CN117740282A - Shockproof battery performance detection device - Google Patents

Abstract

The utility model discloses a vibration-proof battery performance detection device, which relates to the technical field of battery detection and comprises a feeding component used for conveying batteries and placing the batteries on a moving component, wherein the feeding component is used for conveying batteries with different specifications, a detection component used for reducing the working environment of the batteries is arranged on the side edge of the feeding component, the working state of the batteries in a wet and high-temperature environment is detected by the detection component, the moving component is arranged on the detection component in a sliding manner, the moving component drives the batteries to move in the detection component to enter different environment simulation areas, and meanwhile, the moving component drives the batteries to vibrate so as to reduce the real working environment of the batteries, and the detection precision of the battery performance is improved.

Description

Shockproof battery performance detection device

Technical Field

The utility model relates to the technical field of battery detection, in particular to a shockproof battery performance detection device.

Background

The battery of the new energy automobile is an important component of the vehicle, the safety is critical, and the vibration-proof detection can ensure that the battery can resist vibration and impact on a road in the running process of the vehicle, so that the problem that parts inside the battery are loosened, broken or damaged due to vibration is avoided, potential safety hazards are reduced, and if the battery cannot bear the challenges, the battery can be failed or performance of the battery is reduced.

The Chinese patent publication No. CN212160029U discloses a new energy automobile battery shockproof performance detection device, which detects the vibration intensity born by a storage battery through an electromagnetic vibrator, improves the measurement accuracy, and cannot restore the working state of the battery in a humid environment and a high-temperature environment when the device is used for vibration detection of the battery, so that the detection result of the battery is inaccurate.

Disclosure of Invention

In view of the above problems, the present utility model provides a vibration-proof battery performance detecting device.

Aiming at the technical problems, the utility model adopts the following technical scheme: the utility model provides a battery performance detection device takes precautions against earthquakes, includes feeding subassembly, feeding subassembly include support and base, the support on be provided with fixture, the base on be provided with the battery, the base side be provided with movable assembly and detection component, fixture place the battery on movable assembly, movable assembly include the carriage, the carriage on be provided with swing mechanism, swing mechanism carry out the centre gripping to the battery, swing mechanism in be provided with spacing post one and vibrations board, vibrations board drive battery vibrations, detection component include the detection case, the detection case on be provided with the support column, carriage and support column sliding connection, detection case lower extreme be provided with spacing recess, spacing post one with spacing recess sliding connection, the detection case in set up spacing post two, sliding block, heating mechanism and spray mechanism, spray mechanism simulate battery moist operational environment, heating mechanism simulate battery high temperature operational environment.

Further, the clamping mechanism comprises a sliding plate which is slidably mounted on the support, a rotating disc is rotatably arranged on the sliding plate, a lifting frame is slidably arranged on the rotating disc, two groups of first clamping plates are slidably arranged on the lifting frame, and the first clamping plates clamp the battery.

Further, the carriage both sides be provided with a set of wave board and stopper respectively, stopper and carriage sliding connection, be provided with the spring III between stopper and the carriage.

Further, the swing mechanism comprises a swing ring which is slidably mounted on the sliding frame, the first limiting column is mounted at the lower end of the swing ring, the upper end of the swing ring is slidably provided with a lifting block, the lifting block is slidably provided with two groups of second clamping plates, and the second clamping plates clamp the battery.

Further, the vibration plate is slidably mounted on the lifting block, a first spring is arranged between the vibration plate and the lifting block, a cam is rotationally arranged in the lifting block, and the cam drives the vibration plate to slide on the lifting block.

Further, the detection box on be provided with hydraulic pressure cavity, spacing post two and sliding block all install in hydraulic pressure cavity, when spacing post two and sliding block one of them were extruded, another then follow detection incasement slip.

Further, the spraying mechanism comprises a swing frame which is slidably arranged in the detection box, a spring IV is arranged between the swing frame and the detection box, and swing columns and a plurality of groups of spraying heads are arranged on the swing frame.

