CN219636275U

CN219636275U - Cell module tilting mechanism

Info

Publication number: CN219636275U
Application number: CN202320709656.5U
Authority: CN
Inventors: 雷寿长; 林嘉兴
Original assignee: Ningde Sikeqi Intelligent Equipment Co Ltd
Current assignee: Ningde Sikeqi Intelligent Equipment Co Ltd
Priority date: 2023-04-03
Filing date: 2023-04-03
Publication date: 2023-09-05
Anticipated expiration: 2033-04-03

Abstract

The utility model relates to the technical field of battery cell modules, and particularly discloses a battery cell module overturning mechanism which comprises a frame, wherein a lifting plate is arranged in the frame and driven by a driving assembly; the lifting plate is connected with a clamping and positioning assembly through a turnover assembly, the clamping and positioning assembly comprises a supporting frame, and a transverse clamping piece and a longitudinal clamping piece are arranged on the supporting frame; the utility model can turn over the cell module, clamp and fix the cell module before turning over the cell module, and has good fixing effect.

Description

Cell module tilting mechanism

Technical Field

The utility model relates to the technical field of cell modules, and particularly discloses a cell module overturning mechanism.

Background

Chinese patent application number CN201721038467.0 discloses a mandrel group tilter, comprising: a frame; the centering mechanism is arranged at the lower part of the frame and comprises a driving assembly, a first screw rod and a second screw rod, one end of the first screw rod is in transmission connection with the driving assembly and is transversely arranged, and the second screw rod is connected with the other end of the first screw rod through a coupler; the clamping mechanism comprises a left sliding seat, a left overturning clamping jaw arranged on the left sliding seat, a right sliding seat and a right overturning clamping jaw arranged on the right sliding seat; the left sliding seat and the right sliding seat are respectively connected with the first screw rod and the second screw rod in a transmission way; when the left overturning clamping jaw and the right overturning clamping jaw are centered and close, clamping force is generated to clamp the battery cell module; the turnover mechanism is arranged at one end of the sliding seat far away from the screw rod so as to drive the turnover clamping jaw. The utility model discloses a can realize overturning the electric core module, but the clamping mode of electric core module produces clamping force when being close to through left upset clamping jaw and right upset clamping jaw centering to press from both sides tight electric core module, this clamping mode can fix the electric core module, but only presss from both sides tightly through the transverse direction to electric core module, and fixed effect is not good.

Disclosure of Invention

In order to solve the problems, the utility model aims to provide a battery cell module overturning mechanism which can overturn a battery cell module, can clamp and fix the battery cell module before overturning the battery cell module, and has good fixing effect.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the battery cell module overturning mechanism comprises a frame, wherein a lifting plate is arranged in the frame and driven by a driving assembly; the lifting plate is connected with a clamping and positioning assembly through a turnover assembly, the clamping and positioning assembly comprises a supporting frame, and a transverse clamping piece and a longitudinal clamping piece are arranged on the supporting frame.

Further, the driving assembly comprises an electric push rod, the electric push rod is fixed on a cross rod at the upper end of the frame through a fixing plate, and the tail end of the electric push rod penetrates through the fixing plate and is connected with the lifting plate through a first fixing seat;

the four corners of the upper surface of the fixed plate are embedded with first linear bearings, first sliding rods are embedded in the first linear bearings, and the lower ends of the first sliding rods are connected with the lifting plate.

Further, the overturning assembly comprises a motor, motors are fixed at the left end and the right end of the lower surface of the lifting plate, supporting seats are fixed at the left end and the right end of the lower surface of the lifting plate, and the two supporting seats are positioned between the two motors; the supporting seat is fixedly provided with a steering gear, an output shaft of the steering gear is connected with the supporting frame, and an input end of the steering gear is connected with an output shaft of the motor.

