CN117226896B - Surface cutting layering device of belt for transmission equipment - Google Patents

Abstract

The application relates to the technical field of belt layering, in particular to a surface cutting layering device of a belt for transmission equipment, which comprises a frame, a first roller, a second roller and a blade, wherein a first mounting plate is fixedly connected to the frame, and the first roller is rotationally connected to the first mounting plate; the first mounting plate is provided with a driving mechanism which is connected with the second roller and can drive the second roller to move in a direction away from the first roller; the blade is fixedly connected to the first mounting plate and is inserted between the first roller and the second roller. The application has the effect of increasing the applicability of the cutting layering device.

Description

Surface cutting layering device of belt for transmission equipment

Technical Field

The application relates to the technical field of belt layering, in particular to a surface cutting layering device for a belt for transmission equipment.

Background

In the belt course of working, can need to divide into two-layer with a belt, can use the cutting layering device to carry out the layering to the belt this moment to satisfy the processing demand.

At present in belt processing workshop, cutting layering device generally includes clamping assembly, frame and blade, and blade fixed connection is in the frame, and clamping assembly includes the cylinder of mutual symmetry from top to bottom, and the belt is held by two cylinders, when needs cut the layering to the belt, promotes the belt and removes to the direction that is close to the blade to drive two cylinders and rotate, the belt is layered by the blade this moment, thereby divide into two-layer with the belt, with the processing demand that satisfies.

The requirements on the thickness of the layered belt are different for different requirements, but the cutting device can only cut the belt with one thickness, so that the applicability is low.

Disclosure of Invention

The object of the present application is to provide a surface cutting delamination apparatus of a belt for a conveying device, which can increase the applicability of the cutting delamination apparatus.

The application provides a surface cutting layering device of belt for transmission equipment adopts following technical scheme:

the surface cutting layering device for the belt for the transmission equipment comprises a frame, a first roller, a second roller and a blade, wherein a first mounting plate is fixedly connected to the frame, and the first roller is rotatably connected to the first mounting plate;

the first mounting plate is provided with a driving mechanism which is connected with the second roller and can drive the second roller to move in a direction away from the first roller;

the blade is fixedly connected to the first mounting plate and is inserted between the first roller and the second roller.

Through adopting above-mentioned technical scheme, through setting up actuating mechanism to drive second cylinder slides from top to bottom, and then adjusts the clearance between second cylinder and the first cylinder, adjusts the clearance between second cylinder and the blade promptly, thereby adjusts the thickness of belt layering, and then makes the demand that the cutting layering device can adapt to more belt layering, has increased the suitability of cutting layering device.

Optionally, the driving mechanism comprises an arc plate, a sliding plate, a driving block and a bearing assembly, wherein the arc plate is rotationally connected to the first mounting plate, and the rotational connection parts of the arc plate and the arc plate are mutually staggered;

the arc-shaped plate is fixedly connected with a rib, the sliding plate is connected to the first mounting plate in a sliding manner and can be abutted against the rib, and the sliding plate can be driven to move horizontally by the movement of the rib;

the driving block is fixedly connected to the bearing assembly and can be abutted against the sliding plate, and a guide inclined plane is arranged on one surface, close to the sliding plate, of the driving block;

the bearing assembly is used for bearing the second roller.

Through adopting above-mentioned technical scheme, through the rotation of arc to make the bead promote the slide and slide, and then make the slide promote through the direction inclined plane and accept the subassembly and remove, realize the position control to the second cylinder. The sliding plate is pushed to slide through eccentric rotation of the arc plate, so that the path length of the rotating arc plate is larger than that of the sliding plate, namely, the path length of the rotating arc plate is larger than that of the sliding driving block, the path length of the sliding driving block is the variable quantity of the position of the second roller, so that the path of the second roller with larger movement is realized, when the arc plate is rotated, even if the rotating quantity of the arc plate deviates, the deviation quantity of the second roller is reduced on the movement quantity of the second roller, and the accuracy degree of the cutting layering device is increased.

Optionally, the bearing assembly includes a bearing plate and an elastic piece, one end of the elastic piece is abutted with the frame, the other end of the elastic piece is abutted with the bearing plate, and the second roller is rotatably connected with the bearing plate.

