CN113602785B

CN113602785B - Material output sorting device

Info

Publication number: CN113602785B
Application number: CN202110900345.2A
Authority: CN
Inventors: 周志强; 叶从亮; 杨淑强
Original assignee: Zhejiang Huarong Technology Co ltd
Current assignee: Zhejiang Huarong Technology Co ltd
Priority date: 2021-08-06
Filing date: 2021-08-06
Publication date: 2023-05-19
Anticipated expiration: 2041-08-06
Also published as: CN113602785A

Abstract

The invention relates to a material output sorting device which comprises a cutting mechanism, a material receiving assembly, a distribution assembly, a buffer assembly, a gravity linkage assembly and a limiting assembly, wherein the material receiving assembly is connected with the material receiving assembly; the invention solves the problems that the graphite rod cannot be centered and blanked, the graphite rod cannot be buffered and protected in blanking process, the blanking in multiple directions cannot be carried out, the falling direction of the graphite rod cannot be controlled through gravity change and the like after the existing graphite rod is processed.

Description

Material output sorting device

Technical Field

The invention relates to the field of advanced inorganic nonmetallic materials, in particular to a material output sorting device.

Background

Along with research and development of inorganic nonmetallic materials by technological staff, graphite materials are well known from strange, and the graphite materials have good thermal conductivity and chemical stability, so that the graphite materials are widely used for manufacturing and production of various industries, are small in the production of accessories in electronic equipment, are large in the research and development of parts of aerospace instruments, have an increasingly important function in production and life, and are also increasingly wide in application range, so that the graphite materials become an indispensable practical material in the production and life. However, in the process of processing graphite rods, intelligent blanking is still an urgent problem to be solved.

The inventor finds that the graphite rod can not fall into the receiving device in the middle after finishing processing, can not realize blanking from a plurality of directions, can not control the falling direction of the graphite rod through the change of the quantity and the gravity of the graphite rod and the like.

Disclosure of Invention

The invention aims at overcoming the defects of the prior art, and solves the problems that a graphite rod cannot be subjected to buffer protection, cannot be blanked from multiple directions, cannot control the falling direction of the graphite rod through gravity change and the like in the process of blanking in the middle after the existing graphite rod is processed.

The technical solution of the invention is as follows:

the material output sorting device comprises a cutting mechanism, wherein a material receiving assembly is arranged at the tail end of the cutting mechanism, a distribution assembly is arranged at the top of the material receiving assembly, a buffer assembly is arranged on the material receiving assembly, gravity linkage assemblies are arranged on two sides of the lower end of the material receiving assembly, and a limiting assembly is arranged above the distribution assembly; the limiting assembly blocks and limits the distribution assembly which does not receive the graphite rods, the distribution assembly receives the graphite rods output from the cutting mechanism and downwards settles to discharge materials on two sides of the receiving assembly, the buffering assembly buffers and decelerates the falling graphite rods, and the gravity linkage assembly adjusts the discharging direction of the distribution assembly through the weight change of the graphite rods on two sides of the receiving assembly, so that intelligent discharging is performed on the graphite rods.

As a preference, the material receiving assembly comprises a material receiving inclined plate, a placement groove arranged at the tail end of the material receiving inclined plate, a storage box arranged in the placement groove in a sliding manner, a rotating rod arranged at the top of the material receiving inclined plate, an empty groove arranged on the material receiving inclined plate and a square hole arranged on one side of the placement groove.

As one preferable mode, the distribution assembly comprises a rotating ring, a bearing bar, a plurality of sliding grooves formed in the rotating ring and a plurality of supporting rods fixedly arranged at the lower end of the bearing bar, wherein the rotating ring is rotatably arranged on the rotating rod, a reset spring a is arranged on the supporting rods and is slidably arranged in the sliding grooves, the inner wall of the bearing bar is arranged to be a curved surface, and a torsion spring is arranged between the rotating ring and the rotating rod.

Preferably, the buffer assembly comprises a plurality of inclined strips arranged on two sides of the material receiving inclined plate and a plurality of deceleration cross strips arranged at the lower ends of the inclined strips, and the inclined strips are inclined from two sides of the material receiving inclined plate to the middle part.

