CN109366536B

CN109366536B - Insulating film shearing device of coated power battery

Info

Publication number: CN109366536B
Application number: CN201811299922.1A
Authority: CN
Inventors: 李正军; 陈伦炤; 贝维学; 陈红伟; 袁伟宏; 吉跃华
Original assignee: Zhenjiang Cinnic Automatic Technology Co ltd
Current assignee: Jiangsu Chengtai Automation Technology Co ltd
Priority date: 2018-11-02
Filing date: 2018-11-02
Publication date: 2023-05-30
Anticipated expiration: 2038-11-02
Also published as: CN109366536A

Abstract

The invention discloses an insulating film shearing device of a coated power battery, which comprises a base, a frame, a first transmission mechanism, a second transmission mechanism, a first cylinder, first cutters and second cutters, wherein the frame is vertically arranged, the bottom of the frame is connected with the upper surface of the base, the first transmission mechanism and the second transmission mechanism are oppositely arranged at intervals up and down on the same side of the frame and are respectively connected with the frame, the first cylinder is arranged between the first transmission mechanism and the second transmission mechanism and is connected with the frame, the first transmission mechanism and the second transmission mechanism are respectively provided with one first cutter, the two first cutters are horizontally arranged at intervals relatively, and the second cutters are horizontally arranged between the two first cutters along the vertical interval and are respectively connected with the first cylinders. The invention has the advantages that: the synchronous shearing of the insulating films at the upper edge and the lower edge of the coated power battery is realized, the time of the insulating film shearing process of the coated power battery is greatly shortened, and the production efficiency is improved.

Description

Insulating film shearing device of coated power battery

Technical Field

The invention relates to power battery processing equipment, in particular to an insulating film shearing device for a coated power battery.

Background

In the process of processing the power battery, an insulating film coating process is required to be carried out on the periphery of the power battery, and after the coating is finished, a shearing process is required to be carried out on the residual insulating films at the upper edge and the lower edge of the power battery. At present, the insulating films at the upper edge and the lower edge are usually sheared by adopting a standard pneumatic scissors mechanism, so that the insulating films at the upper edge and the lower edge cannot be sheared synchronously and need to be sheared sequentially, the consumed time is increased, in addition, because the insulating films needing to be sheared have larger viscosity, the scissors are extremely easy to adhere to residual glue in the use process, the pneumatic scissors cannot successfully shear the insulating films, the shearing process cannot be carried out smoothly, a large amount of time is required for cleaning and debugging, and the production efficiency of equipment is very influenced.

Disclosure of Invention

The invention aims to: the invention aims to provide the insulating film shearing device for the coated power battery, so that the shearing time is shortened, and meanwhile, the condition that the production efficiency is reduced due to the adhesion of residual glue is avoided.

The technical scheme is as follows: the utility model provides an insulating film shearing mechanism of diolame power battery, includes base, frame, first drive mechanism, second drive mechanism, first cylinder, first cutter, second cutter, the frame is vertical to be set up, its bottom with the upper surface of base is connected, first drive mechanism the second drive mechanism be in the same side of frame relative interval sets up from top to bottom and respectively with the frame is connected, first cylinder set up in first drive mechanism with between the second drive mechanism and with the frame is connected, first drive mechanism installs respectively on the second drive mechanism one first cutter, two first cutter relative interval level sets up, the second cutter is equipped with two, two between first cutter along vertical interval level setting and respectively with first cylinder is connected.

When the cutting process of the insulating film of the coated power battery is carried out, the power battery coated with the insulating film is clamped to a cutting station through other devices, at the moment, the power battery is horizontally placed, the insulating film at the edges on the upper surface and the lower surface of the power battery is respectively positioned between the two cutting edges of the corresponding cutter combination, after the power battery is in place, the first cylinder is started, so that the two second cutters connected with the first cylinder move towards the insulating film at the corresponding edges until the insulating film at the corresponding position is supported, then the first transmission mechanism and the second transmission mechanism are simultaneously started to drive the first cutters on the first transmission mechanism and the second transmission mechanism to move relatively, and the first cutters approach the corresponding second cutters until the insulating film positioned between the first cutters and the second cutters is cut through the cooperation of the corresponding second cutters, thereby completing synchronous cutting of the insulating film at the upper edge and the lower edge of the coated power battery, shortening the cutting time, and improving the processing efficiency of the cutting process.

Further, the blades of the first cutter and the second cutter are ceramic blades. The special material of ceramic blade can reduce the adhesion probability of insulating film residual glue, makes the washing of residual glue more convenient simultaneously to production efficiency has been improved.

Further, the device also comprises a moving mechanism, wherein the moving mechanism is arranged on the upper surface of the base, and the frame is connected with the base through the moving mechanism.

