CN220165109U - Rotary feeding mechanism for battery piece - Google Patents

Abstract

The utility model discloses a battery piece rotary feeding mechanism. Comprises a rotating plate, a discharging box, a lifting mechanism, a rotating mechanism and a bracket; the automatic feeding device is characterized in that a lifting mechanism is arranged in the support, a rotating mechanism is arranged at the top of the lifting mechanism, a rotating plate is arranged on the rotating mechanism, a discharging box is arranged on the rotating plate, and the discharging box is symmetrically arranged in the center of the rotating plate; after the top surface and the front surface of the discharging box are of an opening structure, a material taking structure is arranged on the bottom surface of the discharging box; the initial point and the end point of the rotating track of the discharging box are respectively aligned with the feeding direction of the conveying belt in the previous process and the conveying belt in the next process; and the conveyer belt in the next procedure takes out the battery pieces in the discharging box through a material taking structure. The utility model greatly reduces the labor intensity of operators.

Description

Rotary feeding mechanism for battery piece

Technical field:

the utility model belongs to the technical field of battery piece production, and particularly relates to a battery piece rotary feeding mechanism.

The background technology is as follows:

in the production process of the battery piece, the battery piece is conveyed by a conveying belt between two working procedures. The heights of the conveying belts are different due to different heights of the inlets of the devices in the previous and subsequent procedures. Thus, the battery piece can not be automatically conveyed to the conveying belt of the next process on the conveying belt of the previous process.

In the prior art, operators are arranged at the tail end of a conveyer belt in the previous process to collect battery pieces, then the collected battery pieces are delivered to operators at the initial end of the conveyer belt in the next process, and the operators at the initial end forward convey the collected battery pieces on the conveyer belt in the next process one by one, so that the labor intensity of the operators is high. Because two conveyor belts are generally arranged on the production line for conveying simultaneously, four operators are required to be arranged, and labor cost is increased.

The information disclosed in this background section is only for enhancement of understanding of the general background of the utility model and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person of ordinary skill in the art.

The utility model comprises the following steps:

the utility model aims to provide a battery piece rotary feeding mechanism, which is characterized in that a feeding mechanism is arranged between two conveying belts to replace manual feeding to a subsequent process, so that the manual feeding is reduced, and the defects in the prior art are overcome.

In order to achieve the above purpose, the utility model provides a battery piece rotary feeding mechanism which is arranged between conveying belts in two working procedures; comprises a rotating plate, a discharging box, a lifting mechanism, a rotating mechanism and a bracket; the automatic feeding device is characterized in that a lifting mechanism is arranged in the support, a rotating mechanism is arranged at the top of the lifting mechanism, a rotating plate is arranged on the rotating mechanism, a discharging box is arranged on the rotating plate, and the discharging box is symmetrically arranged in the center of the rotating plate; after the top surface and the front surface of the discharging box are of an opening structure, a material taking structure is arranged on the bottom surface of the discharging box; the initial point and the end point of the rotating track of the discharging box are respectively aligned with the feeding direction of the conveying belt in the previous process and the conveying belt in the next process; and the conveyer belt in the next procedure takes out the battery pieces in the discharging box through a material taking structure.

Preferably, in the technical scheme, the lifting mechanism comprises a lifting cylinder, a lifting plate, a guide pillar, a guide sleeve and a top plate, wherein the lifting cylinder is arranged on the support, the lifting plate and the guide sleeve are arranged in the support, the lifting cylinder is connected with the lifting plate, the guide pillar is arranged on the lifting plate, the guide sleeve is sleeved on the guide pillar, the top of the guide pillar is provided with the top plate, the lifting plate is driven to lift by the lifting cylinder, and the top plate is driven to lift by the lifting plate through the guide pillar.

Preferably, in the technical scheme, the rotating mechanism comprises a rotating motor, a rotating shaft and a reversing transmission mechanism, wherein the rotating motor and the reversing transmission mechanism are arranged on the top plate, the reversing transmission mechanism is in worm and gear transmission, the rotating motor is transmitted with the rotating shaft through the reversing transmission mechanism, and the rotating shaft is connected with the rotating plate.