Through adopting above-mentioned technical scheme, rotate through the board of accepting and second cylinder and be connected to drive and accept the board motion, can realize driving the second cylinder and slide, and accept the in-process that the board moved down, compress the elastic component, when the board resets is accepted to needs, only need to remove the spacing to accepting the board, accept the board and can reset under the drive of elastic component, its operation process is simple and convenient, need not to additionally promote the operation of accepting the board and reset, makes things convenient for staff's use.

Optionally, the cross section of the bearing plate is arc-shaped and is matched with the second roller.

Through adopting above-mentioned technical scheme, accept the transversal arc of personally submitting of board and with the adaptation of second cylinder to make accept the board with half parcel of second cylinder, and then carry out spacingly to the second cylinder, reduced the possibility that the second cylinder takes place the position offset.

Optionally, the sliding plate is made of a magnetic material, the driving block is an electromagnet, and the driving block can attract the sliding plate.

Through adopting above-mentioned technical scheme, attract the slide through the drive block to the restriction slide slides on the drive block, and then at the in-process of belt pushing down the second cylinder, reduced the possibility that the second cylinder takes place to move down under the pressure of belt, and lead to the relative fixation of drive block and slide, make the arc be difficult for taking place to rotate under external interference.

Optionally, a shielding plate is fixedly connected to the first mounting plate, and the shielding plate is arranged above the first roller.

Through adopting above-mentioned technical scheme, through setting up the shielding plate, at first cylinder pivoted in-process, first cylinder is difficult to touch to staff's health position, thereby has reduced first cylinder winding to staff's clothing and has led to the dead condition of card to produce.

Optionally, fixedly connected with second mounting panel in the frame, the slip is provided with the limiting plate in the frame, be provided with on the second mounting panel and drive the limiting plate is in the gliding slide mechanism of first cylinder axis direction.

Through adopting above-mentioned technical scheme, through setting up slide mechanism, make slide mechanism drive limiting plate slip to make the limiting plate drive the belt slip, make belt partly stagger each other with the blade, thereby control the belt and carry out the layering width.

Optionally, the sliding mechanism includes first gear, second gear, lead screw and rack, first gear rotates to be connected on the second mounting panel, the second gear spiro union is in on the lead screw and connect on the second mounting panel, lead screw one end with second mounting panel spiro union, the lead screw other end with limiting plate fixed connection, rack sliding connection be in the frame and with second gear engagement, first gear rotation can drive the rack slides.

Through adopting above-mentioned technical scheme, drive the rack motion through first gear, make the rack drive second gear and rotate to drive the lead screw and slide along second gear axis direction, realize that the lead screw promotes the limiting plate and remove, and then realize carrying out the control of layered width to the belt.

Optionally, the second mounting panel lateral wall rotates and is connected with the third gear, the third gear with first gear meshing, third gear lateral wall fixedly connected with fourth gear, the fourth gear external diameter is less than the third gear external diameter, the fourth gear with the rack meshing.

Through adopting above-mentioned technical scheme, first gear rotates, drive the third gear and rotate, thereby third gear is the same with first gear rotational speed, fourth gear fixed connection is on the third gear, thereby make fourth gear the same with third gear rotational speed, and fourth gear external diameter is less than the third gear external diameter, and then the route that third gear rotated a week needs fourth gear to rotate many weeks, and fourth gear and rack engagement, thereby realize that third gear rotates many weeks, just can make the rack remove certain distance, first gear rotates many weeks promptly, just can drive the limiting plate and slide certain distance, when first gear rotation volume and the deviation takes place for the expected rotation volume, convert on the limiting plate removes the distance, the deviation volume of limiting plate is less. Thereby increasing the accuracy of the cutting delamination apparatus.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the driving mechanism is arranged to drive the second roller to slide up and down, so that the gap between the second roller and the first roller is adjusted, namely the gap between the second roller and the blade is adjusted, the thickness of belt layering is adjusted, the cutting layering device can adapt to the requirement of more belt layering, and the applicability of the cutting layering device is improved;

2. through the rotation of arc to make the bead promote the slide and slide, and then make the slide promote through the direction inclined plane and accept the subassembly and remove, realize the position control to the second cylinder. The sliding plate is pushed to slide through eccentric rotation of the arc plate, so that the path length of the rotating arc plate is longer than that of the sliding plate, namely the path length of the rotating arc plate is longer than that of the sliding driving block, the path length of the sliding driving block is the variable quantity of the position of the second roller, so that the path of the moving arc plate with larger movement is realized, the path of the second roller with smaller movement is realized, when the arc plate is rotated, even if the rotating quantity of the arc plate deviates, the deviation quantity of the second roller is reduced to the moving quantity of the second roller, and the accuracy degree of the cutting layering device is increased;

3. through setting up slide mechanism, make slide mechanism drive limiting plate slip to make the limiting plate drive the belt slip, make belt partly stagger each other with the blade, thereby control the belt and carry out the width of layering.

