CN217619818U - Wire arranging device of wire cutting system and wire cutting machine - Google Patents

Abstract

The embodiment of the application provides a wire arranging device of a wire cutting system and a wire cutting machine. The wire arranging device comprises a wire arranging device body, wherein the wire arranging device body comprises a movable wire arranging wheel; the conductive cutting line penetrates through the space between the at least one pair of the deviation-rectifying conductive columns, and each deviation-rectifying conductive column is connected with a deviation-rectifying circuit unit which can be conducted when the cutting line deviates to be in contact with the deviation-rectifying conductive column. The wire arranging device provided by the embodiment of the application can find the condition that the cutting wire deviates in time.

Description

Wire arranging device of wire cutting system and wire cutting machine

Technical Field

The application relates to the technical field of wire cutting, in particular to a wire arranging device of a wire cutting system and a wire cutting machine.

Background

The wire cutting technology is an advanced evolution processing technology in the world at present. The principle of the method is that diamond wires form a cutting wire net, and the diamond wires moving at a high speed of the cutting wire net rub workpieces to be processed (such as magnetic materials, sapphire and other semiconductor hard and brittle materials), so that the cutting purpose is achieved. When the wire mesh is cut and wired every time, the inlet and outlet wires need to be adjusted before entering the take-up wire wheel or the pay-off wire wheel, namely, the flat cable needs to be adjusted.

Therefore, the conventional traverse device cannot automatically recognize the deviation of the cutting line, which is a technical problem that those skilled in the art are in urgent need to solve.

The above information disclosed in the background section is only for enhancement of understanding of the background of the present application and therefore it may contain information that does not form the prior art that is known to a person of ordinary skill in the art.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a wire arranging device of a wire cutting system with a new structure and a wire cutting machine.

The embodiment of the application provides a winding displacement device of wire-electrode cutting system, includes:

the wire arranging device comprises a wire arranging device body, a wire arranging device and a wire fixing device, wherein the wire arranging device body comprises a movable wire arranging wheel;

the conductive cutting line penetrates through the space between the at least one pair of the deviation-rectifying conductive columns, and each deviation-rectifying conductive column is connected with a deviation-rectifying circuit unit which can be conducted when the cutting line deviates to be in contact with the deviation-rectifying conductive column.

In an implementation, the rectification circuit unit includes:

a power supply for deviation correction;

an analog input module; one pole of the deviation-rectifying power supply is connected with the deviation-rectifying conductive column, and the other pole of the deviation-rectifying power supply is connected with the analog quantity input module;

the cutting line deviates and contacts with any deviation rectifying guide post to connect the deviation rectifying conductive post of the corresponding deviation rectifying circuit unit and the analog quantity input module so as to connect the deviation rectifying circuit unit.

In an implementation, the traverse further comprises:

the deviation rectifying control units are respectively connected with the deviation rectifying circuit units;

the deviation-rectifying control unit is used for controlling the wire-arranging wheel to move to drive the cutting line to leave the deviation-rectifying conductive column contacted with the cutting line.

The embodiment of the application also provides the following technical scheme:

a wire cutting machine, comprising the wire arranging device and the reversing device; the reversing device comprises:

the sliding seat can slide along the length direction of the guide rod and is locked after sliding in place;

and the reversing wheel assembly can swing towards the direction close to and far away from the guide rod and can be locked after swinging to a proper position.

In an implementation, the carriage comprises:

the sliding seat upper sliding block is positioned at the guide rod;

the sliding seat lower sliding block is connected below the sliding seat upper sliding block, and a gap is formed between the sliding seat lower sliding block and the guide rod;

and the sliding seat locking screw penetrates through the sliding seat lower sliding block and enters a gap between the sliding seat lower sliding block and the guide rod so as to lock the sliding seat.

In an implementation, the slide upper slide is provided with a slide upper slide notch with a downward notch; the sliding seat upper sliding block is located at the guide rod through a sliding seat upper sliding block notch;

the sliding seat lower sliding block is provided with a sliding seat lower sliding block notch with an upward notch; the sliding seat lower sliding block is connected below the sliding seat upper sliding block in a mode that a sliding seat lower sliding block groove opening faces upwards, and a gap is formed between the bottom wall of the sliding seat lower sliding block groove opening and the guide rod;

and the sliding seat locking screw penetrates through the sliding seat lower sliding block notch from the bottom of the sliding seat lower sliding block and enters a gap between the bottom wall of the sliding seat lower sliding block notch and the guide rod so as to lock the sliding seat.

