CN116081185A

CN116081185A - Energy-saving belt conveyor with slipping locking mechanism

Info

Publication number: CN116081185A
Application number: CN202310047682.0A
Authority: CN
Inventors: 汪亚
Original assignee: Anhui Yabang Heavy Industry Machinery Co ltd
Current assignee: Anhui Yabang Heavy Industry Machinery Co ltd
Priority date: 2023-01-31
Filing date: 2023-01-31
Publication date: 2023-05-09

Abstract

An energy-saving belt conveyor with a slipping locking mechanism belongs to the technical field of belt conveyors and aims to solve the problems that when the upward inclination conveying angle of the existing belt conveyor is too large, the driving force is insufficient due to slipping between a belt and a driving roller, and goods cannot be effectively and rapidly conveyed to a high-position operation platform; according to the invention, the wear-resistant sleeve and the rubber belt are sleeved on the outer wall of the driving roller, when the driving roller drives the conveying belt to rotate, the limiting strips on the side wall of the wear-resistant sleeve sequentially slide through the locking plates on the inner wall of the mounting rack, the limiting strips slide through one locking plate and are positioned on one side of the limiting strips close to the obliquely upper side of the conveying belt, the limiting strips and the conveying belt are prevented from sliding on the driving roller to one side obliquely lower than the driving roller by the locking plates, and the frosted protrusions and the anti-skid auxiliary pieces on the inner surface of the wear-resistant sleeve sequentially rotate to be attached to the outer wall of the driving roller, so that the friction force between the wear-resistant sleeve and the driving roller is increased, the problem of slipping of the conveying belt is avoided, and the self-driven wear-resistant belt is energy-saving and environment-friendly.

Description

Energy-saving belt conveyor with slipping locking mechanism

Technical Field

The invention relates to the technical field of belt conveyors, in particular to an energy-saving belt conveyor with a slipping locking mechanism.

Background

The belt conveyor is a machine for conveying materials by using endless movement of a belt. Belt deflection is the most common fault when a belt conveyor operates, and important attention is paid to the dimensional accuracy of installation and daily maintenance for solving the fault. The maintenance of the machine is an extremely important and frequent work, and is closely matched with the extremely operation, overhaul and the like, and the machine should be subjected to on-duty inspection by professional staff. The belt conveyor has the advantages of long conveying distance, large conveying capacity, small working resistance, convenience in installation, low power consumption, small abrasion and the like.

In daily life, people often use belt conveyors to continuously and orderly convey goods to a high-place operation table, so that the working efficiency of people is greatly improved. However, when the upward-inclination conveying angle of the existing belt conveyor is overlarge, a slipping phenomenon is easy to occur between a conveying belt for carrying objects and a transmission steel roller, so that the driving force of the conveying belt is insufficient, and the objects are conveyed to an operation platform which is not located at a high place, and the use of the belt conveyor is affected.

Therefore, we propose an energy-saving belt conveyor with a slip locking mechanism.

Disclosure of Invention

The invention aims to provide an energy-saving belt conveyor with a slipping locking mechanism, and aims to solve the problems that in the prior art, when the upward inclined conveying angle of the conventional belt conveyor is too large, the driving force is insufficient due to slipping between a belt and a driving roller, and goods cannot be effectively and rapidly conveyed to a high-altitude operation platform.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides an energy-saving belt conveyor with locking mechanism skids, including installing frame and fixed connection in the controller on the outer wall of installing frame one side end, be provided with the driving roller through the even activity of pivot between installing frame both sides inner wall, the conveyer belt has been cup jointed on the outer wall of driving roller, the conveyer belt includes wear-resisting cover and the rubber belt of fixed connection on wear-resisting cover top layer outer wall that the activity cup jointed on the driving roller outer wall, and even interval fixedly connected with spacing on the outer wall of wear-resisting cover both sides, it is provided with the locking plate to correspond spacing department even interval activity on the both sides inner wall of installing frame, the locking plate expansion end is connected with installing frame inner wall through the torsional spring, and the internal surface even interval of wear-resisting cover is provided with anti-skidding auxiliary, the internal surface of wear-resisting cover between the anti-skidding auxiliary evenly is provided with the dull polish arch.

