CN115354487B - Cloth tearing device - Google Patents

Abstract

The invention provides a cloth tearing device, wherein cloth to be torn is arranged between a first conveying roller and a second conveying roller and between two third conveying rollers. The first driving motor drives the first conveying roller to rotate, the second driving motor drives the second conveying roller to rotate, and each second driving motor drives a second conveying roller to rotate so as to convey the cloth to be torn off. When the short line of the cloth to be torn is positioned between the conveying mechanism and the two tearing mechanisms, the first driving air cylinder drives the first conveying roller through the first driving plate and the two first connecting plates to convey and abut the cloth to be torn on the second conveying roller to extrude and fix the cloth to be torn. Simultaneously, each second driving motor drives a second conveying roller to rotate so as to tear the cloth to be torn. The head end of the torn cloth enters between the two second conveying rollers along the first guide inclined plate and the second guide inclined plate so as to carry out the next tearing work. The cloth tearing device is high in efficiency of tearing the cloth to be torn.

Description

Cloth tearing device

Technical Field

The invention relates to the field of cloth cutting, in particular to a cloth tearing device.

Background

In the process of cutting cloth, cutting equipment is arranged on the market, in order to enable cloth to run continuously and ensure high-efficiency running of cutting work, point-break cutting is carried out on a picture to be cut, a plurality of adhesion points are arranged between two cut cloth sections, and the adhesion points between the two cloth sections are torn off manually in the later period to form Zhang Chengpin cloth.

However, the efficiency of manually tearing off the adhesion point between two cloth sections is low, the labor intensity is high, the error rate is high, and the cloth is easy to damage.

Disclosure of Invention

Based on the above, it is necessary to provide a cloth tearing device aiming at the technical problems of low efficiency, high labor intensity, high error rate and easy damage of cloth caused by manual tearing of an adhesion point between two cloth sections.

A cloth tearing apparatus, the cloth tearing apparatus comprising: the device comprises a storage box, a connecting frame, a conveying mechanism, a guiding mechanism, two tearing mechanisms and a control mechanism; the connecting frame is connected with the storage box, and the conveying mechanism, the guiding mechanism and the two tearing mechanisms are sequentially arranged on the connecting frame from top to bottom; the two tearing mechanisms are symmetrically arranged on the connecting frame;

the conveying mechanism comprises an extrusion assembly and a receiving assembly; the extrusion assembly comprises a first driving cylinder, a first driving plate, two first connecting plates, a first driving motor and a first conveying roller; the first driving cylinder is connected with the connecting frame, the first driving cylinder is in driving connection with the first driving plate, the first driving motor is connected with the first driving plate through a first connecting plate, the first driving motor is in driving connection with the first conveying roller, and one end of the first conveying roller, which is far away from the first driving motor, is connected with the first driving plate through another first connecting plate; the bearing assembly comprises a second driving motor, a second conveying roller and two second connecting plates; the second driving motor is connected with the connecting frame through a second connecting plate, the second driving motor is in driving connection with the second conveying roller, and one end of the second conveying roller, which is far away from the second driving motor, is connected with the connecting frame through another second connecting plate; the first conveying roller is arranged close to the second conveying roller, and a first conveying space is formed between the first conveying roller and the second conveying roller;

the guide mechanism comprises a first guide inclined plate, a second guide inclined plate and a plurality of connecting rods; the first guide inclined plate is connected with the connecting frame through at least one connecting rod, the second guide inclined plate is connected with the connecting frame through at least one connecting rod, and the first guide inclined plate and the second guide inclined plate form a V-shaped flow guiding assembly; the wide opening end of the V-shaped flow guide assembly is arranged close to the first conveying space;

the tearing mechanism comprises a third driving motor, a third conveying roller and two third connecting plates; the third driving motor is connected with the connecting frame through a third connecting plate, the third driving motor is in driving connection with the third conveying roller, and one end of the third conveying roller, which is far away from the third driving motor, is connected with the connecting frame through another third connecting plate; a second conveying space is formed between the two third conveying rollers; the narrow opening end of the V-shaped flow guide assembly is arranged close to the second conveying space;

the first driving cylinder, the first driving motor, the second driving motor and the two third driving motors are all electrically connected with the control mechanism.

