CN111686879A

CN111686879A - Mill uses crushing equipment

Info

Publication number: CN111686879A
Application number: CN202010583884.3A
Authority: CN
Inventors: 盛国
Original assignee: Taiqing Ginseng Antler Line In Harbin Sanke Traditional Chinese Medicine Market
Current assignee: Taiqing Ginseng Antler Line In Harbin Sanke Traditional Chinese Medicine Market
Priority date: 2020-06-23
Filing date: 2020-06-23
Publication date: 2020-09-22

Abstract

The invention relates to crushing equipment, in particular to crushing equipment for a factory, which comprises a conveying mechanism, a primary crushing mechanism, a secondary crushing mechanism and an intermittent output mechanism, wherein the equipment can convey raw materials into a crushing barrel, can crush the raw materials secondarily, can automatically output the raw materials smaller than a crushing output hole onto a crushing output plate, can output the intermittent on the crushing output plate, is connected with the primary crushing mechanism, the primary crushing mechanism is connected with the secondary crushing mechanism, the secondary crushing mechanism is connected with the conveying mechanism, the intermittent output mechanism is connected with the conveying mechanism, and the primary crushing mechanism is connected with the intermittent output mechanism.

Description

Mill uses crushing equipment

Technical Field

The invention relates to crushing equipment, in particular to crushing equipment for a factory.

Background

When raw materials in a factory are crushed, insufficient crushing often occurs, the flow is relatively complex, but no good crushing equipment exists in the market, so that the crushing equipment for the factory is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing the crushing equipment for the factory, the equipment can convey raw materials into a crushing barrel, the equipment can carry out secondary crushing on the raw materials, the equipment can automatically output the raw materials smaller than a crushing output hole onto a crushing output plate, and the equipment can intermittently output the raw materials on the crushing output plate.

In order to solve the technical problems, the invention relates to crushing equipment, in particular to crushing equipment for a factory, which comprises a conveying mechanism, a primary crushing mechanism, a secondary crushing mechanism and an intermittent output mechanism, wherein the equipment can convey raw materials into a crushing barrel, can perform secondary crushing on the raw materials, can automatically output the raw materials smaller than a crushing output hole onto a crushing output plate, and can output the intermittent materials on the crushing output plate.

The conveying mechanism is connected with the primary crushing mechanism, the primary crushing mechanism is connected with the secondary crushing mechanism, the secondary crushing mechanism is connected with the conveying mechanism, the intermittent output mechanism is connected with the conveying mechanism, and the primary crushing mechanism is connected with the intermittent output mechanism.

As a further optimization of the technical scheme, the invention relates to a crushing device for factories, which comprises a conveying motor, a transmission shaft a, a friction column, a transmission shaft b, a conveyor belt, a limit plate a, a rotating plate mechanism, a limit block, a limit plate b, a transmission friction wheel, a transmission shaft c, a transmission mounting plate a, a transmission mounting plate b, a sliding door mechanism and a crushing barrel, wherein the conveying motor is connected with the transmission shaft a, the transmission shaft a is connected with the friction column, the friction column is connected with the transmission shaft b, the transmission shaft b is connected with the transmission mounting plate b through a bearing, the conveyor belt is connected with the friction column, the limit plate a is connected with the conveyor belt, the rotating plate mechanism is connected with the conveyor belt, the limit block is connected with the conveyor belt, the limit plate b is connected with the conveyor belt, the transmission friction wheel is connected with the transmission shaft c, the conveying mounting plate b is connected with the transmission shaft b through a bearing, the sliding door mechanism is connected with the crushing barrel, the crushing barrel is connected with the conveying mounting plate a, the conveying motor is connected with the conveying mounting plate a, the limiting plate a is connected with the rotating plate mechanism, the limiting plate a is connected with the limiting block, the limiting plate a is connected with the limiting plate b, and the conveying mounting plate b is connected with the crushing barrel; the rotating plate mechanism comprises a sliding plate, a hinge and a limit tension spring, the sliding plate is connected with the limit plate a in a sliding mode, the sliding plate is hinged with the conveyor belt through the hinge, and one end of the limit tension spring is connected with the sliding plate while the other end of the limit tension spring is connected with the conveyor belt; the sliding door mechanism comprises a sliding door, a sliding friction plate, a sliding door sliding rail, a sliding door connecting plate a, a sliding reset column, a sliding door connecting plate b and a sliding reset spring, wherein the sliding door is connected with the sliding friction plate, the sliding friction plate is in friction connection with a transmission friction wheel, the sliding door sliding rail is in sliding connection with the sliding door, the sliding door connecting plate a is connected with the sliding door, the sliding reset column is connected with the sliding door connecting plate a, the sliding door connecting plate b is in sliding connection with the sliding reset column, the sliding reset spring is sleeved on the sliding reset column and limited on the sliding door connecting plate a and the sliding door connecting plate b, the sliding door is in sliding connection with the crushing barrel, the sliding door connecting plate a is in sliding connection with the crushing barrel, and the sliding door connecting plate b is connected with.

As a further optimization of the technical scheme, the invention relates to a crushing device for a factory, wherein a primary crushing mechanism comprises a crushing motor a, a motor shaft, a crushing connecting plate a, a crushing connecting block, a rotary inclined plate, a rotary circular plate limiting strip, a crushing plate, a crushing output hole, a crushing motor mounting plate and an upper side sealing plate, wherein the crushing motor a is connected with the motor shaft, the motor shaft is connected with the crushing connecting plate a, the crushing connecting plate a is connected with the crushing connecting block, the crushing connecting block is connected with the rotary inclined plate, the rotary inclined plate is connected with a crushing barrel in a sliding manner, the rotary circular plate is connected with the rotary circular plate limiting strip in a sliding manner, the rotary circular plate limiting strip is connected with the crushing barrel, the crushing plate is connected with the connecting block, the crushing output plate is connected with the crushing connecting block, the crushing output hole is, the upper side sealing plate is connected with the crushing barrel, the rotary circular plate is connected with a bearing of the crushing barrel, the crushing plate is connected with the crushing barrel in a sliding mode, the crushing output plate is connected with the crushing barrel, the crushing motor mounting plate is connected with the crushing barrel, and the upper side sealing plate is connected with the crushing barrel.

