阅读说明：本技术 跨接片用可扩展连续热缩定位装置 (Expandable continuous thermal shrinkage positioning device for jumper ) 是由 沈川杰 李克锋 田雯 张懋慧 王舒丹 杨志云 于 2020-11-26 设计创作，主要内容包括：本发明提供了一种跨接片用可扩展连续热缩定位装置,包括扩展振动单元、分离隔板、导向条和定位尺,可以高精度快速地完成跨接片从分离隔板上部热缩完成后自动穿过分离隔板转移到分离隔板下方。该装置结构简单、构思巧妙,节省人力物力,具有较大的经济效益。本发明采用对称开口结构和磁力吸附的方法解决了跨接片热缩的可扩展性和快速更换性,采用分离开口设计解决了热缩的联系性,采用振动设计解决了跨接片位置不正导致的无法脱出的问题。(The invention provides an expandable continuous thermal shrinkage positioning device for a jumper, which comprises an expansion vibration unit, a separation clapboard, a guide strip and a positioning ruler, and can be used for quickly and accurately completing the transfer of the jumper from the upper part of the separation clapboard to the lower part of the separation clapboard after the thermal shrinkage is completed through the separation clapboard. The device has simple structure and ingenious conception, saves manpower and material resources and has great economic benefit. The invention adopts a symmetrical opening structure and a magnetic force adsorption method to solve the expandability and the quick replaceability of the heat shrinkage of the jumper, adopts a separation opening design to solve the relation of the heat shrinkage, and adopts a vibration design to solve the problem that the jumper cannot be separated due to incorrect position.)

1. An expandable continuous thermal shrinkage positioning device for a jumper, comprising: an expansion vibration unit (1), a separation clapboard (2), a guide strip (3) and a positioning rule (4), wherein,

a plurality of extended vibration units (1) are arranged in an array, the array is arranged on a separation partition board (2), the gap position between the adjacent extended vibration units (1) allows a heat-shrinkable sleeve with a preset length to pass through, and the width T1 of a vertical gap (15) between the adjacent extended vibration units (1) only allows a bridging sheet (5) to pass through but not allows the heat-shrinkable sleeve to pass through;

the guide strip safety device (4) is arranged on the separation partition plate (2) and is in parallel contact with an array formed by a plurality of expansion vibration units (1), and the guide strip safety device (4) controls the expansion vibration units (1) to move on the surface of the separation partition plate (2) only along the direction of the guide strip (4);

each positioning ruler (3) is embedded into the bottom plate (12) of the adjacent expansion vibration unit (1), and each positioning ruler (3) is used for adjusting the distance of the expansion vibration unit (1).

2. An expandable continuous heat-shrinkable positioning device for jumpers according to claim 1, wherein the bottom plate (12), the separating partition (2) and the positioning ruler (4) are made of magnetic materials.

3. An expandable continuous heat-shrinkable positioning device for jumpers according to claim 1, wherein the distance H2 of the gap between the expanded vibration units (1) is slightly larger than the length H2 of the heat-shrinkable sleeve.

4. The expandable continuous thermal shrinkage positioning device for the jumper strips according to claim 1, wherein the separating partition plate (2) is provided with a strip-shaped separating seam which is opposite to the thermal shrinkage processing space, the width of the separating seam is AT1, and AT1 is smaller than the free thickness t2 of the jumper strips before thermal shrinkage and larger than the integral thickness t3 of the jumper strips after thermal shrinkage.

5. The expandable continuous thermal shrinkage positioning device for the jumper strips according to claim 1, wherein the expandable vibration unit (1) comprises vibration clamping plates (11), a bottom plate (12), a vibration motor (13) and a magnet (14), wherein the two vibration clamping plates (11) are connected to form a vertical crack (15), the depth of the vertical crack (15) is H1, the width of the vertical crack is T1, and H1 is matched with the symmetric exposed length H1 of the jumper strips; two vibration clamping plates (11) are vertically arranged on a horizontal bottom plate (12); magnets (14) are installed on two sides of the bottom plate (12), and a vibration motor (13) is arranged at the position, close to the vertical crack (15), of the lower end of the vibration clamping plate (11).

6. The expandable continuous heat-shrinkable positioning device for jumpers according to claim 5, wherein a vertical first groove (112) and a boss (113) are adjacently arranged at the middle position of the inner plane (111) of the vibration clamp plate (11), and the difference between the height of the boss (113) and the depth of the first groove (112) is equal to the width T1 of the vertical seam (15).

7. An expandable continuous heat-shrinkable positioning device for jumpers according to claim 5, characterized in that the inlet end of the jumpers of the vibrating clamp plate (11) is provided with a chamfer (114).

