KR20200103214A - Adjustable formation laminate for electrical connection of battery lug - Google Patents

Abstract

A formation laminate plate capable of adjusting electrical connection of a battery electrode tap, specifically, belongs to a field of battery formation and a machine. The formation laminate plate capable of adjusting electrical connection of a battery electrode tap includes the laminate plate, and at least a pair of electric connection structures of the electrode tap provided on the laminate plate. The electric connection structure of the electrode tap includes a slidable part, an electrical connection module for the electrode tap, and an electrode tap pressuring module. The slidable part is provided to move in a widthwise direction of the laminate plate. The electrical connection module for the electrode tap and the electrode tap pressuring module are fixedly connected to the slidable part. The electrical connection module for the electrode tap and the electrode tap pressuring module are provided at opposite sides of the laminate plate. An adjustment structure adjusts a widthwise distance from the slidable part to the center of the laminate plate. As the position of the electrical connection module for the electrode tap is adjusted depending on the size of an outer portion of the battery, the center of the battery and the center of the laminate plate are aligned in line with the central line of a driving unit of a formation clamp. In addition, the electrode tap of the battery may make contact with the electrical connection module for the electrode tap. Accordingly, the battery is applied with uniform force. One type of a clamp may be applied to various types of battery formations.

Description

[Adjustable formation laminate for electrical connection of 　battery lug}

The present invention belongs to the technical field of a formation laminate capable of controlling electrical connection of a battery electrode tab, and specifically relates to a formation laminate capable of adjusting electrical connection of a battery electrode tab.

Batteries are currently indispensable parts for electronic devices, and are widely applied to products such as electronic devices and power batteries for electric vehicles. Many batteries are batteries with flexible covers installed. When manufacturing a battery with a flexible cover installed, it is necessary to perform a formation process. There are many types of batteries with flexible covers currently on the market, and their sizes are also different. In order to secure the formation of the battery, one battery is matched to a laminate of one formation clamp. Currently, since the laminated plate of the formation clamp generally corresponds to only one battery, it is necessary to prepare various laminated plates according to the specifications of the battery when forming. That is, since it is necessary to match one formation clamp to one battery, the formation clamp has uniqueness, and it cannot be used for other batteries with different specifications. In the following, there is a need to provide a formation laminate capable of controlling electrical connection of battery electrode tabs that can solve the above problems.

The technical problem to be solved by the present invention is to provide a formation laminate that is capable of controlling the electrical connection of the battery electrode tab, and the formation clamp of the prior art has uniqueness, so that these can be used for other batteries with different specifications. It is in trying to solve a problem that cannot be done.

In order to solve the problems of the prior art, the present invention provides a formation laminate capable of controlling the electrical connection of the battery electrode tabs as follows. The formation laminated plate capable of controlling the electrical connection of the battery electrode tabs includes a laminated plate, and at least a set of electrode tab electrical connection structures are formed on the laminated plate. The electrode tab electrical connection structure includes a slide component, an electrode tab electrical connection module, and an electrode tab pressure module. The slide component is installed to move in a horizontal direction of the laminate, the electrode tab electrical connection module and the electrode tab pressing module are both fixedly connected to the slide component, and the electrode tab electrical connection module and the electrode tab pressing module are It is installed to face both sides of the laminate. The adjustment structure adjusts the distance in the transverse direction from the slide part to the center of the laminated plate 1.

The electrode tab pressing module includes a mounting plate, a silicon pressing part, and a compression spring. Both ends of the mounting plate are connected to the slide component, its rear surface is in contact with the laminate, and side plates extending outward are formed on both sides of the mounting plate, and the mounting recess is formed by the two side plates and the mounting plate. Is formed. A limit is formed by bending the side plate into the mounting recess. A plurality of the silicon pressing parts are installed in a parallel state in the mounting recess, and limit steps extending outward are formed on both sides of the lower end of the silicon pressing part, and the limit steps are formed by pressing the silicon pressing part by the compression spring. Combined above the limit.

The electrode tab electrical connection module includes a connection plate and an electrical connection plate, both ends of the connection plate are connected to the slide component, and slide recesses are formed by bending both sides of the connection plate to the outside, and the slide The second limit is formed by bending both sides of the recess inward, and the electrical connection plate is installed in the slide recess. Four sets of independent circuits are formed on the electrical connection plate.