As further optimization of the technical scheme, the invention relates to a crushing device for a factory, wherein a secondary crushing mechanism comprises a crushing motor b, a crushing motor shaft, a crushing belt a, a crushing transmission shaft connecting block and a crushing transmission shaft, belt b, the spliced pole, broken post, spliced pole bearing block, broken transmission shaft connecting plate, broken motor b is connected with broken motor shaft, broken motor shaft and broken belt a friction joint, broken belt a passes broken transmission shaft connecting block and broken transmission shaft friction joint, broken transmission shaft connecting block is connected with broken transmission shaft bearing, belt b passes broken transmission shaft connecting block and broken transmission shaft friction joint, spliced pole and belt b friction joint, broken post is connected with the spliced pole, spliced pole bearing block is connected with spliced pole bearing, broken transmission shaft connecting plate is connected with broken transmission shaft bearing, broken motor b is connected with rotatory plectane.

As a further optimization of the technical scheme, the invention relates to a crushing device for factories, wherein the intermittent output mechanism comprises a compression plate, an output reset shaft, an output spring, a connecting plate a, an output friction wheel a, an output rotating shaft, a torsion spring, a reverse gear a, a reverse gear b, an output gear shaft, a connecting plate b, an output belt, a friction wheel shaft, a friction wheel b, a friction plate b, a connecting plate c, a connecting plate d, an output port, a connecting plate e and a connecting plate f, wherein the compression plate is connected with the output reset shaft, the output reset shaft is in sliding connection with the connecting plate a, the output spring is sleeved on the output reset shaft and limited on the compression plate and the connecting plate a, the connecting plate a is connected with the connecting plates b at two sides, the output friction plate a is connected with the compression plate, the output friction wheel a is connected with the output rotating shaft, the torsion spring is sleeved on the output rotating shaft, one end of the torsion spring is connected with the output friction wheel a, the other end of the torsion spring is connected with the reverse gear a, the reverse gear a is meshed with the reverse gear b, the reverse gear b is connected with the output gear shaft, the output gear shaft is connected with a connecting plate b in a bearing mode, the connecting plate b is connected with a friction wheel shaft in a bearing mode, the output belt is connected with an output gear shaft in a friction mode, the friction wheel shaft is connected with the output belt in a friction mode, the friction wheel b is connected with a friction wheel shaft, the friction plate b is connected with the compression plate, the connecting plate c is connected with the connecting plate a, the connecting plate d is connected with the output port, the output port is connected with the connecting plate b, the connecting plate e is connected with the connecting plate a, the connecting plate f is connected with the output rotating, connecting plate c is connected with the delivery outlet, and connecting plate d is connected with broken bucket, and connecting plate e is connected with connecting plate f.

According to the technical scheme, the crushing equipment for the factory is further optimized, the limiting plate a, the limiting block and the limiting plate b are made of rubber plates capable of elastically deforming, and the rubber plates are made of unidirectional rubber wires.

The crushing equipment for the factory has the beneficial effects that:

according to the crushing equipment for the factory, disclosed by the invention, the equipment can convey the raw materials into the crushing barrel, the equipment can carry out secondary crushing on the raw materials, the equipment can automatically output the raw materials smaller than the crushing output hole onto the crushing output plate, and the equipment can intermittently output the raw materials on the crushing output plate.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a first schematic structural diagram of a crushing plant for a plant according to the present invention.

Fig. 2 is a schematic structural diagram of a crushing plant according to the present invention.

Fig. 3 is a first schematic structural diagram of a conveying mechanism 1 of a crushing plant for a factory according to the present invention.

Fig. 4 is a schematic structural diagram of a conveying mechanism 1 of a crushing plant for a factory according to the second embodiment of the present invention.

Fig. 5 is a third schematic structural diagram of the conveying mechanism 1 of the crushing plant for a factory according to the present invention.

Fig. 6 is a schematic view of the construction of crushing barrels 1-15 of a crushing plant for a factory according to the present invention.

Fig. 7 is a fourth schematic structural diagram of the conveying mechanism 1 of the crushing plant for a factory according to the present invention.

Fig. 8 is a schematic view of the structure of a rotating plate mechanism 1-7 of a crushing plant for a plant according to the present invention.

Fig. 9 is a schematic view of the structure of a sliding door mechanism 1-14 of a crushing plant for a plant according to the present invention.

Fig. 10 is a first schematic structural diagram of a primary crushing mechanism 2 of a crushing plant according to the present invention.

Fig. 11 is a second schematic structural diagram of the primary crushing mechanism 2 of the crushing plant of the present invention.

Fig. 12 is a third schematic structural diagram of the primary crushing mechanism 2 of the crushing plant of the present invention.

Fig. 13 is a first schematic structural diagram of a secondary crushing mechanism 3 of a crushing plant for a factory according to the present invention.

Fig. 14 is a second schematic structural diagram of a secondary crushing mechanism 3 of a crushing plant for a factory according to the present invention.

Fig. 15 is a first schematic structural diagram of the intermittent output mechanism 4 of the crushing plant for a factory according to the invention.

Fig. 16 is a second schematic structural diagram of the intermittent output mechanism 4 of the crushing plant for a factory according to the present invention.

Fig. 17 is a schematic view of the output reset shaft 4-2 of a plant crushing apparatus according to the present invention.