8. An expandable continuous thermal shrinkage positioning device for jumpers according to claim 5, wherein the bottom plate (12) is symmetrically provided with magnet mounting grooves (121) at both sides thereof.

9. An expandable continuous heat-shrinkable positioning device for jumpers according to claim 1, wherein the positioning rule (4) is provided with second grooves (31) on both sides, and the second grooves (31) are embedded in the bottom plate (12) of the expandable vibration unit (1).

10. An expandable continuous heat-shrinkable positioning device for jumpers according to claim 9, wherein the edges of the second groove (31) are further provided with observation holes (32).

Technical Field

The invention relates to an expandable continuous thermal shrinkage positioning device for a jumper.

Background

The jumper bar is a common connecting part for conducting and interconnecting the monomers in the battery pack, and the exposed jumper bar is easy to generate short circuit phenomenon in the production process, so that the battery is damaged, even casualties are caused. The common jumper bar is subjected to thermal shrinkage in a manual thermal shrinkage mode, so that the installation position of a thermal shrinkage pipe is not in accordance with the requirement, interference is caused during installation of the jumper bar, the contact internal resistance is increased, and the local overheating inside the battery pack is caused. In addition, the conventional jumper production adopts manual operation, so that the requirement on the technical skill of workers is high, and the production speed is low.

Disclosure of Invention

The invention aims to provide an expandable continuous thermal shrinkage positioning device for a jumper.

In order to solve the above problems, the present invention provides an expandable continuous thermal shrinkage positioning device for a jumper, comprising: an expansion vibration unit 1, a separation clapboard 2, a guide strip 4, a positioning ruler 3 and a guide strip 4, wherein,

the plurality of expansion vibration units 1 form an array, and a plurality of thermal shrinkage stations are simultaneously carried out; the array is arranged on the separation partition board 2, the gap position between the adjacent expanded vibration units 1 allows a heat-shrinkable tube with a preset length to pass through, the width T1 of the vertical crack 15 between the adjacent expanded vibration units 1 only allows the bridging sheet 5 to pass through, but not allows the heat-shrinkable tube to pass through, and the positioning of the heat-shrinkable tube on the bridging sheet is realized;

the guide strip 4 is arranged on the separation partition plate 2 and is in parallel contact with an array formed by a plurality of the expanded vibration units 1, and the guide strip 4 controls the expanded vibration units 1 to move on the surface of the separation partition plate 2 only along the direction of the guide strip 4;

each positioning rule 3 is embedded in the base plate 12 of the adjacent extension vibration unit 1, and each positioning rule 3 is used to adjust the distance of the extension vibration unit 1.

Further, in the expandable continuous thermal shrinkage positioning device for the jumper, the bottom plate 12, the separation partition plate 2 and the positioning rule 3 are made of magnetic materials.

Further, in the expandable continuous heat-shrinkable positioning device for a jumper, the distance H2 of the gap between the expanded vibration units 1 is slightly larger than the length H2 of the heat-shrinkable sleeve.

Further, in the expandable continuous thermal shrinkage positioning device for the jumper, the separating partition plate 2 is provided with a long and thin strip-shaped separating seam opposite to the thermal shrinkage processing space, the width of the separating seam is AT1, and AT1 is smaller than the free thickness t2 of the jumper before thermal shrinkage and larger than the whole thickness t3 of the jumper after thermal shrinkage.

Further, in the expandable continuous thermal shrinkage positioning device for the jumper, the expandable vibration unit 1 comprises vibration clamping plates 11, a bottom plate 12, a vibration motor 13 and a magnet 14, wherein the two vibration clamping plates 11 are connected to form a vertical gap 15, the depth of the vertical gap 15 is H1, the width of the vertical gap 15 is T1, and H1 is equal to the symmetric exposed length H1 of the jumper in a matching manner; two vibration clamping plates 11 are vertically arranged on a horizontal bottom plate 12; magnets 14 are installed on two sides of the bottom plate 12, a vibration motor 13 is arranged at the position, close to the vertical crack 15, of the lower end of the vibration clamping plate 11, and smoothness and production efficiency of downward movement of the jumper are improved through vibration.

Further, in the expandable continuous thermal shrinkage positioning device for the jumper, a vertical first groove 112 and a boss 113 are adjacently arranged at the middle position of the inner plane 111 of the vibration clamping plate 11, and the difference between the height of the boss 113 and the depth of the first groove 112 is equal to the width T1 of the vertical gap 15.

Further, in the expandable continuous thermal shrinkage positioning device for the jumper, the inlet end of the jumper of the vibration clamp plate 11 is provided with a chamfer 114.

