CN219256049U - Wire saw unit and wire cutting machine - Google Patents

Abstract

The embodiment of the application provides a wire saw unit and wire cutting machine, wherein, the wire saw unit includes: a cutting mechanism; the cutting mechanism comprises at least two cutting main rollers used for winding a cutting line; the winding and unwinding mechanism is arranged on one side of the cutting mechanism; the winding and unwinding mechanism comprises a winding and unwinding roller for storing or releasing the cutting line and a winding and unwinding rotation driver for driving the winding and unwinding roller to rotate circumferentially; the cutting line moves back and forth between the winding and unwinding line roller and the cutting main roller to realize cutting; the tension mechanism and the winding and unwinding mechanism are arranged on the same side of the cutting mechanism; the tension mechanism is provided with a tension wheel; the cutting line between the cutting mechanism and the winding and unwinding mechanism passes through the tension pulley, so that the cutting line released by the winding and unwinding roller is guided to the cutting main roller through the tension pulley, or the cutting line wound from the cutting main roller is guided to the winding and unwinding roller through the tension pulley for storage. The wire saw unit and the wire cutting machine provided by the embodiment of the application can shorten the wiring length of the cutting wire, so that the stability of the cutting wire is improved.

Description

Wire saw unit and wire cutting machine

Technical Field

The application relates to a hard and brittle material cutting technology, in particular to a wire saw unit and a wire cutting machine.

Background

The wire cutting machine is a device for dividing a large workpiece into small workpieces by utilizing cutting wires, the traditional wire cutting machine is divided into a cutting area and a winding area from front to back, a cutting main roller and a reversing wheel are arranged in the cutting area, and a winding-unwinding roller, a winding-unwinding wheel and a tension wheel are arranged in the winding area. And the reversing wheel, the winding and unwinding roller, the winding displacement wheel and the tension wheel are respectively arranged at two sides of the wire cutting machine.

In the scheme, the cutting line moves back and forth in the cutting area and the winding area, the wiring path is longer, and the tension stability of the cutting line is poor.

Disclosure of Invention

In order to solve one of the above technical drawbacks, an embodiment of the present application provides a wire saw unit and a wire cutting machine.

According to a first aspect of embodiments of the present application, there is provided a wire saw unit comprising:

a cutting mechanism; the cutting mechanism comprises at least two cutting main rollers used for winding a cutting line;

the winding and unwinding mechanism is arranged on one side of the cutting mechanism; the winding and unwinding mechanism comprises a winding and unwinding roller for storing or releasing the cutting line and a winding and unwinding rotation driver for driving the winding and unwinding roller to rotate circumferentially; the cutting line moves back and forth between the winding and unwinding line roller and the cutting main roller to realize cutting;

the tension mechanism and the winding and unwinding mechanism are arranged on the same side of the cutting mechanism; the tension mechanism is provided with a tension wheel; the cutting line between the cutting mechanism and the winding and unwinding mechanism passes through the tension pulley, so that the cutting line released by the winding and unwinding roller is guided to the cutting main roller through the tension pulley, or the cutting line wound from the cutting main roller is guided to the winding and unwinding roller through the tension pulley for storage.

According to a second aspect of embodiments of the present application, there is provided a wire cutting machine including: the wire saw unit is arranged on the cutting frame.

According to the technical scheme, the cutting mechanism comprises at least two cutting main rollers used for winding a cutting line, the winding and unwinding mechanism and the tension mechanism are arranged on one side of the winding and unwinding mechanism, the tension mechanism comprises the tension wheel, the winding and unwinding mechanism comprises the winding and unwinding roller and the winding and unwinding rotation driver, the cutting line is cut by reciprocating movement among the cutting main rollers, the tension wheel and the winding and unwinding roller, the tension mechanism and the winding and unwinding mechanism are arranged on the same side of the cutting mechanism and are located on the side face of the cutting mechanism, the winding and unwinding mechanism and the tension mechanism are arranged on the rear of the cutting mechanism in comparison with the traditional scheme, the winding and unwinding mechanism and the tension mechanism can be arranged on the rear of the cutting mechanism, accordingly, the winding and unwinding length of the cutting line can be shortened, tension fluctuation of the cutting line can be reduced, and tension stability can be improved, and cutting quality can be improved.

