CN216711144U - Cutting machine with double-shaft transmission assembly - Google Patents

Abstract

The embodiment of the utility model discloses a splitting machine with a double-shaft transmission assembly, wherein the double-shaft transmission assembly comprises a first body, a first mounting piece, a second mounting piece, a first transmission shaft and a second transmission shaft, the first mounting piece and the second mounting piece respectively reciprocate relative to the first body along the length direction of the first body, so that the first transmission shaft and the second transmission shaft respectively reciprocate relative to the first body along the length direction of the first body, and the first transmission shaft and the second transmission shaft synchronously rotate at the moment. For driving shaft and transmission shaft can not synchronous rotation at the in-process that removes in traditional cutting machine that has biax transmission assembly, the scheme that changes takes place easily in the interval between driving shaft and the transmission shaft, first transmission shaft and second transmission shaft can synchronous rotation in the cutting machine that has biax transmission assembly of this scheme to interval between first transmission shaft and the second transmission shaft is difficult to take place to change.

Description

Cutting machine with double-shaft transmission assembly

Technical Field

The utility model relates to the technical field of processing of positive and negative pole piece materials of lithium batteries, in particular to a splitting machine with a double-shaft transmission assembly.

Background

The splitting machine is a mechanical device for splitting wide paper, mica tapes, films and positive and negative pole pieces of lithium batteries into a plurality of narrow materials, and is commonly used for papermaking machinery, wire and cable mica tapes, lithium batteries and printing and packaging machinery. The slitting machine mainly applies to: non-woven fabrics; mica tape, paper, insulating materials and various film materials, and lithium battery positive and negative pole pieces, and is particularly suitable for cutting narrow tapes (non-woven fabrics, paper, insulating materials, mica tape, films, lithium battery positive and negative pole pieces and the like).

In the traditional splitting machine with the double-shaft transmission assembly, a driving shaft and a transmission shaft cannot synchronously rotate in the moving process, and the distance between the driving shaft and the transmission shaft is easy to change.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a splitting machine with a double-shaft transmission assembly, and aims to solve the problems that a driving shaft and a transmission shaft cannot synchronously rotate in the moving process, and the distance between the driving shaft and the transmission shaft is easy to change.

In order to solve the above problems, the present invention provides a splitting machine with a double-shaft transmission assembly, comprising:

the wall plate is vertically arranged;

the discharging assembly is arranged on the wall plate and used for discharging positive and negative pole pieces of the wide lithium battery;

the slitting assembly is arranged in the middle of the wallboard and is positioned at the downstream of the discharging assembly, and the slitting assembly is used for slitting the positive and negative pole pieces of the wide lithium battery into at least two positive and negative pole pieces of the narrow lithium battery;

at least two winding assemblies which are positioned at the downstream of the slitting assembly;

the slitting component comprises a double-shaft transmission component used for conveying narrow material belts, the double-shaft transmission component comprises a first body, a first mounting part, a second mounting part, a first transmission shaft and a second transmission shaft, the first body is fixedly connected with a wallboard, the first mounting part and the second mounting part are arranged on the first body at intervals, the first transmission shaft is rotatably connected with the first mounting part, the first mounting part can be used for the first body to move in a reciprocating manner along the length direction of the first body, the second transmission shaft is rotatably connected with the second mounting part, the second mounting part can be used for the first body to move in a reciprocating manner along the length direction of the first body, a first rotating part is arranged on the first transmission shaft, a second rotating part is arranged on the second transmission shaft, and a first rotating part matched with the second rotating part is arranged between the first rotating part and the second rotating part The first rotating connecting piece is fixedly connected with the first body;

the first mounting part and the second mounting part are both reciprocated along the length direction of the first body relative to the first body, so that the first transmission shaft and the second transmission shaft are both reciprocated along the length direction of the first body relative to the first body, and at the moment, the first transmission shaft and the second transmission shaft are synchronously rotated.