Further, the width of the wear-resistant sleeve is smaller than that of the rubber belt, the tail ends of the limiting strips on the side wall of the wear-resistant sleeve do not extend to the outer side of the rubber belt, and the locking plates are only arranged on the inner walls of the two sides of the installation frame above the rotating shaft.

Further, the locking plate is obliquely arranged through the torsion spring, the tail end of the locking plate is suspended on one side of the tail end of the limiting strip, and the oblique direction of the tail end of the locking plate is the same as the rotating advancing direction of the conveying belt.

Further, the hydraulic lifting rods are movably arranged at two ends of the bottom of the mounting frame respectively, the bottoms of the hydraulic lifting rods are fixedly connected with moving wheels, hydraulic parking rods are arranged on the side walls of the shells of the moving wheels, and the hydraulic parking rods are used for supporting the ground when the belt conveyor works.

Further, the installation frame is hollow structure, and the pivot at driving roller both ends runs through the installation frame setting, and is provided with drive gear on the pivot outer wall in the installation frame of driving roller one side, through same chain interconnect between the drive gear, and the pivot end of one of them driving roller one end extends to the installation frame outside to be connected with the rotating electrical machines output.

Further, the anti-skid auxiliary piece comprises a mounting seat uniformly embedded on the inner surface of the wear-resistant sleeve and a mounting cavity arranged on the mounting seat, a port of the mounting cavity corresponds to the driving roller, an elastic component is fixedly connected to a bottom plate of the mounting cavity, a moving plate is fixedly connected to the tail end of the elastic component, a rubber disc is fixedly connected to the outer wall of the moving plate, which is close to one side of the port of the mounting cavity, and the tail end of the rubber disc extends to the outside of the port of the mounting cavity.

Further, the piston disc is movably clamped between the inner walls of the rubber discs, a movable rod is fixedly connected to the outer wall of one side, far away from the port of the rubber disc, of the piston disc, the movable rod penetrates through the rubber disc bottom plate and the movable plate and then extends into the mounting cavity, the armature plate is fixedly connected to the tail end of the movable rod, and a buffer spring is wound on the outer wall of the movable rod between the armature plate and the movable plate.

Further, a magnet block is fixedly connected to the position, corresponding to the armature plate, on the bottom plate of the installation cavity, of the piston disc, and when the elastic component keeps a normal diastole state, the tail end of the rubber disc is located at the outer side of the port of the installation cavity, and at the moment, the piston disc is located at the port of the rubber disc.

Further, the even interval fixedly connected with second locking piece of surface of rubber tape, the second locking piece includes fixed strip and the mounting groove of setting on the fixed strip outer wall of fixed connection in the rubber tape surface, the mounting groove is seted up on the outer wall of fixed strip one side of keeping away from the rubber tape, and swing joint has the deflection pole between the inner wall of mounting groove one end, movable block has on the bottom plate of mounting groove, movable block top swing joint is in movable connecting rod, movable connecting rod other end swing joint is in deflection pole bottom, and the one end of movable block passes through reset spring and the fixed link to each other of mounting groove inner wall.

Further, one end of the movable block, which is far away from the reset spring, is fixedly connected with a piston rod, the tail end of the piston rod is movably sleeved in the air cylinder, a buffer air cushion is fixedly connected on the outer wall of one side of the fixed strip, which corresponds to the rotating advancing direction of the rubber belt, and the buffer air cushion is communicated with the air cylinder.

Compared with the prior art, the invention has the following beneficial effects:

according to the energy-saving belt conveyor with the slipping locking mechanism, the wear-resistant sleeve and the rubber belt are sleeved on the outer wall of the driving roller, when the driving roller drives the conveying belt to rotate, the limiting strips on the side wall of the wear-resistant sleeve sequentially slip over the locking plates on the inner wall of the mounting rack, the limiting strips slip over one locking plate and then are positioned on one side, close to the obliquely upper side of the conveying belt, of the conveying belt to be prevented from slipping on one side, obliquely lower, of the conveying belt, and meanwhile, the frosted protrusions and the slipping auxiliary pieces on the inner surface of the wear-resistant sleeve sequentially rotate to be attached to the outer wall of the driving roller, so that friction force between the wear-resistant sleeve and the driving roller is increased, goods are stably conveyed to an obliquely high operating platform, and the energy-saving belt conveyor is convenient and practical.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of a conveyor belt mounting structure of the present invention;