Further, in the expandable continuous thermal shrinkage positioning device for a jumper, magnet installation grooves 121 are symmetrically arranged on two sides of the bottom plate 12.

Further, in the expandable continuous thermal shrinkage positioning device for the jumper, the two sides of the positioning rule 3 are provided with second grooves 31, and the second grooves 31 are embedded in the bottom plate 12 of the expandable vibration unit 1.

Further, in the expandable continuous heat-shrinkable positioning device for a jumper, the edge of the second groove 31 is further provided with a viewing hole 32.

Compared with the prior art, the invention has the following advantages:

(1) the device has simple structure, convenient installation and convenient use, can be used as unit nesting and automatic production line to realize large-scale automatic production of the heat shrinkage of the jumper, and can also be independently used as small-scale rapid production of the heat shrinkage of the jumper.

(2) After the jumper bar is subjected to heat shrinkage, the position of the heat-shrinkable sleeve is accurately controlled, and the product qualification rate is high.

(3) The device has the advantages of fewer parts, low failure rate, no obvious moving parts and safe production process.

Drawings

FIG. 1 is a schematic diagram of the structure of the expandable continuous thermal shrinkage positioning device of the present invention;

FIG. 2 is a schematic diagram illustrating the location of the extended vibration unit spacing according to the present invention;

FIG. 3 is a schematic view of the separating partition and its separating slit according to the present invention;

FIG. 4 is a schematic diagram of the composition of an extended vibration unit of the present invention;

FIG. 5 is a schematic top view of an extended vibration unit of the present invention;

FIG. 6 is a schematic view of the construction of the vibrating splint of the present invention;

FIG. 7 is a schematic structural diagram of a base plate according to the present invention;

FIG. 8 is a schematic view of the positioning ruler of the present invention;

fig. 9 is a comparison of the dimensions of the inventive jumper before and after heat shrinking.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in further detail below.

As shown in fig. 1 to 9, the present invention provides an expandable continuous thermal shrinkage positioning device for a jumper, comprising: an extended vibration unit 1, a separation baffle 2, a positioning rule 3 and a guide strip 4, wherein,

a plurality of extended vibration units 1 constituting an array, the array being mounted on a separation partition 2, a gap position between adjacent extended vibration units 1 allowing a heat-shrinkable sleeve of a preset length to pass therethrough, a width T1 of a vertical slit 15 between adjacent extended vibration units 1 allowing only the jumper 5 to pass therethrough, but not allowing the heat-shrinkable sleeve to pass therethrough;

the guide strips 4 are arranged on the separation partition plate 2 and are in parallel contact with an array formed by the plurality of expansion vibration units 1, and the guide strips 4 control the expansion vibration units 1 to move only along the direction of the guide strips 4 on the surface of the separation partition plate 2 so as to realize that the vertical narrow slits of the expansion vibration units 1 can move randomly in the separation partition plate and are aligned with the long-strip-shaped separation slits of the separation partition plate;

each positioning rule 3 is embedded in the bottom plate 12 of the adjacent expansion vibration unit 1, and each positioning rule 3 is used for adjusting the distance of the expansion vibration unit 1 so as to realize the size matching of the heat shrinkable sleeve.

The invention designs a continuous thermal shrinkage positioning device specially suitable for a jumper, which comprises an expansion vibration unit, a separation partition plate, a guide strip and a positioning ruler, and can quickly finish the transfer of the jumper from the upper part of the separation partition plate to the lower part of the separation partition plate after the thermal shrinkage is finished. The device has simple structure and ingenious conception, saves manpower and material resources and has great economic benefit. The invention adopts a symmetrical opening structure and a magnetic force adsorption method to solve the expandability and the quick replaceability of the heat shrinkage of the jumper, adopts a separation opening design to solve the continuity of the heat shrinkage production, and adopts a vibration design to solve the problem that the jumper cannot be separated due to incorrect position.

In one embodiment of the expandable continuous thermal shrinkage positioning device for the jumper, the bottom plate 12, the separating partition plate 2 and the positioning rule 3 are made of magnetic materials, can be adsorbed by a magnet, and allow local vibration.

Magnets are arranged on two sides of the bottom plate, and the bottom plate, the positioning ruler and the separation partition plate are made of magnetic metal materials, so that the characteristics of quick installation and easy disassembly among the bottom plate, the positioning ruler and the separation partition plate are realized

In an embodiment of the expandable continuous heat-shrinkable positioning device for jumpers of the present invention, as shown in fig. 2 and 9, the distance H2 of the gap between the expanded vibration units 1 is slightly larger than the length H2 of the heat-shrinkable sleeve as shown in fig. 9.