In the figure: a transfer mechanism 1; a transfer motor 1-1; a transmission shaft a 1-2; 1-3 of a friction column; a transmission shaft b 1-4; a conveyor belt 1-5; the limiting plate a 1-6; a rotating plate mechanism 1-7; a slide plate 1-7-1; 1-7-2 parts of a hinge; 1-7-3 of a limit tension spring; 1-8 parts of a limiting block; a limit plate b 1-9; 1-10 parts of a transmission friction wheel; a drive shaft c 1-11; transport mounting board a 1-12; the delivery mounting plate b 1-13; sliding door mechanisms 1-14; a sliding door 1-14-1; sliding friction plates 1-14-2; a sliding door sliding rail 1-14-3; a sliding door connecting plate a 1-14-4; sliding reset columns 1-14-5; a sliding door connecting plate b 1-14-6; sliding return springs 1-14-7; 1-15 parts of a crushing barrel; a primary crushing mechanism 2; a crushing motor a 2-1; a motor shaft 2-2; crushing the connecting plate a 2-3; crushing the connection blocks 2-4; rotating the inclined plate 2-5; rotating the circular plate 2-6; rotating the circular plate limiting strips 2-7; 2-8 parts of a crushing plate; 2-9 parts of a crushing output plate; 2-10 parts of a crushing output hole; a crushing motor mounting plate 2-11; upper side sealing plates 2-12; a secondary crushing mechanism 3; a crushing motor b 3-1; 3-2 parts of a crushing motor shaft; a crushing belt a 3-3; 3-4 parts of a connecting block of a crushing transmission shaft; 3-5 parts of a crushing transmission shaft; belt b 3-6; connecting columns 3-7; 3-8 parts of a crushing column; connecting column bearing blocks 3-9; 3-10 parts of a crushing transmission shaft connecting plate; an intermittent output mechanism 4; a compression plate 4-1; an output reset shaft 4-2; an output spring 4-3; connection board a 4-4; output friction plate a 4-5; output friction wheel a 4-6; an output rotary shaft 4-7; 4-8 parts of a torsion spring; reverse gear a 4-9; reverse gear b 4-10; an output gear shaft 4-11; connecting plate b 4-12; 4-13 of an output belt; 4-14 of friction wheel shaft; friction wheel b 4-15; friction plates b 4-16; connecting plate c 4-17; connecting plate d 4-18; output ports 4-19; connecting plate e 4-20; web f 4-21.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, and fig. 17, and the present invention relates to a crushing apparatus, and more specifically, to a crushing apparatus for a plant, including a conveying mechanism 1, a primary crushing mechanism 2, a secondary crushing mechanism 3, and an intermittent discharge mechanism 4, the apparatus being capable of conveying a raw material into a crushing barrel, the apparatus being capable of secondarily crushing the raw material, the apparatus being capable of automatically discharging the raw material smaller than a crushing output hole onto a crushing output plate, and the apparatus being capable of intermittently discharging the raw material on the crushing output plate.