As one preferable, the gravity linkage assembly comprises a rotating seat, a sliding seat, a swinging arm arranged on the rotating seat in a rotating mode, a bearing arm fixedly arranged at one end of the swinging arm, a jacking rod connected with the other end of the swinging arm in a rotating mode and a pushing plate fixedly arranged at the top of the jacking rod, the jacking rod is arranged in the sliding seat in a sliding mode, the jacking rods on two sides are hinged through the linkage arm, one side of the pushing plate is arranged to be an arc surface, and the jacking rod slides up and down in the empty groove.

Preferably, the limiting component comprises a bracket, a top cover fixedly arranged on the bracket and limiting plates fixedly arranged on two sides of the top cover.

As one preferable mode, the balance assembly is further arranged on the other side of the placement groove and comprises a lifting groove formed in the side wall of the placement groove, a limiting column fixedly arranged in the lifting groove, a supporting plate slidably arranged in the lifting groove and a reset spring b arranged on the limiting column.

Preferably, a traction assembly is further arranged between the cutting mechanism and the distribution assembly, and the traction assembly comprises a support frame, a support block fixedly arranged on the support frame, an output groove formed in the support block, a plurality of rollers rotatably arranged in the output groove and a plurality of traction wheels rotatably arranged on the support block.

Preferably, the cutting mechanism comprises a processing table, a cutting cylinder rotatably arranged on the processing table and a motor fixedly arranged at the lower end of the processing table, and the cutting cylinder is connected with the motor through a belt.

As another preferable mode, the material receiving inclined plate is arranged in a triangular fixed mode from two sides to the middle.

The invention has the beneficial effects that:

1. the invention is provided with the distribution assembly and the limiting assembly, when the distribution assembly does not receive the graphite rod, the bearing bar in the distribution assembly is limited and blocked by the limiting plate in the limiting assembly, when the graphite rod falls onto the bearing bar, the bearing bar is buffered and sunk on the rotating ring through the supporting rod, so that the bearing bar is separated from the blocking of the limiting plate, and then the material receiving inclined plates on two sides of the gravity center position of the bearing bar are randomly discharged according to the material receiving inclined plates of the graphite rod on two sides of the bearing bar, and the components are mutually matched, so that the problem that the graphite rod cannot be discharged from multiple directions in the discharging process at present is solved.

2. The invention is provided with the buffer component, the inclined bars in the buffer component are obliquely arranged from two sides of the material receiving inclined plate to the middle part, when the graphite rod falls onto the material receiving inclined plate, the inclined bars slide to the middle part of the material receiving inclined plate, and when the centered graphite rod continuously falls, the speed reduction transverse bar is used for buffering and reducing the graphite rod, so that the graphite rod is prevented from breaking.

3. According to the invention, the gravity linkage assembly is arranged, when the number of graphite rods received in the storage box at the bottom end of the material receiving inclined plate at one side is larger than that of graphite rods in the storage box at the other side, the bearing arm sinks in the process of changing the graphite rods in the storage box at the other side, the swinging arm is driven to tilt upwards, meanwhile, the lifting rod is pushed upwards, the bearing rod is pushed to the side of the storage box at the other side through the pushing plate at the top of the lifting rod, so that the bearing rod tends to fall into the storage box at the other side, then the graphite rods fall into the storage box with the small number at the other side through the bearing rod, after a certain amount of graphite rods fall, the weight exceeds the original heavier side, the bearing arm is pushed upwards through the storage box, the pushing plate pushes the bearing rod to the original heavier side, the bearing rod tends to tilt upwards, the bearing rod tends to the original heavier side, the material receiving inclined plate is arranged, the gravity linkage assembly is used for controlling the falling direction of the graphite rods according to the number of the graphite rods, the control of the graphite rods is realized through gravity, and the problem that the graphite rods fall into the storage boxes at different directions is more intelligent, and the blanking cannot control the graphite rods accurately.

In summary, the invention has the advantages of being capable of realizing the centered blanking of the graphite rod, buffering and protecting the graphite rod in the blanking process, blanking from a plurality of directions, controlling the falling direction of the graphite rod through gravity change and the like, and is particularly suitable for the field of advanced inorganic nonmetallic materials.