Due to the adoption of the technical scheme, the embodiment of the application has the following technical effects:

when the cutting line does not deviate, the cutting line passes through the interval between the two deviation-rectifying conductive columns and is not contacted with the two deviation-rectifying conductive columns. When the cutting line deviates leftwards, the cutting line can contact with the left deviation-rectifying conductive column, and at the moment, the cutting line is connected with the left deviation-rectifying conductive column, so that the left deviation-rectifying conductive column and the deviation-rectifying circuit unit connected with the left deviation-rectifying conductive column are communicated. Similarly, when the cutting line deviates to the right, the right deviation-rectifying conductive column and the deviation-rectifying circuit unit connected with the right deviation-rectifying conductive column are connected. Therefore, the two deviation rectifying conductive columns correspond to the two deviation rectifying circuit units, the deviation of the cutting line can be found in time, and a foundation is provided for subsequent adjustment of the cutting line.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 is a schematic view of a wire cutting system of a wire cutting machine according to an embodiment of the present application;

FIG. 2 is a schematic view of a wire traversing device of the wire cutting system of FIG. 1;

FIG. 3 is a schematic view of the traverse shown in FIG. 2 from another angle;

FIG. 4 is a schematic view of the reversing device of the wire cutting system shown in FIG. 1 reversing the cutting wire at the inlet end and the outlet end of the cutting wire net;

FIG. 5 is a schematic view of a reversing device of the wire cutting system of FIG. 1;

FIG. 6 is a partial schematic view of the reversing device of FIG. 5;

FIG. 7 is a partial schematic view of another angle of the reversing device of FIG. 5;

fig. 8 is a schematic view of an end face of a guide bar of the reversing device shown in fig. 5.

Reference numerals:

the wire arranging device (34) is provided with a wire arranging device,

a wire arranging wheel 341-1, a first wire arranging rocker 341-2,

a first balancing weight 342-1, a second row line rocker arm 342-2, a second balancing weight 342-3,

a deviation-correcting conductive post 343, a flat cable rotating shaft 344, a flat cable rotating shaft connecting plate 345,

a traverse guide module 346, a traverse slide 347, a traverse slide drive motor 348,

the direction-changing device (36) is provided with a reversing device,

the guide rods 361 are provided in the upper portion of the body,

a slide 362, a slide upper slide 362-1, a slide upper slide notch 362-11, a slide lower slide 362-2, a slide lower slide notch 362-21, a slide locking screw 362-3,

a steering connecting plate 363 is provided with a steering connecting plate,

a reversing wheel assembly 364, a reversing wheel 364-1, a reversing wheel support 364-2, a reversing wheel support mounting pin 364-3, a lower layer arc hole 364-4, a lower layer adjusting screw 364-5, an upper layer adjusting screw 364-6,

the guide bar fixing base 365.

Detailed Description

In order to make the technical solutions and advantages of the embodiments of the present application more apparent, the following further detailed description of the exemplary embodiments of the present application with reference to the accompanying drawings makes it clear that the described embodiments are only a part of the embodiments of the present application, and are not exhaustive of all embodiments. It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

Example one

As shown in fig. 1, 2 and 3, the traverse 34 of the wire cutting system according to the embodiment of the present application includes:

a traverse device body including a movable traverse wheel 341-1;

the wire arranging wheel is provided with at least one pair of deviation-rectifying conductive columns 343 arranged on the same side of the wire arranging wheel at intervals, the conductive cutting line penetrates between the at least one pair of deviation-rectifying conductive columns, and each deviation-rectifying conductive column is connected with a deviation-rectifying circuit unit which can be conducted when the cutting line deviates to be in contact with the deviation-rectifying conductive columns 343.