FIG. 3 is a schematic view of the mounting structure of the stop bar and wear sleeve of the present invention;

FIG. 4 is an enlarged schematic view of the structure of FIG. 2A according to the present invention;

FIG. 5 is a schematic view of the mounting structure of the driving roller and the driving gear of the present invention;

FIG. 6 is a schematic view of the anti-skid auxiliary member of the present invention;

FIG. 7 is a front view of a second latch of the present invention;

fig. 8 is a top view of a second latch of the present invention.

In the figure: 1. a frame is installed; 2. a controller; 3. a rotating shaft; 4. a driving roller; 5. a conveyor belt; 51. a wear-resistant sleeve; 52. a rubber belt; 53. a limit bar; 54. an anti-slip auxiliary; 541. a mounting base; 542. a mounting cavity; 543. an elastic member; 544. a moving plate; 545. a rubber plate; 5451. a piston disc; 5452. a movable rod; 5453. an armature plate; 5454. a buffer spring; 546. a magnet block; 55. grinding the protrusions; 56. a second locking member; 561. a fixing strip; 562. a mounting groove; 563. a deflection lever; 564. a moving block; 565. a movable connecting rod; 566. a position spring; 567. a piston rod; 568. an air cylinder; 569. punching an air cushion; 6. a locking plate; 7. a torsion spring; 8. a hydraulic lifting rod; 9. a transmission gear; 10. and (3) a chain.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, fig. 2 and fig. 5, an energy-saving belt conveyor with a slipping locking mechanism comprises a mounting frame 1 and a controller 2 fixedly connected to the outer wall of one side end of the mounting frame 1, wherein driving rollers 4 are uniformly and movably arranged between the inner walls of two sides of the mounting frame 1 through rotating shafts 3, the mounting frame 1 is of a hollow structure, rotating shafts 3 at two ends of the driving rollers 4 penetrate through the mounting frame 1, driving gears 9 are arranged on the outer wall of the rotating shafts 3 in the mounting frame 1 at one side of the driving rollers 4, the driving gears 9 are mutually connected through the same chain 10, the tail ends of the rotating shafts 3 at one end of one group of the driving rollers 4 extend to the outside of the mounting frame 1 and are connected with the output end of a rotating motor, a conveying belt 5 is sleeved on the outer wall of the driving rollers 4, hydraulic lifting rods 8 are respectively and movably arranged at two ends of the bottom of the mounting frame 1, moving wheels are fixedly connected to the bottom of the hydraulic lifting rods 8, hydraulic parking rods are arranged on the side walls of a housing of the parking wheels, and the hydraulic parking rods are used for supporting the ground during operation of the belt conveyor.

In order to solve the problem that when the upward inclined conveying angle of the existing belt conveyor is overlarge, the driving force is insufficient due to slipping between a belt and a driving roller, and cargoes cannot be effectively and rapidly conveyed to a high-place operation platform, please refer to fig. 1-8, the following preferable technical scheme is provided:

the conveyer belt 5 includes wear-resisting cover 51 that the activity cup jointed on driving roller 4 outer wall and fixed connection are in the rubber belt 52 on wear-resisting cover 51 top layer outer wall, and evenly spaced fixedly connected with spacing 53 on the outer wall of wear-resisting cover 51 both sides, correspond spacing 53 department even interval activity on the both sides inner wall of installation frame 1 and be provided with locking plate 6, locking plate 6 expansion end is connected with installation frame 1 inner wall through torsional spring 7, and wear-resisting cover 51's internal surface even interval is provided with anti-skidding auxiliary member 54, wear-resisting cover 51's internal surface between anti-skidding auxiliary member 54 evenly is provided with the dull polish arch 55, the dull polish arch 55 is used for increasing wear-resisting cover 51 and driving roller 4's contact frictional force.