Further, the longitudinal clamping piece is fixed on the front inner side wall of the supporting frame; the longitudinal clamping piece comprises a first L-shaped plate, two first L-shaped plates are fixed on the front inner side wall of the supporting frame, the two first L-shaped plates are arranged left and right, a first limiting block is fixed at the rear end of the bottom surface of a transverse plate of the first L-shaped plate, a second L-shaped plate is fixed at the front end of the bottom surface of the transverse plate of the first L-shaped plate, and a second limiting block is fixed below the first limiting block at the rear end of a vertical plate of the second L-shaped plate;

a first moving plate is arranged behind the vertical plate of the second L-shaped plate and driven by a driving piece; a third L-shaped plate is fixed below the second limiting block at the lower end of the rear side surface of the first moving plate, a first clamping block is fixed on the rear side surface of a vertical plate of the third L-shaped plate, and a supporting block is fixed on the upper surface of a transverse plate of the third L-shaped plate;

the longitudinal clamping piece is also fixed on the rear inner side wall of the supporting frame.

Further, the driving piece comprises a telescopic cylinder and a guiding piece, the front side surface of the supporting frame is positioned in front of the first moving plate, the telescopic cylinder is fixed, and the tail end of a push rod of the telescopic cylinder penetrates through the supporting frame and is connected with the front side surface of the first moving plate through a second fixing seat;

the front side of the supporting frame is provided with a plurality of guide pieces, each guide piece comprises a second linear bearing, the front side of the supporting frame is provided with two second linear bearings, the rear ends of the second linear bearings penetrate through the supporting frame, second sliding rods are embedded in the second linear bearings, the rear ends of the second sliding rods are connected with the first moving plates, and the front ends of the second sliding rods are fixedly provided with second moving plates; the second movable plate is embedded with a first oil pressure buffer.

Further, the cylinder diameter of the front telescopic cylinder is larger than that of the rear telescopic cylinder; a first proximity switch is embedded on the first clamping block at the front end.

Further, the horizontal clamping piece includes the fixed block, both ends all are fixed with about between two curb plates in braced frame's the front and back the fixed block, the upper surface of fixed block is fixed with the triaxial cylinder, be connected with the second clamping block on the push pedal of triaxial cylinder.

Further, a supporting plate is fixed on a pushing plate of the three-axis cylinder at the right end, one side, far away from the three-axis cylinder at the right end, of the supporting plate is fixed with a second clamping block, the front end and the rear end of the left side of the supporting plate are embedded with second oil pressure buffers, the right ends of the front inner side wall and the rear inner side wall of the supporting frame are fixed with limiting plates matched with the second oil pressure buffers, and the limiting plates are located in the left of the second oil pressure buffers.

Further, the cylinder diameter of the triaxial cylinder at the right end is larger than that of the triaxial cylinder at the left end; a second proximity switch is embedded on the second clamping block at the right end.

Further, tow hooks are fixed at the front end and the rear end of the bottom surface of the second clamping block.

The utility model has the beneficial effects that:

the utility model provides a battery cell module overturning mechanism, which can drive a battery cell module to ascend and descend through a lifting plate, so that the battery cell module can be overturned conveniently; the lifting plate can be moved up and down through the driving assembly, so that the subsequent overturning of the cell module is facilitated; the clamping and positioning assembly can clamp and fix the cell module, and the overturning assembly can overturn the clamping and positioning assembly, so that the cell module can be overturned, and the blue film at the bottom of the cell module can be inspected manually; the transverse clamping piece can clamp and fix the transverse position of the battery cell module, and the longitudinal clamping piece can clamp and fix the longitudinal position of the battery cell module, so that the battery cell module can be prevented from falling off in the overturning process.

The utility model can turn over the cell module, clamp and fix the cell module before turning over the cell module, and has good fixing effect.

Drawings

Fig. 1 is a perspective view of the present utility model.

Fig. 2 is a front view of the present utility model.

Fig. 3 is a perspective view of the clamp positioning assembly.

Fig. 4 is a right side view of the longitudinal clamp.

Fig. 5 is a perspective view of the lateral clamp member.

Detailed Description

The utility model is further described below with reference to the accompanying drawings.