The conveying mechanism 1 is connected with the primary crushing mechanism 2, the primary crushing mechanism 2 is connected with the secondary crushing mechanism 3, the secondary crushing mechanism 3 is connected with the conveying mechanism 1, the intermittent output mechanism 4 is connected with the conveying mechanism 1, and the primary crushing mechanism 2 is connected with the intermittent output mechanism 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes the embodiment, where the conveying mechanism 1 includes a conveying motor 1-1, a transmission shaft a1-2, a friction column 1-3, a transmission shaft b1-4, a transmission belt 1-5, a limit plate a1-6, a rotating plate mechanism 1-7, a limit block 1-8, a limit plate b1-9, a transmission friction wheel 1-10, a transmission shaft c1-11, a transmission mounting plate a1-12, a transmission mounting plate b1-13, a sliding door mechanism 1-14, a crushing barrel 1-15, the conveying motor 1-1 is connected with the transmission shaft a1-2, a transmission shaft a1-2 is connected with a friction column 1-3, the friction column 1-3 is connected with a transmission shaft b1-4, a transmission shaft b1-4 is connected with a transmission mounting plate b1-13 through a bearing, a transmission belt 1-5 is connected with the friction column 1-3 through a friction, a limit plate a1-6 is connected with a transmission belt 1-5, a rotating plate mechanism 1-7 is connected with the transmission belt 1-5, a limit block 1-8 is connected with the transmission belt 1-5, a limit block b1-9 is connected with the transmission belt 1-5, a transmission friction wheel 1-10 is connected with a transmission shaft c1-11, a transmission shaft c1-11 is connected with a transmission mounting plate a1-12 through a bearing, a transmission mounting plate a1-12 is connected with a transmission shaft a1-2 through a bearing, a transmission mounting plate b1-13 is connected, the sliding door mechanism 1-14 is connected with the crushing barrel 1-15, the crushing barrel 1-15 is connected with the transmission mounting plate a1-12, the transmission motor 1-1 is connected with the transmission mounting plate a1-12, the limiting plate a1-6 is connected with the rotating plate mechanism 1-7, the limiting plate a1-6 is connected with the limiting block 1-8, the limiting plate a1-6 is connected with the limiting plate b1-9, and the transmission mounting plate b1-13 is connected with the crushing barrel 1-15; the rotating plate mechanism 1-7 comprises a sliding plate 1-7-1, a hinge 1-7-2 and a limit tension spring 1-7-3, the sliding plate 1-7-1 is connected with a limit plate a1-6 in a sliding mode, the sliding plate 1-7-1 is hinged with a conveyor belt 1-5 through the hinge 1-7-2, one end of the limit tension spring 1-7-3 is connected with the sliding plate 1-7-1, and the other end of the limit tension spring is connected with the conveyor belt 1-5; the sliding door mechanism 1-14 comprises a sliding door 1-14-1, a sliding friction plate 1-14-2, a sliding door slide rail 1-14-3, a sliding door connecting plate a1-14-4, a sliding reset column 1-14-5, a sliding door connecting plate b1-14-6 and a sliding reset spring 1-14-7, wherein the sliding door 1-14-1 is connected with the sliding friction plate 1-14-2, the sliding friction plate 1-14-2 is connected with a transmission friction wheel 1-10 in a friction way, the sliding door slide rail 1-14-3 is connected with the sliding door 1-14-1 in a sliding way, the sliding door connecting plate a1-14-4 is connected with the sliding door 1-14-1, the sliding reset column 1-14-5 is connected with the sliding door connecting plate a1-14-4, a sliding door connecting plate b1-14-6 is in sliding connection with a sliding reset column 1-14-5, a sliding reset spring 1-14-7 is sleeved on the sliding reset column 1-14-5 and limited on a sliding door connecting plate a1-14-4 and a sliding door connecting plate b1-14-6, a sliding door 1-14-1 is in sliding connection with a crushing barrel 1-15, a sliding door connecting plate a1-14-4 is in sliding connection with the crushing barrel 1-15, a sliding door connecting plate b1-14-6 is connected with the crushing barrel 1-15, equipment can convey raw materials into the crushing barrel, a conveying motor 1-1 works, the conveying motor 1-1 works to drive a transmission shaft a1-2 to rotate, the transmission shaft a1-2 rotates to drive a friction column 1-3 to rotate, the friction column 1-3 on the other side rotates synchronously under the action of the conveyor belt 1-5 and the transmission shaft b1-4, the conveyor belt 1-5 moves towards the friction column 1-3 on one side, the conveyor belt 1-5 moves to drive the sliding plate 1-7-1 to move through the hinge 1-7-2, the sliding plate 1-7-1 is perpendicular to the conveyor belt 1-5 under the action of the limit tension spring 1-7-3, raw materials are placed on the sliding plate 1-7-1, the raw materials are conveyed along with the movement of the sliding plate 1-7-1, the conveyor belt 1-5 moves and simultaneously drives the limit plate a1-6 to move, the limit plate a1-6 moves to be in contact with the transmission friction wheel 1-10, and at the moment, the limit plate a1-6 is in friction connection with the transmission friction wheel 1-10, the limiting plate a1-6 moves to drive the transmission friction wheel 1-10 to rotate by taking the transmission shaft c1-11 as an axis, the transmission friction wheel 1-10 rotates to drive the sliding friction plate 1-14-2 to move upwards or downwards, when the sliding friction plate 1-14-2 moves upwards, the sliding friction plate 1-14-2 drives the sliding door 1-14-1 to move upwards by taking the sliding door sliding rail 1-14-3 as a limitation, the sliding door 1-14-1 is gradually opened at the moment, the sliding plate 1-7-1 continues to move to the lower end of the opening of the crushing barrel 1-15, the previous sliding plate 1-7-1 becomes an inclined plate of the next sliding plate 1-7-1 at the moment, the material on the sliding plate 1-7-1 is conveyed into the crushing barrel 1-15, the sliding door 1-14-1 moves and drives the sliding door connecting plate a1-14-4 to move at the same time, the sliding door connecting plate a1-14-4 moves and drives the sliding return spring 1-14-7 to move, the sliding door 1-14-1 can reset under the action of the sliding reset spring 1-14-7, namely the limiting plate a1-6 completely passes through the position of the transmission friction wheel 1-10, the opening on the crushing barrel 1-15 is sealed again by the sliding door 1-14-1 when the transmission friction wheel 1-10 is not stressed, because the limiting plate a1-6 is made of rubber with unidirectional threads, therefore, when the limit plate a1-6 passes through the position of the friction column 1-3, the limit plate a1-6 cannot bend towards two sides, and the conveying mounting plates a1-12 on the two sides further limit the limit plates a 1-6.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes the first embodiment, where the primary crushing mechanism 2 includes a crushing motor a2-1, a motor shaft 2-2, a crushing connecting plate a2-3, a crushing connecting block 2-4, a swash plate 2-5, a rotating circular plate 2-6, a rotating circular plate stopper bar 2-7, a crushing plate 2-8, a crushing output plate 2-9, a crushing output hole 2-10, a crushing motor mounting plate 2-11, and an upper side sealing plate 2-12, the crushing motor a2-1 is connected to the motor shaft 2-2, the motor shaft 2-2 is connected to the crushing connecting plate a2-3, the crushing connecting plate a2-3 is connected with a crushing connecting block 2-4, the crushing connecting block 2-4 is connected with a rotating inclined plate 2-5, the rotating inclined plate 2-5 is connected with a crushing barrel 1-15 in a sliding way, the rotating circular plate 2-6 is connected with a rotating circular plate limiting strip 2-7 in a sliding way, the rotating circular plate limiting strip 2-7 is connected with the crushing barrel 1-15, the crushing plate 2-8 is connected with the connecting block 2-4, the crushing output plate 2-9 is connected with the crushing connecting block 2-4, the crushing output hole 2-10 is arranged on the crushing output plate 2-9, the crushing motor mounting plate 2-11 is connected with a crushing motor a2-1, the upper side sealing plate 2-12 is connected with the crushing barrel 1-15, the rotating circular plate 2-6 is connected with the crushing barrel 1-15 through a bearing, the crushing plate 2-8 is connected with the crushing barrel 1-15 in a sliding mode, the crushing output plate 2-9 is connected with the crushing barrel 1-15, the crushing motor mounting plate 2-11 is connected with the crushing barrel 1-15, and the upper side sealing plate 2-12 is connected with the crushing barrel 1-15.