A connection component is further formed at one end of the electrical connection plate, and the connection component is fixedly connected to the slide component. An air flow path is formed in the connection part, a gas pipe connection part in communication with the air flow path is formed on a side surface of the connection part, and a ventilation concave part in communication with the air flow path is formed at a bottom of the electrical connection plate.

The slide component includes a slide rail and a slide base. The two slide rails are fixed to the upper and lower portions of the laminated plate, respectively, the slide base is installed on the two slide rails, and both ends of the electrical connection module are connected to the same side of the two slide bases, respectively, Both ends of the electrode tab pressing module are respectively connected to the other side of the two slide bases. The adjustment structure adjusts the position of the slide base by driving the two slide bases to slide along the slide rail.

A connection hole is formed on the slide base, and an operation bar is inserted into the predetermined connection hole on the slide base. The operation bar sequentially passes through the connection holes of the formation laminate capable of controlling the electrical connection of the plurality of battery electrode tabs. When the control structure simultaneously presses both ends of the control bar, the control bar drives the slide base to slide.

The electrode tab electrical connection structure is two sets, and the control structure adjusts the distance between the two electrode tab electrical connection structures.

The control structure is a bolt-linked connection structure, an electric control structure, or a manual control structure.

The adjustment structure includes two sets of bolt adjustment structures and a transmission structure, and the two bolt adjustment structures are respectively installed on a support base corresponding to the formation clamp. When driving any one of the bolt adjustment structures, the two bolt adjustment structures are simultaneously driven to move the predetermined operation bar by the transmission structure.

The bolt adjustment structure includes two sets of bolt modules and an electric module, the two bolt modules are installed in parallel along the vertical direction, and the electric module is connected between the two bolt modules. The bolt module includes a mounting base and a bolt, the bolt is rotatably connected to the mounting base, both ends of the bolt are connected to a bearing in a bearing base, and the bearing base is fixedly connected to the support base. . A left rotation screw is formed at one end of the bolt, a right rotation screw is formed at the other end, a predetermined first nut is coupled on the left rotation screw, and a predetermined second nut is coupled on the right rotation screw. Two first nuts installed oppositely are connected to both ends of one of the control rods, and two second nuts installed oppositely are connected to both ends of the other operation bar.

The electric module includes a first electric shaft and a rotating electric module connected between the bolt and the first electric shaft. A second bearing base fixedly connected to the support base is coupled on the first power shaft.

The transmission structure includes two rotating gear cases and a second transmission shaft connected to the rotating shafts of the two rotating gear cases. The other rotation shafts of the two rotation gear cases are connected to the predetermined first transmission shaft. The two slide parts are driven to move in the same or opposite directions by rotating any one of the first electric shafts either by electric drive or manually.

Compared with the prior art, the formation laminate capable of controlling the electrical connection of the battery electrode tab of the present invention can obtain the following effects of the invention.

By adjusting the position of the electrode tab electrical connection module according to the external size of the battery, the center of the battery and the center of the laminate plate are located at the center line of the driving part of the formation clamp, and the electrode tab of the battery contacts the electrode tab electrical connection module. Secure what you do. Therefore, it is possible to ensure that the battery receives an even force, and one clamp can be applied to the formation of various batteries.