Drawings

Fig. 1 is a schematic view showing the overall structure of a surface cutting delamination apparatus for a belt for a conveying apparatus according to an embodiment of the present application.

Fig. 2 is a partial schematic view of an embodiment of the present application for embodying a drive mechanism mounting location.

FIG. 3 is a top partial schematic view of an embodiment of the present application for embodying a slide mechanism mounting location.

In the figure, 1, a base; 2. a frame; 21. a chute; 3. a telescopic cylinder;

4. a first mounting plate; 5. a first roller; 51. a shielding plate;

6. a second drum;

7. a driving mechanism; 71. an arc-shaped plate; 711. a rotating part; 712. a rib; 72. a slide plate; 73. a driving block; 731. a guide slope; 74. a receiving assembly; 741. a receiving plate; 742. an elastic member;

8. a driving motor;

9. a sliding mechanism; 91. a first gear; 92. a second gear; 93. a third gear; 94. a fourth gear; 95. a rack; 96. a screw rod;

10. a blade; 20. a second mounting plate; 30. and a limiting plate.

Detailed Description

The present application is described in further detail below with reference to fig. 1-3.

Referring to fig. 1 and 2, a base 1 and a frame 2 are referred to the surface cutting layering device of a belt for transmission equipment, the base 1 is placed on the ground, the frame 2 is installed above the base 1, a telescopic cylinder 3 is arranged between the frame 2 and the base 1, one end of the telescopic cylinder 3 is fixedly connected with the base 1, and the other end of the telescopic cylinder 3 is fixedly connected with the frame 2. The height of the frame 2 from the ground is adjusted through the extension of the extension cylinder 3, so that the height of a worker is adapted, and the worker can conveniently cut and layer the belt.

The first mounting panel 4 of frame 2 top surface fixedly connected with, the rotation of first mounting panel 4 lateral wall is connected with first cylinder 5, and first cylinder 5 top is provided with shielding plate 51, and shielding plate 51 is the reverse V shape in this embodiment for shelter from first cylinder 5 to at first cylinder 5 pivoted in-process, staff's health position is difficult to touch first cylinder 5. In other embodiments, the shape of the shielding plate 51 may also be arc-shaped, so as to be adapted to the first roller 5, and thus function as shielding for the first roller 5.

The top surface of the frame 2 is provided with a chute 21, a second roller 6 is arranged in the chute 21, the first roller 5 is positioned above the second roller 6, and the second roller 6 can slide in the second chute 21. A driving mechanism 7 is arranged in the chute 21, and the driving mechanism 7 can drive the second roller 6 to slide up and down in the chute 21, so that the gap between the second roller 6 and the first roller 5 is adjusted. In this embodiment, the second roller 6 and the first roller 5 are symmetrically arranged, and the outer surfaces of the second roller 6 and the first roller 5 are fixedly connected with anti-skidding protrusions, and the outer surfaces of the second roller 6 and the outer surfaces of the first roller 5 are fully paved with the anti-skidding protrusions, so that the possibility of skidding of the first roller 5 and the second roller 6 is reduced in the process that the belt passes through the first roller 5 and the second roller 6.

In this embodiment, the driving mechanism 7 is connected with a driving motor 8, and the output end of the driving motor 8 is fixedly connected with the center of the side wall of the second roller 6, and the driving motor 8 runs to make the output shaft of the driving motor 8 rotate, so as to drive the second roller 6 to rotate. The pedal is placed on the ground and is electrically connected with the driving motor 8, and the pedal is stepped on to enable the driving motor 8 to be electrified, so that the second roller 6 is driven to rotate, and the belt is convenient to move.