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes the embodiment, wherein the secondary crushing mechanism 3 comprises a crushing motor b3-1, a crushing motor shaft 3-2, a crushing belt a3-3, a crushing transmission shaft connecting block 3-4, a crushing transmission shaft 3-5, a belt b3-6, a connecting column 3-7, a crushing column 3-8, a connecting column bearing block 3-9, a crushing transmission shaft connecting block 3-10, a crushing motor b3-1 is connected with a crushing motor shaft 3-2, a crushing motor shaft 3-2 is frictionally connected with a crushing belt a3-3, a crushing belt a3-3 is frictionally connected with a crushing transmission shaft 3-5 through a crushing transmission shaft connecting block 3-4, the crushing transmission shaft connecting block 3-4 is in bearing connection with the crushing transmission shaft 3-5, the belt b3-6 penetrates through the crushing transmission shaft connecting block 3-4 to be in friction connection with the crushing transmission shaft 3-5, the connecting column 3-7 is in friction connection with the belt b3-6, the crushing column 3-8 is connected with the connecting column 3-7, the connecting column bearing block 3-9 is in bearing connection with the connecting column 3-7, the crushing transmission shaft connecting plate 3-10 is in bearing connection with the crushing transmission shaft 3-5, the crushing motor b3-1 is connected with the rotating circular plate 2-6, the equipment can perform secondary crushing on raw materials, the crushing motor a2-1 works, the crushing motor a2-1 works to drive the motor shaft 2-2 to rotate, the motor shaft 2-2 rotates to drive the crushing connecting plate a 36, the crushing connecting plate a2-3 rotates to drive the crushing connecting block 2-4 to rotate, the crushing connecting block 2-4 rotates to drive the rotating inclined plate 2-5 and the crushing plate 2-8 to rotate, when the rotating inclined plate 2-5 rotates, the raw material is crushed, the crushing plate 2-8 rotates to crush for the first time, at the moment, the crushing motor b3-1 works, the crushing motor b3-1 works to drive the crushing motor shaft 3-2 to rotate, the crushing motor shaft 3-2 drives the crushing transmission shaft 3-5 to rotate through the crushing belt a3-3, the crushing transmission shaft 3-5 rotates to drive the connecting column 3-7 to rotate through the belt b3-6, the connecting column 3-7 rotates to drive the crushing column 3-8 to rotate, and the crushed raw material is crushed for the second time when the crushing column 3-8 rotates, the equipment can automatically output the raw materials smaller than the crushing output hole to the crushing output plate, and when the raw materials crushed twice are crushed into the materials smaller than the crushing output hole 2-10, the raw materials smaller than the crushing output hole 2-10 can be output to the crushing output plate 2-9 from the crushing output hole under the action of the rotary inclined plate 2-5 and the crushing plate 2-8.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17. the embodiment further describes that the intermittent output mechanism 4 includes a compression plate 4-1, an output reset shaft 4-2, an output spring 4-3, a connecting plate a4-4, an output friction plate a4-5, an output friction wheel a4-6, an output rotating shaft 4-7, a torsion spring 4-8, a counter gear a4-9, a counter gear b4-10, an output gear shaft 4-11, a connecting plate b4-12, an output belt 4-13, a friction wheel shaft 4-14, a friction wheel b4-15, a friction plate b4-16, a connecting plate c4-17, 17, A connecting plate d4-18, an output port 4-19, a connecting plate e4-20, a connecting plate f4-21, a pressing plate 4-1 connected with an output reset shaft 4-2, an output reset shaft 4-2 connected with a connecting plate a4-4 in a sliding way, an output spring 4-3 sleeved on the output reset shaft 4-2 and limited on the pressing plate 4-1 and the connecting plate a4-4, a connecting plate a4-4 connected with connecting plates b4-12 at two sides, an output friction plate a4-5 connected with the pressing plate 4-1, an output friction wheel a4-6 connected with an output rotating shaft 4-7, an output rotating shaft 4-7 connected with a reverse gear a4-9, a torsion spring 4-8 sleeved on the output rotating shaft 4-7, one end of the torsion spring 4-8 connected with the output friction wheel a4-6 and the other end connected with the reverse gear a4-9, a reverse gear a4-9 is meshed with a reverse gear b4-10, a reverse gear b4-10 is connected with an output gear shaft 4-11, an output gear shaft 4-11 is in bearing connection with a connecting plate b4-12, a connecting plate b4-12 is in bearing connection with a friction gear shaft 4-14, an output belt 4-13 is in friction connection with an output gear shaft 4-11, a friction gear shaft 4-14 is in friction connection with an output belt 4-13, a friction wheel b4-15 is in friction connection with a friction gear shaft 4-14, a friction plate b4-16 is connected with a compression plate 4-1, a connecting plate c4-17 is connected with a connecting plate a4-4, a connecting plate d4-18 is connected with an output port 4-19, an output port 4-19 is connected with a connecting plate b4-12, a connecting plate e4-20 is connected with a connecting plate 4-, the connecting plate f4-21 is connected with an output rotating shaft 4-7 through a bearing, the compression plate 4-1 is connected with the crushing output plate 2-9 in a sliding way, the output friction plate a4-5 is connected with the friction wheel b4-15 in a friction way, the friction plate b4-16 is connected with the crushing output plate 2-9 in a friction way, the connecting plate c4-17 is connected with the output port 4-19, the connecting plate d4-18 is connected with the crushing barrel 1-15, the connecting plate e4-20 is connected with the connecting plate f4-21, the device can intermittently output on the crushing output plate, the raw materials output to the crushing output plate 2-9 are continuously increased, the compression plate 4-1 is continuously compressed, the compression plate 4-1 is enabled to move towards the connecting plate a4-4 direction, the compression plate 4-1 continuously moves under the limitation of the output reset shaft 4-2 and the output spring 4-, when the compression plate 4-1 moves, the output friction plate a4-5 is driven to move simultaneously, when the output friction plate a4-5 moves to the position of the reverse gear a4-9, the output friction plate a4-9 is in friction connection with the reverse gear a4-9, the reverse gear a4-9 rotates, the reverse gear a4-9 rotates the output rotating shaft 4-7 and drives the output friction wheel a4-6 to rotate, when the output friction wheel a4-6 and the reverse gear a4-9 rotate simultaneously, the torsion spring 4-8 generates torsion, the reverse gear a4-9 also drives the reverse gear b4-10 to rotate by taking the output gear shaft 4-11 as a shaft, the output gear shaft 4-11 rotates synchronously, the output gear shaft 4-11 rotates and drives the friction gear shaft 4-14 to rotate by the output belt 4-13, the friction gear shaft 4-14 rotates and drives the friction wheel b4-15 to rotate, when the output friction plate a4-5 continues to move to a position which is not in friction connection with the output friction wheel a4-6, the torsion of the torsion spring 4-8 is instantly released to enable the reverse gear a4-9 to reversely rotate, the reverse gear a4-9 drives the reverse gear b4-10 to instantly rotate at a high speed, the reverse gear b4-10 rotates to drive the friction wheel b4-15 to rotate through the output belt 4-13 and the friction wheel shaft 4-14, at the moment, the friction plate b4-16 driven by the compression plate 4-1 is in friction connection with the friction wheel b4-15, the friction wheel b4-15 rotates at a high speed to drive the friction plate b4-16 to rapidly press the compression plate 4-1 towards the connecting plate a4-4 direction, so that the compression plate 4-1 rapidly moves towards the connecting plate a4-4 and moves to a position which exceeds the output port 4-19, the friction plate b4-16 and the friction wheel b4-15 are not in friction connection, raw materials are released through the output port 4-19 instantly, the compression plate 4-1 is reset quickly under the action of the output spring 4-3, the output friction plate a4-5 and the output friction wheel a4-6 are in friction connection again when the compression plate 4-1 is reset, the compression plate 4-1 is decelerated, the friction wheel b4-15 and the friction plate b4-16 are in friction connection to decelerate the compression plate 4-1, the output friction plate a4-5 and the output friction wheel a4-6 are not in friction connection after reset, the friction wheel b4-15 and the friction plate b4-16 are not in friction connection, reverse torsion generated by the torsion spring 4-8 in movement is released, and the movement is repeated.