Further, the heating mechanism comprises a moving block which is slidably mounted on the detection box, a second spring is arranged between the moving block and the detection box, an adjusting mechanism is arranged on the moving block, and the position of the drying head is adjusted by the adjusting mechanism.

Further, adjustment mechanism include the motor one of installing on the movable block, be provided with bevel gear one on the output shaft of motor one, the movable block on rotate and be provided with the rotating turret, the rotating turret rotate with the output shaft of motor one and be connected, the rotating turret on rotate and be provided with the stoving head, be provided with bevel gear two in the axis of rotation of stoving head, bevel gear one and bevel gear two meshing.

Compared with the prior art, the utility model has the beneficial effects that: (1) According to the utility model, the battery is automatically fed through the feeding assembly, so that the feeding speed is ensured, the detection efficiency of the battery feeding device is improved, and meanwhile, the feeding assembly can clamp batteries with various sizes; (2) According to the utility model, the battery is clamped through the moving assembly, the battery is driven to vibrate, the real working environment of the battery is restored, the detection precision of the battery is improved, the moving assembly drives the battery to move in the detecting assembly, and the detection consistency of the battery is improved; (3) The detection assembly provided by the utility model is used for restoring various different working environments of the battery, the wet environment and the high-temperature environment are both related, the spray header is driven by the moving assembly to flap at multiple angles, the drying head and the battery to be detected synchronously move, and the heating efficiency is ensured.

Drawings

Fig. 1 is a left side view of the overall structure of the present utility model.

Fig. 2 is a schematic diagram of the overall structure of the present utility model.

FIG. 3 is a schematic view of the feed assembly of the present utility model.

Fig. 4 is a cross-sectional view of the feed assembly of the present utility model.

FIG. 5 is a schematic diagram of a moving assembly according to the present utility model.

Fig. 6 is a cross-sectional view of a mobile assembly structure according to the present utility model.

FIG. 7 is a schematic view of a part of the structure of the moving assembly of the present utility model.

Fig. 8 is an enlarged schematic view of the structure a in fig. 7.

Fig. 9 is a front view of the structure of the detecting assembly of the present utility model.

Fig. 10 is a cross-sectional view of the structure in the direction A-A of fig. 9.

FIG. 11 is a schematic view of the mounting position of the moving block according to the present utility model.

Fig. 12 is a schematic view of the swing frame structure of the present utility model.

Reference numerals: 1-a feed assembly; 2-a moving assembly; 3-a detection assembly; 101-a bracket; 102-a base; 103-a conveyor belt; 104-a battery; 105-sliding plate; 106-rotating a disc; 107-lifting frames; 108-clamping plate I; 201-swinging ring; 202-a carriage; 203-a first limit column; 204-wave plates; 205-clamping plate two; 206-lifting blocks; 207-vibrating plate; 208-spring one; 209-cam; 210-limiting blocks; 211-pressing surface one; 212-pressing surface II; 213—pressing face three; 301-a detection box; 302-supporting columns; 303-a moving block; 304-a sprinkler; 305, drying the head; 306-swinging rack; 307-spring two; 308-limiting a second column; 309-a slider; 310-limit grooves; 311-swinging columns; 312-motor one; 313-bevel gear one; 314-bevel gear II; 315-turret.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

Referring to fig. 1 to 12, a vibration-proof battery performance detecting device includes a feeding assembly 1 for conveying a battery 104 and placing the battery 104 on a moving assembly 2, a detecting assembly 3 for reducing the working environment of the battery 104 is disposed at the side of the feeding assembly 1, the moving assembly 2 is slidably disposed in the detecting assembly 3, and the moving assembly 2 drives the battery 104 to move and vibrate the battery 104.

