CN219485296U

CN219485296U - Welding strip cutting device

Info

Publication number: CN219485296U
Application number: CN202320348199.1U
Authority: CN
Inventors: 曹建伟; 傅林坚; 朱亮; 卢嘉彬; 高红刚; 张剑光; 郭伟强; 黄长兴
Original assignee: Zhejiang Jingsheng Mechanical and Electrical Co Ltd
Current assignee: Zhejiang Jingsheng Mechanical and Electrical Co Ltd
Priority date: 2023-02-23
Filing date: 2023-02-23
Publication date: 2023-08-08
Anticipated expiration: 2033-02-23

Abstract

The utility model discloses a welding strip cutting device, which comprises: the grinding wheel mechanism is used for cutting the welding strip; the first driving mechanism is rotationally connected to the grinding wheel mechanism and controls the grinding wheel mechanism to rotate around the axis of the grinding wheel mechanism; the driving assembly is connected to the first driving mechanism and controls the first driving mechanism to move along the horizontal direction and/or the vertical direction of the welding strip cutting device. Through the arrangement, the welding strips at different stations can be cut; the cutting precision of the welding strip can be improved, so that the deformation of the welding strip after cutting is reduced, and the service life of the welding strip is prolonged.

Description

Welding strip cutting device

Technical Field

The utility model relates to the technical field of photovoltaic processing equipment, in particular to a welding strip cutting device.

Background

In the photovoltaic processing field, the existing welding strip cutting mode generally adopts an upper cutter and a lower cutter for cutting. Specifically, the upper cutter and/or the lower cutter are driven to move by a linear motor or the like, so that the cutting effect of the welding strip cutting device on the welding strip is realized.

However, cutting the solder strip by the cutter may cause bending deformation of the solder strip, which is disadvantageous for subsequent processing of the solder strip. In addition, the structure of the cutting device adopting the cutting mode is complex, the occupied space is large, the cutting precision of the cutter is low, the controllability is poor, and the subsequent processing of the welding strip is not facilitated, so that the processing efficiency is influenced.

Disclosure of Invention

In order to solve the defects in the prior art, the utility model aims to provide a welding strip cutting device capable of improving cutting precision.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

a solder strip cutting device comprising: the grinding wheel mechanism is used for cutting the welding strip; the first driving mechanism is rotationally connected to the grinding wheel mechanism and controls the grinding wheel mechanism to rotate around the axis of the grinding wheel mechanism; the driving assembly is connected to the first driving mechanism and controls the first driving mechanism to move along the horizontal direction and/or the vertical direction of the welding strip cutting device.

Further, the driving assembly comprises a second driving mechanism and a third driving mechanism; the second driving mechanism is connected with the first driving mechanism, the second driving mechanism controls the first driving mechanism to move along the horizontal direction, the third driving mechanism is connected with the second driving mechanism, and the third driving mechanism controls the second driving mechanism to move along the vertical direction; or the second driving mechanism is connected with the third driving mechanism, the second driving mechanism controls the third driving mechanism to move along the horizontal direction, the third driving mechanism is connected with the first driving mechanism, and the third driving mechanism controls the first driving mechanism to move along the vertical direction.

Further, the welding strip cutting device further comprises a dust removing mechanism, the dust removing mechanism is at least partially arranged on the second driving mechanism, and the dust removing mechanism is arranged close to the grinding wheel mechanism.

Further, the dust removing mechanism comprises a dust removing air pipe and a first driving piece for generating negative pressure, one end of the dust removing air pipe is arranged on the side face of the grinding wheel mechanism and at least partially surrounds the grinding wheel mechanism, and the first driving piece is arranged at the other end of the dust removing air pipe.

Further, the second driving mechanism comprises a first sliding groove and a second driving piece, the first driving mechanism is in sliding connection with the first sliding groove, and the second driving piece controls the first driving mechanism to move along the first sliding groove.

Further, the first chute extends in the horizontal direction.