1 is a three-dimensional view showing a first embodiment of a formation laminate capable of controlling the electrical connection of the battery electrode tab of the present invention.
FIG. 2 is a three-dimensional view from another direction showing Example 1 of a formation laminate capable of controlling electrical connection of a battery electrode tab of the present invention.
3 is a three-dimensional view showing a second embodiment of a formation laminate capable of controlling the electrical connection of the battery electrode tab of the present invention.
Fig. 4 is a three-dimensional view from another direction showing the second embodiment of the formation laminate capable of adjusting the electrical connection of the battery electrode tab of the present invention.
5 is an exploded view showing a second embodiment of a formation laminate capable of controlling electrical connection of a battery electrode tab of the present invention.
6 is a three-dimensional view showing an electrical connection structure of an electrode tab of a formation laminate capable of controlling electrical connection of a battery electrode tab of the present invention.
7 is an exploded view showing an electrical connection structure of an electrode tab of a formation laminate in which electrical connection of a battery electrode tab of the present invention can be adjusted.
8 is a cross-sectional view showing an electrical connection structure of an electrode tab of a formation laminate capable of controlling electrical connection of a battery electrode tab of the present invention.
9 is a three-dimensional view showing an electrode tab pressing module of a formation laminate capable of controlling electrical connection of a battery electrode tab according to the present invention.
10 is a cross-sectional view showing an electrode tab pressing module of a formation laminate capable of controlling electrical connection of a battery electrode tab of the present invention.
11 is a partially enlarged view showing that the electrode tab pressing module is connected to the operation bar in the formation laminate plate capable of controlling the electrical connection of the battery electrode tab of the present invention.
12 is a three-dimensional view showing the application of the formation laminated plate to the formation clamp capable of controlling the electrical connection of the battery electrode tab of the present invention.
13 is a structural diagram showing that the control structure of the formation laminate capable of controlling the electrical connection of the battery electrode tab of the present invention is installed in the formation clamp.
14 is a bottom view showing that the control structure of the formation laminate capable of controlling the electrical connection of the battery electrode tab of the present invention is installed on the formation clamp.
15 is a structural diagram showing a bolt adjustment structure of a formation laminate capable of adjusting electrical connection of a battery electrode tab of the present invention.

Hereinafter, the present invention will be described in more detail with reference to specific embodiments and the drawings.

By describing a plurality of detailed technical matters of the present invention in the following sentences, the matters constituting the following embodiments will be understood in more detail. A person skilled in the art may implement the present invention according to some or all technical details of the following examples. In the absence of special circumstances, well-known technical matters are not described in detail.

Example 1

As shown in Figs. 1 to 2 and 6 to 8, a formation laminate that can control the electrical connection of the battery electrode tabs includes a laminate plate 1, and a set of electrode tabs are electrically connected on the laminate plate 1 Structure 2 is formed. The electrode tab electrical connection structure 2 includes a slide component 20, an electrode tab electrical connection module 21, and an electrode tab pressing module 22. The slide component 20 is installed to move in the horizontal direction of the laminated plate 1, and both the electrode tab electrical connection module 21 and the electrode tab pressing module 22 are fixedly connected to the slide component 20 In addition, the electrode tab electrical connection module 21 and the electrode tab pressing module 22 are installed to face both sides of the laminated plate 1. The adjustment structure adjusts the distance in the transverse direction from the slide part 20 to the center of the laminated plate 1. When a plurality of sets of the formation laminate is used as a formation clamp of a battery, the control structure is controlled by adjusting the position of the electrode tab electrical connection module 21 according to the external size of the battery. It is ensured that the center is located on the center line of the driving part of the formation clamp, and that the electrode tab of the battery contacts the electrode tab electrical connection module 21. This ensures that the battery receives an equal force, and one clamp can be applied to the formation of various batteries. Specifically, the electrode tab electrical connection module 21 includes a connection plate 210 and an electrical connection plate 211, and both ends of the connection plate 210 are connected to the slide part 20, and the connection plate The slide recess 2100 is formed by bending both sides of 210 to the outside, and the second limit 2101 is formed by bending both sides of the slide recess 2100 to the inside, and the electrical connection plate 211 is installed in the slide recess 2100, and 4 sets of independent circuits are formed on the electrical connection plate 211. In this embodiment, the positive electrode tab and the negative electrode tab are formed in the formation of the battery on the same side, and two sets of circuits are electrically connected to the positive electrode and the negative electrode in four sets of independent circuits on the electrical connection plate 211. Electricity is supplied to the battery, and the formation voltage of the battery is detected by electrically connecting two sets of other circuits to the positive and negative electrodes of the battery.