The width of the wear-resistant sleeve 51 is smaller than that of the rubber belt 52, the tail ends of the limiting strips 53 on the side wall of the wear-resistant sleeve 51 do not extend to the outer side of the rubber belt 52, and the locking plates 6 are only arranged on the inner walls of the two sides of the installation frame 1 above the rotating shaft 3.

The antiskid auxiliary piece 54 includes the mount pad 541 of even gomphosis in wear-resisting cover 51 internal surface and the installation cavity 542 of setting on the mount pad 541, the installation cavity 542 port corresponds driving roller 4 setting, and fixedly connected with elastomeric element 543 on the installation cavity 542 bottom plate, elastomeric element 543's terminal fixedly connected with movable plate 544, fixedly connected with rubber disk 545 on the outer wall of movable plate 544 near installation cavity 542 port side, rubber disk 545 end extends to the installation cavity 542 port outside, rubber disk 545 on the wear-resisting cover 51 internal surface is along with the rotation of wear-resisting cover 51, rotatory laminating driving roller 4 outer wall in proper order, rubber disk 545 is pushed movable plate 544 by the extrusion of driving roller 4 compresses elastomeric element 543, make rubber disk 545 to remove in the installation cavity 542 on the mount pad 541, make wear-resisting cover 51 laminate driving roller 4 outer wall completely, rubber disk 545 and dull polish protruding 55 laminate driving roller 4 outer wall in order to increase frictional force, avoid wear-resisting cover 51 to take place the friction to skid, thereby guarantee that rubber belt 52 stably carries the goods, convenience and practicability.

A piston disc 5451 is movably clamped between the inner walls of the rubber disc 545, a movable rod 5452 is fixedly connected to the outer wall of one side, far away from the port of the rubber disc 545, of the piston disc 5451, the movable rod 5452 penetrates through the bottom plate of the rubber disc 545 and the movable plate 544 and then extends into the mounting cavity 542, the tail end of the movable rod 5452 is fixedly connected with an armature plate 5453, and a buffer spring 5454 is wound on the outer wall of the movable rod 5452 between the armature plate 5453 and the movable plate 544; the magnet piece 546 is fixedly connected to the position, corresponding to the armature piece 5453, on the bottom plate of the installation cavity 542, of the magnet piece 546, when the elastic component 543 keeps a normal diastole state, the tail end of the rubber disc 545 is located at the outer side of the port of the installation cavity 542, at this time, the piston disc 5451 is located at the port of the rubber disc 545, after the rubber disc 545 is attached to the driving roller 4 and moves towards the installation cavity 542, the armature piece 5453 is close to the magnet piece 546 at the bottom of the installation cavity 542, the magnet piece 546 adsorbs the armature piece 5453 to drive the moving rod 5452, the moving rod 5452 draws the piston disc 5451 away from the port of the rubber disc 545, the inner cavity air pressure of the rubber disc 545 between the piston disc 5451 and the driving roller 4 is reduced, the rubber disc 545 is adsorbed on the outer wall of the driving roller 4, friction force between the wear-resistant sleeve 51 and the driving roller 4 is further increased, and accordingly the driving roller 4 stably rotates along with the driving roller 4, and stability of goods obliquely conveyed by the conveying belt 5 is guaranteed.

The outer surface of the rubber belt 52 is fixedly connected with second locking pieces 56 at uniform intervals, each second locking piece 56 comprises a fixing strip 561 fixedly connected to the outer surface of the rubber belt 52 and a mounting groove 562 arranged on the outer wall of the fixing strip 561, each mounting groove 562 is formed in the outer wall of one side, far away from the rubber belt 52, of the fixing strip 561, a deflection rod 563 is movably connected between the inner walls of one end of each mounting groove 562, a moving block 564 is movably clamped on the bottom plate of each mounting groove 562, the top of each moving block 564 is movably connected with a movable connecting rod 565, the other end of each movable connecting rod 565 is movably connected with the bottom of each deflection rod 563, and one end of each moving block 564 is fixedly connected with the inner wall of each mounting groove 562 through a reset spring 566; the movable block 564 is fixedly connected with the piston rod 567 at one end far away from the reset spring 566, the tail end of the piston rod 567 is movably sleeved in the air cylinder 568, the fixed strip 561 is fixedly connected with the buffer air cushion 569 on the outer wall corresponding to one side of the rotary advancing direction of the rubber belt 52, the buffer air cushion 569 is communicated with the air cylinder 568, when goods are placed on the surface of the rubber belt 52 for conveying obliquely upwards, the goods slide downwards and are contacted with the buffer air cushion 569 to extrude the goods, the buffer air cushion 569 is compressed and then the gas inside the goods is extruded into the air cylinder 568, the piston rod 567 pushes the movable block 564 to move in the mounting groove 562, the movable block 567 deflects the movable connecting rod 565 while the movable block 564 compresses the reset spring 566, the movable rod 563 deflects out of the port of the mounting groove 562 on the fixed strip 561, the deflecting rod 563 is obliquely erected at the top of the rubber belt 52, the goods are prevented from rolling when the goods slide downwards and contact with the buffer air cushion 569, and the goods are prevented from rolling and the goods are conveyed safely.