Drawings

The invention is further described with reference to the accompanying drawings:

FIG. 1 is a schematic diagram of a material output sorting apparatus;

FIG. 2 is a schematic view of the structure of the receiving assembly and the buffer assembly;

FIG. 3 is a schematic view of the structure of a dispensing assembly;

FIG. 4 is a schematic structural view of the torsion spring in the dispensing assembly;

FIG. 5 is a schematic structural view of a gravity linkage assembly;

FIG. 6 is an enlarged schematic view of FIG. 5A;

FIG. 7 is a schematic structural view of a spacing assembly;

FIG. 8 is a schematic structural view of a balancing assembly;

FIG. 9 is a schematic view of the cutting mechanism and the pulling assembly;

FIG. 10 is an enlarged schematic view at B in FIG. 9;

FIG. 11 is a schematic view of the direction of rotation of the bin and carrier strip.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to the accompanying drawings.

Example 1

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

As shown in fig. 1 to 11, a material output sorting device comprises a cutting mechanism 1, wherein a material receiving component 2 is arranged at the tail end of the cutting mechanism 1, a distributing component 3 is arranged at the top of the material receiving component 2, a buffer component 4 is arranged on the material receiving component 2, gravity linkage components 5 are arranged on two sides of the lower end of the material receiving component 2, a limit component 6 is arranged above the distributing component 3, a balance component 7 is further arranged in the material receiving component 2, and a traction component 8 is arranged between the cutting mechanism 1 and the distributing component 3; the traction assembly 8 is used for traction of the machined graphite rod 10, the graphite rod 10 is more smoothly taken out from the cutting mechanism 1, the limiting assembly 6 is used for blocking and limiting the distribution assembly 3 which is not used for taking the graphite rod 10, when the graphite rod is not taken out from the beginning, the distribution assembly is prevented from toppling to the side, the distribution assembly 3 is used for taking the graphite rod 10 output from the cutting mechanism 1 and discharging materials from two sides of the receiving assembly 2 downwards, the balancing assembly 7 is used for supporting the receiving assembly 2, the buffer assembly 4 is used for buffering and decelerating the falling graphite rod 10, breakage of the graphite rod 10 is effectively avoided, the integrity of the graphite rod 10 is protected, the gravity linkage assembly 5 is used for intelligently discharging the graphite rod 10 through weight change adjustment of the graphite rod 10 at two sides of the receiving assembly 2, artificial participation is reduced, and the discharging of the graphite rod 10 is more orderly.

As shown in fig. 2, the receiving assembly 2 includes a receiving inclined plate 21, a placement groove 22 disposed at the tail end of the receiving inclined plate 21, a storage box 23 slidably disposed in the placement groove 22, a rotating rod 24 disposed at the top of the receiving inclined plate 21, an empty groove 25 formed on the receiving inclined plate 21, and a square hole 26 formed at one side of the placement groove 22, and the empty groove 21 is formed to avoid interference between the gravity linkage assembly 5 and the receiving inclined plate 21 during operation, so that normal operation of the gravity linkage assembly 5 is ensured.

As shown in fig. 3 and 4, the distribution assembly 3 includes a rotating ring 31, a carrying bar 32, a plurality of sliding grooves 33 formed on the rotating ring 31, and a plurality of supporting bars 34 fixedly arranged at the lower end of the carrying bar 32, the rotating ring 31 is rotatably arranged on the rotating bar 24, a return spring a35 is arranged on the supporting bars 34 and slidably arranged in the sliding grooves 33, the inner wall of the carrying bar 32 is arranged to be a curved surface, a torsion spring 36 is arranged between the rotating ring 31 and the rotating bar 24, the carrying bar 32 can be quickly reset by arranging the torsion spring 36, and the inner wall of the carrying bar 32 is arranged to be a curved surface so as to be more fit when the graphite rod 10 is taken in.

It should be noted that, this embodiment is provided with distribution subassembly 3 and spacing subassembly 6, when distribution subassembly 3 did not connect graphite rod 10, the carrier bar 32 in the distribution subassembly 3 was spacing by spacing board 63 in spacing subassembly 6 to be blocked, after graphite rod 10 whereabouts on carrier bar 32, carrier bar 32 passed through bracing piece 34 and is sunk on swivel ring 31 buffering for carrier bar 32 breaks away from the blocking of spacing board 63, then according to the material receiving swash plate 21 random blowing of the different directional both sides of graphite rod 10 on carrier bar 32 focus position, each subassembly mutually support and have solved the problem that can not follow a plurality of directions blanking to graphite rod 10 unloading in-process at present.