In the wire arranging device of the wire cutting system of the embodiment of the application, when the cutting line is not deviated, the cutting line penetrates through the space between the at least one pair of deviation-rectifying conductive posts and is not contacted with the two deviation-rectifying conductive posts. As shown in fig. 2 and 3, when the cutting line deviates to the left, the cutting line will contact with the left deviation-correcting conductive pillar, and at this time, the cutting line is connected with the left deviation-correcting conductive pillar, so as to connect the deviation-correcting circuit unit connected with the left deviation-correcting conductive pillar. Similarly, when the cutting line deviates to the right, the deviation rectifying circuit unit connected with the deviation rectifying conductive column is connected. Therefore, each deviation-rectifying conductive column corresponds to one deviation-rectifying circuit unit, the deviation condition and the deviation direction of the cutting line can be found in time, and a foundation is provided for the subsequent adjustment of the cutting line.

In an implementation, the rectification circuit unit includes:

a power supply for deviation correction;

an analog input module; one pole of the deviation-rectifying power supply is connected with the deviation-rectifying conductive column, and the other pole of the deviation-rectifying power supply is connected with the analog quantity input module;

the cutting line deviates and contacts with any deviation rectifying guide post to connect the deviation rectifying conductive post of the corresponding deviation rectifying circuit unit and the analog quantity input module so as to connect the deviation rectifying circuit unit.

Thus, one pole of the deviation-correcting power supply is connected with the deviation-correcting conductive column, the other pole of the deviation-correcting power supply is connected with the analog quantity input module, and the deviation-correcting circuit unit and the deviation-correcting conductive column are in open circuit when the cutting line is not in contact with the deviation-correcting conductive column. When the cutting line is contacted with the deviation rectifying conductive column, the deviation rectifying circuit unit and the deviation rectifying conductive column are a path. The detection of the cutting line deviation is achieved by a simple structure.

In an implementation, the wire arranging device further comprises:

the deviation rectifying control units are respectively connected with the deviation rectifying circuit units;

the deviation-rectifying control unit is used for controlling the wire-arranging wheel to move to drive the cutting line to leave the deviation-rectifying conductive column contacted with the cutting line.

The deviation-rectifying control unit is matched with the deviation-rectifying circuit unit and the deviation-rectifying conductive columns, the deviation-rectifying control unit controls the wire-arranging wheel to move towards the left deviation-rectifying conductive columns under the condition that the cutting line deviates leftwards and is connected with the left deviation-rectifying conductive columns, and the deviation-rectifying circuit unit and the left deviation-rectifying conductive columns are connected, so that the cutting line is not contacted with the two deviation-rectifying conductive columns. In a similar way, under the condition that the cutting line deviates to the right and is connected with the deviation-rectifying conductive column on the right side, the deviation-rectifying control unit controls the wire arranging wheel to move towards the deviation-rectifying conductive column on the right side, so that the cutting line is not contacted with the two deviation-rectifying conductive columns.

In implementation, as shown in fig. 2 and 3, the traverse body includes a first traverse rocker 341-2 and a traverse wheel rotating assembly, and the traverse wheel 341-2 is installed at one side of the first traverse rocker 341-2; the wire arrangement wheel rotating component comprises:

a flat cable rotating shaft 344;

a flat cable rotation shaft connection plate 345 rotatably connected to the outer circumference of the flat cable rotation shaft;

a second traverse rocker arm 342-2 and the first traverse rocker arm 341-1, respectively fixed to the traverse rotation axis connection plate 345 and located at both sides of the traverse rotation axis 344;

a first weight 342-1 installed at the second traverse rocker 342-2, and the first weight 342-1 is movable in a direction perpendicular to the axial direction of the traverse rotation shaft 344;

the second balancing weight 342-3 is arranged at the top of the flat cable rotating shaft connecting plate and is close to the position of the second flat cable rocker arm;

the first wire arranging rocker arm and the wire arranging wheel are in a distance balance state so that the cutting wire is located in a wire groove of the wire arranging wheel.

Second winding displacement rocking arm, first balancing weight and second balancing weight, first winding displacement rocking arm and winding displacement wheel are in apart from balanced state, and like this, the winding displacement wheel is not rotating when not receiving line of cut effort and being in natural state, is certain angle between winding displacement wheel and the winding displacement rotation axis, so that the line of cut is located the wire casing of winding displacement wheel.

In implementation, as shown in fig. 2 and 3, a first counterweight mounting screw is convexly disposed at a position of the second traverse rocker 342-2 away from the traverse rotating shaft connecting plate;

the first balancing weight 342-1 is rotatably installed at the first balancing weight installation screw through a threaded hole reserved in the first balancing weight, and the first balancing weight can move along the length direction of the first balancing weight installation screw.

