134, the first conveying mechanism 12 is slidably disposed on the displacement slide rail 133 and is connected to the longitudinal displacement driving mechanism 132 through the longitudinal displacement connecting member 134, the longitudinal displacement driving mechanism 132 is configured to drive the first conveying mechanism 12 to move longitudinally along the displacement slide rail 133, wherein the longitudinal displacement driving mechanism 132 may be a conventional belt driving mechanism, but is not limited thereto.

Referring to fig. 1 and 3, the feeding mechanism 11 includes a feeding bracket 111, a transverse driving mechanism 112, a longitudinal driving mechanism 113, a vertical driving mechanism 114, and at least one material taking assembly 115, the transverse driving mechanism 112 is installed on the feeding bracket 111, the longitudinal driving mechanism 113 is installed at an output end of the transverse driving mechanism 112, the vertical driving mechanism 114 is installed at an output end of the longitudinal driving mechanism 113, the material taking assembly 115 is installed at an output end of the vertical driving mechanism 114, the material taking assembly 115 is used for picking up a battery 10 to be tested, and the material taking assembly 115 transfers the picked battery 10 to be tested under the driving of the transverse driving mechanism 112, the longitudinal driving mechanism 113, and the vertical driving mechanism 114. Above-mentioned feed mechanism 11's degree of automation is high, can be automatically with the battery 10 material loading to first transport mechanism 12 that awaits measuring, is favorable to saving manufacturing cost and human cost.

Specifically, in the present embodiment, the lateral driving mechanism 112 and the vertical driving mechanism 114 are driving cylinders, but are not limited thereto. The longitudinal driving mechanism 113 includes a longitudinal support 1131 installed at the output end of the transverse driving mechanism 112, a longitudinal sliding rail 1132 and a longitudinal transmission mechanism 1133 installed on the longitudinal support 1131, and a longitudinal moving member 1134 slidably disposed on the longitudinal sliding rail 1132, the vertical driving mechanism 114 is installed on the longitudinal moving member 1134, and the longitudinal moving member 1134 moves along the longitudinal sliding rail 1132 under the driving of the longitudinal transmission mechanism 1133, wherein the longitudinal transmission mechanism 1133 may be a conventional belt transmission mechanism, but is not limited thereto.

Referring to fig. 3, the material taking assembly 115 includes a jaw driver 1151, and a first jaw 1152 and a second jaw 1153 mounted at an output end of the jaw driver 1151, wherein the jaw driver 1151 is used for driving the first jaw 1152 and the second jaw 1153 to move towards each other to clamp the battery 10 to be tested, but not limited thereto, for example, the material taking assembly 115 may also be a vacuum suction device.

Referring to fig. 1 and 4, the driving device 34 includes a driving support frame 341, a traverse driving mechanism 342, and a vertical moving driving mechanism 343, the traverse driving mechanism 342 is installed on the driving support frame 341, the vertical moving driving mechanism 343 is installed at an output end of the traverse driving mechanism 342, the first material moving mechanism 31, the second material moving mechanism 32, and the third material moving mechanism 33 are vacuum material absorbers and are installed at an output end of the vertical moving driving mechanism 343, the first material moving mechanism 31, the second material moving mechanism 32, and the third material moving mechanism 33 are used for absorbing corresponding batteries 10 and synchronously moving under driving of the traverse driving mechanism 342 and the vertical moving driving mechanism 343 to transfer the absorbed batteries 10, so as to realize automatic transfer of the batteries 10 to be tested to different testing positions 20 in sequence for testing, which is beneficial to avoid manual testing of operating differences of the batteries 10.

In the present embodiment, the material moving device 3 is provided with one driving device 34, but is not limited thereto, for example, the material moving device 3 may also be provided with a plurality of driving devices 34, and the plurality of driving devices 34 are respectively connected with the first material moving mechanism 31, the second material moving mechanism 32 and the third material moving mechanism 33 and drive the first material moving mechanism 31, the second material moving mechanism 32 and the third material moving mechanism 33 to move synchronously.