As shown in fig. 2, the buffer assembly 4 includes a plurality of inclined bars 41 disposed on both sides of the inclined receiving plate 21 and a plurality of deceleration bars 42 disposed on the lower ends of the inclined bars 41, and the inclined bars 41 are inclined from both sides of the inclined receiving plate 21 to the middle.

Here, this embodiment is provided with buffer assembly 4, the slope strip 41 in the buffer assembly 4 is by receiving material swash plate 21 both sides slope setting to the middle part, after graphite rod 10 whereabouts is to receiving on the material swash plate 21, slide to receiving the middle part of material swash plate 21 through slope strip 41, when graphite rod 10 in the middle continues to drop, buffer deceleration is carried out to graphite rod 10 by the horizontal strip 42 of slowing down, prevent that graphite rod 10 from breaking, compare with current equipment, set up buffer assembly 4 effectually solve present equipment can not carry out blanking in the middle to graphite rod 10 and can not carry out buffer deceleration's problem to graphite rod 10 of whereabouts in-process, better avoided graphite rod 10 to take place the fracture at blanking in-process.

As shown in fig. 5 and 6, the gravity linkage assembly 5 includes a rotating base 51, a sliding base 52, a swing arm 53 rotatably disposed on the rotating base 51, a bearing arm 54 fixedly disposed at one end of the swing arm 53, a lifting rod 55 rotatably connected to the other end of the swing arm 53, and a pushing plate 56 fixedly disposed at the top of the lifting rod 55, wherein the lifting rod 55 is slidably disposed in the sliding base 52, the lifting rods 55 on both sides are hinged by a linkage arm 57, one side of the pushing plate 56 is disposed as a cambered surface 58, and the lifting rod 55 slides up and down in the empty slot 25.

It should be further noted that, this embodiment is provided with the gravity linkage assembly 5, when the graphite rod 10 in the storage box 23 at the bottom end of the material receiving inclined plate 21 at one side is more than the graphite rod 10 in the storage box 23 at the other side, the carrying arm 54 is sunk in the changing process of the graphite rod 10 in the storage box 23 at the other side, the swinging arm 53 is driven to tilt up, and meanwhile the lifting rod 55 is pushed upwards, the carrying bar 32 is pushed to the side of the storage box 23 at the other side through the pushing plate 56 at the top of the lifting rod 55, so that the carrying bar 32 tends to fall into the storage box 23 at the other side by the carrying bar 32, then the graphite rod 10 falls into the storage box 23 at the other side with less quantity by the carrying bar 32, after a certain quantity of graphite rod 10 falls, the weight exceeds the side with the original heavy weight, the carrying arm 54 is pushed down by the storage box 23, the swinging arm 53 is pushed upwards by the way of the lifting rod 55, the carrying bar 32 is pushed to the side with the push plate 56 towards the side with the original heavy side, so that the carrying bar 32 tends to push the material receiving inclined plate 21 at the one side, the other side, the gravity assembly 5 is arranged, the graphite rod 32 is controlled by the gravity change according to the quantity of the graphite rod 10, the graphite rod 10 falls down, and the graphite rod 10 is controlled to fall into the graphite rod 10, and the graphite rod 10 is not to fall in the direction is controlled accurately, and the graphite rod 10 is not can fall, and the problem is controlled, and the graphite rod is not can fall down in the direction is controlled.

As shown in fig. 7, the limiting assembly 6 includes a bracket 61, a top cover 62 fixedly arranged on the bracket 61, and limiting plates 63 fixedly arranged on two sides of the top cover 62, wherein the top cover 62 is circular and better matches with the graphite rod 10 to fall onto the bearing strip 32 for output.

As shown in fig. 9 and 10, a traction assembly 8 is further arranged between the cutting mechanism 1 and the distribution assembly 3, the traction assembly 8 comprises a supporting frame 81, a supporting block 82 fixedly arranged on the supporting frame 81, an output groove 83 formed in the supporting block 82, a plurality of rollers 84 rotatably arranged in the output groove 83 and a plurality of traction wheels 85 rotatably arranged on the supporting block 82, and the rollers 84 and the traction wheels 85 are matched to enable the graphite rod 10 to be more smooth when discharged from the cutting mechanism 1, and meanwhile the problem that the graphite rod 10 is easy to break when being output is avoided.

As shown in fig. 9, the cutting mechanism 1 includes a processing table 11, a cutting cylinder 12 rotatably provided on the processing table 11, and a motor 13 fixedly provided at a lower end of the processing table 11, the cutting cylinder 12 being connected to the motor 13 by a belt 14.