A blade 10 is arranged between the first roller 5 and the second roller 6, the blade 10 is inserted into a gap between the first roller 5 and the second roller 6, and the blade 10 is fixedly connected with the first mounting plate 4. In this embodiment, the cross section of the blade 10 is triangular, when the belt is divided into two layers by the blade 10, the belt at the upper layer contacts with the upper surface of the blade 10, and the belt at the lower layer contacts with the lower surface of the blade 10, and because the cross section of the blade 10 is triangular, the belt at the upper layer is gradually far away from the belt at the lower layer, so that the belt is conveniently layered.

When the belt needs to be layered, the position of the second roller 6 is adjusted through the driving mechanism 7, so that the distance between the second roller 6 and the blade 10 is adjusted, and the thickness of the layered belt is determined. At this time, the pedal is stepped on again, so that the second roller 6 rotates, and then the belt to be layered is inserted into the gap between the first roller 5 and the second roller 6, so that the belt is tightly attached to the second roller 6, and is driven by the second roller 6 to move in the direction close to the blade 10, so that the belt is divided into two layers by the blade 10.

The driving mechanism 7 comprises an arc-shaped plate 71, the cross section of the arc-shaped plate 71 is three-fifths of a circle, a rotating part 711 is fixedly connected to the center of the arc-shaped plate 71, one end of the rotating part 711 away from the center of the arc-shaped plate 71 is rotationally connected with the first mounting plate 4, so that the arc-shaped plate 71 is rotationally connected with the first mounting plate 4, and the center of the arc-shaped plate 71 is mutually staggered with the rotational connection part of the arc-shaped plate 71 and the first mounting plate 4.

One surface of the arc-shaped plate 71, which is close to the first mounting plate 4, is fixedly connected with a convex rib 712, and the convex rib 712 is arc-shaped and corresponds to the arc-shaped edge of the arc-shaped plate 71. The driving mechanism 7 further comprises a sliding plate 72, the sliding plate 72 is slidably connected to the first mounting plate 4, one end of the sliding plate 72 is abutted against the convex rib 712, and when the arc plate 71 rotates, the convex rib 712 is driven to rotate, and because the circle center of the arc plate 71 and the rotation center of the arc plate 71 are staggered, the convex rib 712 pushes the sliding plate 72 to horizontally slide.

The driving mechanism 7 further comprises a driving block 73 and a bearing assembly 74, the bearing assembly 74 is arranged below the second roller 6 and used for bearing the second roller 6, the driving block 73 is connected to the bearing assembly 74, a guide inclined plane 731 is arranged on one surface, close to the sliding plate 72, of the driving block 73, the sliding plate 72 is in mutual abutting joint with the guide inclined plane 731, when the sliding plate 72 slides, the driving block 73 moves downwards under the guiding action of the guide inclined plane 731, and accordingly the driving block 73 drives the bearing assembly 74 to move downwards, and then the bearing assembly 74 drives the second roller 6 to move downwards, and adjustment of the roller position is achieved.

The receiving component 74 includes a receiving plate 741 and an elastic member 742, the driving block 73 is fixedly connected to the receiving plate 741, the second roller 6 is rotatably connected to the receiving plate 741, the receiving plate 741 is slidably disposed in the chute 21, the elastic member 742 is disposed between the receiving plate 741 and an inner wall of the chute 21, one end of the elastic member 742 abuts against the receiving plate 741, the other end of the elastic member 742 abuts against an inner wall of the chute 21, in this embodiment, the elastic member 742 adopts a spring, and the elastic member 742 is fixedly connected to the receiving plate 741 and the inner wall of the chute 21 respectively. When the driving block 73 moves down, the receiving plate 741 is driven to move down, so that the elastic member 742 is compressed, and when the slider moves away from the driving block 73, the elastic member 742 is restored, and the receiving plate 741 is driven to move up, so that the receiving plate 741 drives the driving block 73 to move up.

In this embodiment, the cross section of the receiving plate 741 is arc-shaped and is adapted to the second roller 6, so that the receiving plate 741 wraps half of the second roller 6, and further limits the second roller 6, thereby reducing the possibility of position deviation of the second roller 6.

When the height of the second roller 6 needs to be adjusted, the arc plate 71 is rotated, so that the arc plate 71 drives the convex rib 712 to rotate, and the convex rib 712 pushes the sliding plate 72 to slide horizontally, and the sliding plate 72 sliding horizontally pushes the receiving plate 741 to move downwards under the guiding action of the guiding inclined plane 731, so as to compress the elastic piece 742, and at the moment, the second roller 6 moves downwards along with the receiving plate 741, so that the position of the second roller 6 is adjusted.