The feeding assembly 1 comprises a bracket 101 and a base 102, wherein a conveying belt 103 is arranged on the base 102, the conveying belt 103 is used for conveying a battery 104, a sliding plate 105 is arranged on the bracket 101 in a sliding mode, the sliding plate 105 slides on the bracket 101 through a linear motor, a rotating disc 106 is arranged on the sliding plate 105 in a rotating mode, a lifting frame 107 is arranged on the rotating disc 106 in a sliding mode, a lifting frame 107 slides on the rotating disc 106 through a linear motor, two groups of clamping plates I108 are arranged on the lifting frame 107 in a sliding mode, when the two groups of clamping plates I108 are close to each other, the battery 104 is clamped, when the battery 104 is required to be clamped, a linear motor on the lifting frame 107 is started, the lifting frame 107 drives the two groups of clamping plates I108 to descend to be aligned with the battery 104, then the two groups of clamping plates I108 are driven to be close to each other, the battery 104 is clamped by the two groups of clamping plates I108, then the rotating disc 106 is reset, meanwhile, the linear motor on the sliding plate 105 slides on the bracket 101, the rotating disc 106 is driven to rotate on the sliding plate 105, the lifting disc 106 drives the lifting frame 107 to rotate with the clamping plates I108, when the battery 104 is required to be clamped, and the positions of the battery 104 are required to be clamped, and the battery 104 cannot move in different specifications, and the assembly 2 cannot move.

The moving assembly 2 comprises a sliding frame 202, a swing ring 201 is arranged on the sliding frame 202 in a sliding manner, a wave plate 204 and a limiting block 210 are respectively arranged on two sides of the sliding frame 202, a first limiting column 203 is arranged at the lower end of the swing ring 201, a lifting block 206 is arranged on the upper end of the swing ring 201 in a sliding manner, the lifting block 206 slides on the swing ring 201 through a linear motor, a vibration plate 207 and two groups of clamping plates 205 are arranged on the lifting block 206 in a sliding manner, when the two groups of clamping plates 205 are close to each other, a battery 104 is clamped, a first spring 208 is arranged between the vibration plate 207 and the lifting block 206, a cam 209 is arranged in the lifting block 206 in a rotating manner, the vibration plate 207 is driven to slide back and forth in the lifting block 206 when the cam 209 rotates, a first pressing surface 211, a second pressing surface 212 and a third pressing surface 213 are arranged on the limiting block 210, and a second spring is arranged between the limiting block 210 and the swing ring 201.

The detection assembly 3 comprises a detection box 301, a support column 302 is arranged on the detection box 301, the sliding frame 202 slides on the support column 302, a limit groove 310 is arranged at the lower end of the detection box 301, a first limit column 203 slides in the limit groove 310, a hydraulic chamber is arranged on the detection box 301, a second limit column 308 and a sliding block 309 are arranged in the hydraulic chamber in a sliding manner, when one of the second limit column 308 and the sliding block 309 is extruded, the other one slides out of the detection box 301, the extending length of the sliding block 309 is the same as the width of the first pressing surface 211, the sliding block 309 does not contact the second pressing surface 212 with the third pressing surface 213, when the sliding block 309 contacts the first pressing surface 211, the sliding block 309 presses the limiting block 210 to retract into the sliding frame 202, the upper end of the detection box 301 is slidably provided with a moving block 303 and a plurality of groups of swinging frames 306, a second spring 307 is arranged between the moving block 303 and the detection box 301, a fourth spring is arranged between the swinging frames 306 and the detection box 301, swinging columns 311 and a plurality of groups of spray heads 304 are arranged at the lower end of the swinging frames 306, the wave plate 204 extrudes the plurality of groups of swinging columns 311, the swinging columns 311 drive the swinging frames 306 to swing on the detection box 301, a first motor 312 is arranged on the moving block 303, a first bevel gear 313 is arranged on an output shaft of the first motor 312, a rotating frame 315 is rotatably arranged on the moving block 303, the rotating frame 315 is rotatably connected with an output shaft of the first motor 312, a drying head 305 is rotatably arranged on the rotating shaft of the drying head 305, a second bevel gear 314 is arranged on the rotating shaft of the drying head 305, and the first bevel gear 313 is meshed with the second bevel gear 314.