As shown in fig. 1, the material receiving inclined plate 21 is arranged in a triangular fixed manner from two sides to the middle, so that the stability of the material receiving inclined plate 21 is improved.

Example two

As shown in fig. 8, wherein the same or corresponding parts as those in the first embodiment are given the same reference numerals as those in the first embodiment, only the points of distinction from the first embodiment will be described below for the sake of brevity; the second embodiment is different from the first embodiment in that: the balance assembly 7 is further arranged on the other side of the placement groove 22, the balance assembly 7 comprises a lifting groove 71 formed in the side wall of the placement groove 22, a limiting column 72 fixedly arranged in the lifting groove 71, a supporting plate 73 slidably arranged in the lifting groove 71 and a reset spring b74 arranged on the limiting column 72, the supporting plate 73 can support the storage box 23, the supporting arm 54 is matched to balance the storage box 23, and the graphite rod 10 is prevented from being broken in the storage box 23 due to shaking of the storage box 23.

Here, this embodiment sets up balance assembly 7, through setting up the support of layer board 73 cooperation carrier arm 54 to storage tank 23, reduces storage tank 23 and rocks, avoids graphite rod 10 to fracture in storage tank 23, and after graphite rod 10 was transferred by the staff, storage tank 23 reset through reset spring b74, conveniently next time to the graphite rod 10 access and cooperate gravity linkage assembly 5 to carrying out the interference control to the strip 32 direction.

Working process

Firstly, a traction wheel 85 in a traction assembly 8 is matched with a roller 84 to drag a processed graphite rod 10 from a cutting mechanism 1 to a bearing bar 32 in a distribution assembly, a limiting plate 63 blocks the bearing bar 32, when the graphite rod 10 completely falls into the bearing bar 32, the bearing bar 32 sinks under the gravity of the graphite rod 10 and is separated from the limitation of the limiting plate 63, then the bearing bar 32 randomly leans to a material receiving inclined plate 21 on one side according to the difference of the gravity center positions of the graphite rod 10 on the bearing bar 32, the graphite rod 10 is discharged onto the material receiving inclined plate 21, the graphite rod 10 falling onto the material receiving inclined plate 21 slides towards the middle of the material receiving inclined plate 21 under the action of an inclined bar 41, is buffered under the action of a deceleration transverse bar 42, and finally falls into a material storage box 23 to finish storage;

when a certain amount of graphite rods 10 are picked up by the storage box 23 on one side, the storage box 23 is settled downwards, the bearing arm 54 is pressed downwards to enable the swinging arm 53 to tilt upwards, the lifting rod 55 is pushed upwards, the bearing bar 32 is pushed to the storage box 23 on the other side through the pushing plate 56, the bearing bar 32 is inclined to the storage box 23 on the other side, then the graphite rods 10 are blanked into the storage box 23 on the other side, when the number of the graphite rods 10 picked up by the storage box 23 on the other side exceeds the number of the graphite rods 10 in the storage box 23 on the original side, the bearing bar 32 is inclined to the storage box 23 on the original side again under the swinging of the swinging arm 53 on the other side, blanking is continued, and the above processes are repeated circularly in the falling process of the graphite rods 10, so that the number of the graphite rods 10 in the storage boxes 23 on the two sides is balanced.

In the description of the present invention, it should be understood that the directions or positional relationships indicated by the terms "front and rear", "left and right", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of description and simplification of the description, and do not indicate or imply that the apparatus or component in question must have a specific orientation, be constructed and operated in a specific orientation, and therefore should not be construed as limiting the invention.

Of course, in this disclosure, those skilled in the art will understand that the term "a" or "an" is to be interpreted as "at least one" or "one or more," i.e., in one embodiment, the number of elements may be one, and in another embodiment, the number of elements may be multiple, and the term "a" is not to be construed as limiting the number.

While the invention has been described with reference to the preferred embodiments, it should be noted that the invention is not limited to the above embodiments, and that various changes and modifications can be made by those skilled in the art without departing from the structure of the invention, and these should also be regarded as the scope of the invention without affecting the effect and practicality of the implementation of the invention.