The sixth specific implementation mode:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, and fig. 17, and the present embodiment further describes the present embodiment, in which the stopper plates a1-6, the stopper plates 1-8, and the stopper plates b1-9 are made of an elastically deformable rubber plate, and the rubber plate is made of a unidirectional rubber wire.

The working principle of the device is as follows: the equipment can convey raw materials into a crushing barrel, a conveying motor 1-1 works, the conveying motor 1-1 works to drive a transmission shaft a1-2 to rotate, the transmission shaft a1-2 rotates to drive a friction column 1-3 to rotate, the friction column 1-3 on the other side rotates synchronously under the action of a conveyor belt 1-5 and a transmission shaft b1-4, the conveyor belt 1-5 moves towards the friction column 1-3 on one side, the conveyor belt 1-5 moves to drive a sliding plate 1-7-1 to move through a hinge 1-7-2, the sliding plate 1-7-1 is vertical to the conveyor belt 1-5 under the action of a limit tension spring 1-7-3, the raw materials are placed on the sliding plate 1-7-1 and are conveyed along with the movement of the sliding plate 1-7-1, the conveyor belt 1-5 moves and simultaneously drives the limit plate a1-6 to move, when the limit plate a1-6 moves to be in contact with the transmission friction wheel 1-10, the limit plate a1-6 is in friction connection with the transmission friction wheel 1-10, the limit plate a1-6 moves to drive the transmission friction wheel 1-10 to rotate by taking the transmission shaft c1-11 as a shaft, the transmission friction wheel 1-10 rotates to drive the sliding friction plate 1-14-2 to move upwards or downwards, when the sliding friction plate 1-14-2 moves upwards, the sliding friction plate 1-14-2 drives the sliding door 1-14-1 to move upwards by taking the sliding door sliding rail 1-14-3 as a limit, at the moment, the sliding door 1-14-1 is gradually opened, the sliding plate 1-7-1 continues to move to the lower end of the opening of the crushing barrel 1-15, at the moment, the front sliding plate 1-7-1 becomes an inclined plate of the rear sliding plate 1-7-1, the material on the sliding plate 1-7-1 is conveyed into the crushing barrel 1-15, the sliding door 1-14-1 moves and simultaneously drives the sliding door connecting plate a1-14-4 to move, the sliding door connecting plate a1-14-4 moves and drives the sliding return spring 1-14-7 to move, the sliding door 1-14-1 can be reset under the action of the sliding return spring 1-14-7, namely, the limiting plate a1-6 completely passes through the position of the transmission friction wheel 1-10, the sliding door 1-14-1 re-closes the opening on the crushing barrel 1-15 when the transmission friction wheel 1-10 is not stressed, and the limiting plate a1-6 is made of rubber with unidirectional threads, therefore, when the limiting plate a1-6 passes through the position of the friction column 1-3, the limiting plate a1-6 cannot bend towards two sides, the conveying mounting plate a1-12 at two sides further limits the limiting plate a1-6, the equipment can carry out secondary crushing on raw materials, the crushing motor a2-1 works, the crushing motor a2-1 works to drive the motor shaft 2-2 to rotate, the motor shaft 2-2 rotates to drive the crushing connecting plate a2-3 to rotate, the crushing connecting plate a2-3 rotates to drive the crushing connecting block 2-4 to rotate, the crushing connecting block 2-4 rotates to drive the rotating inclined plate 2-5 and the crushing plate 2-8 to rotate, when the rotating inclined plate 2-5 rotates, the raw materials are knocked away, the crushing plate 2-8 rotates to carry out primary crushing, and at the moment, the crushing motor b3-1 works, the crushing motor b3-1 works to drive the crushing motor shaft 3-2 to rotate, the crushing motor shaft 3-2 drives the crushing transmission shaft 3-5 to rotate through the crushing belt a3-3, the crushing transmission shaft 3-5 rotates to drive the connecting column 3-7 to rotate through the belt b3-6, the connecting column 3-7 rotates to drive the crushing column 3-8 to rotate, the crushed raw materials are crushed for the second time when the crushing column 3-8 rotates, the equipment can automatically output the raw materials smaller than the crushing output hole to the crushing output plate, when the raw materials crushed twice are crushed into the size smaller than the crushing output hole 2-10, the raw materials smaller than the crushing output hole 2-10 can be output to the crushing output plate 2-9 from the crushing output hole under the action of the rotary inclined plate 2-5 and the crushing plate 2-8, the device can intermittently output materials on the crushing output plate, the raw materials output to the crushing output plate 2-9 are continuously increased, the compression plate 4-1 is continuously compressed, the compression plate 4-1 moves towards the connecting plate a4-4, the compression plate 4-1 continuously moves under the limitation of the output reset shaft 4-2 and the output spring 4-3, the compression plate 4-1 drives the output friction plate a4-5 to simultaneously move when moving, the output friction plate a4-5 is in friction connection with the reverse gear a4-9 when moving to the position of the reverse gear a4-9, the reverse gear a4-9 rotates, the reverse gear a4-9 rotates the output rotating shaft 4-7 and drives the output friction wheel a4-6 to rotate, the output friction wheel a4-6 and the reverse gear a4-9 simultaneously rotate, the torsion spring 4-8 generates torsion, the reverse gear a4-9 simultaneously drives the reverse gear b4-10 to rotate by taking the output gear shaft 4-11 as a shaft, the output gear shaft 4-11 rotates synchronously, the output gear shaft 4-11 rotates to drive the friction gear shaft 4-14 to rotate through the output belt 4-13, the friction gear shaft 4-14 rotates to drive the friction wheel b4-15 to rotate, when the output friction plate a4-5 continues to move until the output friction wheel a4-6 is not in friction connection with the output friction wheel a4-6, the torsion of the torsion spring 4-8 is instantly released to enable the reverse gear a4-9 to rotate reversely, the reverse gear a4-9 drives the reverse gear b4-10 to rotate instantly at high speed, the reverse gear b4-10 rotates to drive the friction wheel b4-15 to rotate through the output belt 4-13 and the friction gear shaft 4-14, and the friction plate b4-16 driven by the compression plate 4-1 simultaneously is in friction connection with the friction wheel b4-15 at the The friction wheel b4-15 rotates at a high speed to drive the friction plate b4-16 to rapidly press the compression plate 4-1 towards the connecting plate a4-4, so that the compression plate 4-1 rapidly moves towards the connecting plate a4-4, when the compression plate moves to a position exceeding the output port 4-19, the friction plate b4-16 is not in friction connection with the friction wheel b4-15, the raw material is released through the output port 4-19 instantly, the compression plate 4-1 is rapidly reset under the action of the output spring 4-3, the output friction plate a4-5 is in friction connection with the output friction wheel a4-6 again when the compression plate 4-1 is reset, the compression plate 4-1 is decelerated, the friction wheel b4-15 is in friction connection with the friction plate b4-16 to decelerate the compression plate 4-1, and the output friction plate a4-5 is not in friction connection with the output friction wheel a4-6 after reset, the friction wheel b4-15 is not in friction connection with the friction plate b4-16, and the reverse torque generated by the torsion spring 4-8 is released during the movement, and the movement is repeated.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a crushing apparatus for mill, includes transport mechanism (1), broken mechanism (2), secondary crushing mechanism (3), intermittent type nature output mechanism (4), its characterized in that: the conveying mechanism (1) is connected with the primary crushing mechanism (2), the primary crushing mechanism (2) is connected with the secondary crushing mechanism (3), the secondary crushing mechanism (3) is connected with the conveying mechanism (1), the intermittent output mechanism (4) is connected with the conveying mechanism (1), and the primary crushing mechanism (2) is connected with the intermittent output mechanism (4).