The embodiment of the utility model has the following beneficial effects:

having adopted above-mentioned cutting machine that has biax transmission assembly, first installed part and second installed part are all for first body along the length direction reciprocating motion of first body to make first transmission shaft and second transmission shaft all for the length direction reciprocating motion of first body along first body of first body, first transmission shaft and second transmission shaft synchronous rotation this moment. Because first transmission shaft and second transmission shaft can synchronous rotation for first body along the length direction reciprocating motion's of first body in-process first transmission shaft and second transmission shaft to the interval between first transmission shaft and the second transmission shaft is difficult to change. For driving shaft and transmission shaft can not synchronous rotation at the in-process that removes in the cutting machine that traditional has biax transmission subassembly, the scheme that the interval between driving shaft and the transmission shaft changed takes place easily, first transmission shaft and second transmission shaft can synchronous rotation for the in-process first transmission shaft and the second transmission shaft of first body along the length direction reciprocating motion of first body in the cutting machine that has biax transmission subassembly of this scheme to interval between first transmission shaft and the second transmission shaft is difficult to take place to change.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Wherein:

fig. 1 is a schematic view of the overall structure of the slitting machine with a double-shaft transmission assembly according to the utility model.

Fig. 2 is a perspective view of a double-shaft driving assembly of the slitting machine with the double-shaft driving assembly shown in fig. 1.

Fig. 3 is an enlarged view of the combination of the first rotating member, the second rotating member and the first rotating connecting member and the third rotating member, the fourth rotating member and the second rotating connecting member of the biaxial transmission assembly of the slitting machine with the biaxial transmission assembly as shown in fig. 2.

Fig. 4 is an exploded view of the double shaft drive assembly of the slitting machine with the double shaft drive assembly shown in fig. 2.

Fig. 5 is an enlarged view of the first rotational coupling of the double shaft drive assembly of the slitting machine with the double shaft drive assembly as shown in fig. 2.

Fig. 6 is an enlarged view of the first body of the double shaft drive assembly of the slitting machine with the double shaft drive assembly as shown in fig. 2.

Reference numerals:

10-a wallboard;

20-a discharging assembly;

300-a double-shaft transmission assembly, 301-a first body, 3011-a base plate, 3013-a first slide rail, 302-a first mounting part, 3021-a first mounting plate, 3023-a first slider, 303-a second mounting part, 3031-a second mounting plate, 3033-a second slider, 304-a first transmission shaft, 3041-a first rotating part, 3043-a third rotating part, 305-a second transmission shaft, 3051-a second rotating part, 3053-a fourth rotating part, 306-a first rotating connecting part, 30611-a first fixing part, 30613-a second fixing part, 3063-a connecting part, 307-a first power part, 308-a second power part, 311309-a second rotating connecting part, 310-a second body, 311-a third mounting part, 1-a third mounting plate, 3113-third slide, 3121-fourth mounting plate, 3123-fourth slide;

and 40-rolling the assembly.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as upper, lower, left, right, front and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of the feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

As shown in fig. 1, 2, 3, and 4, an embodiment of the present invention provides a splitting machine with a dual-shaft transmission assembly, including a wall plate 10, the wall plate 10 is vertically disposed, a discharging assembly 20 disposed on the wall plate 10 for discharging positive and negative pole pieces of a wide lithium battery, a splitting assembly disposed in the middle of the wall plate 10 and located at the downstream of the discharging assembly 20, the splitting assembly for splitting the positive and negative pole pieces of the wide lithium battery into at least two positive and negative pole pieces of a narrow lithium battery, at least two winding assemblies 40, and at least two winding assemblies 40 both located at the downstream of the splitting assembly.

The slitting assembly comprises a double-shaft transmission assembly 300 for conveying narrow-width material belts, the double-shaft transmission assembly 300 comprises a first body 301, a first mounting part 302, a second mounting part 303, a first transmission shaft 304 and a second transmission shaft 305, the first body 301 is fixedly connected with the wall board 10, the first mounting part 302 and the second mounting part 303 are arranged on the first body 301 at intervals, the first transmission shaft 304 is rotatably connected with the first mounting part 302, the first mounting part 302 can reciprocate relative to the first body 301 along the length direction of the first body 301, the second transmission shaft 305 is rotatably connected with the second mounting part 303, the second mounting part 303 can reciprocate relative to the first body 301 along the length direction of the first body 301, a first rotating part 3041 is arranged on the first transmission shaft 304, a second rotating part 3051 is arranged on the second transmission shaft 305, a first rotating connecting part 306 matched with the first rotating part 3041 and the second rotating part 3051 is arranged between the first rotating part 3041 and the second rotating part 3051, the first rotational connector 306 is fixedly connected to the first body 301.