Further, the welding strip cutting device further comprises a rotating mechanism, the rotating mechanism is connected to the second driving mechanism, and the rotating mechanism controls the second driving mechanism to rotate along the circumferential direction of the welding strip cutting device.

Further, the rotating mechanism is at least partially arranged between the second driving mechanism and the third driving mechanism, two ends of the rotating mechanism are respectively connected to the second driving mechanism and the third driving mechanism, and the third driving mechanism controls the rotating mechanism to move along the vertical direction of the welding strip cutting device.

Further, the rotating mechanism comprises a connecting piece connected to the third driving mechanism in a sliding way, and a rotating piece fixedly connected to the connecting piece, wherein the rotating piece has a rotation degree of freedom and is also connected with the second driving mechanism.

Further, the third driving mechanism comprises a second chute and a third driving piece, the connecting piece is connected with the second chute in a sliding mode, the third driving piece controls the connecting piece to move along the second chute, and the second chute extends in the vertical direction.

According to the welding strip cutting device provided by the utility model, the rotation of the grinding wheel mechanism can be controlled through the first driving mechanism, and the horizontal position and the vertical position of the grinding wheel mechanism are controlled through the driving assembly, so that the cutting of welding strips at different stations is realized; the cutting precision of the welding strip can be improved through the grinding wheel mechanism, so that the deformation of the welding strip after cutting is reduced, and the service life of the welding strip is prolonged.

Drawings

Fig. 1 is a schematic structural view of a solder strip cutting device according to the present utility model.

Fig. 2 is a schematic view of another angle of the solder strip cutting device according to the present utility model.

Fig. 3 is an enlarged view of a portion of fig. 2 a in accordance with the present utility model.

Fig. 4 is a schematic side view of the solder strip cutting device of the present utility model.

Fig. 5 is a schematic structural connection diagram of the solder strip cutting device of the present utility model.

Detailed Description

In order to make the present utility model better understood by those skilled in the art, the technical solutions in the specific embodiments of the present utility model will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present utility model.

As shown in fig. 1 and 2, a welding-ribbon cutting device 100 includes a grinding wheel mechanism 11, a first driving mechanism 12, and a driving assembly 13. The grinding wheel mechanism 11 serves as a cutting member of the welding-ribbon cutting device 100 for cutting the welding ribbon. The grinding wheel mechanism 11 is rotatably connected to the first drive mechanism 12 such that the first drive mechanism 12 is capable of controlling the grinding wheel mechanism 11 to rotate about the axis of the grinding wheel mechanism 11. The driving assembly 13 is connected to the first driving mechanism 12, and the driving assembly 13 controls the first driving mechanism 12 to move along the horizontal direction and/or the vertical direction of the welding-strip cutting device 100, so as to drive the grinding wheel mechanism 11 to move along the horizontal direction and/or the vertical direction of the welding-strip cutting device 100. Specifically, the drive assembly 13 includes a second drive mechanism 131 and a third drive mechanism 132. The second driving mechanism 131 is used for controlling the first driving mechanism 12 to move in the horizontal direction of the ribbon cutting device 100, and the third driving mechanism 132 is used for controlling the first driving mechanism 12 to move in the vertical direction of the ribbon cutting device 100. More specifically, the second driving mechanism 131 is connected to the first driving mechanism 12, so that the second driving mechanism 131 can control the first driving mechanism 12 to move in the horizontal direction of the ribbon cutting device 100 to drive the grinding wheel mechanism 11 to move in the horizontal direction of the ribbon cutting device 100. The third driving mechanism 132 is connected to the second driving mechanism 131, so that the third driving mechanism 132 can control the second driving mechanism 131 to move along the vertical direction of the welding-strip cutting device 100, so as to drive the grinding wheel mechanism 11 to move along the vertical direction of the welding-strip cutting device 100. It will be appreciated that as an alternative implementation, the second driving mechanism 131 is connected to the third driving mechanism 132, such that the second driving mechanism 131 can control the third driving mechanism 132 to move in the horizontal direction of the ribbon cutting device 100, and the third driving mechanism 132 is connected to the first driving mechanism 12, such that the third driving mechanism 132 controls the first driving mechanism 12 to move in the vertical direction of the ribbon cutting device 100. For clarity of explanation of the technical solution of the present utility model, the front side, the rear side, the left side, the right side, the upper side, and the lower side are also defined as shown in fig. 1. The second driving mechanism 131 is connected to the first driving mechanism 12, and the third driving mechanism 132 is connected to the second driving mechanism 131 is exemplified.