In one embodiment, the extrusion assembly further comprises four first sliding columns, wherein the four first sliding columns are connected with the connecting frame and are arranged around the first driving cylinder; four first sliding holes are formed in the first driving plate and are matched with the first sliding columns, and each first sliding column is inserted into one first sliding hole and is in sliding connection with the first driving plate.

In one embodiment, the first sliding column is a cylinder.

In one embodiment, the fabric tearing device further comprises a point-breaking cutting mechanism, wherein the point-breaking cutting mechanism is arranged on the connecting frame and is located above the conveying mechanism.

In one embodiment, the point-break cutting mechanism comprises a second driving cylinder, a second driving plate, a point-break cutting knife and a cutting plate; the second driving air cylinder is connected with the connecting frame, the second driving air cylinder is in driving connection with the point-break cutting knife through the second driving plate, the cutting plate is connected with the connecting frame, the second driving air cylinder drives the point-break cutting knife to move close to or far away from the cutting plate through the second driving plate, and a plurality of point-break cuts are uniformly formed in the cutting edge of the point-break cutting knife; the second driving cylinder is electrically connected with the control mechanism.

In one embodiment, the point breaking and cutting mechanism further comprises four second sliding columns, and the four second sliding columns are connected with the connecting frame and are arranged around the second driving cylinder; four second sliding holes are formed in the second driving plate, the second sliding holes are matched with the second sliding columns, and each second sliding column is inserted into one second sliding hole and is in sliding connection with the second driving plate.

In one embodiment, the fabric tearing device further comprises a storage mechanism, and the storage mechanism is arranged in the storage box and used for storing and arranging the torn fabric sections.

In one embodiment, the accommodating mechanism comprises an accommodating assembly, two correcting fans and an accommodating table, wherein the two correcting fans are arranged on two sides of the accommodating assembly up and down, and the accommodating table is arranged at the bottom of the accommodating box; the storage assembly comprises a third driving cylinder, a third driving plate, a fourth driving motor, a fourth connecting plate, a rectangular storage box, an optical position sensor, a fourth driving cylinder and an extrusion plate; the third driving air cylinder is connected with the inner wall of the storage box, the third driving air cylinder is in driving connection with the third driving plate, the fourth driving motor is connected with the third driving plate through the fourth connecting plate, and the fourth driving motor is in driving connection with the rectangular storage box; an opening is formed in one end, far away from the third driving plate, of the rectangular storage box; the fourth driving cylinder is connected with the outer wall of the rectangular storage box, the fourth driving cylinder is in driving connection with the extrusion plate, the extrusion plate is accommodated in the rectangular storage box, and the fourth driving cylinder is in driving connection with the extrusion plate; the extruding plate is provided with a signal through hole; the transmitting end of the optical position sensor is connected with one side wall of the rectangular storage box, the receiving end of the optical position sensor is connected with the other side wall of the rectangular storage box, and an electric signal transmitted by the transmitting end of the optical position sensor is received by the receiving end of the optical position sensor after passing through the signal through hole; the correction fan, the third driving air cylinder, the third driving motor, the light position sensor and the fourth driving air cylinder are all electrically connected with the control mechanism.

In one embodiment, the storage assembly further comprises four third sliding columns, and the four third sliding columns are connected with the inner wall of the storage box and are arranged around the third driving cylinder; four third sliding holes are formed in the third driving plate and are matched with the third sliding columns, and each third sliding column is inserted into one third sliding hole and is in sliding connection with the second driving plate.

In one embodiment, the third sliding column is a cylinder.

In the working process, the cloth tearing device is characterized in that the cloth to be torn is arranged between the first conveying roller and the second conveying roller and between the two third conveying rollers. The first driving motor drives the first conveying roller to rotate, the second driving motor drives the second conveying roller to rotate, and each second driving motor drives a second conveying roller to rotate so as to convey the cloth to be torn off. When the short line of the cloth to be torn is positioned between the conveying mechanism and the two tearing mechanisms, the first driving air cylinder drives the first conveying roller through the first driving plate and the two first connecting plates to convey and abut the cloth to be torn on the second conveying roller to extrude and fix the cloth to be torn. Simultaneously, each second driving motor drives a second conveying roller to rotate so as to tear the cloth to be torn. The head end of the torn cloth enters between the two second conveying rollers along the first guide inclined plate and the second guide inclined plate so as to carry out the next tearing work. The cloth tearing device is high in efficiency of tearing cloth to be torn, low in labor cost and low in error rate.

