CN221234518U - Multi-station feeding device for battery isolation pad - Google Patents

Abstract

The utility model relates to a multi-station feeding device for a battery isolation pad, which comprises a machine table, wherein a rack is arranged on one side of the machine table; the first feeding mechanism is arranged on the machine table and used for providing a battery isolation pad; the second feeding mechanism is arranged on the machine table and used for providing a battery isolation pad; the feeding mechanism is arranged on the frame; the first transfer mechanism is arranged on the frame and used for transferring the battery isolation pad provided by the first feeding mechanism to the feeding mechanism; the second transfer mechanism is arranged on the frame and used for transferring the battery isolation pad provided by the second feeding mechanism to the feeding mechanism. According to the utility model, under the cooperation of the first transfer mechanism and the second transfer mechanism, the first feeding mechanism and the second feeding mechanism can be in seamless connection to feed to the feeding mechanism, so that the feeding mechanism can perform feeding action without stopping for feeding, the feeding speed is improved, and the production rate is improved.

Description

Multi-station feeding device for battery isolation pad

Technical Field

The utility model relates to the technical field of battery production equipment, in particular to a multi-station feeding device for a battery isolation pad.

Background

The battery is an energy storage device, which is a device capable of converting chemical energy into electric energy and has a positive electrode and a negative electrode. In daily life, batteries are commonly used to provide electrical energy to various products or devices that consume electricity. Batteries are classified into different types according to materials used, and common batteries include lithium ion batteries, sodium ion batteries, nickel hydrogen batteries, lead acid batteries, carbonaceous batteries, silver batteries, and the like. In practical application, according to different requirements or application scenes, the batteries have different specifications, if the required capacity of the batteries is larger, a single battery cannot meet the requirements, so that a plurality of batteries are generally assembled into a larger battery pack/battery pack, an isolation pad needs to be added between adjacent batteries in the process of producing the battery pack/battery pack, the surface of the isolation pad is provided with a release film, and the release film on the surface of the isolation pad needs to be torn to expose an adhesive surface in the process of assembling, so that the isolation pad is convenient to be connected with the batteries. The traditional operation mode is to manually tear off the release film on the surface of the isolation pad, but the mode is low in efficiency, and in order to improve the efficiency, an auxiliary film tearing device is adopted to tear off the release film on the surface of the isolation pad at present. However, the existing feeding mechanism is not designed for feeding the isolation pad, and the requirement of the film tearing device of the isolation pad is difficult to meet. For example, the feeding mechanism with the publication number of CN212893031U adopts the cooperation of a linear module and a cylinder to realize feeding, namely, the feeding position of the processing equipment is transferred after a material is grabbed, but the feeding action is slower in such a mode, the efficiency is still not high, and the battery isolation pad is generally stacked in a material rack or a material box, and the material rack or the material box needs to be replaced after being taken out by the feeding mechanism, so that the feeding is required to be stopped at the moment, and the efficiency is further reduced.

Disclosure of utility model

In order to solve the problems, the utility model provides a multi-station feeding device for a battery isolation pad, which can realize rapid feeding of the isolation pad.

The utility model is realized by the following scheme:

A multistation loading attachment for battery isolation pad includes

The machine table is provided with a rack at one side;

the first feeding mechanism is arranged on the machine and used for providing a battery isolation pad;

The second feeding mechanism is arranged on the machine and used for providing a battery isolation pad;

The feeding mechanism is arranged on the frame;

The first transfer mechanism is arranged on the rack and used for transferring the battery isolation pad provided by the first feeding mechanism to the feeding mechanism;

The second transfer mechanism is arranged on the rack and used for transferring the battery isolation pad provided by the second feeding mechanism to the feeding mechanism;

The feeding mechanism comprises a turntable assembly arranged on the frame, and a plurality of material loading jigs arranged on the turntable assembly. Along with the rotation of carousel mechanism, first move and carry the mechanism and place the battery isolation pad that first feeding mechanism provided on carrying the material tool one by one, and when first move and carry the mechanism and get the battery isolation pad on a work or material rest on the first feeding mechanism, second move and carry mechanism and second feeding mechanism and can seamless joint and continue to shift the battery isolation pad to the feeding mechanism, after the battery isolation pad was shifted to carrying the material tool, tear membrane equipment can take away the battery isolation pad and tear the membrane.