Wherein moving in the horizontal direction of the ribbon cutting device 100 means linearly reciprocating in a direction in a plane perpendicular to the up-down direction of the ribbon cutting device 100; the vertical direction refers to the up-down direction of the solder strip cutting device 100. Through the arrangement, the rotation of the grinding wheel mechanism 11 can be controlled through the first driving mechanism 12, the horizontal position of the grinding wheel mechanism 11 is controlled through the second driving mechanism 131, and the vertical position of the grinding wheel mechanism 11 is controlled through the third driving mechanism 132, so that the welding strips at different stations are cut; in addition, the arrangement mode can improve the structural compactness of the welding strip cutting device 100, and is beneficial to improving the space utilization rate of the welding strip cutting device 100. In addition, through the above-mentioned setting mode, can also improve the cutting accuracy of welding strip through grinding wheel mechanism 11 to reduce the deformation of welding strip after the cutting, and then improve the life of welding strip. As an alternative implementation manner, the first driving mechanism 12 is configured as a driving member capable of controlling the rotation of the grinding wheel mechanism 11, such as a driving motor, and the second driving mechanism 131 and the third driving mechanism 132 are configured as driving members capable of achieving linear reciprocating motion, such as a linear motor.

As shown in fig. 1 to 3, as an implementation manner, the welding strip cutting device 100 further includes a dust removing mechanism 15, where the dust removing mechanism 15 is disposed near the grinding wheel mechanism 11 and is used for collecting welding strip residues generated when the grinding wheel mechanism 11 cuts the welding strip, so as to avoid the welding strip residues remaining on the surface of the battery piece, prevent the adverse effect on the subsequent processing flow, and further improve the working efficiency of the welding strip processing. Specifically, the dust removing mechanism 15 is at least partially disposed on the second driving mechanism 131, so that the dust removing mechanism 15 can move along with the grinding wheel mechanism 11, which is advantageous for improving the dust removing effect of the dust removing mechanism 15.

It will be appreciated that the dust removing mechanism 15 may be disposed on other parts of the welding strip cutting device 100, and it is only required that the dust removing mechanism 15 can move along with the grinding wheel mechanism 11.

As shown in fig. 3, more specifically, the dust removing mechanism 15 includes a dust removing air duct 151 and a first driving member (not shown in the drawing) for generating negative pressure, one end of the dust removing air duct 151 is disposed on the side of the grinding wheel mechanism 11 and at least partially around the grinding wheel mechanism 11, and the other end of the dust removing air duct 151 is provided with the first driving member. The first drive element may be configured as a negative pressure device or as another drive element capable of generating suction. In the present embodiment, the first driving element generates negative pressure in the dust removing duct 151, so that the residue generated after the grinding wheel mechanism 11 cuts the weld tape can be collected by the dust removing mechanism 15.

As shown in fig. 2, as one implementation, the second drive mechanism 131 includes a first runner 1311 and a second drive member 1312. The second driver 1312 is at least partially disposed on the first runner 1311. The first drive mechanism 12 is slidably coupled to the first runner 1311, i.e., the first drive mechanism 12 is capable of sliding along the first runner 1311. The second driver 1312 is also coupled to the first driver 12 such that the second driver 1312 can control the movement of the first driver 12 along the first runner 1311. Wherein the first runner 1311 extends in a horizontal direction. Through the arrangement, the second driving mechanism 131 can drive the first driving mechanism 12 to move along the horizontal direction of the welding strip cutting device 100, so that the grinding wheel mechanism 11 connected with the first driving mechanism 12 is driven, the grinding wheel mechanism 11 can move along the horizontal direction of the welding strip cutting device 100, the grinding wheel mechanism 11 can meet the cutting of welding strips at different stations, and the flexibility and the cutting convenience of the grinding wheel mechanism 11 are improved.