Further, the moving mechanism comprises a first straight rail, a second air cylinder and a moving platen, wherein two first straight rails are arranged, parallel intervals are fixed on the upper surface of the base, the second air cylinder is arranged on the base between the two first straight rails, the moving platen is arranged on the two first straight rails in a crossing mode above the second air cylinder, the second air cylinder is connected with the moving platen, two sliding grooves are arranged at the bottom of the moving platen in parallel intervals, the sliding grooves are in butt joint and match with the corresponding first straight rails, and the bottom of the frame is fixed with the upper surface of the moving platen.

Further, the moving mechanism further comprises two buffers, buffer mounting plates and baffle plates, wherein one buffer is arranged on the outer side of the first straight rail, the two buffers are oppositely arranged and respectively close to two ends of the first straight rail, each buffer is respectively connected with the base through one buffer mounting plate, and the baffle plates are arranged between the two buffers and are fixed on one side surface corresponding to the moving platen.

Through setting up moving mechanism, make the diolame power battery be convenient for more reach and cut the station, avoid bumping. The movable platen can move linearly along the first straight rail under the drive of the second cylinder, so that the frame on the movable platen is driven to move synchronously, and the first transmission mechanism, the second transmission mechanism, the first cylinder, the first cutter and the second cutter which are arranged on the frame move together with the frame, so that a larger space can be provided for the coating power battery during feeding.

Further, the first transmission mechanism comprises a third cylinder, a first floating joint, a first connecting plate, a first cutter fixing plate and a second straight rail, the third cylinder is mounted on the upper portion of the frame, the cylinder shaft of the third cylinder faces downwards, the first connecting plate is horizontally arranged and connected with the cylinder shaft of the third cylinder through the first floating joint, the plate surface of the first cutter fixing plate is L-shaped, one end of the first cutter fixing plate is connected with the first connecting plate, the other end of the first cutter fixing plate is connected with the corresponding first cutter, the second straight rail is vertically arranged and mounted on the frame, and the first cutter fixing plate is mounted in cooperation with the second straight rail.

Further, the second transmission mechanism comprises a fourth cylinder, a second floating joint, a second connecting plate, a second cutter fixing plate and a third straight rail, the fourth cylinder is mounted at the lower part of the frame, the cylinder shaft of the fourth cylinder faces upwards, the second connecting plate is horizontally arranged and connected with the cylinder shaft of the fourth cylinder through the second floating joint, the plate surface of the second cutter fixing plate is L-shaped, one end of the second cutter fixing plate is connected with the second connecting plate, the other end of the second cutter fixing plate is connected with a corresponding first cutter, and the third straight rail is vertically arranged and mounted on the frame and is mounted in a matched mode with the third straight rail.

When shearing, the third cylinder and the fourth cylinder are started simultaneously, the third cylinder drives the first cutter fixing plate to move downwards along the second straight rail through the first connecting plate, so that the first cutter arranged on the first cutter fixing plate moves downwards, and the fourth cylinder drives the second cutter fixing plate to move upwards along the third straight rail through the second connecting plate, so that the first cutter arranged on the second cutter fixing plate moves upwards, and the two first cutters move relatively and move towards the corresponding second cutters respectively.

Further, the first cylinder is a finger cylinder. The second cutters are respectively arranged on the two clamping jaws of the first cylinder.

The beneficial effects are that: compared with the prior art, the invention has the advantages that: the combination that sets up two first cutters and second cutters, through the first cylinder, the second cylinder, the mutual cooperation of third cylinder, realize the synchronous shearing of every first cutter of group and second cutter, thereby realize the synchronous shearing of the insulating film at the upper and lower border of diolame power battery, the time spent of the insulating film shearing process of diolame power battery that shortens greatly improves production efficiency, in addition, the blade of first cutter, second cutter is ceramic blade, ceramic blade's special material can reduce the adhesion probability of insulating film plastic residue, make the washing of plastic residue more convenient simultaneously, thereby further improved production efficiency.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

fig. 2 is a front view of the present invention.

Detailed Description

The invention will be further elucidated with reference to the drawings and to specific embodiments, it being understood that these embodiments are only intended to illustrate the invention and are not intended to limit the scope thereof.

The insulating film shearing device of the coated power battery comprises a base 1, a frame 2, a first transmission mechanism 3, a second transmission mechanism 4, a first cylinder 5, a first cutter 6, a second cutter 7 and a moving mechanism 8, wherein the blades of the first cutter 6 and the second cutter 7 are ceramic blades.