Drawings

FIG. 1 is a schematic view of a fabric tearing apparatus according to an embodiment;

FIG. 2 is a schematic view of a part of a fabric tearing apparatus according to an embodiment;

FIG. 3 is a schematic view of a housing assembly according to one embodiment;

FIG. 4 is a schematic view of a fabric tearing apparatus according to an embodiment;

FIG. 5 is a schematic diagram of a mechanism for breaking and cutting in one embodiment.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the invention, whereby the invention is not limited to the specific embodiments disclosed below. In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

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 at least one such feature. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present invention, unless explicitly specified 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; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present invention, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Referring to fig. 1 to 5, the present invention provides a fabric tearing apparatus 10, wherein the fabric tearing apparatus 10 includes: the storage box 100, the connection frame 200, the conveying mechanism 300, the guide mechanism 400, the two tearing mechanisms 500, and a control mechanism (not shown). The connection frame 200 is connected to the storage box 100, and the conveying mechanism 300, the guiding mechanism 400, and the two tearing mechanisms 500 are sequentially provided on the connection frame 200 from top to bottom. The two tearing mechanisms 500 are symmetrically disposed on the connection frame 200.

The transfer mechanism 300 includes a compression assembly 310 and a receiving assembly 320. The pressing assembly 310 includes a first driving cylinder 311, a first driving plate 312, two first connection plates 313, a first driving motor 314, and a first transfer roller 315. The first driving cylinder 311 is connected with the connecting frame 200, the first driving cylinder 311 is in driving connection with the first driving plate 312, the first driving motor 314 is connected with the first driving plate 312 through a first connecting plate 313, the first driving motor 314 is in driving connection with the first conveying roller 315, and one end, far away from the first driving motor 314, of the first conveying roller 315 is connected with the first driving plate 312 through another first connecting plate 313. The receiving assembly 320 includes a second driving motor (not shown), a second transfer roller 322, and two second connection plates 323. The second driving motor is connected with the connecting frame 200 through a second connecting plate 323, the second driving motor is in driving connection with the second conveying roller 322, and one end, far away from the second driving motor, of the second conveying roller 322 is connected with the connecting frame 200 through another second connecting plate 323. The first transfer roller 315 is disposed near the second transfer roller 322 with a first transfer space 301 formed between the first transfer roller 315 and the second transfer roller 322.

The guide mechanism 400 includes a first guide swash plate 410, a second guide swash plate 420, and a plurality of connecting rods 430. The first guide inclined plate 410 is connected with the connection frame 200 through at least one connection rod 430, the second guide inclined plate 420 is connected with the connection frame 200 through at least one connection rod 430, and the first guide inclined plate 410 and the second guide inclined plate 420 form a V-shaped flow guiding assembly. The wide mouth end of the V-shaped baffle assembly is disposed adjacent the first transfer space 301.

The tear-off mechanism 500 includes a third drive motor 510, a third conveying roller 520, and two third connecting plates 530. The third driving motor 510 is connected to the connection frame 200 through a third connection plate 530, the third driving motor 510 is in driving connection with the third conveying roller 520, and one end of the third conveying roller 520, which is far away from the third driving motor 510, is connected to the connection frame 200 through another third connection plate 530. A second conveying space 501 is formed between the two third conveying rollers 520. The narrow mouth end of the V-shaped baffle assembly is positioned adjacent to the second transfer space 501.

The first driving cylinder 311, the first driving motor 314, the second driving motor, and the two third driving motors 510 are all electrically connected to a control mechanism, which in this embodiment is a lower computer. Specifically, the control mechanism is a PLC, and in other embodiments, the control mechanism is a single chip microcomputer. In other embodiments, the control mechanism includes an upper computer and a lower computer, and the upper computer is electrically connected to the lower computer. The control mechanism may control the first driving cylinder 311, the first driving motor 314, the second driving motor, and the two third driving motors 510 to coordinate to increase the cloth tearing apparatus 10.