In implementation, as shown in fig. 2 and 3, a second counterweight mounting screw is convexly disposed on the top of the flat cable rotating shaft connecting plate 345;

the second balancing weight 342-3 is rotatably installed at the second balancing weight installation screw through a threaded hole reserved in the second balancing weight 342-3, and the second balancing weight 342-3 can move along the length direction of the second balancing weight installation screw;

the second weight 342-3 is mounted on the top of the traverse rotating shaft connecting plate 345 and near the second traverse rocker arm 342-2.

Like this, the length direction adjustment of first balancing weight installation screw can be followed to the position of first balancing weight, and the length direction adjustment of second balancing weight installation screw can be followed to the position of second balancing weight, and moment is no longer balanced, can drive the rotation of calandria wheel. The first balancing weight and the second balancing weight are adjusted repeatedly until the cutting line is located in the wire groove of the wire arranging wheel, so that the stability of the cutting line of the wire cutting system during high-speed reciprocating operation is ensured.

In an implementation, as shown in fig. 2 and 3, the traverse further includes:

a flat cable guide module 346;

a flat cable sliding seat 347 slidably connected to the flat cable guide module 346;

the flat cable rotating shaft 344 is fixed to the flat cable sliding seat 347;

a traverse carriage driving motor 348 connected to the traverse carriage 347 for driving the traverse carriage 347 to move along the guiding direction of the traverse guide module 346.

The winding displacement rotating shaft and the winding displacement sliding seat are fixed, namely the winding displacement rotating shaft does not rotate and is fixed. The wire arranging slide seat moves along the guiding direction of the wire arranging guiding module to drive the wire arranging wheel to move along with the wire arranging wheel.

Specifically, the deviation correction control unit is connected to the traverse slide driving motor 348, and further controls the traverse slide driving motor 348 to operate to drive the traverse wheel to move to the left or right.

Under the condition that the cutting line is deviated leftwards and connected with the left deviation-rectifying conductive column, and the left deviation-rectifying conductive column and the corresponding deviation-rectifying circuit unit are connected, the deviation-rectifying control unit controls the wire arranging sliding seat driving motor 348 to work, so that the wire arranging sliding seat 347 is controlled to move leftwards along the guiding direction of the wire arranging guiding module 346, the wire arranging wheel is moved leftwards, and the cutting line is not contacted with the two deviation-rectifying conductive columns. In a similar way, the cutting line is deviated rightwards and is connected with the deviation-rectifying conductive column on the right side, and the deviation-rectifying control unit, the winding displacement sliding seat driving motor and the winding displacement sliding seat are matched to realize that the winding displacement wheel moves rightwards, so that the cutting line is not contacted with the two deviation-rectifying conductive columns.

Example two

The embodiment of the application provides a wire cutting machine, which comprises a wire arranging device and a reversing device in the first embodiment.

As shown in fig. 1, 4 to 8, the reversing device 36 includes:

the guide rod 361 and the sliding seat 362 are connected with the guide rod 361, and the sliding seat can slide along the length direction of the guide rod and is locked after sliding in place;

a steering link plate 363 fixed to the slide base 362;

the steering wheel assembly 364 is connected to the steering connection plate 363, and the steering wheel assembly 364 can swing towards and away from the guide rod and can swing to a position to be locked.

In the reversing device, a sliding seat and a steering connecting plate are fixed together, and a reversing wheel assembly is connected to the steering connecting plate. Therefore, when the sliding seat slides along the length direction of the guide rod, the steering connecting plate and the reversing wheel component can be driven to move. After the slide carriage is slid into position, the slide carriage is locked, and the position of the slide carriage and the steering link plate relative to the guide bar is locked. The reversing wheel assembly can swing towards the direction close to and away from the guide rod. And after the reversing wheel swings to the right position, the reversing wheel assembly is locked, and at the moment, the distance between the reversing wheel assembly and the guide rod is fixed. The switching-over device of cutting wire net of this application embodiment, on the one hand the position of switching-over wheel subassembly in the length direction of guide bar can be adjusted, and on the other hand, the switching-over wheel subassembly also can be adjusted in the direction that is close to and keeps away from the guide bar, has realized the adjustment of switching-over wheel subassembly in a plurality of directions, and then has realized the nimble direction of adjusting the diamond wire through the switching-over wheel subassembly.