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 embodiments of the application and together with the description serve to explain the application and do not constitute an undue limitation to the application. In the drawings:

fig. 1 is an axial view of a wiresaw unit provided in an embodiment of the present application;

FIG. 2 is a schematic diagram of the movement direction of a linear tension mechanism according to an embodiment of the present disclosure;

FIG. 3 is a schematic view of another movement direction of the linear tension mechanism according to the embodiment of the present application;

fig. 4 is a schematic structural diagram of a wire cutting machine according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of another wire cutting machine according to an embodiment of the present disclosure;

fig. 6 is another schematic structural diagram of another wire cutting machine according to an embodiment of the present disclosure.

Reference numerals:

1-a cutting mechanism; 11-cutting a main roller;

21-a tension pulley;

3-a wire winding and unwinding mechanism; 31-a wire winding and unwinding roller; 32-take-up and pay-off rotation drive.

4-a feeding mechanism;

5-silicon rod;

6-cutting the frame;

7-cutting lines.

Detailed Description

In order to make the technical solutions and advantages of the embodiments of the present application more apparent, the following detailed description of exemplary embodiments of the present application is given with reference to the accompanying drawings, and it is apparent that the described embodiments are only some of the embodiments of the present application and not exhaustive of all the embodiments. It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other.

The embodiment provides a wire saw unit which can be used in a wire cutting machine for cutting a large workpiece into small workpieces. The workpiece may be a bar of hard and brittle material, such as: single crystal silicon material rods, polycrystalline silicon material rods, sapphire rods, magnetic material rods, and the like. In this embodiment, a wire saw unit and a wire cutting machine will be described in detail using a silicon rod as an example (hereinafter, simply referred to as a silicon rod). The solution provided by the present embodiment can also be applied by those skilled in the art to cut other sticks of material.

The wire cutting machine may be a cutter, a squarer, a slicer, or the like. The cutting machine is used for cutting the strip-shaped workpiece into small sections, the squarer is used for cutting the cylindrical workpiece into cuboid, and the slicer is used for cutting the cylindrical workpiece into slices. In this embodiment, a slicer is taken as an example, and a technical scheme will be described in detail. The technical scheme provided by the embodiment can also be applied to other wire cutting machines by a person skilled in the art.

As shown in fig. 1 and 4, the wire saw unit provided in this embodiment includes: cutting mechanism, receive unwrapping wire mechanism and tension mechanism. The cutting mechanism comprises at least two main cutting rollers 11, and the at least two main cutting rollers 11 are arranged side by side. The cutting wires are wound on the cutting main rollers 11 to form a cutting wire net, and the cutting wires between two adjacent cutting main rollers 11 are used as wire saws for cutting the silicon rod.

The winding and unwinding mechanism is arranged on one side of the cutting mechanism, and comprises a winding and unwinding roller 31 and a winding and unwinding rotation driver 32, wherein the winding and unwinding rotation driver 32 is used for driving the winding and unwinding roller 31 to rotate circumferentially, and the winding and unwinding roller stores or releases the cutting line in the circumferential rotation process. The cutting line reciprocates between the take-up and pay-off roller 31 and the cutting main roller 11 to cut the silicon rod.

The tension mechanism and the winding and unwinding mechanism are arranged on the same side of the cutting mechanism. The tension mechanism has a tension pulley 21, and the cutting line between the cutting mechanism and the take-up and pay-off mechanism passes through the tension pulley 21, the tension pulley 21 being movable to adjust the tension of the cutting line. The cutting line released from the take-up and pay-off roller 31 is guided to the cutting main roller 11 via the tension roller 21, or the cutting line wound out from the cutting main roller 11 is guided to the take-up and pay-off roller 31 via the tension roller 21 for storage.

The silicon rod 5 moves downward in the Y direction in fig. 1, and the silicon rod 5 is cut by the cutting line 7.

In the wire saw unit provided in this embodiment, the cutting wire released from the wire winding and unwinding roller 31 is guided to the cutting main roller 11 via the tension roller 21, and wound from at least two cutting main rollers 11 to form a cutting wire net, and wound from the cutting main roller 11 and guided to the other wire winding and unwinding roller 31 via the other tension roller 21.