Example 2

As shown in FIGS. 3 to 4 and 6 to 8, the formation laminated board capable of controlling the electrical connection of the battery electrode tabs includes a laminated plate 1, and on the laminated plate 1, two sets of electrode tabs electrical connection structure (2). ) Is formed, and the two sets of electrode tab electrical connection structures 2 are installed on both sides of the laminated plate 1, respectively. The electrode tab electrical connection structure 2 includes a slide component 20, an electrode tab electrical connection module 21, and an electrode tab pressing module 22. The slide component 20 is installed to move in the horizontal direction of the laminated plate 1, and both the electrode tab electrical connection module 21 and the electrode tab pressing module 22 are fixedly connected to the slide component 20 Then, the electrode tab electrical connection module 21 and the electrode tab pressing module 22 are installed on both sides of the laminated plate 1. The control structure adjusts the distance between the two electrode tab electrical connection structures 2. In this embodiment, the positive electrode tab and the negative electrode tab are formed on both sides of the battery formation laminate, respectively. By simultaneously adjusting the distance between the two electrode tab electrical connection structures 2 by the control structure, the positive electrode tab and the negative electrode tab of the battery are electrically connected to the electrical connection module 21. The electrode tab electrical connection module 21 includes a connection plate 210 and an electrical connection plate 211, and both ends of the connection plate 210 are connected to the slide part 20, and the connection plate 210 ) Is formed by bending both sides of the slide concave portion 2100 to the outside, and the second limit 2101 is formed by bending both sides of the slide concave portion 2100 inward, and the electrical connection plate 211 ) Is installed in the slide recess 2100, and two independent circuits are formed on the electrical connection plate 211.

The control structure of the above two embodiments may be a bolt-linked connection structure, an electric control structure, or a manual control structure.

9 and 10, the electrode tab pressing module 22 of the above two embodiments includes a mounting plate 220, a silicon pressing part 221, and a compression spring 222. Both ends of the mounting plate 220 are connected to the slide part 20, the rear surface thereof is in contact with the laminated plate 1, and side plates 2200 extending to the outside are respectively provided on both sides of the mounting plate 220. Is formed, and the mounting recess 2201 is formed by the two side plates 2200 and the mounting plate 220, and the limit 2202 is formed by bending the side plate 2200 into the mounting recess 2201 do. The plurality of silicon pressing parts 221 are installed in a parallel state in the mounting recess 2201, and limit steps 2211 extending outwardly are formed on both lower sides of the silicon pressing part 221, and the compression spring By 222 pressing the silicon pressing part 221, the limit stairs 2211 are coupled on the limit 2202. There are a plurality of formation laminates capable of adjusting the electrical connection of the battery electrode tabs, and these are installed in parallel in the formation clamp. When forming a battery, the battery is installed between the adjacent two laminated plates 1, and the electrode tabs of the battery are pressed with the electrode tab pressing module 22, so that the electrical connection plate 211 of the laminated plate 1 is different. ).

A connection part 212 is further formed at one end of the electrical connection plate 211 of the above embodiment. 6 to 8, the connection part 212 is fixedly connected to the slide part 20. An air flow path is formed in the connection part 212, a gas pipe connection part 213 in communication with the air flow path is formed on a side surface of the connection part 212, and the bottom part of the electrical connection plate 211 has the Ventilation concave portions 2110 in communication with the airflow passage are formed. The gas pipe connection part 213 is connected to a pipe line of a gas supply facility, and when forming, the temperature of the electrical connection plate 211 is lowered by supplying a cooling gas to the ventilation concave part 2110, and the electrode When the tab is electrically connected to the electrical connection plate 211, it is possible to avoid heat being transmitted to the inside of the battery.

Referring to FIG. 11, the slide component 20 includes a slide rail 200 and a slide base 201. The two slide rails 200 are fixed to the upper and lower portions of the laminated plate 1, respectively, the slide base 201 is installed on the two slide rails 200, and the electrical connection module 21 Both ends are connected to the same side of the two slide bases 201, respectively, and both ends of the electrode tab pressing module 22 are connected to the other side of the two slide bases 201, respectively. The adjustment structure controls the position of the slide base 201 by driving the two slide bases 201 to slide along the slide rail 200, thereby adjusting the position of the electrode tab electrical connection device. Can be adjusted.

Referring to FIG. 11, a connection hole 2010 is formed on the slide base 201, and the operation bar 4 is inserted into the predetermined connection hole 2010 on the slide base 201, and the operation The bar 4 passes through the connection holes 2010 of the formation laminate in which the electrical connection of the plurality of sets of the battery electrode tabs can be adjusted. When the control structure simultaneously presses both ends of the control bar, the control bar 4 drives the slide base 201 to slide. The operation bar 4 is inserted into the predetermined connection hole 2010 formed in a parallel state on the slide base 201 of the formation clamp, and the operation bar 4 is moved to the slide base by driving the adjustment structure. By moving 201), the positions of all the electrode tab electrical connection structures 2 can be adjusted at the same time.