The first mounting part 302 and the second mounting part 303 are each reciprocated in the lengthwise direction of the first body 301 with respect to the first body 301, so that the first transmission shaft 304 and the second transmission shaft 305 are each reciprocated in the lengthwise direction of the first body 301 with respect to the first body 301, at which time the first transmission shaft 304 and the second transmission shaft 305 are rotated in synchronization.

With the above-described slitting machine with the double-shaft transmission assembly, the first mounting member 302 and the second mounting member 303 are both reciprocated relative to the first body 301 in the longitudinal direction of the first body 301, so that the first transmission shaft 304 and the second transmission shaft 305 are both reciprocated relative to the first body 301 in the longitudinal direction of the first body 301, and at this time, the first transmission shaft 304 and the second transmission shaft 305 are rotated in synchronization. Since the first transmission shaft 304 and the second transmission shaft 305 can rotate synchronously during the reciprocating motion of the first transmission shaft 304 and the second transmission shaft 305 relative to the first body 301 along the length direction of the first body 301, the distance between the first transmission shaft 304 and the second transmission shaft 305 is not easily changed. For driving shaft and transmission shaft can not synchronous rotation at the in-process that removes in the traditional cutting machine that has double-shaft drive assembly, the scheme that the interval between driving shaft and the transmission shaft changed takes place easily, first transmission shaft and second transmission shaft can synchronous rotation for first body along the length direction reciprocating motion's of first body in this scheme's the cutting machine that has double-shaft drive assembly in first transmission shaft and second transmission shaft to interval between first transmission shaft and the second transmission shaft is difficult to take place to change.

As shown in fig. 5, the first rotating connector 306 includes a fixing portion fixedly connected to the first body 301, and a connecting portion 3063 formed by extending from one side of the fixing portion in a direction away from the fixing portion, and the connecting portion 3063 is configured to be matched with the first rotating member 3041 and the second rotating member 3051.

Specifically, the first rotating connector 306 includes a fixed portion fixedly connected to the first body 301, and a connecting portion 3063 formed by extending from one side of the fixed portion in a direction away from the fixed portion, and the connecting portion 3063 is used for matching with the first rotating member 3041 and the second rotating member 3051, so that the dual-shaft transmission assembly is compact in structure.

In this embodiment, the fixing portion includes a first fixing portion 30611 and a second fixing portion 30613 connected to the first fixing portion 30611, the height of the first fixing portion 30611 is lower than the height of the second fixing portion 30613, a side of the first fixing portion 30611 away from the second fixing portion 30613 is used for connecting with the connecting portion 3063, a gap is formed between the first fixing portion 30611 and the first body 301, and the second fixing portion 30613 is used for fixedly connecting with the first body 301.

Specifically, the fixing portions include a first fixing portion 30611 and a second fixing portion 30613 connected to the first fixing portion 30611, the height of the first fixing portion 30611 is lower than that of the second fixing portion 30613, a side of the first fixing portion 30611 away from the second fixing portion 30613 is used for being connected to the connecting portion 3063, a gap is formed between the first fixing portion 30611 and the first body 301, and the second fixing portion 30613 is used for being fixedly connected to the first body 301, so that the structure of the dual-shaft transmission assembly is further compact.

In the present embodiment, the first rotational connector 306 has a bar shape, and the first rotational connector 306 extends in a longitudinal direction of the first body 301.

Specifically, the first rotational connector 306 is bar-shaped, and the first rotational connector 306 extends along the length direction of the first body 301, so that the first rotational member 3041 and the second rotational member 3051 can move back and forth along the length direction of the first body 301, and thus the first mounting part 302 and the second mounting part 303 can reciprocate relative to the first body 301 along the length direction of the first body 301.

In the present embodiment, the first rotating member 3041 and the second rotating member 3051 are both gears, and a rack is provided on a surface of the connecting portion 3063 away from the fixed portion.

Specifically, the first rotating member 3041 and the second rotating member 3051 are both gears, and a rack is disposed on a side of the connecting portion 3063 away from the fixing portion, and the gears are engaged with the rack, so that transmission is stable.