The winding and unwinding rollers 31 alternately perform winding and unwinding so that the cutting line reciprocates between the cutting main roller 11, the tension roller 21, and the winding and unwinding rollers 31 to cut.

According to the technical scheme, the cutting mechanism comprises at least two cutting main rollers used for winding a cutting line, the winding and unwinding mechanism and the tension mechanism are arranged on one side of the winding and unwinding mechanism, the tension mechanism comprises a tension wheel, the winding and unwinding mechanism comprises a winding and unwinding roller and a winding and unwinding rotation driver, the cutting line is cut by reciprocating between the cutting main rollers, the tension wheel and the winding and unwinding roller, the tension mechanism and the winding and unwinding mechanism are arranged on the same side of the cutting mechanism and are located on the side face of the cutting mechanism, the winding and unwinding mechanism and the tension mechanism are arranged on the rear of the cutting mechanism compared with the traditional scheme, the winding and unwinding length of the cutting line can be shortened by the scheme provided by the embodiment, so that tension fluctuation of the cutting line is reduced, tension stability is improved, and cutting quality is improved.

The embodiment provides an application scenario: the cutting mechanism 2 includes two cutting main rollers which extend in the horizontal direction, are arranged side by side, and are arranged at intervals. The two ends of the cutting main roller are respectively arranged at the front end of the cutting frame 6 through bearing boxes. One end of the cutting main roller is connected with a driving motor, the driving motor drives the cutting main roller to rotate, and the driving motor is arranged at the rear end of the cutting frame 6. The cutting wire is wound in from one end of a cutting main roller and is wound out from the other end. For example: the cutting line winds in from above one end of the main cutting roller and winds out from above the other end of the main cutting roller.

The top of the cutting frame 6 is also provided with a feeding mechanism 4 which drives the silicon rod to move downwards and move between the two main cutting rollers, and the silicon rod is sliced through a cutting line.

As shown in fig. 4 to 6, the two take-up and pay-off mechanisms are arranged on the same side of the cutting mechanism 1, and as shown in the view angle of fig. 1, the two take-up and pay-off mechanisms are arranged on the left side of the cutting mechanism or on the right side of the cutting mechanism. The cutting wire released from one of the take-up and pay-off rollers 31 is wound into the cutting mechanism through the tension pulley 21, the cutting wire wound out from the cutting mechanism is guided to the other take-up and pay-off roller 31 through the tension pulley 21, and the cutting wire reciprocates between the two take-up and pay-off rollers 31, the tension pulley 21 and the cutting main rollers 11.

In this solution, the axes of the take-up and pay-off rolls 31 in the two take-up and pay-off mechanisms 3 extend horizontally, for example parallel to the axis of the cutting main roll 11, as shown in fig. 5 and 6. Alternatively, the axes of the take-up and pay-off rolls 31 in the two take-up and pay-off mechanisms 3 extend in the vertical direction, as shown in fig. 4.

In addition to the above, the feeding mechanism 4 may be disposed at the bottom of the cutting frame 6 to drive the silicon rod to move upward for slicing.

The number of cutting main rolls in the cutting mechanism 2 may be two, three or more than three. If the number of the cutting main rollers is two, the two cutting main rollers are arranged along the horizontal direction; if the number of the cutting main rollers is three, the three cutting main rollers are arranged into a regular triangle; if the number of the cutting main rollers is four, the four cutting main rollers are arranged in a regular triangle or rectangle.

When the number of the cutting main rollers 11 is three, two cutting main rollers 11 are above and one cutting main roller 11 is below. For example: the cutting line may be wound in from one end of the upper one of the cutting main rollers 11 and wound out from the other end of the lower one of the cutting main rollers 11.

The tension mechanism specifically comprises a tension wheel 21, a tension motor and a tension arm, wherein the tension arm is connected with an output shaft of the tension motor, and the tension motor is used for driving the tension arm to swing. The tension pulley 21 is rotatably provided to the tension arm, and the tension pulley 21 guides the cutting line during rotation, and the tension pulley 21 is used for adjusting the tension of the cutting line during swinging together with the tension arm.