The base 1 is fixed, the upper surface of base 1 is equipped with moving mechanism 8, moving mechanism 8 includes first straight rail 81, second cylinder 82, remove platen 83, buffer 84, buffer mounting panel 85, baffle 86, first straight rail 81 is equipped with two, parallel interval is fixed in the upper surface of base 1, second cylinder 82 is installed on base 1 between two first straight rails 81, remove platen 83 and stride to locate on two first straight rails 81 above second cylinder 82, second cylinder 82 is connected with remove platen 83, the bottom parallel interval of remove platen 83 is equipped with two spouts, the spout is matchd with the butt joint of corresponding first straight rail 81, frame 2 sets up vertically, the bottom surface of frame 2 is fixed with the upper surface of remove platen 83, buffer 84 is equipped with two, outside at one of them first straight rail 81 sets up relatively and is close to the both ends of this first straight rail 81 respectively, every buffer 84 is connected with base 1 through a buffer mounting panel 85 respectively, baffle 86 sets up between two buffers 84 and is fixed with the side that removes 83 corresponds, buffer 84 is the elasticity buffer.

The first transmission mechanism 3, the second transmission mechanism 4 and the first air cylinder 5 are arranged on the same side of the frame 2, the first transmission mechanism 3 and the second transmission mechanism 4 are arranged at intervals in an up-down opposite mode, the first air cylinder 5 is arranged between the first transmission mechanism 3 and the second transmission mechanism 4, and the first air cylinder 5 is connected with the frame 2.

The first transmission mechanism 3 comprises a third cylinder 31, a first floating joint 32, a first connecting plate 33, a first cutter fixing plate 34 and a second straight rail 35, wherein the third cylinder 31 is arranged on the upper portion of the frame 2, a cylinder shaft of the third cylinder 31 is vertically downward, the first connecting plate 33 is horizontally arranged and is connected with the cylinder shaft of the third cylinder 31 through the first floating joint 32, the plate surface of the first cutter fixing plate 34 is L-shaped, one end of the first cutter fixing plate 34 is connected with the first connecting plate 33, the other end of the first cutter fixing plate is vertically downward and is connected with a first cutter 6, the second straight rail 35 is vertically arranged and is arranged on the frame 2, and the first cutter fixing plate 34 and the second straight rail 35 are matched and arranged.

The second transmission mechanism 4 comprises a fourth cylinder 41, a second floating joint 42, a second connecting plate 43, a second cutter fixing plate 44 and a third straight rail 45, wherein the fourth cylinder 41 is arranged at the lower part of the frame 2, the cylinder shaft of the fourth cylinder 41 is vertically upwards, the second connecting plate 43 is horizontally arranged and is connected with the cylinder shaft of the fourth cylinder 41 through the second floating joint 42, the plate surface of the second cutter fixing plate 44 is L-shaped, one end of the second cutter fixing plate 44 is connected with the second connecting plate 43, the other end of the second cutter fixing plate is vertically upwards and is connected with a first cutter 6, the third straight rail 45 is vertically arranged and is arranged on the frame 2, and the second cutter fixing plate 44 and the third straight rail 45 are matched and arranged.

The first cutter fixing plate 34 and the second cutter fixing plate 44 are respectively provided with a first cutter 6, and the two first cutters 6 are arranged in parallel at intervals and have opposite cutting edges.

The first air cylinder 5 is a finger air cylinder, the second cutters 7 are two, are horizontally arranged between the two first cutters 6 along the vertical interval and are respectively connected with the two clamping jaws of the first air cylinder 5, and the cutting edges of the two second cutters 7 are opposite to each other and are respectively matched with the corresponding first cutters 6.

The present apparatus performs a cutting process on a part of the insulating film 200 that is more than the upper and lower edges of the power cell 100 coated with the insulating film 200.

Before the shearing process, other parts outside the base in the device are driven to move together by the moving mechanism, so that a proper space is conveniently provided for feeding the power battery coated with the insulating film. The second cylinder starts to drive the movable platen to conduct linear motion along one side of the first straight rail, so that the feeding space of the power battery is increased, the movable platen drives the frame on the movable platen to conduct synchronous motion, and accordingly the first transmission mechanism, the second transmission mechanism, the first cylinder, the first cutter and the second cutter which are installed on the frame move together with the frame.

The device is provided with two cutter combinations of the first cutters and the second cutters, and the second cylinder can be started again according to the specific size of the power battery, so that the first cutters and the second cutters are pushed towards the direction of the power battery, and therefore, the insulating films at the edges on the upper surface and the lower surface of the power battery are respectively positioned between the two cutting edges of the corresponding cutter combinations.

After the power battery is in place, the first air cylinder is started, so that two second cutters connected with the first air cylinder move towards the insulating film at the corresponding edge until the insulating film at the corresponding position is supported, then, the third air cylinder and the fourth air cylinder are started simultaneously, the third air cylinder drives the first cutter fixing plate to move downwards along the second straight rail through the first connecting plate, so that the first cutter arranged on the first cutter fixing plate moves upwards along the third straight rail, the fourth air cylinder drives the second cutter fixing plate to move upwards through the second connecting plate, the two first cutters move relatively and move towards the corresponding second cutters respectively until the insulating film positioned between the two cutters is sheared by matching with the corresponding second cutters, and therefore synchronous shearing of the insulating film at the upper edge and the lower edge of the coated power battery is completed, shearing time is shortened, and processing efficiency of a shearing procedure is improved.