The reversing device is particularly suitable for being used as a reversing device of a magnetic material multi-wire cutting machine.

In practice, as shown in fig. 5, 6 and 7, the slide 362 comprises:

a carriage upper slide 362-1 having a carriage upper slide slot 362-11 with a slot facing downward; wherein the slider-on-carriage 362-1 is seated at the guide bar 361 through the slider-on-carriage notch 362-11;

a carriage lower slide 362-2 having a carriage lower slide slot 362-21 with an upward slot; wherein the carriage lower slider 362-2 is connected below the carriage upper slider 362-1 in such a manner that the carriage lower slider notch 362-21 faces upward, and a gap is provided between the bottom wall of the carriage lower slider notch 362-21 and the guide bar 361;

a slide locking screw 362-3, the slide locking screw 362-3 passing through the slide lower slider slot from the bottom of the slide lower slider 362-2 and entering the gap between the bottom wall of the slide lower slider slot and the guide bar to lock the slide.

When the sliding seat needs to slide along the length direction of the guide rod, the sliding seat locking screw is unscrewed, and a gap is reserved between the top of the sliding seat locking screw and the guide rod. And after the sliding slide seat slides in place, a slide seat locking screw is screwed, and the slide seat locking screw abuts against the bottom of the guide rod, so that the slide seat is locked in the length direction relative to the guide rod. The mode of the position of the sliding seat is fixed through the sliding seat locking screw below the sliding seat lower sliding block, and the device is convenient and reliable and is more convenient to operate.

In implementation, as shown in fig. 8, the guide bar 361 is a straight-angle rhombus with a straight-angle cutting end face, and four straight angles of the straight-angle rhombus are respectively upward, downward, leftward and rightward;

as shown in fig. 7, the sliding block upper sliding block notch 362-11 is an inverted V-shaped notch, and the sliding block upper sliding block is located at the upward flat angle of the flat angle rhombus through the V-shaped notch;

as shown in fig. 7, the notches 362-21 of the lower slider are concave notches, and the inner groove walls of the concave notches are clamped at the left and right flat corners of the rhomboid.

The slide block on the slide seat is located at the upward flat angle of the flat angle rhombus through the inverted V-shaped groove opening under the action of gravity. The inner groove wall of the concave groove opening is clamped at the two flat corners of the square rhombus facing left and right, and the connection between the sliding block on the sliding seat and the top of the groove wall of the concave groove opening can be conveniently realized through bolts and screw holes. The top of the sliding seat locking screw can be propped against the downward flat angle of the flat angle diamond, so that the sliding seat locking screw can be stably propped against the guide rod, and the sliding seat is locked.

In operation, as shown in fig. 6, the reversing wheel assembly 364 comprises a reversing wheel 364-1 and a reversing wheel support 364-2, wherein the reversing wheel 364-1 is mounted on the reversing wheel support 364-2;

the steering connecting plate is provided with a reversing wheel support mounting hole, and the reversing wheel support is rotatably mounted at the steering connecting plate 363 through a reversing wheel support mounting pin 364-3 and the reversing wheel support mounting hole.

The reversing wheel is arranged on the reversing wheel support, so that the reversing wheel can rotate. The reversing wheel support mounting hole is matched with the reversing wheel support mounting pin shaft, so that the reversing wheel and the reversing wheel support can rotate relative to the steering connecting plate, and the reversing wheel support can swing towards the direction close to and away from the guide rod. The reversing wheel adjusts the angle of the steering connecting plate to adapt to the routing and steering of the wire inlet end and the wire outlet end of the cutting wire net of the multi-wire cutting machine, so that the wire net wire moving mechanism of the multi-wire cutting machine is formed, the problem of the shaking of the cutting wire net when the cutting wire net of the multi-wire cutting machine runs at a high speed is solved, and the cutting stability and the cutting quality of equipment are improved.

Specifically, as shown in fig. 6, the upper edge of the reverser wheel is tangent to the axial direction of the reverser wheel bearing mounting pin 364-3.

In practice, as shown in fig. 6, the steering connecting plate is further provided with a lower layer arc-shaped hole 364-4, and the lower layer arc-shaped hole 364-4 is positioned below the reversing wheel support mounting hole;

the reversing wheel assembly further comprises a lower layer adjusting screw 364-5 and a lower layer locking nut; the lower layer adjusting screw 364-5 passes through the lower layer arc-shaped hole 364-4 and the reversing wheel support to be in threaded connection with the lower layer locking nut.