Further, the first feeding mechanism and the second feeding mechanism comprise conveying components arranged on the machine table, and lifting components arranged on the machine table and used for lifting the battery isolation pad; the conveying assembly comprises a plurality of conveying belts which are arranged side by side and used for conveying the material frames, a first pushing assembly used for pushing the material frames between the adjacent conveying belts, and a second pushing assembly used for pushing the material frames from the conveying belts to the lifting assembly; the conveying directions of two adjacent conveying belts are opposite.

Further, the lifting assembly comprises a linear module connected with the frame, and a lifting piece connected with the linear module, wherein the linear module is arranged along the vertical direction.

Further, the first pushing component and the second pushing component both comprise a first guide rail connected with the conveyor belt, a pushing piece movably connected to the guide rail, and a first pushing driving piece used for driving the pushing piece to move along the guide rail.

Further, the first feeding mechanism and the second feeding mechanism each further comprise a third pushing assembly for pushing the material rack from the lifting assembly to the conveyor belt; the third pushing assembly comprises a second guide rail arranged on the conveyor belt, a movable seat connected with the second guide rail, an elastic pushing block arranged on the movable seat, and a second pushing driving piece for driving the movable seat. One end of the elastic push block is rotationally connected with the movable seat, and an elastic piece is connected between the elastic push block and the movable seat, so that the elastic push block can stretch under the action of the elastic piece, namely can retract when contacting with the material rack from one direction, and can prop against the material rack when contacting with the material rack from the opposite direction, so as to push the material rack to move.

Further, the conveyor belt is provided with three conveyor belts including two feeding conveyor belts and one discharging conveyor belt. Two feeding conveyors can place more racks.

Further, the first transferring mechanism and the second transferring mechanism both comprise transferring rotating seats arranged on the frame, transferring supports connected with the transferring rotating seats, and transferring driving components used for driving the transferring supports to rotate, and a plurality of material taking pieces are arranged on the transferring supports.

Furthermore, a plurality of support arms are uniformly distributed on the transfer support, and the material taking parts are arranged on the support arms.

Further, the material taking part is a suction nozzle, a switching mechanism used for connecting the material taking part is arranged on the frame, the switching mechanism comprises a switching frame arranged on the frame, a rotary air connector arranged on the switching frame, and the rotary air connector is connected with the material taking part.

Further, the feeding mechanism further comprises a feeding driving piece which is arranged on the frame and used for driving the turntable assembly to rotate.

Compared with the prior art, the utility model has the following beneficial effects:

According to the utility model, the first feeding mechanism, the second feeding mechanism and the feeding mechanism are arranged, and the first feeding mechanism and the second feeding mechanism can be in seamless connection to feed to the feeding mechanism under the cooperation of the first transferring mechanism and the second transferring mechanism, so that the feeding mechanism can perform feeding action without stopping for feeding, the feeding speed is improved, and the production rate is improved. Simultaneously, a plurality of work or material rest can be placed in advance to first feeding mechanism and second feeding mechanism, can carry out automatic reloading fast at the feeding in-process, need not manual operation, has further improved the operating efficiency.

Drawings

Fig. 1 is a schematic structural diagram of a multi-station feeding device for a battery isolation pad.

Figure 2 is a schematic view of a lift assembly of the present utility model.

Fig. 3 is a schematic view of a third pushing assembly according to the present utility model.

FIG. 4 is a schematic view of another embodiment of the present utility model.

The figure comprises the following components:

The machine platform 1, the machine frame 11, the first feeding mechanism 2, the conveying assembly 21, the conveying belt 211, the first pushing assembly 212, the first guide rail 212a, the pushing piece 212b, the first pushing driving piece 212c, the second pushing assembly 213, the lifting assembly 22, the linear module 221, the lifting piece 222, the third pushing assembly 23, the second guide rail 231, the elastic pushing block 232, the second pushing driving piece 233, the second feeding mechanism 3, the feeding mechanism 4, the turntable assembly 41, the loading jig 42, the feeding driving piece 43, the first transferring mechanism 5, the transferring rotating seat 51, the transferring bracket 52, the transferring driving assembly 53, the material taking piece 54, the supporting arm 55, the second transferring mechanism 6, the transferring mechanism 7, the transferring bracket 71 and the rotary air joint 72.

Detailed Description

In order to facilitate an understanding of the present utility model by those skilled in the art, the present utility model will be described in further detail with reference to specific examples and drawings.