Specifically, the traverse driving mechanism 342 includes a traverse driver 3421 and a traverse slider 3422, the traverse driver 3421 is used for driving the traverse slider 3422 to move transversely, the vertical driving mechanism 343 includes a vertical driver 3431, a vertical slide rail 3432 and a vertical slide block 3433, the vertical slide block 3433 is slidably disposed on the vertical slide rail 3432 and connected to the output end of the vertical driver 3431, the vertical driver 3431 is used for driving the vertical slide block 3433 to slide along the vertical slide rail 3432, the traverse driver 3421 is a sliding table cylinder, and the vertical driver 3431 is a biaxial cylinder, but is not limited thereto.

Referring to fig. 1 and 5, the detecting device 2 includes a supporting platform 211 and a plurality of detectors 212, the detectors 212 include two detecting probes 2121, the detecting positions 20 are disposed on the supporting platform 211, the detecting probes 2121 are electrically connected to the positive electrode 101 and the negative electrode 102 of the battery 10 to be detected placed on the detecting positions 20, and the detecting probes 2121 are used for detecting performance parameters of the battery 10 to be detected. The detection probes 2121 located at different detection positions 20 detect the batteries 10 for multiple times to obtain multiple sets of performance parameters of the batteries 10, so that the operation difference of manually detecting the batteries 10 can be avoided, and an accurate detection result can be obtained.

Specifically, the detecting device 2 further comprises a data processor (not shown), the detector 212 further comprises a data transmission line 2122, and the detecting probe 2121 is connected to the data processor through the data transmission line 2122. The positive electrode 101 and the negative electrode 102 of the battery 10 are copper sheets, and the sensing probe 2121 is pressed down to the positive electrode 101 and the negative electrode 102 of the battery 10 to sense the battery 10, and then transmits the sensed performance parameters of the battery 10 to the data processor through the data transmission line 2122.

Specifically, in the present embodiment, the detection device 2 is provided with three detection positions 20 and three corresponding detectors 212, but is not limited thereto, the material moving device 3 is provided with two second material moving mechanisms 32, the detection device 2 can perform three detections on the battery 10 to obtain three sets of performance parameters of the battery 10 under the cooperation of the first material moving mechanism 31 and the two second material moving mechanisms 32, the performance parameters of the battery 10 include data such as voltage and internal resistance, the data processor can perform identification and judgment on the three sets of parameters and calculate an average value of the three sets of parameters to obtain a detection result of the battery 10, the detection result of the battery 10 can be displayed by the display 5, and a tester can determine the performance of the battery 10 according to the detection result.

Referring to fig. 1, 5 and 6, the detecting device 2 is provided with a pressing mechanism 22 corresponding to the detecting position 20, and when the detecting device 2 detects the battery 10 to be detected, the pressing mechanism 22 is used for pressing and fixing the battery 10 to be detected on the detecting position 20, which is beneficial for stable connection between the detecting probe 2121 and the battery 10 to be detected, so as to obtain accurate performance parameters of the battery 10.

Referring to fig. 5 and 6, the pressing mechanism 22 includes a pressing bracket 221, two pressing rails 222 and a vertical driver 223 mounted on the pressing bracket 221, two pressing sliders 224, and two pressing pieces 225 respectively mounted on the pressing sliders 224, wherein the two pressing rails 222 are arranged in a V shape, and the two pressing sliders 224 are respectively slidably disposed on the two pressing rails 222; the inner sides of the two pressing sliding blocks 224 are provided with boosting inclined planes 2241 which are arranged in an inverted V shape, and the output end of the vertical driver 223 is connected with a pushing block 2231 which is positioned between the boosting inclined planes 2241 on the two sides; when the vertical driver 223 drives the pushing block 2231 upwards, the pushing block 2231 pushes the two boosting inclined planes 2241, and under the constraint of the two pressing slide rails 222, the two pressing slide blocks 224 slide outwards and upwards to drive the two pressing pieces 225 to get away from the pressed battery 10, so that the material moving device 3 can pick up the battery 10 at the detection position 20; when the vertical driver 223 drives the pushing block 2231 downwards, the two pressing sliders 224 slide inwards and downwards under the action of self gravity to drive the two pressing pieces 225 to press the battery 10 to be tested, which is beneficial to avoiding the deviation of the battery 10 to be tested during testing.