2. A plant crushing apparatus according to claim 1, wherein: the conveying mechanism (1) comprises a conveying motor (1-1), a transmission shaft a (1-2), a friction column (1-3), a transmission shaft b (1-4), a conveyor belt (1-5), a limiting plate a (1-6), a rotating plate mechanism (1-7), a limiting block (1-8), a limiting plate b (1-9), a transmission friction wheel (1-10), a transmission shaft c (1-11), a transmission mounting plate a (1-12), a transmission mounting plate b (1-13), a sliding door mechanism (1-14) and a crushing barrel (1-15), wherein the conveying motor (1-1) is connected with the transmission shaft a (1-2), the transmission shaft a (1-2) is connected with the friction column (1-3), the friction column (1-3) is connected with the transmission shaft b (1-4), the transmission shaft b (1-4) is in bearing connection with the transmission mounting plate b (1-13), the transmission belt (1-5) is in friction connection with the friction column (1-3), the limiting plate a (1-6) is connected with the transmission belt (1-5), the rotating plate mechanism (1-7) is connected with the transmission belt (1-5), the limiting block (1-8) is connected with the transmission belt (1-5), the limiting plate b (1-9) is connected with the transmission belt (1-5), the transmission friction wheel (1-10) is connected with the transmission shaft c (1-11), the transmission shaft c (1-11) is in bearing connection with the transmission mounting plate a (1-12), the transmission mounting plate a (1-12) is in bearing connection with the transmission shaft a (1-2), the transmission mounting plate b (1-13) is in bearing connection with the transmission shaft b (1-4), the sliding door mechanism (1-14) is connected with the crushing barrel (1-15), the crushing barrel (1-15) is connected with the conveying mounting plate a (1-12), the conveying motor (1-1) is connected with the conveying mounting plate a (1-12), the limiting plate a (1-6) is connected with the rotating plate mechanism (1-7), the limiting plate a (1-6) is connected with the limiting block (1-8), the limiting plate a (1-6) is connected with the limiting plate b (1-9), and the conveying mounting plate b (1-13) is connected with the crushing barrel (1-15); the rotating plate mechanism (1-7) comprises a sliding plate (1-7-1), a hinge (1-7-2) and a limiting tension spring (1-7-3), the sliding plate (1-7-1) is connected with the limiting plate a (1-6) in a sliding mode, the sliding plate (1-7-1) is hinged to the conveyor belt (1-5) through the hinge (1-7-2), one end of the limiting tension spring (1-7-3) is connected with the sliding plate (1-7-1), and the other end of the limiting tension spring is connected with the conveyor belt (1-5); the sliding door mechanism (1-14) comprises a sliding door (1-14-1), a sliding friction plate (1-14-2), a sliding door sliding rail (1-14-3), a sliding door connecting plate a (1-14-4), a sliding reset column (1-14-5), a sliding door connecting plate b (1-14-6) and a sliding reset spring (1-14-7), wherein the sliding door (1-14-1) is connected with the sliding friction plate (1-14-2), the sliding friction plate (1-14-2) is in friction connection with a transmission friction wheel (1-10), the sliding door sliding rail (1-14-3) is in sliding connection with the sliding door (1-14-1), a sliding door connecting plate a (1-14-4) is connected with the sliding door (1-14-1), the sliding reset column (1-14-5) is connected with a sliding door connecting plate a (1-14-4), the sliding door connecting plate b (1-14-6) is connected with the sliding reset column (1-14-5) in a sliding mode, a sliding reset spring (1-14-7) is sleeved on the sliding reset column (1-14-5) and limited on the sliding door connecting plate a (1-14-4) and the sliding door connecting plate b (1-14-6), the sliding door (1-14-1) is connected with the crushing barrel (1-15) in a sliding mode, the sliding door connecting plate a (1-14-4) is connected with the crushing barrel (1-15) in a sliding mode, and the sliding door connecting plate b (1-14-6) is connected with the crushing barrel (1-15).