Referring to fig. 1 to 4, the multi-station feeding device for battery isolation pads provided by the utility model comprises a machine table 1, a frame 11, a first feeding mechanism 2, a second feeding mechanism 3, a feeding mechanism 4, a first transferring mechanism 5 and a second transferring mechanism 6.

Wherein: a rack 11 is arranged on one side of the machine table 1; the first feeding mechanism 2 is arranged on the machine table 1 and is used for providing a battery isolation pad; the second feeding mechanism 3 is arranged on the machine table 1 and is used for providing a battery isolation pad; the feeding mechanism 4 is arranged on the frame 11; the first transfer mechanism 5 is arranged on the frame 11 and is used for transferring the battery isolation pad provided by the first feeding mechanism 2 to the feeding mechanism 4; the second transfer mechanism 6 is disposed on the frame 11, and is configured to transfer the battery isolation pad provided by the second feeding mechanism 3 to the feeding mechanism 4.

The feeding mechanism 4 comprises a turntable assembly 41 arranged on the frame 11, and a plurality of material loading jigs 42 arranged on the turntable assembly 41. The feeding mechanism 4 further comprises a feeding driving member 43 disposed on the frame 11 and used for driving the turntable assembly 41 to rotate. In this embodiment, the feeding driving member 43 employs a motor. In this embodiment, the loading fixture 42 is uniformly provided with four stations, that is, four stations, and sequentially includes a first loading station, an empty station, a second loading station, and a loading station, where the first loading station corresponds to the first transfer mechanism 5, and the second loading station corresponds to the second transfer mechanism.

Along with the rotation of carousel mechanism, first move and carry mechanism 5 and place the battery isolation pad that first feeding mechanism 2 provided on carrying tool 42 one by one, and when first move and carry mechanism 5 and get the battery isolation pad on a work or material rest on the first feeding mechanism 2, second move and carry mechanism 6 and second feeding mechanism 3 can seamless joint continue to shift the battery isolation pad to feed mechanism 4, after the battery isolation pad was shifted to carrying tool 42, tear membrane equipment can take away the battery isolation pad and tear the membrane.

The first feeding mechanism 2 and the second feeding mechanism 3 comprise a conveying assembly 21 arranged on the machine table 1, and a lifting assembly 22 arranged on the machine frame 11 and used for lifting a battery isolation pad; the conveying assembly 21 comprises a plurality of conveying belts 211 which are arranged side by side and used for conveying the material frames, a first pushing assembly 212 for pushing the material frames between the adjacent conveying belts 211, and a second pushing assembly 213 for pushing the material frames from the conveying belts 211 to the lifting assembly 22; the conveying directions of the adjacent two conveying belts 211 are opposite.

In this embodiment, the conveyor 211 is provided with three conveyor 211 including two feeding conveyors 211 and one discharging conveyor 211. More racks can be placed on the two feeding conveyor belts 211, but more feeding conveyor belts 211 can be arranged according to actual requirements to store more racks. The first pushing assembly 212 is disposed at the end of the conveying path of the feeding conveyor belt 211 (or at the beginning of the conveying path of the feeding conveyor belt 211) for pushing the racks from one of the conveyor belts 211 into the other conveyor belt 211. The material rack with the isolation pad is placed on the feeding conveyor belt 211 until the two feeding conveyor belts 211 are piled up, and after the battery isolation pad on the material rack is taken out, the material rack is pushed into the discharging conveyor belt 211 to be sent out, and then the material rack is taken out by a worker.

The lifting assembly 22 comprises a linear module 221 connected with the frame 11, and a lifting member 222 connected with the linear module 221, wherein the linear module 221 is arranged along the vertical direction. The lifting assembly 22 further comprises a loading table, the material rack is pushed into the loading table by the second pushing assembly 213 and then stops, at this time, the lifting element 222 is located below the battery isolation pad at the lowest position of the material rack, and when the linear module 221 drives the lifting element 222 to move upwards, the battery isolation pad in the material rack can be lifted upwards, so that the first transfer mechanism 5/the second transfer mechanism 6 can be conveniently removed.

The first pushing assembly 212 and the second pushing assembly 213 each include a first guide rail 212a connected to the conveyor 211, a pushing member 212b movably connected to the guide rail, and a first pushing driving member 212c for driving the pushing member 212b to move along the guide rail. The pushing member 212b may push the rack from one of the feeding conveyor belts 211 to the other feeding conveyor belt 211 under the driving of the first pushing driving member 212c.