Referring to fig. 1, 2, and 7, the discharging device 4 includes a second conveying mechanism 41, the second conveying mechanism 41 is configured to receive and convey the battery 10 transferred by the third material transferring mechanism 33, the first conveying mechanism 12 and the second conveying mechanism 41 respectively include a conveying driving mechanism 201, a driving roller 202 connected to an output end of the conveying driving mechanism 201, a driving roller 203, and a conveying belt 204 wound between the driving roller 202 and the driving roller 203, and the conveying belt 204 is driven by the conveying driving mechanism 201 to perform circular transmission, which is beneficial to realizing automatic charging and discharging of the battery 10.

Specifically, in the present embodiment, the conveyance drive mechanism 201 is a rotary drive motor, but is not limited thereto. Wherein the rotary driving motor of the first conveying mechanism 12 is in transmission connection with the driving roller 202 of the first conveying mechanism 12 through a transmission belt 205, and the driving roller 202 of the second conveying mechanism 41 is arranged at the output end of the rotary driving motor of the second conveying mechanism 41.

Specifically, the blanking device 4 further includes a placing table 42, and the placing table 42 is disposed at one end of the second conveying mechanism 41 away from the material moving device 3 to receive the detected battery 10 conveyed by the second conveying mechanism 41.

Referring to fig. 1 and 7, the discharging device 4 is provided with a counting sensor 43, and the counting sensor 43 is used for sensing the batteries 10 conveyed by the discharging device 4 to count the number of the batteries 10.

Specifically, in the present embodiment, the counting sensor 43 is an infrared counter, but is not limited thereto. The counting sensor 43 is disposed at one side of the second transfer mechanism 41, and when the counting sensor 43 senses the battery 10, it sends sensing information to the data processor, and the data processor records the number of the batteries 10 according to the sensing information.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the invention, therefore, the invention is not limited thereto.

Claims (10)

1. A battery test apparatus, comprising:

the feeding device comprises a feeding mechanism and a first conveying mechanism, the feeding mechanism is used for transferring the battery to be tested to the first conveying mechanism, and the first conveying mechanism is used for conveying the battery to be tested;

the detection device is sequentially provided with a plurality of detection positions and is used for detecting the battery to be detected placed at the detection positions;

the material moving device comprises a first material moving mechanism, at least one second material moving mechanism, a third material moving mechanism and at least one driving device which are sequentially arranged, the driving device is used for driving the first material moving mechanism, the second material moving mechanism and the third material moving mechanism to synchronously move, the first material moving mechanism is used for transferring a battery to be detected on the first conveying mechanism to the initial detection position, the second material moving mechanism is used for transferring the battery to be detected which is detected at the previous detection position to the next detection position, and the third material moving mechanism is used for transferring the battery which is detected at the last detection position;

and the blanking device is used for receiving the battery which is transferred by the third material moving mechanism and completes detection.

2. The battery detection apparatus according to claim 1, wherein the feeding device further includes a shift driving mechanism, the first conveying mechanism is installed at an output end of the shift driving mechanism, a plurality of limiting members are disposed at intervals on the first conveying mechanism, the limiting members extend along a conveying direction of the first conveying mechanism, a conveying channel is formed between two adjacent limiting members, and the shift driving mechanism is configured to drive the first conveying mechanism to move so that a battery to be detected conveyed on one of the conveying channels corresponds to the first material moving mechanism.