In another embodiment, the first rotating member 3041 and the second rotating member 3051 are both gears, and a chain is provided on a side of the connecting portion 3063 away from the fixed portion.

In this embodiment, the dual-shaft transmission assembly 300 further includes a first power member 307 and a second power member 308, the first power member 307 is fixedly connected to the first mounting member 302, the first power member 307 is used for driving the first transmission shaft 304 to rotate, the second power member 308 is fixedly connected to the second mounting member 303, and the second power member 308 is used for driving the second transmission shaft 305 to rotate.

Specifically, the dual-shaft transmission assembly 300 further includes a first power member 307 and a second power member 308, the first power member 307 is fixedly connected to the first mounting portion 302, the first power member 307 is used for driving the first transmission shaft 304 to rotate, the second power member 308 is fixedly connected to the second mounting portion 303, the second power member 308 is used for driving the second transmission shaft 305 to rotate, the first power member 307 provides power for the first transmission shaft 304 to rotate, so that the first mounting portion 302 can reciprocate relative to the first body 301 along the length direction of the first body 301, and the second power member 308 provides power for the second transmission shaft 305 to rotate, so that the second mounting portion 303 can reciprocate relative to the first body 301 along the length direction of the first body 301.

Preferably, the first transmission shaft 304 is further provided with a third rotating member 3043 spaced apart from the first rotating member 3041, the second transmission shaft 305 is further provided with a fourth rotating member 3053 spaced apart from the second rotating member 3051, a second rotating connecting member 309 matched with the third rotating member 3043 and the fourth rotating member 3053 is disposed between the third rotating member 3043 and the fourth rotating member 3053, and the second rotating connecting member 309 is used for being fixedly connected to the fixed carrier.

Specifically, the first transmission shaft 304 is further provided with a third rotating member 3043 spaced from the first rotating member 3041, the second transmission shaft 305 is further provided with a fourth rotating member 3053 spaced from the second rotating member 3051, a second rotating connecting member 309 matched with the third rotating member 3043 and the fourth rotating member 3053 is disposed between the third rotating member 3043 and the fourth rotating member 3053, the second rotating connecting member 309 is used for being fixedly connected with a fixed carrier, and the third rotating member 3043 and the fourth rotating member 3053 are matched with the second rotating connecting member 309, so that the first transmission shaft 304 and the second transmission shaft 305 are more stable when reciprocating along the length direction of the first body 301 relative to the first body 301.

Preferably, the first rotating member 3041 and the third rotating member 3043 are respectively located at two ends of the first transmission shaft 304, and the second rotating member 3051 and the fourth rotating member 3053 are respectively located at two ends of the second transmission shaft 305.

Specifically, the first rotating member 3041 and the third rotating member 3043 are respectively located at two ends of the first transmission shaft 304, so that the first transmission shaft 304 is more stable when reciprocating along the length direction of the first body 301, and the second rotating member 3051 and the fourth rotating member 3053 are respectively located at two ends of the second transmission shaft 305, so that the second transmission shaft 305 is more stable when reciprocating along the length direction of the first body 301 relative to the first body 301.

Preferably, the biaxial transmission assembly 300 further comprises a second body 310, a third mounting part 311 and a fourth mounting part, the second body 310 is used for being fixedly connected with a fixed carrier, the third mounting part 311 and the fourth mounting part are arranged on the second body 310 at intervals, the first transmission shaft 304 is rotatably connected with the third mounting part 311, the third mounting part 311 can reciprocate relative to the second body 310 along the length direction of the second body 310, the second transmission shaft 305 is rotatably connected with the fourth mounting part, and the fourth mounting part can reciprocate relative to the second body 310 along the length direction of the second body 310.

Specifically, the dual-shaft transmission assembly 300 further includes a second body 310, a third mounting part 311 and a fourth mounting part, the second body 310 is configured to be fixedly connected to a fixed carrier, the third mounting part 311 and the fourth mounting part are disposed on the second body 310 at intervals, the first transmission shaft 304 is rotatably connected to the third mounting part 311, the third mounting part 311 is capable of reciprocating relative to the second body 310 along the length direction of the second body 310, the second transmission shaft 305 is rotatably connected to the fourth mounting part, the fourth mounting part is capable of reciprocating relative to the second body 310 along the length direction of the second body 310, and the third mounting part 311 and the fourth mounting part are matched with the second body 310, which is beneficial to further improving the stability of the movement of the first transmission shaft 304 and the second transmission shaft 305, and also plays a supporting role for the first transmission shaft 304 and the second transmission shaft 305.