Referring to fig. 1 to 3, the utility model provides a turnover mechanism of a battery cell module, which comprises a frame 1, wherein a lifting plate 2 is arranged in the frame 1, and the battery cell module can be driven to lift by the lifting plate 2, so that the battery cell module can be turned over later; the lifting plate 2 is driven by the driving component 3, and the lifting plate 2 can be moved up and down through the driving component 3, so that the subsequent overturning of the cell module is facilitated;

the lifting plate 2 is connected with a clamping and positioning assembly 5 through a turnover assembly 4, the clamping and positioning assembly 5 can clamp and fix the cell module, and the turnover assembly 4 can turn over the clamping and positioning assembly 5, so that the cell module can be turned over, and the blue film at the bottom of the cell module can be inspected manually;

the clamping and positioning assembly 5 comprises a supporting frame 6, wherein a transverse clamping piece and a longitudinal clamping piece are arranged on the supporting frame 6, the transverse position of the battery cell module can be clamped and fixed through the transverse clamping piece, and the longitudinal position of the battery cell module can be clamped and fixed through the longitudinal clamping piece, so that falling of the battery cell module in the overturning process can be avoided.

With continued reference to fig. 1 and 2, the driving assembly 3 includes an electric push rod 31, and the lifting plate 2 can be moved up and down by the electric push rod 31, so as to facilitate the subsequent overturning of the cell module; the electric push rod 31 is fixed on the cross bar at the upper end of the frame 1 through a fixing plate 32, and the tail end of the electric push rod 31 penetrates through the fixing plate 32 and is connected with the lifting plate 2 through a first fixing seat;

the four corners of the upper surface of the fixed plate 32 are embedded with first linear bearings 33, the first linear bearings 33 are embedded with first sliding rods 34, the first linear bearings 33 are matched with the first sliding rods 34, the guide effect can be achieved when the lifting plate 2 moves up and down, and the lower ends of the first sliding rods 34 are connected with the lifting plate 2.

With continued reference to fig. 1 and 2, the turnover assembly 4 includes a motor 41, and the motors 41 are fixed at the left and right ends of the lower surface of the lifting plate 2, so that the cell module can be turned over by the motors 41; support seats 42 are fixed at the left and right ends of the lower surface of the lifting plate 2 and used for installing a steering gear 43, and the two support seats 42 are positioned between the two motors 41; the supporting seat 42 is fixed with a steering gear 43, an output shaft of the steering gear 43 is connected with the supporting frame 6, and an input end of the steering gear 43 is connected with an output shaft of the motor 41.

The starting motor 41 drives the output shaft of the steering gear 43 to rotate, so as to drive the supporting frame 6 to rotate, and drive the clamping and positioning assembly 5 to rotate, so as to drive the battery cell module to rotate.

With continued reference to fig. 3 and 4, the front inner sidewall of the supporting frame 6 is fixed with the longitudinal clamping member; the longitudinal clamping piece comprises a first L-shaped plate 81, two first L-shaped plates 81 are fixed on the front inner side wall of the supporting frame 6, the two first L-shaped plates 81 are arranged left and right, a first limiting block 82 is fixed at the rear end of the bottom surface of a transverse plate of the first L-shaped plate 81, a second L-shaped plate 83 is fixed at the front end of the bottom surface of the transverse plate of the first L-shaped plate 81, and a second limiting block 84 is fixed below the first limiting block 82 at the rear end of a vertical plate of the second L-shaped plate 83; the cell module can be coarsely positioned by the first stopper 82 and the second stopper 84.