As shown in fig. 3, in an embodiment of the expandable continuous thermal shrinkage positioning device for a jumper, the separation partition plate 2 is provided with a long and thin strip-shaped separation seam facing the thermal shrinkage processing space, the width of the separation seam is AT1, AT1 is smaller than the free thickness t2 of the jumper before thermal shrinkage as shown in fig. 9, and is slightly larger than the whole thickness t3 of the jumper after thermal shrinkage as shown in fig. 9.

The separating partition board is provided with a long and thin strip-shaped separating seam which is opposite to the thermal shrinkage processing space; the device is outer to the adjacent pyrocondensation pipe of spacer plate continuously heating, makes the pyrocondensation pipe shrink, when the pyrocondensation pipe is not pyrocondensated, because of the pyrocondensation pipe size exceeds bridging piece separation seam and can't pass through, after the pyrocondensation pipe pyrocondensation size meets the demands, the pyrocondensation pipe reaches the spacer plate below through the separation seam from the spacer plate top under the effect of gravity and vibration, and the pyrocondensation is accomplished.

As shown in fig. 4 and 5, in an embodiment of the expandable continuous thermal shrinkage positioning device for a jumper, the expandable vibration unit 1 comprises a vibration clamping plate 11, a bottom plate 12, a vibration motor 13 and a magnet 14, wherein the two vibration clamping plates 11 are connected to form a vertical gap 15, the depth of the vertical gap is H1, the width of the vertical gap is T1, and the H1 is substantially equal to the symmetric exposed length H1 of the jumper as shown in fig. 9; two vibrating splints 11 are vertically mounted to a horizontal base plate 12 to form a stable vertical structure; magnets 14 are installed on two sides of the bottom plate 12, a vibration motor 13 is arranged at the position, close to the vertical crack 15, of the lower end of the vibration clamping plate 11, and the vibration clamping plate can vibrate smoothly under the action of the vibration motor by matching with the non-rigid connection characteristic of the bottom plate and the separating plate, so that the bridging sheet which is well in thermal shrinkage can pass smoothly.

Here, a plurality of extension vibration units 1 are arranged on the separation partition board 2 in an array, gaps between adjacent extension vibration units 1 allow a heat-shrinkable sleeve with a certain length sleeved on the jumper to pass through, the width of a vertical narrow slit 15 of the adjacent extension vibration unit 1 is T1, only the jumper 5 is allowed to pass through, but the heat-shrinkable sleeve is not allowed to pass through, the depth H1 of the vertical narrow slit 15 is matched with the symmetric exposed length H1 of the jumper to be basically equal, and therefore the heat-shrinkable sleeve can be guaranteed to be in the middle of the jumper regardless of the inclination of the jumper.

In an embodiment of the expandable continuous thermal shrinkage positioning device for a jumper in the invention, as shown in fig. 6, a vertical first groove 112 and a boss 113 are adjacently arranged at the middle position of an inner plane 111 of the vibration clamping plate, and the difference between the height of the boss 113 and the depth of the first groove 112 is equal to the width T1 of the vertical crack 15. The inlet end of the jumper of the vibrating clamp plate is provided with a chamfer 114 to facilitate the automatic entry of the jumper.

As shown in fig. 7, in an embodiment of the expandable continuous thermal shrinkage positioning device for a jumper according to the present invention, magnet installation slots 121 are symmetrically disposed on two sides of the bottom plate 12.

As shown in fig. 8, in an embodiment of the expandable continuous thermal shrinkage positioning device for a jumper, second grooves 31 are provided on two sides of the positioning rule 3, and the second grooves 31 are embedded in the bottom plate 12 of the expandable vibration unit 1, so as to realize the limitation of the length direction of the thermal shrinkage bush; the edge of the second groove 31 is also provided with a viewing hole 32, so that whether the second groove is installed in place can be observed from the viewing hole 32.

As shown in fig. 9, the present invention utilizes the change in the dimension of the heat shrinkable sleeve before and after heat shrinking on the jumper tab to achieve the basic condition for the continuity of the heat shrinking process.

The invention has the following advantages:

(1) the device has simple structure, convenient installation and convenient use, can be used as unit nesting and automatic production line to realize large-scale automatic production of the heat shrinkage of the jumper, and can also be independently used as small-scale rapid production of the heat shrinkage of the jumper.

(2) After the jumper bar is subjected to heat shrinkage, the position of the heat-shrinkable sleeve is accurately controlled, and the product qualification rate is high.

(3) The device has the advantages of fewer parts, low failure rate, no obvious moving parts and safe production process.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

It will be apparent to those skilled in the art that various changes and modifications may be made in the invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.