3. A plant crushing apparatus according to claim 1, wherein: the primary crushing mechanism (2) comprises a crushing motor a (2-1), a motor shaft (2-2), a crushing connecting plate a (2-3), a crushing connecting block (2-4), a rotary sloping plate (2-5), a rotary circular plate (2-6), a rotary circular plate limiting strip (2-7), a crushing plate (2-8), a crushing output plate (2-9), a crushing output hole (2-10), a crushing motor mounting plate (2-11) and an upper side sealing plate (2-12), wherein the crushing motor a (2-1) is connected with the motor shaft (2-2), the motor shaft (2-2) is connected with the crushing connecting plate a (2-3), the crushing connecting plate a (2-3) is connected with the crushing connecting block (2-4), the crushing connecting block (2-4) is connected with the rotary sloping plate (2-5), a rotary inclined plate (2-5) is connected with a crushing barrel (1-15) in a sliding way, a rotary circular plate (2-6) is connected with a rotary circular plate limiting strip (2-7) in a sliding way, the rotary circular plate limiting strip (2-7) is connected with the crushing barrel (1-15), a crushing plate (2-8) is connected with a connecting block (2-4), a crushing output plate (2-9) is connected with a crushing connecting block (2-4), a crushing output hole (2-10) is formed in the crushing output plate (2-9), a crushing motor mounting plate (2-11) is connected with a crushing motor a (2-1), an upper side sealing plate (2-12) is connected with the crushing barrel (1-15), the rotary circular plate (2-6) is connected with the crushing barrel (1-15) through a bearing, the crushing plate (2-8) is connected with the crushing barrel (1-15) in a sliding way, the crushing output plate (2-9) is connected with the crushing barrel (1-15), the crushing motor mounting plate (2-11) is connected with the crushing barrel (1-15), and the upper side sealing plate (2-12) is connected with the crushing barrel (1-15).

4. A plant crushing apparatus according to claim 1, wherein: the secondary crushing mechanism (3) comprises a crushing motor b (3-1), a crushing motor shaft (3-2), a crushing belt a (3-3), a crushing transmission shaft connecting block (3-4), a crushing transmission shaft (3-5), a belt b (3-6), a connecting column (3-7), a crushing column (3-8), a connecting column bearing block (3-9) and a crushing transmission shaft connecting plate (3-10), wherein the crushing motor b (3-1) is connected with the crushing motor shaft (3-2), the crushing motor shaft (3-2) is in friction connection with the crushing belt a (3-3), the crushing belt a (3-3) penetrates through the crushing transmission shaft connecting block (3-4) to be in friction connection with the crushing transmission shaft (3-5), and the crushing transmission shaft connecting block (3-4) is in bearing connection with the crushing transmission shaft (3-5), the belt b (3-6) penetrates through the crushing transmission shaft connecting block (3-4) to be in friction connection with the crushing transmission shaft (3-5), the connecting column (3-7) is in friction connection with the belt b (3-6), the crushing column (3-8) is connected with the connecting column (3-7), the connecting column bearing block (3-9) is in bearing connection with the connecting column (3-7), the crushing transmission shaft connecting plate (3-10) is in bearing connection with the crushing transmission shaft (3-5), and the crushing motor b (3-1) is connected with the rotating circular plate (2-6).

5. A plant crushing apparatus according to claim 1, wherein: the intermittent output mechanism (4) comprises a compression plate (4-1), an output reset shaft (4-2), an output spring (4-3), a connecting plate a (4-4), an output friction plate a (4-5), an output friction wheel a (4-6), an output rotating shaft (4-7), a torsion spring (4-8), a reverse gear a (4-9), a reverse gear b (4-10), an output gear shaft (4-11), a connecting plate b (4-12), an output belt (4-13), a friction wheel shaft (4-14), a friction wheel b (4-15), a friction plate b (4-16), a connecting plate c (4-17), a connecting plate d (4-18), an output port (4-19), a connecting plate e (4-20), A connecting plate f (4-21), a compression plate (4-1) is connected with an output reset shaft (4-2), the output reset shaft (4-2) is connected with a connecting plate a (4-4) in a sliding way, an output spring (4-3) is sleeved on the output reset shaft (4-2) and is limited on the compression plate (4-1) and the connecting plate a (4-4), the connecting plate a (4-4) is connected with connecting plates b (4-12) at two sides, an output friction plate a (4-5) is connected with the compression plate (4-1), an output friction wheel a (4-6) is connected with an output rotating shaft (4-7), the output rotating shaft (4-7) is connected with a reverse gear a (4-9), and a torsion spring (4-8) is sleeved on the output rotating shaft (4-7), one end of a torsion spring (4-8) is connected with an output friction wheel a (4-6), the other end is connected with a reverse gear a (4-9), the reverse gear a (4-9) is meshed with a reverse gear b (4-10), the reverse gear b (4-10) is connected with an output gear shaft (4-11), the output gear shaft (4-11) is connected with a connecting plate b (4-12) through a bearing, the connecting plate b (4-12) is connected with a friction wheel shaft (4-14) through a bearing, an output belt (4-13) is connected with the output gear shaft (4-11) through a friction, the friction wheel shaft (4-14) is connected with an output belt (4-13) through a friction, the friction wheel b (4-15) is connected with a friction wheel shaft (4-14), and the friction plate b (4-16) is connected with a compression plate (4-1), the connecting plate c (4-17) is connected with the connecting plate a (4-4), the connecting plate d (4-18) is connected with the output port (4-19), the output port (4-19) is connected with the connecting plate b (4-12), the connecting plate e (4-20) is connected with the connecting plate a (4-4), the connecting plate f (4-21) is connected with the bearing of the output rotating shaft (4-7), the compression plate (4-1) is connected with the crushing output plate (2-9) in a sliding way, the output friction plate a (4-5) is connected with the friction wheel b (4-15) in a friction way, the friction plate b (4-16) is connected with the crushing output plate (2-9) in a friction way, the connecting plate c (4-17) is connected with the output port (4-19), the connecting plate d (4-18) is connected with the crushing barrel (1-15), the connecting plates e (4-20) are connected with the connecting plates f (4-21).

6. A plant crushing apparatus according to claim 1, wherein: the limiting plates a (1-6), the limiting blocks (1-8) and the limiting plates b (1-9) are made of rubber plates capable of elastically deforming, and the rubber plates are made of unidirectional rubber wires.