A first moving plate 85 is arranged behind the vertical plate of the second L-shaped plate 83, and the first clamping block 88 can be driven to move back and forth through the first moving plate 85, so that the longitudinal direction of the battery cell module can be clamped and fixed; the first moving plate 85 is driven by a driving member 86, and the driving member 86 can drive the first moving plate 85 to move back and forth; a third L-shaped plate 87 is fixed below the second limiting block 84 at the lower end of the rear side of the first moving plate 85, a first clamping block 88 is fixed at the rear side of a vertical plate of the third L-shaped plate 87, and the first clamping block 88 is made of a high-strength adhesive, so that the cell module can be prevented from being damaged when being clamped, and the cell module can be clamped and fixed through the first clamping block 88; a supporting block 89 is fixed on the upper surface of the transverse plate of the third L-shaped plate 87, and the cell module can be supported by the supporting block 89;

the longitudinal clamping pieces are also fixed on the rear inner side wall of the supporting frame 6, and the longitudinal direction of the battery cell module can be clamped and fixed through the front longitudinal clamping piece and the rear longitudinal clamping piece.

The driving member 86 includes a telescopic cylinder 861 and a guiding member, the front side surface of the supporting frame 6 is located in front of the first moving plate 85, and is fixed with the telescopic cylinder 861, and the telescopic cylinder 861 can drive the first moving plate 85 to move back and forth; the tail end of the push rod of the telescopic cylinder 861 penetrates through the supporting frame 6 and is connected with the front side surface of the first movable plate 85 through a second fixed seat;

the front side surface of the supporting frame 6 is provided with a plurality of guide pieces, and the guide pieces can play a role in guiding when the first moving plate 85 moves forwards and backwards; the guide piece comprises a second linear bearing 862, two second linear bearings 862 are arranged on the front side surface of the supporting frame 6, the rear ends of the second linear bearings 862 penetrate through the supporting frame 6, a second sliding rod 863 is embedded in the second linear bearings 862, and the second linear bearings 862 are matched with the second sliding rod 863 to play a role in guiding when the first moving plate 85 moves forwards and backwards; the rear end of the second sliding rod 863 is connected to the first moving plate 85, and the second moving plate 864 is fixed to the front end of the second sliding rod 863;

the second moving plate 864 is embedded with a first hydraulic buffer 865, and the first hydraulic buffer 865 may be of a type RBQ2007, but is not limited thereto, and the first hydraulic buffer 865 may provide a buffering function when the second moving plate 864 contacts the support frame 6.

With continued reference to fig. 3 and fig. 5, the transverse clamping member includes a fixing block 91, the fixing blocks 91 are fixed at both left and right ends between the front and rear side plates of the support frame 6, and are used for mounting a tri-axial air cylinder 92, the tri-axial air cylinder 92 is fixed on the upper surface of the fixing block 91, the tri-axial air cylinder 92 may be MGPM63-25Z, but not limited thereto, a second clamping block 93 is connected to a push plate of the tri-axial air cylinder 92, and the second clamping block 93 is made of a high-strength adhesive, so as to avoid damaging the cell module when clamping the cell module; the second clamping block 93 can be driven to clamp and fix the transverse direction of the battery module through the triaxial cylinder 92.

The embodiment has the following working principle: when the electric power module is used, the electric push rod 31 is started to drive the lifting plate 2 to move downwards, so that the clamping and positioning assembly 5 is driven to move downwards to sleeve the electric core module; starting a telescopic cylinder 861 at the front end and a telescopic cylinder 861 at the rear end to drive a first clamping block 88 to clamp and fix the battery cell module, so as to clamp and fix the battery cell module in the longitudinal direction; starting the left triaxial cylinder 92 and the right triaxial cylinder 92 to drive the second clamping block 93 to clamp and fix the cell module, so as to clamp and fix the cell module in the transverse direction; after the clamping and positioning assembly 5 clamps and fixes the cell module, the lifting plate 2 is driven to move upwards by the electric push rod 31, the starting motor 41 drives the cell module to turn over, and the blue film at the bottom of the cell module is inspected manually.