3. The battery detection apparatus according to claim 1, wherein the feeding mechanism includes a feeding bracket, a transverse driving mechanism, a longitudinal driving mechanism, a vertical driving mechanism, and at least one material taking assembly, the transverse driving mechanism is installed on the feeding bracket, the longitudinal driving mechanism is installed at an output end of the transverse driving mechanism, the vertical driving mechanism is installed at an output end of the longitudinal driving mechanism, the material taking assembly is installed at an output end of the vertical driving mechanism, the material taking assembly is used for picking up a battery to be detected, and the material taking assembly is driven by the transverse driving mechanism, the longitudinal driving mechanism, and the vertical driving mechanism to transfer the picked battery to be detected.

4. The battery testing apparatus of claim 3, wherein the reclaiming assembly comprises a jaw driver and a first jaw and a second jaw mounted at an output end of the jaw driver, and the jaw driver is configured to drive the first jaw and the second jaw to move toward each other to clamp the battery to be tested.

5. The battery detection apparatus according to claim 1, wherein the driving device comprises a driving support frame, a lateral moving driving mechanism and a vertical moving driving mechanism, the lateral moving driving mechanism is mounted on the driving support frame, the vertical moving driving mechanism is mounted at an output end of the lateral moving driving mechanism, the first material moving mechanism, the second material moving mechanism and the third material moving mechanism are vacuum material absorbers and are mounted at an output end of the vertical moving driving mechanism, and the first material moving mechanism, the second material moving mechanism and the third material moving mechanism are used for absorbing corresponding batteries and synchronously moving under the driving of the lateral moving driving mechanism and the vertical moving driving mechanism to transfer the absorbed batteries.

6. The battery testing apparatus according to claim 1, wherein said testing device comprises a support platform and a plurality of testing devices, said testing devices comprise two testing probes, said testing locations are disposed on said support platform, said two testing probes are electrically connected to the positive and negative electrodes of the battery to be tested placed on said testing locations, said testing probes are used for testing the performance parameters of the battery to be tested.

7. The battery detection apparatus according to claim 1, wherein the detection device is provided with a pressing mechanism corresponding to the detection position, and the pressing mechanism is configured to press and fix the battery to be detected at the detection position when the detection device detects the battery to be detected.

8. The battery detection device according to claim 7, wherein the pressing mechanism comprises a pressing bracket, two pressing slide rails and a vertical driver which are mounted on the pressing bracket, two pressing sliders which are arranged in a V-shape, and two pressing pieces which are respectively mounted on the pressing sliders, and the two pressing slide rails are respectively slidably mounted on the two pressing slide rails;

boosting inclined planes which are arranged in an inverted V shape are formed on the inner sides of the two pressing sliding blocks, and the output end of the vertical driver is connected with a pushing block which is positioned between the boosting inclined planes on the two sides; when the vertical driver drives the pushing block upwards, the pushing block pushes the two boosting inclined planes, the two pressing sliding blocks slide outwards and upwards to drive the two pressing pieces to be far away from the pressed battery under the constraint of the two pressing slide rails, and when the vertical driver drives the pushing block downwards, the two pressing sliding blocks slide inwards and downwards under the action of self gravity to drive the two pressing pieces to press the battery to be tested.

9. The battery detection device according to claim 1, wherein the blanking device comprises a second conveying mechanism, the second conveying mechanism is used for receiving and conveying the battery transferred by the third material moving mechanism, the first conveying mechanism and the second conveying mechanism respectively comprise a conveying driving mechanism, a driving roller connected with an output end of the conveying driving mechanism, a driving roller and a conveying belt wound between the driving roller and the driving roller, and the conveying belt is driven by the conveying driving mechanism to perform circular transmission.

10. The battery detection apparatus according to claim 1, wherein the blanking device is provided with a counting sensor for sensing the battery received by the blanking device to count the number of the batteries.

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