As shown in fig. 6, the first body 301 includes a bottom plate 3011 and a first slide rail 3013 disposed on the bottom plate 3011, the first mounting piece 302 includes a first mounting plate 3021 and a first slider 3023 disposed on the first mounting plate 3021, the first slider 3023 and the first slide rail 3013 are matched so that the first mounting piece 302 can reciprocate along the length direction of the first body 301 with respect to the first body 301, the second mounting piece 303 includes a second mounting plate 3031 and a second slider 3033 disposed on the second mounting plate 3031, and the second slider 3033 and the first slide rail 3013 are matched so that the second mounting piece 303 can reciprocate along the length direction of the first body 301 with respect to the first body 301.

Specifically, the first body 301 includes a bottom plate 3011 and a first slide rail 3013 disposed on the bottom plate 3011, the first mounting piece 302 includes a first mounting plate 3021 and a first slider 3023 disposed on the first mounting plate 3021, the first slider 3023 and the first slide rail 3013 are matched so that the first mounting piece 302 can reciprocate in the length direction of the first body 301 relative to the first body 301, the second mounting piece 303 includes a second mounting plate 3031 and a second slider 3033 disposed on the second mounting plate 3031, the second slider 3033 and the first slide rail 3013 are matched so that the second mounting piece 303 can reciprocate in the length direction of the first body 301 relative to the first body 301, and the first slider 3023 and the second slider 3033 are matched with the first slide rail 3013, so that the resistance during movement can be reduced, and the movement is more sensitive.

Preferably, the second body 310 is a second slide rail, the third mounting part 311 includes a third mounting plate 3111 and a third slider 3113 disposed on the third mounting plate 3111, the third slider 3113 and the second slide rail are matched such that the third mounting part 311 can reciprocate in a length direction of the second body 310 with respect to the second body 310, the fourth mounting part includes a fourth mounting plate 3121 and a fourth slider 3123 disposed on the fourth mounting plate 3121, and the fourth slider 3123 and the second slide rail are matched such that the fourth mounting part can reciprocate in the length direction of the second body 310 with respect to the second body 310.

Specifically, the second body 310 is a second slide rail, the third mounting part 311 includes a third mounting plate 3111 and a third slider 3113 disposed on the third mounting plate 3111, the third slider 3113 is matched with the second slide rail so that the third mounting part 311 can reciprocate relative to the second body 310 along the length direction of the second body 310, the fourth mounting part includes a fourth mounting plate 3121 and a fourth slider 3123 disposed on the fourth mounting plate 3121, the fourth slider 3123 is matched with the second slide rail so that the fourth mounting part can reciprocate relative to the second body 310 along the length direction of the second body 310, and the third slider 3113 and the fourth slider 3123 are matched with the second slide rail, so that the resistance during the movement can be reduced, and the movement is more sensitive.

While the utility model has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the utility model is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Claims (10)

1. The utility model provides a cutting machine with biax transmission assembly which characterized in that includes:

the wall plate is vertically arranged;

the discharging assembly is arranged on the wall plate and used for discharging positive and negative pole pieces of the wide lithium battery;

the slitting assembly is arranged in the middle of the wallboard and is positioned at the downstream of the discharging assembly, and the slitting assembly is used for slitting the positive and negative pole pieces of the wide lithium battery into at least two positive and negative pole pieces of the narrow lithium battery;

at least two winding assemblies which are positioned at the downstream of the slitting assembly;