In implementation, the steering connecting plate is also provided with an upper-layer arc-shaped hole, and the upper-layer arc-shaped hole is positioned between the reversing wheel support mounting hole and the lower-layer arc-shaped hole;

the reversing wheel assembly further comprises an upper layer adjusting screw 364-6 and an upper layer locking nut; and the upper layer adjusting screw penetrates through the upper layer arc-shaped hole and the reversing wheel support to be fixedly connected with the upper layer locking nut in a threaded manner.

When the angle of the reversing wheel needs to be adjusted, the lower-layer locking nut and the upper-layer locking nut are unscrewed, the reversing wheel support is rotated by taking the reversing wheel support mounting pin shaft as the center, the rotation is limited by the lengths of the lower-layer arc-shaped hole and the upper-layer arc-shaped hole, and then the steering wheel is driven to swing towards the direction close to and away from the guide rod by taking the reversing wheel support mounting pin shaft as the center. The lower-layer arc-shaped hole, the lower-layer adjusting screw and the lower-layer locking nut are arranged, and the upper-layer arc-shaped hole, the upper-layer adjusting screw and the upper-layer locking nut are also arranged, so that the stress of the reversing wheel support is uniform.

In operation, as shown in fig. 5 and 6, the slider 362 and the reversing wheel assembly 364 are located on the same side of the steering linkage plate.

Thus, the structure of the reversing device is simple.

In practice, as shown in fig. 1 and 4, one guide bar corresponds to only one reversing wheel assembly.

Thus, one guide rod only corresponds to one reversing wheel assembly, the guide rod only bears the force of the diamond wire of the corresponding reversing wheel assembly, and the deformation amount is small.

In implementation, as shown in fig. 5, the reversing device further includes:

and two guide bar fixing seats 365 respectively fixed to both ends of the guide bar 361 for fixing the reversing device.

The reversing device is fixed through the two guide rod fixing seats, so that the reversing device is fixed stably.

While the preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all alterations and modifications as fall within the scope of the application.

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

Claims (14)

1. A traverse of a wire cutting system, comprising:

the wire arranging device comprises a wire arranging wheel capable of moving;

the conductive cutting line penetrates through the space between the at least one pair of the deviation-rectifying conductive columns, and each deviation-rectifying conductive column is connected with a deviation-rectifying circuit unit which can be conducted when the cutting line deviates to be in contact with the deviation-rectifying conductive column.

2. The traverse of claim 1, wherein the deskew circuit unit comprises:

a power supply for deviation correction;

an analog input module; one pole of the deviation-rectifying power supply is connected with the deviation-rectifying conductive column, and the other pole of the deviation-rectifying power supply is connected with the analog quantity input module;

the cutting line deviates and contacts with any deviation rectifying guide post to connect the deviation rectifying conductive post of the corresponding deviation rectifying circuit unit and the analog quantity input module so as to connect the deviation rectifying circuit unit.

3. The traverse of claim 2, further comprising:

the deviation rectifying control units are respectively connected with the deviation rectifying circuit units;

the deviation-rectifying control unit is used for controlling the wire-arranging wheel to move to drive the cutting line to leave the deviation-rectifying conductive column contacted with the cutting line.

4. The traverse of claim 3, wherein the traverse body comprises a first traverse rocker and a traverse wheel rotating assembly, the traverse wheel being mounted on one side of the first traverse rocker; the wire arrangement wheel rotating component comprises:

a flat cable rotating shaft;

the flat cable rotating shaft connecting plate is rotatably connected to the periphery of the flat cable rotating shaft;

the second flat cable rocker arm and the first flat cable rocker arm are respectively fixed with the flat cable rotating shaft connecting plate and are positioned on two sides of the flat cable rotating shaft;

a first weight block installed at the second traverse rocker arm and movable in a direction perpendicular to an axial direction of the traverse rotation shaft;

the second balancing weight is arranged at the top of the flat cable rotating shaft connecting plate and is close to the position of the second flat cable rocker arm;

the first wire arranging rocker arm and the wire arranging wheel are in a distance balance state so that the cutting wire is located in a wire groove of the wire arranging wheel.