In operation of the cloth tearing apparatus 10, the cloth to be torn is between the first conveying roller 315 and the second conveying roller 322 and between the two third conveying rollers 520. The first driving motor 314 drives the first conveying roller 315 to rotate, the second driving motor drives the second conveying roller 322 to rotate, and each second driving motor drives one second conveying roller 322 to rotate so as to convey the cloth to be torn off. When the short line of the cloth to be torn is located between the conveying mechanism 300 and the two tearing mechanisms 500, the first driving cylinder 311 drives the first conveying roller 315 to convey and abut the cloth to be torn on the second conveying roller 322 through the first driving plate 312 and the two first connecting plates 313, so as to squeeze and fix the cloth to be torn. At the same time, each second driving motor drives a second conveying roller 322 to rotate so as to tear the cloth to be torn. The head end of the torn cloth enters between the two second conveying rollers 322 along the first guiding inclined plate 410 and the second guiding inclined plate 420 for the next tearing operation. The cloth tearing device 10 has high efficiency, low labor cost and low error rate when tearing the cloth to be torn.

In order to increase the working stability of the pressing assembly 310, in one embodiment, the pressing assembly 310 further includes four first sliding columns 316, and the four first sliding columns 316 are connected to the connecting frame 200 and disposed around the first driving cylinder 311. Four first sliding holes 302 are formed in the first driving plate 312, the first sliding holes 302 are matched with the first sliding columns 316, and each first sliding column 316 is inserted into one first sliding hole 302 and is slidably connected with the first driving plate 312. In this embodiment, the first sliding column 316 is a cylinder. The four first sliding columns 316 define the running track of the first driving plate 312, so as to avoid the first driving plate 312 from shaking during the moving process. Thus, the operational stability of the pressing assembly 310 is increased.

To cut a point break on the fabric to be cut, in one embodiment, the fabric tearing apparatus 10 further includes a point break cutting mechanism 600, the point break cutting mechanism 600 being disposed on the connection frame 200 above the conveying mechanism 300. In the present embodiment, the spot-cutting mechanism 600 includes a second driving cylinder 610, a second driving plate 620, a spot-cutting blade 630, and a cutting plate 640. The second driving cylinder 610 is connected with the connecting frame 200, the second driving cylinder 610 is in driving connection with the point breaking cutter 630 through the second driving plate 620, the cutting plate 640 is connected with the connecting frame 200, the second driving cylinder 610 drives the point breaking cutter 630 to move close to or away from the cutting plate 640 through the second driving plate 620, and a plurality of point breaking openings 601 are uniformly formed in the cutting edge of the point breaking cutter 630. The second drive cylinder 610 is electrically connected to the control mechanism. In operation, the second driving cylinder 610 drives the point-breaking cutter 630 through the second driving plate 620 to abut the cloth to be cut on the cutting plate 640 to cut out the point-breaking line of the cloth to be cut.

In order to increase the working stability of the spot-breaking cutting mechanism 600, in one embodiment, the spot-breaking cutting mechanism 600 further includes four second sliding posts 660, and the four second sliding posts 660 are connected to the connecting frame 200 and disposed around the second driving cylinder 610. Four second sliding holes 601 are formed in the second driving plate 620, the second sliding holes 601 are matched with the second sliding columns 660, and each second sliding column 660 is inserted into one second sliding hole 601 and is slidably connected with the second driving plate 620. The four second sliding posts 660 define the moving track of the second driving plate 620, and prevent the second driving plate 620 from shaking during the moving process. Thus, the operation stability of the dot-off cutting mechanism 600 is increased.