The first feeding mechanism 2 and the second feeding mechanism 3 also comprise a third pushing assembly 23 for pushing the material rack from the lifting assembly 22 to the conveyor belt 211; the third pushing assembly 23 includes a second guide rail 231 disposed on the conveyor belt 211, a moving seat connected to the second guide rail 231, an elastic pushing block 232 disposed on the moving seat, and a second pushing driving member 233 for driving the moving seat. In this embodiment, the first pushing driving member 212c and the second pushing driving member 233 each use an air cylinder. One end of the elastic push block 232 is rotationally connected with the movable seat, meanwhile, an elastic piece is connected between the elastic push block 232 and the movable seat, one end of the elastic push block 232 stretches out of the range of the material rack in an initial state, after the movable seat starts to move from one side of the material rack, the elastic piece is compressed after the elastic push block 232 contacts with the material rack, the elastic push block 232 retracts, after the movable seat moves to the other end beyond the material rack, the elastic push block 232 resets, at the moment, the movable seat moves back, the elastic push block 232 clamps the material rack, and therefore the material rack is pushed to move.

The first transfer mechanism 5 and the second transfer mechanism 6 each comprise a transfer rotating seat 51 arranged on the frame 11, a transfer support 52 connected with the transfer rotating seat 51, and a transfer driving assembly 53 for driving the transfer support 52 to rotate, wherein a plurality of material taking pieces 54 are arranged on the transfer support 52. The transferring rotating seat 51 can be matched with a guide seat, and the guide seat is provided with a guide structure (such as a wave-shaped structure), so that the transferring rotating seat 51 can ascend or descend after rotating for a certain angle, the transferring support 52 descends when the material taking part 54 reaches the corresponding position of the lifting assembly 22, the material taking part 54 sucks up the battery isolation pad, and descends when the material taking part 54 reaches the corresponding position of the material carrying jig 42, and the battery isolation pad is placed on the material carrying jig 42.

A plurality of support arms 55 are uniformly distributed on the transfer support 52, and the material taking member 54 is arranged on the support arms 55. In this embodiment, the transfer support 52 has four support arms 55, i.e., forming a cross shape, and 2 material taking members 54 are provided on each support arm 55. Namely, every ninety degrees of rotation, the first transfer mechanism 5/the second transfer mechanism 6 can finish the actions of taking, transferring and discharging the battery isolation pad, and the feeding rhythm is fast.

The material taking part 54 is a suction nozzle, the frame 11 is provided with a transfer mechanism 7 for connecting the material taking part 54, the transfer mechanism 7 comprises a transfer frame 71 arranged on the frame 11, a rotary air connector 72 arranged on the transfer frame 71, and the rotary air connector 72 is connected with the material taking part 54. The material loading jig 42 may adopt a suction cup, and a rotary air connector 72 is required to be correspondingly arranged, so that the battery isolation pad can be adsorbed after being placed on the suction cup by the first transfer mechanism 5/the second transfer mechanism 6, and the battery isolation pad is prevented from falling off.

In specific operation, a worker firstly places the material rack storing the battery isolation pad on the feeding conveyor belt 211 of the first feeding mechanism 2 (places a plurality of material racks, and can fill the conveyor belt 211), then the material rack storing the battery isolation pad enters the lifting component 22 of the first feeding mechanism 2, the first feeding starts feeding (at this time, the material rack storing the battery isolation pad can be placed on the feeding conveyor belt 211 of the second feeding mechanism 3 at the same time, of course, the material rack can be placed on the first feeding mechanism 2 and the second feeding mechanism 3 at the same time), the first transferring mechanism 5 sequentially transfers the battery isolation pad provided by the first feeding mechanism 2 onto the loading tool 42 of the loading mechanism 4, the turntable component 41 sequentially rotates, when the battery isolation pad of the current material rack of the first feeding mechanism 2 is taken out, the first feeding mechanism 2 needs to send the empty material rack to the discharging conveyor belt 211, the second mechanism 3 starts feeding, the second mechanism 3 can transfer the battery isolation pad to the other lifting component 22 in the process of filling the first feeding mechanism 2, and the other material rack is lifted by the second feeding mechanism 3. When the battery isolation pad of the current material rack is taken out by the second feeding mechanism 3, the empty material rack needs to be sent out to the discharging conveyor belt 211, and the first feeding mechanism 2 takes over for feeding, and so on. The first feeding mechanism 2 and the second feeding mechanism 3 can be in seamless connection for feeding, so that the operation without stopping is performed.