Specifically, when the driving roller 4 drives the conveyer belt 5 to rotate and convey goods obliquely upward based on friction force, the limiting strips 53 on the outer walls of the two sides of the wear-resistant sleeve 51 above the driving roller 4 move rotationally along with the wear-resistant sleeve 51 and the rubber belt 52, and when the wear-resistant sleeve 51 moves in the rotating forward direction, the tail ends of the limiting strips 53 move to squeeze the locking plate 6 on the inner wall of the mounting rack 1 above the driving roller 4, the locking plate 6 is pushed to deflect and squeeze the torsion spring 7, so that the limiting strips 53 slide to one side of the conveyer belt 5 obliquely above the locking plate 6, then the torsion spring 7 enables the locking plate 6 to reset, when the rubber belt 52 obliquely conveys goods obliquely upward, the limiting strips 53 abut against the locking plate 6, and when the wear-resistant sleeve 51 rotates along with the wear-resistant sleeve 4, the grinding protrusions 55 and the auxiliary pieces 54 on the inner wall of the wear-resistant sleeve 51 contact the outer wall of the driving roller 4, so that the friction force of the wear-resistant sleeve 51 and the roller 4 is increased, the friction force of the driving roller 5 is increased, the energy-saving and the driving force is prevented from slipping to the environment-friendly conveyer belt 5 when the conveyer belt 5 is inclined obliquely upward, and the problem of the driving force cannot be caused is avoided, and the problem of the self-driving is avoided.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an energy-saving belt conveyor with locking mechanism skids, includes installing frame (1) and fixed connection in installing frame (1) one side end controller (2) on the outer wall, is provided with driving roller (4) through pivot (3) even activity between installing frame (1) both sides inner wall, has cup jointed conveyer belt (5), its characterized in that on the outer wall of driving roller (4): the conveyer belt (5) including the activity cup joint wear-resisting cover (51) on driving roller (4) outer wall and fixed connection rubber tape (52) on wear-resisting cover (51) top layer outer wall, and even interval fixedly connected with spacing (53) on the outer wall of wear-resisting cover (51) both sides, the activity of even interval department of corresponding spacing (53) on the both sides inner wall of installing frame (1) is provided with locking board (6), locking board (6) expansion end is connected with installing frame (1) inner wall through torsional spring (7), and the internal surface uniform interval of wear-resisting cover (51) is provided with antiskid auxiliary (54), the internal surface of wear-resisting cover (51) between antiskid auxiliary (54) evenly is provided with dull polish arch (55).

2. An energy-saving belt conveyor with a slip locking mechanism as in claim 1 wherein: the width of the wear-resistant sleeve (51) is smaller than that of the rubber belt (52), the tail end of the limiting strip (53) on the side wall of the wear-resistant sleeve (51) does not extend to the outer side of the rubber belt (52), and the locking plate (6) is only arranged on the inner walls of the two sides of the installation frame (1) above the rotating shaft (3).

3. An energy-saving belt conveyor with a slip locking mechanism as in claim 2 wherein: the locking plate (6) is obliquely arranged through the torsion spring (7), the tail end of the locking plate (6) is suspended on one side of the tail end of the limiting strip (53), and the oblique direction of the tail end of the locking plate (6) is the same as the rotating forward direction of the conveyor belt (5).