In order to store the torn piece of cloth, in one embodiment, the cloth tearing apparatus 10 further includes a storage mechanism 700, where the storage mechanism 700 is disposed in the storage box 100 for storing and sorting the torn piece of cloth. In this embodiment, the storage mechanism 700 includes a storage module 710, two correction fans 720 and a storage table 730, the two correction fans 720 are disposed on two sides of the storage module 710, and the storage table 730 is disposed at the bottom of the storage box 100. The receiving assembly 710 includes a third driving cylinder 711, a third driving plate 712, a fourth driving motor 713, a fourth connection plate 714, a rectangular receiving box 715, an optical position sensor 716, a fourth driving cylinder 717, and a pressing plate 718. The third driving cylinder 711 is connected to the inner wall of the storage box 100, the third driving cylinder 711 is connected to the third driving plate 712 by driving, the fourth driving motor 713 is connected to the third driving plate 712 by the fourth connecting plate 714, and the fourth driving motor 713 is connected to the rectangular storage box 715 by driving. The rectangular receiving box 715 has an opening at an end thereof remote from the third driving plate 712. The fourth driving cylinder 717 is connected to the outer wall of the rectangular receiving case 715, the fourth driving cylinder 717 is in driving connection with the pressing plate 718, the pressing plate 718 is received in the rectangular receiving case 715, and the fourth driving cylinder 717 is in driving connection with the pressing plate 718. The extrusion plate 718 is provided with a signal through hole 701. The transmitting end of the optical position sensor 716 is connected with one side wall of the rectangular storage box 715, the receiving end of the optical position sensor 716 is connected with the other side wall of the rectangular storage box 715, and an electric signal transmitted by the transmitting end of the optical position sensor 716 is received by the receiving end of the optical position sensor 716 after passing through the signal through hole 701. The correction fan 720, the third driving cylinder 711, the third driving motor 510, the light position sensor 716, and the fourth driving cylinder 717 are electrically connected to a control mechanism. In the working process of the storage mechanism 700, the torn cloth segment enters the rectangular storage box 715 from the opening, so that the electric signal emitted by the emitting end of the optical position sensor 716 cannot be received by the receiving end of the optical position sensor 716, and at this time, the control mechanism controls the fourth driving cylinder 717 to drive the extrusion plate 718 to extrude and fix the torn cloth segment on the inner wall of the rectangular storage box 715. Subsequently, the control mechanism controls the fourth driving motor 713 to drive the rectangular receiving box 715 to rotate 90 degrees. At this time, the control mechanism controls the two correction fans 720 to blow out air flow to shape the cloth section, so as to avoid bending and folding of the cloth section. After the cloth section is in shape, the two correction fans stop working, the fourth driving cylinder 717 drives the extrusion plate 718 to be far away from the cloth section, and meanwhile, the third driving cylinder 711 drives the rectangular storage box 715 to move so as to separate from the cloth section through the third driving plate 712, so that the cloth section falls into the storage table 730 neatly under the action of gravity. In this way, the storage mechanism 700 can store the torn cloth piece.

To increase the operational stability of the receiving assembly 710. In one embodiment, the storage assembly 710 further includes four third sliding columns, which are connected to the inner wall of the storage box 100 and are disposed around the third driving cylinder 711. The third driving plate 712 is provided with four third sliding holes 702, and the third sliding holes 702 are adapted to third sliding columns, and each third sliding column is inserted into one third sliding hole 702 and slidably connected to the second driving plate 620. In this embodiment, the third sliding column is a cylinder. The four third sliding columns define the movement track of the third driving plate 712, so that the third driving plate 712 is prevented from shaking during the movement process. Thus, the working stability of the receiving assembly 710 is increased.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. A cloth tearing apparatus, comprising: the device comprises a storage box, a connecting frame, a conveying mechanism, a guiding mechanism, two tearing mechanisms and a control mechanism; the connecting frame is connected with the storage box, and the conveying mechanism, the guiding mechanism and the two tearing mechanisms are sequentially arranged on the connecting frame from top to bottom; the two tearing mechanisms are symmetrically arranged on the connecting frame;

the conveying mechanism comprises an extrusion assembly and a receiving assembly; the extrusion assembly comprises a first driving cylinder, a first driving plate, two first connecting plates, a first driving motor and a first conveying roller; the first driving cylinder is connected with the connecting frame, the first driving cylinder is in driving connection with the first driving plate, the first driving motor is connected with the first driving plate through a first connecting plate, the first driving motor is in driving connection with the first conveying roller, and one end of the first conveying roller, which is far away from the first driving motor, is connected with the first driving plate through another first connecting plate; the bearing assembly comprises a second driving motor, a second conveying roller and two second connecting plates; the second driving motor is connected with the connecting frame through a second connecting plate, the second driving motor is in driving connection with the second conveying roller, and one end of the second conveying roller, which is far away from the second driving motor, is connected with the connecting frame through another second connecting plate; the first conveying roller is arranged close to the second conveying roller, and a first conveying space is formed between the first conveying roller and the second conveying roller;

the guide mechanism comprises a first guide inclined plate, a second guide inclined plate and a plurality of connecting rods; the first guide inclined plate is connected with the connecting frame through at least one connecting rod, the second guide inclined plate is connected with the connecting frame through at least one connecting rod, and the first guide inclined plate and the second guide inclined plate form a V-shaped flow guiding assembly; the wide opening end of the V-shaped flow guide assembly is arranged close to the first conveying space;