As one implementation, the ribbon cutting device 100 further includes a rotation mechanism 16, the rotation mechanism 16 being connected to the second driving mechanism 131, the rotation mechanism 16 controlling the second driving mechanism 131 to rotate in the circumferential direction of the ribbon cutting device 100. Wherein circumferential rotation of the ribbon cutting device 100 refers to rotation about the axis of the rotation mechanism 16. Through the arrangement, the rotating mechanism 16 can drive the second driving mechanism 131 to rotate around the axis of the rotating mechanism 16, so that the grinding wheel mechanism 11 can contact the edge of the welding strip to be cut through a rotating angle, and the cutting effect of the grinding wheel mechanism 11 is improved.

Specifically, the rotation mechanism 16 is at least partially disposed between the second driving mechanism 131 and the third driving mechanism 132, and both ends of the rotation mechanism 16 are respectively connected to the second driving mechanism 131 and the third driving mechanism 132, so that the third driving mechanism 132 controls the rotation mechanism 16 to move in the vertical direction of the welding-strip cutting device 100, and further controls the first driving mechanism 12, the second driving mechanism 131, and the grinding-wheel mechanism 11 to move in the vertical direction of the welding-strip cutting device 100 through the rotation mechanism 16, so that the grinding-wheel mechanism 11 is lowered to a specified height when in operation, and the grinding-wheel mechanism 11 is raised to a preset height when not in operation. The specified height can be adjusted according to actual conditions and only needs to meet the requirement of cutting the welding strip; the preset height can be adjusted according to actual conditions, and normal operation of other devices is not affected.

As shown in fig. 4, in the present embodiment, the rotation mechanism 16 includes a link 161 slidably connected to the third driving mechanism 132, a rotation member 162 fixedly connected to the link 161, the rotation member 162 having a degree of freedom of rotation, the rotation member 162 being further connected to the second driving mechanism 131. Through the above arrangement, the connecting piece 161 can be driven to move along the up-and-down direction by the third driving mechanism 132, so that the rotating piece 162 drives the grinding wheel mechanism 11 connected to the second driving mechanism 131 to move along the up-and-down direction, so that the grinding wheel mechanism 11 can be at a specified height or a preset height, and the cutting efficiency of the grinding wheel mechanism 11 can be improved.

As shown in fig. 2, as one implementation, the third driving mechanism 132 includes a second sliding slot 1321 and a third driving member 1322, where the third driving member 1322 is at least partially disposed on the second sliding slot 1321. The connecting member 161 is slidably connected to the second slide 1321, i.e. the connecting member 161 is movable along the second slide 1321. The third driving member 1322 is further connected to the connecting member 161, so that the third driving member 1322 can control the movement of the connecting member 161 along the second sliding groove 1321. Wherein the second sliding groove 1321 extends in the vertical direction. Through the arrangement, the third driving mechanism 132 can drive the rotating mechanism 16 to move along the vertical direction of the welding strip cutting device 100, so as to drive the second driving mechanism 131 connected with the rotating mechanism 16, so that the grinding wheel mechanism 11 can move along the vertical direction of the welding strip cutting device 100, and the grinding wheel mechanism 11 can meet the cutting of welding strips at different stations, thereby being beneficial to improving the flexibility and cutting convenience of the grinding wheel mechanism 11. Further, the third driving mechanism 132, the rotating mechanism 16 and the second driving member 1312 are mutually matched, so that the grinding wheel mechanism 11 can perform linear reciprocating motion in the vertical direction, rotate in the circumferential direction and perform linear reciprocating motion in the horizontal direction, cutting of welding strips of different stations is met, and flexibility and cutting convenience of the grinding wheel mechanism 11 are improved.