12 to 15, the adjustment structure includes two sets of bolt adjustment structures 30 and transmission structures 31, and the two bolt adjustment structures 30 include a support base 5A corresponding to a formation clamp. It is installed on each of 5B).

The bolt adjustment structure (30) includes two sets of bolt modules (300) and an electric module (301), the two bolt modules (300) are installed in parallel in the vertical direction, the electric module (301) It is connected between the two bolt modules (300). The bolt module (300) includes a mounting base (3000) and a bolt (3001), the bolt (3001) is rotatably connected to the mounting base (3000), both ends of the bolt (3001) are bearings It is connected to a bearing in the base 3002, and the bearing base 3002 is fixedly connected to a corresponding support base. One end of the bolt 3001 is formed with a left screw (3001a), the other end is formed with a right screw (3001b), a predetermined first nut (3003) is coupled on the left screw (3001a), and the right screw A predetermined second nut (3004) is coupled on the (3001b). Two first nuts 3003 installed oppositely are connected to both ends of one operation bar 4, respectively. By installing the two first nuts 3003 against each other, they are made to correspond to the first nut 3003 on the support base 5A and the first nut 3003 on the other support base 5B. Two second nuts 3004 installed oppositely are respectively connected to both ends of the other operating bar 4.

The transmission module 301 includes a first transmission shaft 3010 and a rotation transmission module 3011 connected between the bolt 3001 and the first transmission shaft 3010. The first transmission shaft 3010 is coupled to a second bearing base 3012 fixedly connected to the support bases 5A and 5B. The rotational transmission module 3011 may be a pair of conical gears, a pair of helical gears, or a worm and worm gear coupled to each other. When the first transmission shaft (3010) rotates, the two bolts (3001) on the support base rotate together, and by the driving of the transmission structure (31), the two bolts (3001) on the other support base rotate together. do. As a result, the first nut 3003 and the second nut 3004 move in the same or opposite directions, and the operation bar 4 drives the predetermined slide base 201 to move, thereby electrically connecting the electrode tab. Adjust the position of the structure (2).

The transmission structure 31 includes two rotating gear cases 310 and a second transmission shaft 311 connected to the rotating shafts of the two rotating gear cases 310. The other rotation shafts of the two rotation gear cases 310 are connected to the predetermined first transmission shaft 3010. The two slide parts 20 are driven to move in the same direction or in opposite directions by rotating any one of the first electric shafts 3010 either electrically or manually.

The present invention is not limited to the above specific embodiments. It goes without saying that the technician of the present invention can derive various modifications without creative research according to the above embodiments, and even if such modifications are present, they are included in the present invention.

1: laminated plate
2: electrode tab electrical connection structure 20: slide part
21: electrode tap electrical connection module 22: electrode tap pressure module
200: slide rail 201: slide base
2010: connection hole 210: connection plate
211: electrical connection plate 212: connection parts
213: gas pipe connection part 2100: slide recess
2101: second limit 2110: ventilation recess
220: mounting plate 221: silicon pressing part
222: compression spring 2200: side plate
2201: mounting recess 2202: limit
2211: limit stairs
30: bolt adjustment structure 31: transmission structure
300: bolt module 301: electric module
310: rotation gear case 311: second transmission shaft
3000: mounting base 3001: bolt
3001a: left turn screw 3001b: right turn screw
3002: bearing base 3003: first nut
3004: second nut 3010: first transmission shaft
3011: rotary electric module 3012: second bearing base
4: operation bar
5A, 5B: support base

Claims (10)