The present embodiment also provides another implementation of the tension mechanism: the tension mechanism is a linear tension mechanism, and specifically comprises: a tension wheel and a tension wheel driving mechanism for driving the tension wheel to move in a plane perpendicular to the cutting main roller 11, close to or far from the cutting mechanism to adjust the tension of the cutting line.

One embodiment is: as shown in fig. 2, the tension pulley 21 moves in the vertical direction (Y direction in fig. 2) toward or away from the cutter main roller 11. Specifically, the tension pulley 21 is higher than the cutting main roller 11, and the cutting line passes around the upper half of the tension pulley 21. When the tension of the cutting line is small, the tension wheel 21 is driven to move upwards, so that the cutting line is tightened to increase the tension; when the string tension is high, the tension pulley 21 is driven downward, causing the string to loosen slightly and reduce the tension.

Another embodiment: as shown in fig. 3, the tension pulley 21 moves in the horizontal direction, approaching or moving away from the cutter main roller 11. When the tension of the cutting line is small, the tension wheel 21 is driven to move rightwards, so that the cutting line is tightened to increase the tension; when the string tension is high, the tension pulley 21 is driven to move to the left, causing the string to loosen a little bit to reduce the tension.

The calculation principle of the linear tension mechanism is as follows:

force at tension wheel on linear tension mechanismEquilibrium equation

Wherein f=f ₁ ＝F ₂ 。

Tension of linear tension mechanism

Speed difference v of linear tension mechanism _line ＝v ₁ -v ₂ 。

Acceleration in a linear tension mechanism

The linear motor provides constant thrust output and influences factors of tension fluctuation in the linear tension mechanism

Is the difference between the mass of the motion mechanism and the speed (or linear acceleration) of the two sides of the tension wheel.

Compared with a tension mechanism adopting a swing arm structure, the linear displacement error generated by the swing angle does not exist in the linear motion of the linear tension mechanism. Assuming that the cutting lines on the two sides of the tension wheel are equal in length and the two ends are fixed, the displacement of the cutting lines on the two sides is affected equally by the movement displacement of the linear tension mechanism when the tension is adjusted, namely delta l ₁ ＝Δl ₂ 。

Compared with a tension mechanism adopting a swing arm structure, the linear motion of the linear tension mechanism has no influence of a swing angle.

Compared with a tension mechanism adopting a swing arm structure, when the speed difference of the linear tension mechanism on two sides of the tension wheel is constant, the main influencing factor index of the tension fluctuation is that

The error is smaller.

The parameters in the above formulas are as follows:

F、F ₁ and F ₂ -cutting line tension, unit N;

F _T -linear motor thrust, unit N;

m ₁ -mass of linear motor, unit kg;

v ₁ ,v ₂ -linear speed of the cutting line on both sides of the tension wheel, in m/min;

F _f the friction force of the linear motor is very small and can be ignored, and the unit is N;

v _line -the movement speed of the linear motor in m/min;

on the basis of the above technical solution, an electric control area may be formed at the bottom of the cutting frame 6, and at least one of the electric control device, the liquid supply cylinder in the cooling system, and the hydraulic driving device may be disposed in the electric control area. If the electric control device is arranged in the electric control area at the bottom, the problem that the electric control device is arranged in the cutting area in the traditional scheme can cause larger interference to the rotation operation of the cutting main roller can be solved, the electromechanical separation is realized, the water and electric safety is improved, the electric control device can better isolate dust generated by cutting, and the service life of the electric control device is prolonged.

If the liquid supply cylinder or the hydraulic driving device is arranged in the electric control area at the bottom, the distance between the liquid supply cylinder or the hydraulic driving device and the cutting mechanism 2 can be shortened, the length of the liquid supply pipeline and the length of the hydraulic pipeline can be shortened, on one hand, the manufacturing and maintenance cost can be reduced, on the other hand, the control hysteresis rate can be reduced, the control accuracy can be improved, the cutting quality can be improved, the liquid supply path can be shortened, and the leakage and the cooling heat loss can be reduced.