When the second roller 6 needs to be moved upwards, the arc plate 71 is reversely rotated, so that the arc plate 71 drives the rib 712 to rotate, and the rib 712 slides in a direction away from the sliding plate 72, at this time, the elastic piece 742 is restored, and drives the receiving plate 741 to slide upwards, so that the receiving plate 741 drives the driving block 73 to move upwards, and the driving block 73 drives the sliding plate 72 to slide through the guiding inclined plane 731, so that the sliding plate 72 continuously abuts against the rib 712.

In order to fix the sliding plate 72 and the limiting block with each other, the sliding plate 72 is made of a magnetic material, the sliding plate 72 is made of an iron material in the embodiment, the limiting block is an electromagnet, and the sliding plate 72 and the limiting block are fixed with each other through the electromagnet. And further, the possibility of the second roller 6 moving downward under the pressure of the belt is reduced in the process of pressing the second roller 6 by the belt.

Referring to fig. 2 and 3, a second mounting plate 20 is fixedly connected to the frame 2, the second mounting plate 20 and the first mounting plate 4 are flush with each other, a limiting plate 30 is slidably connected to the frame 2, a sliding mechanism 9 is arranged between the limiting plate 30 and the second mounting plate 20, and the sliding mechanism 9 can drive the limiting plate 30 to slide in a direction away from the second mounting plate 20. Before the belt is cut and layered, the belt is tightly attached to the limiting plate 30, and the limiting plate 30 is driven to slide through the sliding mechanism 9 at the moment, so that the his limiting plate 30 drives the belt to slide, and then one part of the belt is aligned with the blade 10, and the other part of the belt is staggered with the blade 10, so that the width of the belt for layering is controlled.

The sliding mechanism 9 includes a first gear 91, a second gear 92, a third gear 93, a fourth gear 94 and a screw rod 96, wherein the first gear 91 is rotatably connected to a surface of the second mounting plate 20 near the limiting plate 30, the third gear 93 is rotatably connected to a surface of the second mounting plate 20 near the limiting plate 30, and the third gear 93 is meshed with the first gear 91. The fourth gear 94 is fixedly connected to the third gear 93 at a surface far away from the second mounting plate 20, the first gear 91 is identical to the third gear 93, the outer diameter of the fourth gear 94 is smaller than that of the third gear 93, and the fourth gear 94 is identical to the second gear 92.

Rack 95 sliding connection is on frame 2 and set up between limiting plate 30 and second mounting panel 20, lead screw 96 one end and second mounting panel 20 spiro union, lead screw 96 other end fixed connection is on limiting plate 30, second gear 92 cover is established on lead screw 96 and with lead screw 96 spiro union, be provided with the sleeve between second gear 92 and the second mounting panel 20, the sleeve cover is established on lead screw 96 and has the clearance between lead screw 96, sleeve one end and second mounting panel 20 fixed connection, the sleeve other end and second gear 92 change to be connected, rack 95 meshes with second gear 92 and fourth gear 94 simultaneously.

The first gear 91 is rotated, so that the first gear 91 drives the third gear 93 to rotate, and then the third gear 93 drives the fourth gear 94 to rotate, so that the fourth gear 94 drives the rack 95 to slide, and the rack 95 slides to drive the second gear 92 to rotate, and the screw rod 96 screwed with the second gear 92 slides along the axis direction of the second gear 92, so that the limiting plate 30 is pushed to slide.

The implementation principle of the embodiment of the application is as follows: when the belt cutting is required, the upper belt is firstly placed on the frame 2 and attached to the limiting plate 30, the first gear 91 is rotated at the moment, so that the rack 95 is driven to slide through the third gear 93 and the fourth gear 94, the rack 95 slides to drive the second gear 92 to rotate, the screw rod 96 slides along the axis direction of the second gear 92, the limiting plate 30 is driven to move, and the width of the belt to be layered is adjusted.