Working principle: when the battery 104 is placed on the conveyor belt 103 in operation, the conveyor belt 103 is started to drive the battery 104 to move, the linear motor on the lifting frame 107 is started, the lifting frame 107 drives the two groups of clamping plates I108 to descend to be aligned with the battery 104, then the two groups of clamping plates I108 are driven to be close to each other, the two groups of clamping plates I108 clamp the battery 104, then the rotating disc 106 is reset, meanwhile, the linear motor on the sliding plate 105 is driven, the sliding plate 105 slides on the bracket 101, the rotating disc 106 is driven to rotate on the sliding plate 105, the rotating disc 106 drives the lifting frame 107 and the clamping plates I108 to rotate, the position of the battery 104 is changed, the battery 104 is placed between the two groups of clamping plates II 205, then the two groups of clamping plates II 205 are started to be close to each other, and the clamping plates II 205 clamp the battery 104.

When the battery 104 is detected, the linear motor on the lifting block 206 is started, the lifting block 206 drives the battery 104 to descend into the swinging ring 201, the driving cam 209 rotates, the cam 209 drives the vibration plate 207 to reciprocate on the lifting block 206, the vibration plate 207 drives the battery to vibrate, the linear motor on the sliding frame 202 is started, the sliding frame 202 slides in the swinging ring 201, the first limit post 203 slides in the limit groove 310, the limit groove 310 drives the detection box 301 to swing left and right, after the wave plate 204 enters the detection box 301, the wave plate 204 pushes the swing post 311 to move, the swing post 311 drives the swing frame 306 to slide in the detection box 301, the spraying range of the spraying head 304 is improved, when the sliding frame 202 moves to the moving block 303, the second pressing surface 212 contacts with the moving block 303, the moving block 303 is pushed by the second pressing surface 212, the moving block 303 slides on the detection box 301, the second spring 307 is simultaneously driven by the moving block 303, the drying head 305 slides on the battery 104, the first limit post 202 does not contact with the sliding block 309 when the sliding block 309 slides on the sliding block 309, the second limit post 202 is pressed by the sliding frame 202 to reach the position of the second limit post 308, the second limit post 202 is pressed by the second limit post 308, the second limit post 308 is always pressed by the pressing block 308, and the second limit post 309 is pushed by the second limit post 308, the second sliding block 202 is always pressed by the second limit post 308 in the second side of the sliding block 308, and the second sliding block is pushed by the second side of the second limiting block 309 is pushed by the second pressing block 309, and the second limiting block 309 is pushed by the second sliding block 303 in the second sliding block 309, and the second sliding block is pushed by the second sliding block 309, and the second side is pushed by the second sliding, and the second sliding block is in the second side, and is heated, when the second slide block is heated, and heated, when the battery is heated, and is heated and heated.

When the sliding frame 202 is reset, the moving block 303 first presses the third pressing surface 213, and the third pressing surface 213 drives the limiting block 210 to retract into the sliding frame 202, so as to complete the reset.

When the angle of the drying head 305 needs to be adjusted, the motor one 312 is started, the motor one 312 drives the bevel gear one 313 to rotate, the bevel gear one 313 drives the bevel gear two 314 to rotate, the bevel gear two 314 drives the drying head 305 to rotate, the rotating frame 315 is driven to rotate on the moving block 303, the rotating frame 315 drives the drying head 305 to rotate with the axis of the motor one 312, and at the moment, the position adjustment of the drying head 305 is completed, and the heating efficiency is improved.

The present utility model is not limited to the above-described embodiments, and various modifications are possible within the scope of the present utility model without inventive labor, as those skilled in the art will recognize from the above-described concepts.