Preferably, in the technical scheme, the rotating plate comprises a longitudinal plate and a transverse plate, wherein the transverse plates are symmetrically arranged at the centers of two ends of the longitudinal plate, the longitudinal plate and the transverse plate form a Z-shaped structure, a discharging box is arranged on the transverse plate, and the longitudinal plate is connected with the rotating shaft.

Preferably, in the technical scheme, the material taking structure on the bottom surface of the material placing box is a material taking groove, the trend of the material taking groove is consistent with the conveying belt direction of the next process, the size of the material taking groove is matched with the conveying belt of the next process, and the conveying belt of the next process is provided with the material taking groove to take out the battery pieces in the material placing box.

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

the battery piece can be placed on the conveyer belt to be conveyed forwards by replacing an operator on the conveyer belt in the next process through the rotary feeding mechanism, and the operator at the tail end of the conveyer belt in the previous process only needs to collect the battery piece and place the battery piece in the discharging box. The number of operators is halved, and the labor cost is reduced.

Description of the drawings:

FIG. 1 is a front view of a rotary battery plate feeding mechanism of the present utility model;

FIG. 2 is a perspective view of a rotary battery plate feeding mechanism according to the present utility model;

FIG. 3 is a schematic diagram illustrating the assembly of a rotary battery plate feeding mechanism according to the present utility model;

the reference numerals are: 1-rotating plate, 2-discharging box, 3-lifting mechanism, 4-rotating mechanism, 5-bracket, 6-conveyer belt of previous process, 7-conveyer belt of next process, 8-battery piece, 10-longitudinal plate, 11-transverse plate, 20-material taking groove, 30-lifting cylinder, 31-lifting plate, 32-guide pillar, 33-guide sleeve, 34-top plate, 40-rotating motor and 41-rotating shaft.

The specific embodiment is as follows:

the following detailed description of specific embodiments of the utility model is, but it should be understood that the utility model is not limited to specific embodiments.

Throughout the specification and claims, unless explicitly stated otherwise, the term "comprise" or variations thereof such as "comprises" or "comprising", etc. will be understood to include the stated element or component without excluding other elements or components.

As shown in fig. 1-3, a battery piece rotary feeding mechanism is arranged between conveying belts in two working procedures; comprises a rotating plate 1, a discharging box 2, a lifting mechanism 3, a rotating mechanism 4 and a bracket 5; the lifting mechanism 3 is arranged in the bracket 5, the lifting mechanism 3 comprises a lifting cylinder 30, a lifting plate 31, a guide pillar 32, a guide sleeve 33 and a top plate 34, the lifting cylinder 30 is arranged on the bracket 5, the lifting plate 31 and the guide sleeve 33 are arranged in the bracket 5, the lifting cylinder 30 is connected with the lifting plate 31, the lifting plate 31 is provided with the guide pillar 32, the guide pillar 32 is sleeved with the guide sleeve 33, the top of the guide pillar 32 is provided with the top plate 34, the lifting plate 31 is driven to lift by the lifting cylinder 30, and the lifting plate 31 drives the top plate 34 to lift by the guide pillar 32; the rotating mechanism 4 comprises a rotating motor 40, a rotating shaft 41 and a worm and gear transmission mechanism, the rotating motor 40 and the worm and gear transmission mechanism are arranged on the top plate 34, the rotating motor 40 is transmitted with the rotating shaft 41 through the worm and gear transmission mechanism, and the rotating shaft 41 is connected with the rotating plate 1; the rotating plate 1 comprises a longitudinal plate 10 and a transverse plate 11, wherein the transverse plates 11 are arranged at the centers of two ends of the longitudinal plate 10 in a symmetrical mode, the longitudinal plate 10 and the transverse plate 11 form a Z-shaped structure, the transverse plate 11 is provided with a discharging box 2, and the longitudinal plate 10 is connected with a rotating shaft 41.

After the top surface and the front surface of the discharging box 2 are of an opening structure, a material taking groove 20 is formed in the bottom surface of the discharging box 2, the trend of the material taking groove 20 is consistent with that of the conveying belt 7 in the next process, and the size of the material taking groove 20 is matched with that of the conveying belt 7 in the next process; the initial point and the end point of the rotating track of the discharging box 2 are respectively aligned with the feeding direction of the conveying belt 6 in the previous process and the conveying belt 7 in the next process; the conveyer belt 7 in the next process takes out the battery pieces 8 in the discharging box 2 through the material taking groove 20.