According to the scheme, the bottom space of the cutting frame 6 is utilized, an electric control device, a liquid supply cylinder, a hydraulic driving device and the like can be arranged, the space utilization rate is improved, the volume of the slicer is further reduced, and the slicing machine is convenient to hoist and transport.

After the improvement of the scheme, the whole volume of the slicer is reduced, the weight is reduced, a hub can be additionally arranged at the bottom of the cutting frame 6, and the position of the cutting line can be moved through the hub. The whole volume of the slicer is reduced, the occupied area is small after the weight is lightened, more slicers can be accommodated in unit space, and the production efficiency is improved.

Fig. 4, 5 and 6 show that two tension mechanisms are arranged on the same side of the cutting mechanism 2 and are respectively positioned on both sides of the two take-up and pay-off mechanisms 3. Taking the scheme that the two take-up and pay-off mechanisms 3 are horizontally arranged as an example, the two tension mechanisms are respectively positioned at the left side and the right side of the two take-up and pay-off mechanisms 3 and correspond to the left and the right take-up and pay-off mechanisms 3.

The right side tension mechanism and right side wall are removed in fig. 5 to facilitate the display of the position of the tension pulley 21. A left side wall is provided on the cutting frame 6, and a tension mechanism is provided on the left side wall. The cutting line is guided to the left end of the cutting mechanism 1 through the tension mechanism after being wound out from the left winding and unwinding mechanism 3, or the cutting line wound out from the left end of the cutting mechanism 1 is guided to the left winding and unwinding mechanism 3 through the tension mechanism for storage.

The left side tension mechanism and left side wall are removed in fig. 6. The right side wall is arranged on the cutting frame, and the tension mechanism is arranged on the right side wall. The cutting line is guided to the right end of the cutting mechanism 1 through the tension mechanism after being wound out from the right-side winding and unwinding mechanism 3, or the cutting line wound out from the right end of the cutting mechanism 1 is guided to the right-side winding and unwinding mechanism 3 through the tension mechanism for storage.

The cutting line reciprocates between the cutting mechanism and the two coiling and uncoiling mechanisms to cut the silicon rod. Further, the wire saw unit further comprises a wire arranging mechanism, and the wire arranging mechanism and the wire winding and unwinding mechanism are arranged on the same side of the cutting mechanism. The winding mechanism comprises a winding wheel capable of reciprocating along the axial direction of the winding roller and is used for uniformly storing the cutting line in the winding roller or uniformly releasing the cutting line from the winding roller.

Another embodiment: the take-up and pay-off mechanism 3 further includes: and the winding and unwinding line moving driver is used for driving the winding and unwinding line roller to move axially and reciprocally so as to uniformly store the cutting line wound by the cutting mechanism in the winding and unwinding line roller or uniformly release the cutting line by the winding and unwinding line roller and wind the cutting mechanism in the circumferential rotation and axial reciprocating movement process of the winding and unwinding line roller. By adopting the scheme, the winding and unwinding mechanism 3 has the function of arranging wires, and the cutting wires can be uniformly wound on the winding and unwinding roller 31. The wire arranging mechanism in the traditional scheme is not adopted any more, and the wire wheel through which the cutting wire passes is further reduced, so that the additional tension of the cutting wire is reduced. As shown in fig. 5 and 6, the bottom of the pay-off and take-up mechanism 3 is provided with a sliding rail, and the pay-off and take-up mechanism 3 can slide horizontally along the sliding rail, namely: and moves along the axial direction of the winding and unwinding line roller.

In addition, two tension wheels 21 are arranged one above the other in fig. 1, which is only a schematic view. In practice, the two tension wheels 21 are not necessarily arranged up and down, but may be arranged at the same height, respectively corresponding to the two ends of the cutting main roller. The winding and unwinding rollers are not necessarily arranged up and down, and can be at the same height.

The embodiment also provides a wire cutting machine, including: the wire saw unit is arranged on the cutting frame.

The middle part of cutting frame is formed with the cutting space, and the side in cutting space is equipped with the opening. The cutting mechanism is arranged in the cutting space, and the winding and unwinding mechanism is positioned at the outer side of the cutting space and at one side of the cutting frame; the cutting line passes through the opening and is wound between the winding and unwinding roller and the cutting main roller. The tension mechanism and the take-up and pay-off mechanism are arranged on the same side of the cutting frame.