Claims (9)

1. The utility model provides a battery performance detection device takes precautions against earthquakes, includes feeding subassembly (1), its characterized in that: the feeding component (1) comprises a bracket (101) and a base (102), the bracket (101) is provided with a clamping mechanism, the base (102) is provided with a battery (104), the side edge of the base (102) is provided with a moving component (2) and a detecting component (3), the clamping mechanism is used for placing the battery (104) on the moving component (2), the moving component (2) comprises a sliding frame (202), the sliding frame (202) is provided with a swinging mechanism, the swinging mechanism clamps the battery (104), the swinging mechanism is internally provided with a first limiting column (203) and a vibrating plate (207), the vibrating plate (207) drives the battery (104) to vibrate, the detecting component (3) comprises a detecting box (301), the detecting box (301) is provided with a supporting column (302), the sliding frame (202) is in sliding connection with the supporting column (302), the lower end of the detecting box (301) is provided with a limiting groove (310), the first limiting column (203) is connected with the detecting column (203) and the second limiting column (308), the first limiting column (203) is connected with the second limiting column (308) in a spraying mechanism, and the spraying mechanism (309) is connected with the spraying mechanism in a simulation mode, the heating mechanism simulates the high-temperature working environment of the battery.

2. The shock-resistant battery performance detection device according to claim 1, wherein: the clamping mechanism comprises a sliding plate (105) which is slidably mounted on a bracket (101), a rotating disc (106) is rotatably arranged on the sliding plate (105), a lifting frame (107) is slidably arranged on the rotating disc (106), two groups of clamping plates I (108) are slidably arranged on the lifting frame (107), and the clamping plates I (108) clamp the battery (104).

3. The shock-resistant battery performance detection device according to claim 1, wherein: a group of wave plates (204) and limiting blocks (210) are respectively arranged on two sides of the sliding frame (202), the limiting blocks (210) are connected with the sliding frame (202) in a sliding mode, and springs III are arranged between the limiting blocks (210) and the sliding frame (202).

4. A shock-resistant battery performance detection apparatus according to claim 3, wherein: the swing mechanism comprises a swing ring (201) which is slidably mounted on a sliding frame (202), a first limiting column (203) is mounted at the lower end of the swing ring (201), a lifting block (206) is slidably arranged at the upper end of the swing ring (201), two groups of second clamping plates (205) are slidably arranged on the lifting block (206), and the second clamping plates (205) clamp the battery (104).

5. The shock-resistant battery performance detection device according to claim 4, wherein: the vibrating plate (207) is slidably mounted on the lifting block (206), a first spring (208) is arranged between the vibrating plate (207) and the lifting block (206), a cam (209) is rotationally arranged in the lifting block (206), and the cam (209) drives the vibrating plate (207) to slide on the lifting block (206).

6. The shock-resistant battery performance detection device according to claim 1, wherein: the detection box (301) is provided with a hydraulic chamber, the second limiting column (308) and the sliding block (309) are both arranged in the hydraulic chamber, and when one of the second limiting column (308) and the sliding block (309) is extruded, the other one slides from the detection box (301).

7. The shock-resistant battery performance detection device according to claim 6, wherein: the spraying mechanism comprises a swing frame (306) which is slidably arranged in the detection box (301), a spring IV is arranged between the swing frame (306) and the detection box (301), and swing columns (311) and a plurality of groups of spraying heads (304) are arranged on the swing frame (306).

8. The shock-resistant battery performance detection device according to claim 7, wherein: the heating mechanism comprises a moving block (303) which is slidably arranged on the detection box (301), a second spring (307) is arranged between the moving block (303) and the detection box (301), an adjusting mechanism is arranged on the moving block (303), and the position of the drying head (305) is adjusted by the adjusting mechanism.

9. The shock-resistant battery performance detection device according to claim 8, wherein: the adjusting mechanism comprises a first motor (312) arranged on the moving block (303), a first bevel gear (313) is arranged on an output shaft of the first motor (312), a rotating frame (315) is rotatably arranged on the moving block (303), the rotating frame (315) is rotatably connected with an output shaft of the first motor (312), a drying head (305) is rotatably arranged on the rotating frame (315), a second bevel gear (314) is arranged on a rotating shaft of the drying head (305), and the first bevel gear (313) is meshed with the second bevel gear (314).