Claims

1. An insulating film shearing device of a coated power battery is characterized in that: the automatic cutting machine comprises a base (1), a frame (2), a first transmission mechanism (3), a second transmission mechanism (4), a first air cylinder (5), first cutters (6) and second cutters (7), wherein the frame (2) is vertically arranged, the bottom of the frame is connected with the upper surface of the base (1), the first transmission mechanism (3) and the second transmission mechanism (4) are arranged at the same side of the frame (2) at intervals up and down and are respectively connected with the frame (2), the first air cylinder (5) is arranged between the first transmission mechanism (3) and the second transmission mechanism (4) and is connected with the frame (2), one first cutter (6) is respectively arranged on the first transmission mechanism (3) and the second transmission mechanism (4), two first cutters (6) are horizontally arranged at intervals, and the second cutters (7) are horizontally arranged at intervals along the vertical intervals between the two first cutters (6) and are respectively connected with the first air cylinder (5); the blades of the first cutter (6) and the second cutter (7) are ceramic blades;

the first transmission mechanism (3) comprises a third cylinder (31), a first floating joint (32), a first connecting plate (33), a first cutter fixing plate (34) and a second straight rail (35), wherein the third cylinder (31) is arranged on the upper portion of the frame (2), the cylinder shaft of the third cylinder (31) faces downwards, the first connecting plate (33) is horizontally arranged and connected with the cylinder shaft of the third cylinder (31) through the first floating joint (32), the plate surface of the first cutter fixing plate (34) is L-shaped, one end of the first cutter fixing plate (34) is connected with the first connecting plate (33), the other end of the first cutter fixing plate is connected with the corresponding first cutter (6), the second straight rail (35) is vertically arranged and arranged on the frame (2), and the first cutter fixing plate (34) is matched with the second straight rail (35).

2. The insulating film shearing device for an envelope power cell as defined in claim 1, wherein: the mobile device further comprises a moving mechanism (8), wherein the moving mechanism (8) is arranged on the upper surface of the base (1), and the frame (2) is connected with the base (1) through the moving mechanism (8).

3. The insulating film shearing device for an envelope power cell as defined in claim 2, wherein: the moving mechanism (8) comprises a first straight rail (81), a second air cylinder (82) and a moving platen (83), wherein the first straight rail (81) is provided with two sliding grooves, the sliding grooves are fixed on the upper surface of the base (1) at parallel intervals, the second air cylinder (82) is installed on the base (1) between the two first straight rails (81), the moving platen (83) is arranged above the second air cylinder (82) in a straddling manner on the two first straight rails (81), the second air cylinder (82) is connected with the moving platen (83), the two sliding grooves are arranged at the bottom of the moving platen (83) at parallel intervals, and the sliding grooves are in butt joint with the corresponding first straight rails (81), and the bottom of the frame (2) is fixed with the upper surface of the moving platen (83).

4. The insulating film shearing device for a coated power battery according to claim 3, wherein: the moving mechanism (8) further comprises buffers (84), buffer mounting plates (85) and baffles (86), wherein the buffers (84) are arranged in two, one of the buffers is oppositely arranged outside the first straight rail (81) and is respectively close to two ends of the first straight rail (81), each buffer (84) is respectively connected with the base (1) through one buffer mounting plate (85), and the baffles (86) are arranged between the two buffers (84) and are fixed on one side surface corresponding to the moving platen (83).

5. The insulating film shearing device for an envelope power cell as defined in claim 1, wherein: the second transmission mechanism (4) comprises a fourth cylinder (41), a second floating joint (42), a second connecting plate (43), a second cutter fixing plate (44) and a third straight rail (45), wherein the fourth cylinder (41) is arranged at the lower part of the frame (2), the cylinder shaft of the fourth cylinder (41) faces upwards, the second connecting plate (43) is horizontally arranged and connected with the cylinder shaft of the fourth cylinder (41) through the second floating joint (42), the plate surface of the second cutter fixing plate (44) is L-shaped, one end of the second cutter fixing plate (44) is connected with the second connecting plate (43), the other end of the second cutter fixing plate is connected with a corresponding first cutter (6), the third straight rail (45) is vertically arranged and is arranged on the frame (2), and the second cutter fixing plate (44) is matched with the third straight rail (45).

6. The insulating film shearing device for an envelope power cell as defined in claim 1, wherein: the first air cylinder (5) is a finger air cylinder.