the tearing mechanism comprises a third driving motor, a third conveying roller and two third connecting plates; the third driving motor is connected with the connecting frame through a third connecting plate, the third driving motor is in driving connection with the third conveying roller, and one end of the third conveying roller, which is far away from the third driving motor, is connected with the connecting frame through another third connecting plate; a second conveying space is formed between the two third conveying rollers; the narrow opening end of the V-shaped flow guide assembly is arranged close to the second conveying space;

the first driving cylinder, the first driving motor, the second driving motor and the two third driving motors are all electrically connected with the control mechanism.

2. The cloth tearing apparatus of claim 1, wherein the pressing assembly further comprises four first sliding columns, each of the four first sliding columns being connected to the connecting frame and disposed around the first driving cylinder; four first sliding holes are formed in the first driving plate and are matched with the first sliding columns, and each first sliding column is inserted into one first sliding hole and is in sliding connection with the first driving plate.

3. The cloth tear device of claim 2, wherein the first sliding post is a cylinder.

4. The cloth tearing apparatus of claim 1, further comprising a point-break cutting mechanism disposed on the connecting frame above the transfer mechanism.

5. The cloth tearing apparatus of claim 4, wherein the point-break cutting mechanism comprises a second drive cylinder, a second drive plate, a point-break cutting knife, and a cutting plate; the second driving air cylinder is connected with the connecting frame, the second driving air cylinder is in driving connection with the point-break cutting knife through the second driving plate, the cutting plate is connected with the connecting frame, the second driving air cylinder drives the point-break cutting knife to move close to or far away from the cutting plate through the second driving plate, and a plurality of point-break cuts are uniformly formed in the cutting edge of the point-break cutting knife; the second driving cylinder is electrically connected with the control mechanism.

6. The cloth tearing apparatus of claim 5, wherein the point-breaking cutting mechanism further comprises four second sliding columns, each of the four second sliding columns being connected to the connecting frame and disposed around the second driving cylinder; four second sliding holes are formed in the second driving plate, the second sliding holes are matched with the second sliding columns, and each second sliding column is inserted into one second sliding hole and is in sliding connection with the second driving plate.

7. The cloth tearing apparatus of claim 6, further comprising a storage mechanism disposed in the storage box for storing and organizing the torn cloth segments.

8. The cloth tearing apparatus of claim 7, wherein the storage mechanism comprises a storage assembly, two straightening fans and a storage table, the two straightening fans are arranged on two sides of the storage assembly up and down, and the storage table is arranged at the bottom of the storage box; the storage assembly comprises a third driving cylinder, a third driving plate, a fourth driving motor, a fourth connecting plate, a rectangular storage box, an optical position sensor, a fourth driving cylinder and an extrusion plate; the third driving air cylinder is connected with the inner wall of the storage box, the third driving air cylinder is in driving connection with the third driving plate, the fourth driving motor is connected with the third driving plate through the fourth connecting plate, and the fourth driving motor is in driving connection with the rectangular storage box; an opening is formed in one end, far away from the third driving plate, of the rectangular storage box; the fourth driving cylinder is connected with the outer wall of the rectangular storage box, the fourth driving cylinder is in driving connection with the extrusion plate, the extrusion plate is accommodated in the rectangular storage box, and the fourth driving cylinder is in driving connection with the extrusion plate; the extruding plate is provided with a signal through hole; the transmitting end of the optical position sensor is connected with one side wall of the rectangular storage box, the receiving end of the optical position sensor is connected with the other side wall of the rectangular storage box, and an electric signal transmitted by the transmitting end of the optical position sensor is received by the receiving end of the optical position sensor after passing through the signal through hole; the correction fan, the third driving air cylinder, the third driving motor, the light position sensor and the fourth driving air cylinder are all electrically connected with the control mechanism.

9. The cloth tearing apparatus of claim 8, wherein the receiving assembly further comprises four third sliding columns, each of the four third sliding columns being connected to an inner wall of the receiving box and disposed around the third driving cylinder; four third sliding holes are formed in the third driving plate and are matched with the third sliding columns, and each third sliding column is inserted into one third sliding hole and is in sliding connection with the second driving plate.

10. The cloth tear device of claim 9, wherein the third sliding post is a cylinder.