With continued reference to fig. 1 to 5, in an embodiment of the present utility model, the first clamping block 88 at the front end is made of steel, the middle part is made of steel, the two ends are made of euler rubber, and the thickness of the euler rubber is greater than that of the steel, so that the clamping surface of the first clamping block 88 at the front end can play a role in buffering when being used as a precise positioning reference surface, and the first clamping block 88 at the rear end is made of euler rubber;

the cylinder diameter of the front telescopic cylinder 861 is larger than that of the rear telescopic cylinder 861, so that the thrust of the rear telescopic cylinder 861 is smaller than that of the front telescopic cylinder 861 under the same air pressure, and therefore the clamping surface of the front first clamping block 88 is equivalent to a fine positioning reference surface, and the positioning accuracy can be ensured;

a first proximity switch (not shown) is embedded on the first clamping block 88 at the front end, the first proximity switch is fixed in the steel racing part, a signal can be sent to the telescopic cylinder 861 at the rear side through the first proximity switch, and the telescopic cylinder 861 at the rear side drives the first clamping block 88 at the rear side to move forwards to clamp and fix the battery cell module; the first proximity switch may be of the IQ06-03BPSKU3S type, but is not limited thereto.

A supporting plate 94 is fixed on a push plate of the triaxial cylinder 92 at the right end, one side, far away from the triaxial cylinder 92 at the right end, of the supporting plate 94 is fixed with a second clamping block 93, the front end and the rear end of the left side of the supporting plate 94 are embedded with second oil pressure buffers 95, and the second oil pressure buffers 95 can play a role in buffering when the supporting plate 94 is contacted with a limiting plate 96; the second hydraulic buffer 95 may be of a type RBQ2007, but is not limited thereto, and the right ends of the front and rear inner side walls of the support frame 6 are each fixed with a limiting plate 96 that is matched with the second hydraulic buffer 95, and the limiting plates 96 are located at the left side of the second hydraulic buffer 95.

The second clamping block 93 at the right end is made of middle section of racing steel, the two ends of the second clamping block are made of excellent rubber, and the thickness of the excellent rubber is larger than that of the racing steel, so that the clamping surface of the second clamping block 93 at the right end can play a role in buffering when being used as a precise positioning reference surface; the second clamping block 93 at the left end is made of high-strength glue;

the cylinder diameter of the right triaxial cylinder 92 is larger than that of the left triaxial cylinder 92, so that the thrust of the right triaxial cylinder 92 is smaller than that of the left triaxial cylinder 92 under the same air pressure, and therefore the clamping surface of the right second clamping block 93 is equivalent to a fine positioning reference surface, and the positioning accuracy can be ensured;

a second proximity switch (not shown) is embedded on the second clamping block 93 at the right end, the second proximity switch is fixed in the steel racing part, a signal can be sent to the triaxial air cylinder 92 at the left end through the second proximity switch, and the triaxial air cylinder 92 at the left end drives the second clamping block 93 at the left end to move rightwards to clamp and fix the battery cell module; the second proximity switch may be of the IQ06-03BPSKU3S type, but is not limited thereto.

Tow hooks 97 are fixed at the front end and the rear end of the bottom surface of the second clamping block 93, so that the cell module can be supported.

The embodiment has the following working principle: when the electric power module is used, the electric push rod 31 is started to drive the lifting plate 2 to move downwards, so that the clamping and positioning assembly 5 is driven to move downwards to sleeve the electric core module; starting a telescopic cylinder 861 at the front end to drive a first clamping block 88 at the front end to move backwards, and driving a push rod of the telescopic cylinder 861 at the front end to not move backwards any more, and driving the first clamping block 88 at the rear end to clamp and fix the battery cell module by the telescopic cylinder 861 at the rear end so as to clamp and fix the battery cell module in the longitudinal direction;

starting the three-axis air cylinder 92 at the right end to drive the second clamping block 93 at the right end to move leftwards, and driving the second clamping block 93 at the right end to clamp and fix the battery cell module by the three-axis air cylinder 92 at the right end until the push rod of the three-axis air cylinder 92 at the left end is not moving rightwards, so as to clamp and fix the battery cell module in the transverse direction;

after the clamping and positioning assembly 5 clamps and fixes the cell module, the lifting plate 2 is driven to move upwards by the electric push rod 31, the starting motor 41 drives the cell module to turn over, and the blue film at the bottom of the cell module is inspected manually.