Specifically, the solder strip cutting process is as follows:

the third driving mechanism 132 controls the grinding wheel mechanism 11 to descend to a specified height, and simultaneously the rotating mechanism 16 rotates to a specified angle, so that the grinding wheel mechanism 11 is positioned at the edge of the welding strip to be cut, and the axis of the grinding wheel mechanism 11 and the welding strip are parallel to each other;

the first driving mechanism 12 drives the grinding wheel mechanism 11 to rotate, and the second driving mechanism 131 realizes the cutting effect of the grinding wheel mechanism 11 on the welding belt. Simultaneously, the dust removing mechanism 15 synchronously moves along with the grinding wheel mechanism 11, so that the dust removing mechanism 15 can collect residues generated when the grinding wheel mechanism 11 cuts a welding strip;

after the grinding wheel mechanism 11 completes cutting the welding strip, the third driving mechanism 132 controls the grinding wheel mechanism 11 to rise to a preset height, and waits for the next welding strip cutting.

It will be understood that modifications and variations will be apparent to those skilled in the art from the foregoing description, and it is intended that all such modifications and variations be included within the scope of the following claims.

Claims

1. A solder strip cutting device, comprising:

the grinding wheel mechanism is used for cutting the welding strip;

a first drive mechanism rotatably coupled to the grinding wheel mechanism, the first drive mechanism controlling rotation of the grinding wheel mechanism about an axis of the grinding wheel mechanism;

the driving assembly is connected to the first driving mechanism and controls the first driving mechanism to move along the horizontal direction and/or the vertical direction of the welding strip cutting device.

2. The solder strip cutting device of claim 1, wherein the drive assembly comprises a second drive mechanism and a third drive mechanism;

the second driving mechanism is connected with the first driving mechanism, the second driving mechanism controls the first driving mechanism to move along the horizontal direction, the third driving mechanism is connected with the second driving mechanism, and the third driving mechanism controls the second driving mechanism to move along the vertical direction;

or, the second driving mechanism is connected with the third driving mechanism, the second driving mechanism controls the third driving mechanism to move along the horizontal direction, the third driving mechanism is connected with the first driving mechanism, and the third driving mechanism controls the first driving mechanism to move along the vertical direction.

3. The welding-strip cutting device of claim 2 further comprising a dust removal mechanism disposed at least partially on the second drive mechanism, the dust removal mechanism disposed proximate the grinding wheel mechanism.

4. A welding strip cutting apparatus according to claim 3, wherein the dust removing mechanism comprises a dust removing air pipe and a first driving member for generating negative pressure, one end of the dust removing air pipe is arranged on the side surface of the grinding wheel mechanism and at least partially surrounds the grinding wheel mechanism, and the other end of the dust removing air pipe is provided with the first driving member.

5. The solder strip cutting device according to any of claims 2 to 4, wherein the second drive mechanism comprises a first runner and a second drive member, the first drive mechanism being slidably coupled to the first runner, the second drive member controlling movement of the first drive mechanism along the first runner.

6. The solder strip cutting device of claim 5, wherein the first runner extends in the horizontal direction.

7. The ribbon cutting device of any one of claims 2 to 4, further comprising a rotation mechanism coupled to the second drive mechanism, the rotation mechanism controlling the second drive mechanism to rotate in a circumferential direction of the ribbon cutting device.

8. The ribbon cutting device of claim 7, wherein the rotation mechanism is at least partially disposed between the second drive mechanism and the third drive mechanism, both ends of the rotation mechanism being connected to the second drive mechanism and the third drive mechanism, respectively, the third drive mechanism controlling the rotation mechanism to move in a vertical direction of the ribbon cutting device.

9. The solder strip cutting device of claim 8, wherein the rotation mechanism comprises a connection member slidably coupled to the third drive mechanism, a rotation member fixedly coupled to the connection member, the rotation member having a rotational degree of freedom, the rotation member further coupled to the second drive mechanism.

10. The solder strip cutting device of claim 9, wherein the third drive mechanism comprises a second chute and a third drive member, the connector and the second chute being slidably coupled, the third drive member controlling movement of the connector along the second chute, the second chute extending in the vertical direction.