The battery piece 8 is conveyed to an operator from the conveyer belt 6 in the previous process, the operator collects the battery piece 8 and then places the battery piece 8 in the discharging box 2, the lifting cylinder 30 is started to drive the discharging box 2 to ascend, the rotating motor 40 is started, the discharging box 2 rotates 180 degrees, the discharging box 2 rotates to the position above the inlet of the conveyer belt 7 in the next process, the lifting cylinder 30 is reset, the discharging box 2 descends to the inlet of the conveyer belt 7 in the next process, the conveyer belt 7 in the next process takes out the battery piece 8 in the discharging box 2 through the material taking groove 20, and meanwhile, the operator places the collected battery piece 8 in the discharging box 2 on one side of the conveyer belt 6 in the previous process, and the battery piece 8 is conveyed continuously in a circulating mode. Compared with the prior art, the labor intensity of operators is greatly reduced. The number of operators is halved, and the labor cost is reduced.

The foregoing descriptions of specific exemplary embodiments of the present utility model are presented for purposes of illustration and description. It is not intended to limit the utility model to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain the specific principles of the utility model and its practical application to thereby enable one skilled in the art to make and utilize the utility model in various exemplary embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the utility model be defined by the claims and their equivalents.

Claims (5)

1. The utility model provides a rotatory feed mechanism of battery piece which characterized in that: the battery piece rotary feeding mechanism is arranged between the conveying belts of the two working procedures; comprises a rotating plate, a discharging box, a lifting mechanism, a rotating mechanism and a bracket; the automatic feeding device is characterized in that a lifting mechanism is arranged in the support, a rotating mechanism is arranged at the top of the lifting mechanism, a rotating plate is arranged on the rotating mechanism, a discharging box is arranged on the rotating plate, and the discharging box is symmetrically arranged in the center of the rotating plate; after the top surface and the front surface of the discharging box are of an opening structure, a material taking structure is arranged on the bottom surface of the discharging box; the initial point and the end point of the rotating track of the discharging box are respectively aligned with the feeding direction of the conveying belt in the previous process and the conveying belt in the next process; and the conveyer belt in the next procedure takes out the battery pieces in the discharging box through a material taking structure.

2. The rotary battery plate feeding mechanism according to claim 1, wherein: the lifting mechanism comprises a lifting cylinder, a lifting plate, a guide pillar, a guide sleeve and a top plate, wherein the lifting cylinder is arranged on the support, the lifting plate and the guide sleeve are arranged in the support, the lifting cylinder is connected with the lifting plate, the lifting plate is provided with the guide pillar, the guide sleeve is sleeved on the guide pillar, the top of the guide pillar is provided with the top plate, the lifting plate is driven to lift by the lifting cylinder, and the lifting plate drives the top plate to lift by the guide pillar.

3. The rotary battery plate feeding mechanism according to claim 2, wherein: the rotating mechanism comprises a rotating motor, a rotating shaft and a reversing transmission mechanism, wherein the rotating motor and the reversing transmission mechanism are arranged on the top plate, the reversing transmission mechanism is in worm and gear transmission, the rotating motor is transmitted with the rotating shaft through the reversing transmission mechanism, and the rotating shaft is connected with the rotating plate.

4. The rotary battery plate feeding mechanism according to claim 3, wherein: the rotating plate comprises a longitudinal plate and a transverse plate, wherein the transverse plates are symmetrically arranged at the centers of two ends of the longitudinal plate, the longitudinal plate and the transverse plate form a Z-shaped structure, a discharging box is arranged on the transverse plate, and the longitudinal plate is connected with the rotating shaft.

5. The rotary battery plate feeding mechanism according to claim 1, wherein: the material taking structure on the bottom surface of the discharging box is a material taking groove, the trend of the material taking groove is consistent with the conveying belt direction of the next process, the size of the material taking groove is matched with the conveying belt of the next process, and the conveying belt of the next process is provided with the material taking groove to take out the battery pieces in the discharging box.