the slitting component comprises a double-shaft transmission component used for conveying narrow material belts, the double-shaft transmission component comprises a first body, a first mounting part, a second mounting part, a first transmission shaft and a second transmission shaft, the first body is fixedly connected with a wallboard, the first mounting part and the second mounting part are arranged on the first body at intervals, the first transmission shaft is rotatably connected with the first mounting part, the first mounting part can be used for the first body to move in a reciprocating manner along the length direction of the first body, the second transmission shaft is rotatably connected with the second mounting part, the second mounting part can be used for the first body to move in a reciprocating manner along the length direction of the first body, a first rotating part is arranged on the first transmission shaft, a second rotating part is arranged on the second transmission shaft, and a first rotating part matched with the second rotating part is arranged between the first rotating part and the second rotating part The first rotating connecting piece is fixedly connected with the first body;

the first mounting part and the second mounting part are both reciprocated along the length direction of the first body relative to the first body, so that the first transmission shaft and the second transmission shaft are both reciprocated along the length direction of the first body relative to the first body, and at the moment, the first transmission shaft and the second transmission shaft are synchronously rotated.

2. The slitting machine with a double-shaft transmission assembly according to claim 1, wherein the first rotating connecting member includes a fixed portion fixedly connected with the first body and a connecting portion formed to extend from a side of the fixed portion in a direction away from the fixed portion, the connecting portion being adapted to mate with the first rotating member and the second rotating member.

3. The slitting machine with the double-shaft transmission assembly according to claim 2, wherein the fixing portions include a first fixing portion and a second fixing portion connected to the first fixing portion, the first fixing portion has a height lower than that of the second fixing portion, a side of the first fixing portion away from the second fixing portion is used for being connected to the connecting portion, a gap is formed between the first fixing portion and the first body, and the second fixing portion is used for being fixedly connected to the first body.

4. The slitting machine with a dual shaft drive assembly of claim 3 wherein the first rotational connection is bar shaped and extends along a length of the first body.

5. The slitting machine with the double-shaft transmission assembly as claimed in claim 2, wherein the first rotating member and the second rotating member are both gears, and a rack is disposed on a side of the connecting portion away from the fixing portion.

6. The slitting machine with a dual shaft drive assembly of claim 1 wherein the dual shaft drive assembly further comprises a first power member fixedly coupled to the first mounting member for driving the first drive shaft in rotation and a second power member fixedly coupled to the second mounting member for driving the second drive shaft in rotation.

7. The slitting machine with the double-shaft transmission assembly according to any one of claims 1 to 6, wherein a third rotating member is further disposed on the first transmission shaft and spaced from the first rotating member, a fourth rotating member is further disposed on the second transmission shaft and spaced from the second rotating member, a second rotating connecting member is disposed between the third rotating member and the fourth rotating member and matched with the third rotating member and the fourth rotating member, and the second rotating connecting member is used for being fixedly connected with a fixed carrier.

8. The slitting machine with a dual shaft drive assembly of claim 7 wherein the first rotating member and the third rotating member are located at respective ends of the first drive shaft and the second rotating member and the fourth rotating member are located at respective ends of the second drive shaft.

9. The slitting machine with a dual-shaft drive assembly of claim 8, wherein the dual-shaft drive assembly further comprises a second body for fixed connection to the stationary carrier, a third mount and a fourth mount spaced apart from the second body, the first drive shaft is rotatably coupled to the third mount, the third mount is reciprocally movable relative to the second body along a length of the second body, the second drive shaft is rotatably coupled to the fourth mount, and the fourth mount is reciprocally movable relative to the second body along a length of the second body.

10. The slitting machine with a dual shaft drive assembly of claim 9 wherein the first body includes a base plate and a first slide rail disposed on the base plate, the first mount includes a first mounting plate and a first slide block disposed on the first mounting plate, the first slide block and the first slide rail mating such that the first mount is reciprocatable relative to the first body along a length of the first body, the second mount includes a second mounting plate and a second slide block disposed on the second mounting plate, the second slide block and the first slide rail mating such that the second mount is reciprocatable relative to the first body along the length of the first body;

the second body is a second slide rail, the third mounting part comprises a third mounting plate and a third slider arranged on the third mounting plate, the third slider and the second slide rail are matched, so that the third mounting part can reciprocate relative to the second body along the length direction of the second body, and the fourth mounting part comprises a fourth mounting plate and a fourth slider arranged on the fourth mounting plate, and the fourth slider and the second slide rail are matched, so that the fourth mounting part can reciprocate relative to the second body along the length direction of the second body.

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