The electric push rod, the linear bearing, the motor, the steering gear and the telescopic cylinder are all in the prior art, and a person skilled in the art can clearly understand that the electric push rod, the linear bearing, the motor, the steering gear and the telescopic cylinder are not described in detail herein, and the utility model protects the structural characteristics of the turnover mechanism of the battery cell module.

The above description is only of the preferred embodiments of the present utility model, and should not be construed as limiting the utility model, but rather as covering all equivalent variations and modifications according to the appended claims.

Claims

1. Cell module tilting mechanism, its characterized in that: the lifting device comprises a frame, wherein a lifting plate is arranged in the frame and driven by a driving assembly; the lifting plate is connected with a clamping and positioning assembly through a turnover assembly, the clamping and positioning assembly comprises a supporting frame, and a transverse clamping piece and a longitudinal clamping piece are arranged on the supporting frame.

2. The cell module tilting mechanism according to claim 1, wherein: the driving assembly comprises an electric push rod, the electric push rod is fixed on a cross rod at the upper end of the frame through a fixing plate, and the tail end of the electric push rod penetrates through the fixing plate and is connected with the lifting plate through a first fixing seat;

3. The cell module tilting mechanism according to claim 1, wherein: the overturning assembly comprises a motor, motors are fixed at the left and right ends of the lower surface of the lifting plate, supporting seats are fixed at the left and right ends of the lower surface of the lifting plate, and the two supporting seats are positioned between the two motors; the supporting seat is fixedly provided with a steering gear, an output shaft of the steering gear is connected with the supporting frame, and an input end of the steering gear is connected with an output shaft of the motor.

4. The cell module tilting mechanism according to claim 1, wherein: the front inner side wall of the supporting frame is fixedly provided with the longitudinal clamping piece; the longitudinal clamping piece comprises a first L-shaped plate, two first L-shaped plates are fixed on the front inner side wall of the supporting frame, the two first L-shaped plates are arranged left and right, a first limiting block is fixed at the rear end of the bottom surface of a transverse plate of the first L-shaped plate, a second L-shaped plate is fixed at the front end of the bottom surface of the transverse plate of the first L-shaped plate, and a second limiting block is fixed below the first limiting block at the rear end of a vertical plate of the second L-shaped plate;

5. The cell module tilting mechanism according to claim 4, wherein: the driving piece comprises a telescopic air cylinder and a guide piece, the front side surface of the supporting frame is positioned in front of the first moving plate, the telescopic air cylinder is fixed, and the tail end of a push rod of the telescopic air cylinder penetrates through the supporting frame and is connected with the front side surface of the first moving plate through a second fixing seat;

6. The cell module tilting mechanism according to claim 5, wherein: the cylinder diameter of the front telescopic cylinder is larger than that of the rear telescopic cylinder; a first proximity switch is embedded on the first clamping block at the front end.

7. The cell module tilting mechanism according to claim 1, wherein: the transverse clamping piece comprises a fixed block, the left end and the right end between the front side plate and the rear side plate of the supporting frame are respectively fixed with the fixed block, the upper surface of the fixed block is fixedly provided with a triaxial cylinder, and a pushing plate of the triaxial cylinder is connected with a second clamping block.

8. The cell module tilting mechanism according to claim 7, wherein: the backup pad is fixed with in the push pedal of the triaxial cylinder of right-hand member, one side of keeping away from the triaxial cylinder of right-hand member in the backup pad is fixed with the second presss from both sides tight piece, both ends all inlay around the left side of backup pad are equipped with second oil pressure buffer, the right-hand member of two inside walls all be fixed with around braced frame with second oil pressure buffer matched with limiting plate, the limiting plate is located the left side of second oil pressure buffer.

9. The cell module tilting mechanism according to claim 8, wherein: the cylinder diameter of the triaxial cylinder at the right end is larger than that of the triaxial cylinder at the left end; a second proximity switch is embedded on the second clamping block at the right end.

10. The cell module tilting mechanism according to claim 8, wherein: tow hooks are fixed at the front end and the rear end of the bottom surface of the second clamping block.