In the formation laminated plate comprising a laminated plate, wherein the electric connection of the battery electrode tabs having at least one set of electrode tabs electrical connection structure formed on the laminated plate can be controlled, wherein the electrode tabs electrical connection structure includes a slide component, an electrode tab electrical connection module, and an electrode A tab pressing module, wherein the slide component is installed to move in a horizontal direction of the laminate, and both the electrode tab electrical connection module and the electrode tab pressing module are fixedly connected to the slide component, and the electrode tab electrical connection module And the electrode tab pressing module is installed to face both sides of the laminate, and the control structure adjusts the distance in the horizontal direction from the slide part to the center of the laminate. Possible formation laminate. The method of claim 1, wherein the electrode tab pressing module includes a mounting plate, a silicon pressing part, and a compression spring, and both ends of the mounting plate are connected to the slide component, and a rear surface thereof is in contact with the laminated plate, and the mounting plate Side plates extending to the outside are formed on both sides of the side plate, a mounting recess is formed by the two side plates and the mounting plate, a limit is formed by bending the side plate into the mounting recess, and a plurality of the silicon pressing portions It is installed in a parallel state in the mounting recess, and limit steps extending outward are formed on both sides of the lower end of the silicon pressing part, and the limit steps are coupled on the limit by pressing the compression springs on the silicon pressing part,
The electrode tab electrical connection module includes a connection plate and an electrical connection plate, both ends of the connection plate are connected to the slide component, and slide recesses are formed by bending both sides of the connection plate to the outside, and the slide Electrical connection of a battery electrode tab, characterized in that the second limit is formed by bending both sides of the recessed portion inward, the electrical connection plate is installed in the slide recess, and four sets of independent circuits are formed on the electrical connection plate Formation laminate that can be adjusted. The method of claim 2, wherein a connection component is further installed at one end of the electrical connection plate, the connection component is fixedly connected to the slide component, an air flow path is formed in the connection component, and a side surface of the connection component A gas pipe connection part in communication with the air flow passage is formed, and a ventilation recess in communication with the air flow passage is formed at a bottom of the electrical connection plate. According to any one of claims 1 to 3, wherein the slide component includes a slide rail and a slide base, and the two slide rails are fixed to the upper and lower portions of the laminated plate, respectively, and the slide base is on the two slide rails. Is installed, both ends of the electrical connection module are connected to the same side of the two slide bases, respectively, both ends of the electrode tab pressing module are connected to the other side of the two slide bases, respectively, and the control structure has two The formation laminated plate capable of controlling electrical connection of the battery electrode tab, characterized in that the position of the slide base is adjusted by driving the slide base to slide along the slide rail. The method of claim 4, wherein a connection hole is formed on the slide base, an operation bar is inserted into the predetermined connection hole on the slide base, and the operation bar is adapted to control electrical connection of the plurality of sets of battery electrode tabs. The electrical connection of the battery electrode tab, characterized in that by passing through the connection holes of the formation laminate as possible in sequence, and by simultaneously pressing both ends of the control bar, the control structure drives the slide base to slide. Formation laminate that can be adjusted. The formation of claim 5, wherein the electrode tab electrical connection structure is two sets, and the control structure controls a distance between the two electrode tab electrical connection structures. Laminated plate. The formation laminate of claim 5, wherein the control structure is a bolt-linked connection structure, an electric control structure, or a manual control structure. The method of claim 6, wherein the adjustment structure includes two sets of bolt adjustment structures and a transmission structure, and the two bolt adjustment structures are respectively installed on a support base corresponding to a formation clamp, and any one bolt adjustment structure The formation laminated plate capable of controlling electrical connection of the battery electrode tabs, characterized in that when driving the two bolt adjustment structures simultaneously drive the operation bar predetermined by the transmission structure to move. The method of claim 8, wherein the bolt adjustment structure includes two sets of bolt modules and an electric module, and the two bolt modules are installed in parallel along the vertical direction, and the electric module is connected between the two bolt modules. The bolt module includes a mounting base and a bolt, the bolt is rotatably connected to the mounting base, both ends of the bolt are connected to a bearing in the bearing base, and the bearing base is connected to the support base. It is fixedly connected, a left rotation screw is formed at one end of the bolt, a right rotation screw is formed at the other end, a predetermined first nut is coupled on the left rotation screw, a predetermined second nut is coupled on the right rotation screw, and The two installed first nuts are respectively connected to both ends of the one operation bar, and the two second nuts installed oppositely are connected to both ends of the other operation bar,
The transmission module includes a first transmission shaft and a rotation transmission module connected between the bolt and the first transmission shaft, and a second bearing base fixedly connected to the support base is coupled to the first transmission shaft. Formation laminated plate capable of controlling electrical connection of battery electrode tabs. The method of claim 9, wherein the transmission structure includes two rotation gear cases and a second transmission shaft connected to the rotation shafts of the two rotation gear cases, and the other rotation shafts of the two rotation gear cases are the predetermined first Electricity of a battery electrode tab, characterized in that the two slide parts are driven to move in the same direction or in opposite directions by rotating any one of the first electric shafts connected to the transmission shaft and electrically driven or manually. Formation laminated board with adjustable connection.

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