At this time, the arc plate 71 is rotated, so that the arc plate 71 drives the sliding plate 72 to slide through the convex rib 712, and the sliding plate 72 drives the driving block 73 to move downwards through the guiding inclined plane 731, so that the driving block 73 pushes the bearing plate 741 to slide, and further, the position adjustment of the second roller 6 is realized, and therefore, the gap between the second roller 6 and the blade 10 is adjusted, and the adjustment of the layering thickness of the belt is realized. After the adjustment is completed, the driving block 73 is energized, so that the driving block 73 attracts the slide plate 72, thereby restricting the sliding of the slide plate 72 on the driving block 73.

At the moment, the column pedal is stepped on, so that the driving motor 8 drives the second roller 6 to rotate and simultaneously pushes the belt to move towards the blade 10, and the blade 10 layers the belt, so that the belt is processed.

The embodiments of this embodiment are all preferred embodiments of the present application, and are not intended to limit the scope of the present application, in which like parts are denoted by like reference numerals. Therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (4)

1. The surface cutting layering device for the belt for the transmission equipment comprises a frame (2), a first roller (5), a second roller (6) and a blade (10), wherein the first roller (5) is positioned above the second roller (6), and is characterized in that a first mounting plate (4) is fixedly connected to the frame (2), and the first roller (5) is rotatably connected to the first mounting plate (4);

the first mounting plate (4) is provided with a driving mechanism (7), and the driving mechanism (7) is connected with the second roller (6) and can drive the second roller (6) to move in a direction away from the first roller (5);

the blade (10) is fixedly connected to the first mounting plate (4) and the blade (10) is inserted between the first roller (5) and the second roller (6);

the driving mechanism (7) comprises an arc-shaped plate (71), a sliding plate (72), a driving block (73) and a bearing assembly (74), wherein the arc-shaped plate (71) is rotationally connected to the first mounting plate (4), and the rotational connection positions of the arc-shaped plate (71) and the arc-shaped plate (71) are mutually staggered with the rotational connection positions of the first mounting plate (4);

the arc-shaped plate (71) is fixedly connected with a rib (712), the sliding plate (72) is connected to the first mounting plate (4) in a sliding manner and can be abutted against the rib (712), and the rib (712) can move to drive the sliding plate (72) to move horizontally;

the driving block (73) is fixedly connected to the bearing assembly (74) and can be abutted against the sliding plate (72), and a guide inclined plane (731) is arranged on one surface of the driving block (73) close to the sliding plate (72);

-said receiving assembly (74) for holding said second drum (6);

the bearing assembly (74) comprises a bearing plate (741) and an elastic piece (742), one end of the elastic piece (742) is abutted against the frame (2), the other end of the elastic piece (742) is abutted against the bearing plate (741), and the second roller (6) is rotatably connected with the bearing plate (741);

the machine frame (2) is fixedly connected with a second mounting plate (20), a limiting plate (30) is arranged on the machine frame (2) in a sliding mode, and a sliding mechanism (9) capable of driving the limiting plate (30) to slide in the axial direction of the first roller (5) is arranged on the second mounting plate (20);

the sliding mechanism (9) comprises a first gear (91), a second gear (92), a screw rod (96) and a rack (95), wherein the first gear (91) is rotationally connected to the second mounting plate (20), the second gear (92) is in threaded connection with the screw rod (96) and is connected to the second mounting plate (20), one end of the screw rod (96) is in threaded connection with the second mounting plate (20), the other end of the screw rod (96) is fixedly connected with the limiting plate (30), the rack (95) is in sliding connection with the rack (2) and is meshed with the second gear (92), and the first gear (91) can drive the rack (95) to slide in a rotating manner;

the side wall of the second mounting plate (20) is rotationally connected with a third gear (93), the third gear (93) is meshed with the first gear (91), the side wall of the third gear (93) is fixedly connected with a fourth gear (94), the outer diameter of the fourth gear (94) is smaller than that of the third gear (93), and the fourth gear (94) is meshed with the rack (95).

2. A surface-cutting delamination device for conveyor belts according to claim 1, characterized in that the receiving plate (741) has an arc-shaped cross section and is adapted to the second drum (6).

3. A surface cutting delamination apparatus for a conveyor belt according to claim 1, wherein the slide plate (72) is made of a magnetic material, the driving block (73) is an electromagnet, and the driving block (73) attracts the slide plate (72).

4. A surface cutting delamination apparatus for a conveyor belt according to claim 1, wherein a shielding plate (51) is fixedly connected to the first mounting plate (4), the shielding plate (51) being arranged above the first drum (5).