According to the utility model, the first feeding mechanism 2, the second feeding mechanism 3 and the feeding mechanism 4 are arranged, and under the cooperation of the first transfer mechanism 5 and the second transfer mechanism 6, the first feeding mechanism 2 and the second feeding mechanism 3 can be in seamless connection to feed to the feeding mechanism 4, so that the feeding mechanism 4 can perform feeding action uninterruptedly without stopping for feeding, the feeding speed is improved, and the productivity is improved. Simultaneously, a plurality of work or material rest can be placed in advance to first feeding mechanism 2 and second feeding mechanism 3, can carry out automatic reloading fast at the feeding in-process, need not manual operation, has further improved the operating efficiency.

In the description of the present utility model, it should be understood that the orientation or positional relationship indicated is based on the orientation or positional relationship shown in the drawings, and is merely for convenience in describing the present utility model and simplifying the description, and does not indicate or imply that the apparatus or element referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the present utility model, unless explicitly specified and limited otherwise, the terms "connected," "fixed" and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

While the utility model has been described in conjunction with the specific embodiments above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, all such alternatives, modifications, and variations are included within the scope of the appended claims.

Claims (10)

1. A multistation loading attachment for battery isolation pad, characterized by including

The machine table is provided with a rack at one side;

the first feeding mechanism is arranged on the machine and used for providing a battery isolation pad;

The second feeding mechanism is arranged on the machine and used for providing a battery isolation pad;

The feeding mechanism is arranged on the frame;

The first transfer mechanism is arranged on the rack and used for transferring the battery isolation pad provided by the first feeding mechanism to the feeding mechanism;

The second transfer mechanism is arranged on the rack and used for transferring the battery isolation pad provided by the second feeding mechanism to the feeding mechanism;

The feeding mechanism comprises a turntable assembly arranged on the frame, and a plurality of material loading jigs arranged on the turntable assembly.

2. The multi-station feeding device for battery isolation pads according to claim 1, wherein the first feeding mechanism and the second feeding mechanism comprise a conveying assembly arranged on the machine table, and a lifting assembly arranged on the machine frame and used for lifting the battery isolation pads; the conveying assembly comprises a plurality of conveying belts which are arranged side by side and used for conveying the material frames, a first pushing assembly used for pushing the material frames between the adjacent conveying belts, and a second pushing assembly used for pushing the material frames from the conveying belts to the lifting assembly; the conveying directions of two adjacent conveying belts are opposite.

3. The multi-station feeding device for battery isolation pads according to claim 2, wherein the lifting assembly comprises a linear module connected with the frame, and a lifting piece connected with the linear module, and the linear module is arranged along the vertical direction.

4. The multi-station loading device for battery isolation pads according to claim 2, wherein the first pushing component and the second pushing component each comprise a first guide rail connected with the conveyor belt, a pushing piece movably connected to the guide rail, and a first pushing driving piece for driving the pushing piece to move along the guide rail.

5. The multi-station feeding device for battery spacers as claimed in claim 2, wherein the first and second feeding mechanisms each further comprise a third pushing assembly for pushing the racks from the lifting assembly to the conveyor belt; the third pushing assembly comprises a second guide rail arranged on the conveyor belt, a movable seat connected with the second guide rail, an elastic pushing block arranged on the movable seat, and a second pushing driving piece for driving the movable seat.

6. The multi-station feeding device for battery spacers as claimed in claim 2, wherein the conveyor belts are three, including two feeding conveyor belts and one discharging conveyor belt.

7. The multi-station loading device for battery isolation pads according to claim 1, wherein the first transfer mechanism and the second transfer mechanism comprise a transfer rotating seat arranged on the frame, a transfer support connected with the transfer rotating seat, and a transfer driving assembly for driving the transfer support to rotate, and a plurality of material taking pieces are arranged on the transfer support.

8. The multi-station feeding device for battery isolation pads according to claim 7, wherein a plurality of support arms are uniformly distributed on the transfer support, and the material taking pieces are arranged on the support arms.

9. The multi-station feeding device for the battery isolation pad according to claim 7, wherein the material taking part is a suction nozzle, a switching mechanism for connecting the material taking part is arranged on the rack, the switching mechanism comprises a switching frame arranged on the rack, a rotary gas connector is arranged on the switching frame, and the rotary gas connector is connected with the material taking part.

10. The multi-station loading device for battery isolation pads of claim 1, wherein the loading mechanism further comprises a loading driving member arranged on the frame and used for driving the turntable assembly to rotate.