Claims

1. A material output sorting device comprising a cutting mechanism (1), characterized in that: the tail end of the cutting mechanism (1) is provided with a material receiving assembly (2), the top of the material receiving assembly (2) is provided with a distribution assembly (3), the material receiving assembly (2) is provided with a buffer assembly (4), two sides of the lower end of the material receiving assembly (2) are respectively provided with a gravity linkage assembly (5), and a limit assembly (6) is arranged above the distribution assembly (3); the limiting assembly (6) is used for blocking and limiting the distribution assembly (3) which does not receive the graphite rods (10), the distribution assembly (3) receives the graphite rods (10) output from the cutting mechanism (1) and downwards sinks to discharge materials at two sides of the receiving assembly (2), the buffer assembly (4) is used for buffering and decelerating the falling graphite rods (10), and the gravity linkage assembly (5) is used for intelligently discharging the graphite rods (10) by adjusting the discharging direction of the distribution assembly (3) according to the weight change of the graphite rods (10) at two sides of the receiving assembly (2); the material receiving assembly (2) comprises a material receiving inclined plate (21), a placement groove (22) arranged at the tail end of the material receiving inclined plate (21), a storage box (23) arranged in the placement groove (22) in a sliding manner, a rotating rod (24) arranged at the top of the material receiving inclined plate (21), an empty groove (25) formed in the material receiving inclined plate (21) and a square hole (26) formed in one side of the placement groove (22); the gravity linkage assembly (5) comprises a rotating seat (51), a sliding seat (52), a swinging arm (53) rotatably arranged on the rotating seat (51), a bearing arm (54) fixedly arranged at one end of the swinging arm (53), a lifting rod (55) rotatably connected with the other end of the swinging arm (53) and a pushing plate (56) fixedly arranged at the top of the lifting rod (55), the lifting rod (55) is slidably arranged in the sliding seat (52), the lifting rods (55) at two sides are hinged through the linkage arm (57), one side of the pushing plate (56) is provided with an arc surface (58), and the lifting rod (55) vertically slides in the empty groove (25); the limiting assembly (6) comprises a bracket (61), a top cover (62) fixedly arranged on the bracket (61) and limiting plates (63) fixedly arranged on two sides of the top cover (62).

2. A material output sorting device according to claim 1, characterized in that the distribution assembly (3) comprises a rotating ring (31), a bearing strip (32), a plurality of sliding grooves (33) formed in the rotating ring (31) and a plurality of supporting rods (34) fixedly arranged at the lower end of the bearing strip (32), the rotating ring (31) is rotatably arranged on the rotating rod (24), a return spring a (35) is arranged on the supporting rods (34) and is slidably arranged in the sliding grooves (33), the inner wall of the bearing strip (32) is provided with a curved surface, and a torsion spring (36) is arranged between the rotating ring (31) and the rotating rod (24).

3. A material output sorting apparatus according to claim 1, characterized in that the buffer assembly (4) comprises a plurality of inclined bars (41) arranged at both sides of the material receiving inclined plate (21) and a plurality of deceleration cross bars (42) arranged at the lower ends of the inclined bars (41), wherein the inclined bars (41) are inclined from both sides of the material receiving inclined plate (21) to the middle.

4. A material output sorting apparatus according to claim 1, wherein the other side of the placement groove (22) is further provided with a balancing component (7), the balancing component (7) comprises a lifting groove (71) formed on the side wall of the placement groove (22), a limit post (72) fixedly arranged in the lifting groove (71), a supporting plate (73) slidingly arranged in the lifting groove (71) and a return spring b (74) arranged on the limit post (72).

5. A material output sorting apparatus according to claim 1, characterized in that a traction assembly (8) is further arranged between the cutting mechanism (1) and the distribution assembly (3), the traction assembly (8) comprises a support frame (81), a support block (82) fixedly arranged on the support frame (81), an output groove (83) arranged on the support block (82), a plurality of rollers (84) rotatably arranged in the output groove (83) and a plurality of traction wheels (85) rotatably arranged on the support block (82).

6. A material output sorting apparatus according to claim 1, characterized in that the cutting mechanism (1) comprises a processing table (11), a cutting cylinder (12) rotatably arranged on the processing table (11) and a motor (13) fixedly arranged at the lower end of the processing table (11), the cutting cylinder (12) being connected with the motor (13) by a belt (14).

7. A material output sorting apparatus according to claim 1, characterized in that the material receiving sloping plate (21) is arranged in a triangular fixed manner with inclination from both sides to the middle.