The wire cutting machine may be a slicer. The wire cutting machine provided in the present embodiment has the same technical effects as the wire saw unit described above.

In the description of the present application, it should be understood that the terms "center," "longitudinal," "transverse," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate an orientation or positional relationship based on that shown in the drawings, merely for convenience of description and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, the meaning of "plurality" is at least two, such as two, three, etc., unless explicitly defined otherwise.

In this application, unless specifically stated and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; may be mechanically connected, may be electrically connected or may communicate with each other; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art as the case may be.

While 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. It is therefore intended that the following claims be interpreted as including the preferred embodiments and all such alterations and modifications as fall within the scope of the application.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present application without departing from the spirit or scope of the application. Thus, if such modifications and variations of the present application fall within the scope of the claims and the equivalents thereof, the present application is intended to cover such modifications and variations.

Claims (11)

1. A wire saw unit, comprising:

a cutting mechanism; the cutting mechanism comprises at least two cutting main rollers used for winding a cutting line;

the winding and unwinding mechanism is arranged on one side of the cutting mechanism; the winding and unwinding mechanism comprises a winding and unwinding roller for storing or releasing the cutting line and a winding and unwinding rotation driver for driving the winding and unwinding roller to rotate circumferentially; the cutting line moves back and forth between the winding and unwinding line roller and the cutting main roller to realize cutting;

the tension mechanism and the winding and unwinding mechanism are arranged on the same side of the cutting mechanism; the tension mechanism is provided with a tension wheel; the cutting line between the cutting mechanism and the winding and unwinding mechanism passes through the tension pulley, so that the cutting line released by the winding and unwinding roller is guided to the cutting main roller through the tension pulley, or the cutting line wound from the cutting main roller is guided to the winding and unwinding roller through the tension pulley for storage.

2. The wire saw unit of claim 1, wherein the wire take-up and payout mechanism further comprises: and the winding and unwinding line moving driver is used for driving the winding and unwinding line roller to move axially and reciprocally so as to uniformly wind and arrange the cutting line on the winding and unwinding line roller or uniformly release the cutting line in the circumferential rotation and axial reciprocating movement process of the winding and unwinding line roller.

3. The wire saw unit according to claim 1, wherein the tension pulley is movable in a plane perpendicular to the cutting main roller axis, closer to or further from the cutting mechanism to adjust the tension of the cutting wire.

4. The wire saw unit according to claim 3, wherein the axis of the cutting main roller extends in a horizontal direction; the tension wheel moves vertically closer to or farther from the cutting mechanism.

5. The wire saw unit according to claim 4, wherein the tension pulley is higher than the cutting mechanism and higher than the take-up and pay-off roller such that the cutting wire passes around from an upper half of the tension pulley.

6. The wire saw unit of claim 5, wherein the cutting mechanism comprises: the two main cutting rollers are sequentially arranged along the horizontal direction; the cutting line is wound in or out from the bottom of the cutting main roller.

7. The wire saw unit according to claim 1, wherein the axis of the take-up and pay-off roller is parallel to the axis of the cutting main roller.

8. The wire saw unit according to claim 1, further comprising:

the winding and unwinding mechanism and the winding and unwinding mechanism are arranged on the same side of the cutting mechanism; the winding displacement mechanism comprises a winding displacement wheel capable of moving back and forth along the axial direction of the winding and unwinding roller and is used for enabling the cutting line to be uniformly stored in the winding and unwinding roller or enabling the cutting line to be uniformly released from the winding and unwinding roller.

9. A wire cutting machine, comprising: a cutting frame and the wiresaw unit of any of claims 1-8, the wiresaw unit being disposed on the cutting frame.

10. The wire cutting machine according to claim 9, wherein a cutting space is formed in the middle of the cutting frame, and an opening is provided at a side of the cutting space; the cutting mechanism is arranged in the cutting space, and the winding and unwinding mechanism is positioned at the outer side of the cutting space; the cutting line passes through the opening and is wound between the winding and unwinding roller and the cutting main roller.

11. The wire cutting machine of claim 10, wherein the wire cutting machine is a microtome.

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