5. The traverse of claim 4, wherein a first counterweight mounting screw is provided at a position of the second traverse rocker arm away from the traverse rotating shaft connection plate;

the first balancing weight is rotatably installed at the position of the first balancing weight installation screw through a threaded hole reserved in the first balancing weight, and the first balancing weight can move along the length direction of the first balancing weight installation screw.

6. The traverse of claim 5, wherein a second weight mounting screw is provided at the top of the traverse rotating shaft connection plate;

the second balancing weight is rotatably installed at the second balancing weight installation screw through a threaded hole reserved in the second balancing weight, and the second balancing weight can move along the length direction of the second balancing weight installation screw;

the second balancing weight is installed at the top of the flat cable rotating shaft connecting plate and close to the position of the second flat cable rocker arm.

7. The traverse of claim 6, further comprising:

a flat cable guide module;

the flat cable sliding seat is connected with the flat cable guide module in a sliding way;

the flat cable rotating shaft is fixed with the flat cable sliding seat;

and the wire arranging slide seat driving motor is connected with the wire arranging slide seat to drive the wire arranging slide seat to move along the guiding direction of the wire arranging guide module.

8. A wire cutting machine comprising the wire arranging device of any one of claims 1 to 7 and a reversing device; the reversing device comprises:

the sliding seat can slide along the length direction of the guide rod and is locked after sliding in place;

and the reversing wheel assembly can swing towards the direction close to and far away from the guide rod and can be locked after swinging to a proper position.

9. The wire cutting machine according to claim 8, wherein the carriage comprises:

the sliding seat upper sliding block is positioned at the guide rod;

the sliding seat lower sliding block is connected below the sliding seat upper sliding block, and a gap is formed between the sliding seat lower sliding block and the guide rod;

and the sliding seat locking screw penetrates through the sliding seat lower sliding block and enters a gap between the sliding seat lower sliding block and the guide rod so as to lock the sliding seat.

10. The wire cutting machine according to claim 9 wherein the slide upper block has a slide upper block notch with a notch facing downward; the sliding seat upper sliding block is located at the guide rod through a sliding seat upper sliding block notch;

the sliding seat lower sliding block is provided with a sliding seat lower sliding block notch with an upward notch; the sliding seat lower sliding block is connected below the sliding seat upper sliding block in a mode that a sliding seat lower sliding block groove opening faces upwards, and a gap is formed between the bottom wall of the sliding seat lower sliding block groove opening and the guide rod;

and the sliding seat locking screw penetrates through the sliding seat lower sliding block notch from the bottom of the sliding seat lower sliding block and enters a gap between the bottom wall of the sliding seat lower sliding block notch and the guide rod so as to lock the sliding seat.

11. The wire cutting machine according to claim 10, wherein the guide bar has a flat-angled rhombus with four flat angles facing upward, downward, leftward and rightward, respectively;

the sliding seat upper sliding block notch is an inverted V-shaped notch, and the sliding seat upper sliding block is located at the upward flat angle of the flat angle rhombus through the V-shaped notch;

the sliding seat lower sliding block notch is a concave notch, and the inner groove wall of the concave notch is clamped at two horizontal angles towards the left and the right of the horizontal angle rhombus.

12. The wire cutting machine according to claim 8, wherein one guide bar corresponds to only one of the reversing wheel assemblies.

13. The wire cutting machine according to claim 11, characterized by further comprising:

the steering connecting plate is fixed with the sliding seat;

the reversing wheel assembly is connected to the steering connecting plate;

the reversing wheel assembly comprises a reversing wheel and a reversing wheel support, and the reversing wheel is mounted on the reversing wheel support;

the steering connecting plate is provided with a reversing wheel support mounting hole, and the reversing wheel support is rotatably mounted at the steering connecting plate through a reversing wheel support mounting pin shaft and the reversing wheel support mounting hole.

14. The wire cutting machine of claim 13 wherein the steering linkage plate further has a lower arcuate aperture positioned below the diverter wheel bracket mounting aperture;

the reversing wheel assembly further comprises a lower layer adjusting screw and a lower layer locking nut; and the lower layer adjusting screw penetrates through the lower layer arc-shaped hole and the reversing wheel support to be in threaded connection with the lower layer locking nut.

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