4. An energy-saving belt conveyor with a slip locking mechanism as in claim 1 wherein: the hydraulic lifting rods (8) are movably arranged at two ends of the bottom of the mounting frame (1) respectively, the movable wheels are fixedly connected to the bottoms of the hydraulic lifting rods (8), hydraulic parking rods are arranged on the side walls of the shells of the movable wheels, and the hydraulic parking rods are used for supporting the ground when the belt conveyor works.

5. An energy-saving belt conveyor with a slip locking mechanism as in claim 1 wherein: the installation frame (1) is hollow structure, and pivot (3) at driving roller (4) both ends run through installation frame (1) setting, and are provided with drive gear (9) on pivot (3) outer wall in driving roller (4) one side installation frame (1), pass through same root chain (10) interconnect between drive gear (9), and pivot (3) end of a set of driving roller (4) one end extends to installation frame (1) outside to be connected with the rotating electrical machines output.

6. An energy-saving belt conveyor with a slip locking mechanism as in claim 1 wherein: the anti-skid auxiliary piece (54) comprises a mounting seat (541) uniformly embedded on the inner surface of the wear-resistant sleeve (51) and a mounting cavity (542) arranged on the mounting seat (541), a port of the mounting cavity (542) is arranged corresponding to the driving roller (4), an elastic component (543) is fixedly connected to a bottom plate of the mounting cavity (542), a movable plate (544) is fixedly connected to the tail end of the elastic component (543), a rubber disc (545) is fixedly connected to the outer wall, close to one side of the port of the mounting cavity (542), of the movable plate (544), and the tail end of the rubber disc (545) extends to the outside of the port of the mounting cavity (542).

7. An energy-saving belt conveyor with a slip locking mechanism as in claim 6 wherein: piston disc (5451) is movably clamped between inner walls of rubber discs (545), movable rods (5452) are fixedly connected to the outer walls of one sides, far away from ports of the rubber discs (545), of the piston disc (5451), the movable rods (5452) penetrate through bottom plates of the rubber discs (545) and the movable plates (544) and then extend into mounting cavities (542), armature plates (5453) are fixedly connected to tail ends of the movable rods (5452), and buffer springs (5454) are wound on the outer walls of the movable rods (5452) between the armature plates (5453) and the movable plates (544).

8. An energy-saving belt conveyor with a slip locking mechanism as in claim 7 wherein: the magnet block (546) is fixedly connected to the position, corresponding to the armature plate (5453), on the bottom plate of the installation cavity (542), and when the elastic component (543) keeps a normal diastole state, the tail end of the rubber disc (545) is located at the outer side of the port of the installation cavity (542), and at the moment, the piston disc (5451) is located at the port of the rubber disc (545).

9. An energy-saving belt conveyor with a slip locking mechanism as in claim 1 wherein: the outer surface of the rubber belt (52) is uniformly and fixedly connected with second locking pieces (56) at intervals, the second locking pieces (56) comprise fixing strips (561) fixedly connected to the outer surface of the rubber belt (52) and mounting grooves (562) formed in the outer walls of the fixing strips (561), the mounting grooves (562) are formed in the outer walls of the fixing strips (561) on one side far away from the rubber belt (52), deflection rods (563) are movably connected between the inner walls of one ends of the mounting grooves (562), moving blocks (564) are movably clamped on the bottom plate of the mounting grooves (562), the tops of the moving blocks (564) are movably connected to movable connecting rods (565), the other ends of the movable connecting rods (565) are movably connected to the bottoms of the deflection rods (563), and one ends of the moving blocks (564) are fixedly connected with the inner walls of the mounting grooves (562) through reset springs (566).

10. An energy-saving belt conveyor with a slip locking mechanism as in claim 9 wherein: one end of the moving block (564) far away from the reset spring (566) is fixedly connected with a piston rod (567), the tail end of the piston rod (567) is movably sleeved in the air cylinder (568), a buffer air cushion (569) is fixedly connected on the outer wall of one side of the fixed strip (561) corresponding to the rotating advancing direction of the rubber belt (52), and the buffer air cushion (569) is communicated with the air cylinder (568).