CN219377331U - Transmission form of hammer crusher - Google Patents

Abstract

The application discloses hammer crusher transmission form belongs to crushing equipment technical field, and it includes motor and main shaft, is provided with fluid coupling between main shaft and the motor, and fluid coupling's both ends are equipped with input sleeve pipe and output shaft respectively, and the pivot of motor can be dismantled and be connected in input sleeve pipe, are equipped with drive assembly between main shaft and the output shaft. The motor locking device has the effect of reducing the possibility of locking of the motor, so that the possibility of damage of the motor is reduced.

Description

Transmission form of hammer crusher

Technical Field

The application relates to the technical field of crushing equipment, in particular to a driving form of a hammer crusher.

Background

Currently, hammer crushers are a type of equipment for crushing material in the form of impact, in two forms, single rotor and double rotor. The hammer crusher is suitable for crushing medium hardness materials in cement, chemical industry, electric power, metallurgy and other industrial departments, such as medium crushing and fine crushing operations of limestone, slag, coke, coal and other materials.

In the prior art, a hammer crusher mainly comprises a shell, a rotor, a hammer head, a reaction lining plate, a sieve plate, a motor and the like, wherein a feed inlet is formed in the upper part of the shell; the rotor consists of a main shaft, a hammer disc, a pin shaft, a hammer head and the like; when the hammer crusher works, the motor drives the rotor to rotate at a high speed, materials uniformly enter the crusher cavity, the hammer heads rotating at a high speed impact and shear the torn materials to cause the materials to be crushed, meanwhile, the gravity of the materials self causes the materials to impact the inside of the frame body from the hammer heads rotating at a high speed to impact the lining plates and the screen bars, and the materials with the size larger than the screen holes are blocked on the screen plate to be continuously impacted and ground by the hammer until the materials are crushed to the required discharging granularity, and finally the materials are discharged out of the crusher through the screen plate.

With respect to the above related art, the inventor considers that when the crusher crushes materials, when large iron blocks exist in the materials, the crusher may be blocked, and the motor continues to operate at this time, but the main shaft of the crusher stops rotating, and the motor may be locked and damaged, so that great economic loss may be caused.

Disclosure of Invention

In order to reduce the possibility of locking of the motor and thus the possibility of damage to the motor, the present application provides a hammer crusher drive.

The application provides a hammer crusher transmission form adopts following technical scheme:

the utility model provides a hammer crusher transmission form, includes motor and main shaft, the main shaft with be provided with the fluid coupling ware between the motor, the both ends of fluid coupling ware are equipped with input sleeve pipe and output shaft respectively, the pivot fixed connection of motor in input sleeve pipe, the main shaft with be equipped with drive assembly between the output shaft.

By adopting the technical scheme, before the hydraulic coupler is installed, a worker places the hydraulic coupler beside the crusher, and the motor is placed beside the hydraulic coupler; after that, the staff is fixedly connected with the motor with the input of fluid coupling, and the output of fluid coupling is connected with the main shaft of breaker through drive assembly, after motor, fluid coupling and breaker are connected, the staff starts the motor, and the pivot of motor rotates, and under fluid coupling's effect, the main shaft takes place to rotate to drive hammer breaker and begin work, when the breaker was blocked, the main shaft stopped rotating, can know according to fluid coupling's theory of operation, and the motor can continue to rotate, does not receive the breaker influence, thereby reduces the possibility that the motor takes place the locking, and then reduces the possibility that the motor damaged.

Preferably, the driving assembly comprises a connecting pipe, a first guide block and a second guide block; the first guide block is fixedly connected to the connecting pipe, the main shaft is fixedly connected with a connecting sleeve, and a first guide groove for the first guide block to be inserted is formed in the inner wall of the connecting sleeve; the second guide block is fixedly connected to the output shaft, a second guide groove for inserting the second guide block is formed in the connecting pipe, and the connecting pipe can slide on the output shaft along the second guide block.

By adopting the technical scheme, a worker preferentially installs the connecting pipe on the output shaft of the hydraulic coupler, and inserts the second guide block into the second guide groove; then, the worker stretches the connecting pipe towards the direction of the connecting sleeve to slide on the main shaft until the first guide block is inserted into the first guide groove; after the motor starts, the output shaft of the hydraulic coupler rotates, the second guide block drives the connecting pipe to rotate, the first guide block drives the connecting sleeve to rotate, and the connecting sleeve can drive the main shaft of the crusher to rotate, so that the crusher can be driven to work.

Preferably, a storage groove is formed in the inner wall of the connecting sleeve, and a first plug block and a first spring are arranged in the storage groove; the two ends of the first spring are respectively and fixedly connected to the first plug block and the inner wall of the storage groove, the first plug block is in sliding connection with the inner wall of the storage groove, and a limiting assembly for limiting the first plug block is arranged in the connecting sleeve; and the side wall of the connecting pipe is provided with a plugging groove for plugging the first plugging block.

Through adopting above-mentioned technical scheme, before connecting pipe and adapter sleeve connection, support tight piece butt in first spliced block, first spliced block presses first spring to be in the storage tank, at the staff with the in-process of connecting pipe insertion adapter sleeve, when the spacing effect of spacing subassembly to first spliced block is relieved to the connecting pipe, first spliced block is located the top of spliced groove, at this moment, first spliced block inserts to the spliced groove under the promotion of first spring force, thereby can reduce the possibility that the connecting pipe breaks away from adapter sleeve.

Preferably, the limiting assembly comprises a propping spring and a propping block, and two ends of the propping spring are respectively propped against the propping block and the inner wall of the connecting sleeve; the abutting block is connected to the inner wall of the connecting sleeve in a sliding mode, and can abut against the first plug-in block.

By adopting the technical scheme, before a worker inserts the connecting pipe into the connecting sleeve, the abutting block abuts against the first plug-in block, so that the first plug-in block is positioned in the storage groove and compresses the first spring; in the process that the staff inserts the connecting pipe in the adapter sleeve, first guide block sliding connection in first guide way inner wall, the connecting pipe can butt in supporting tight piece, and the connecting pipe can promote to support tight piece compression and support tight spring and remove, simultaneously, the connecting pipe butt in first joint piece, when the connecting pipe promotes to support tight piece and keep away from first joint piece, the spacing of first joint piece is relieved.

Preferably, the first pull rod is fixedly connected to the first plug-in block, the other end of the first pull rod is penetrated and arranged in the inner wall of the storage groove in a sliding manner, and the first pull rod is far away from one end of the first plug-in block, and the pull block is fixedly connected to the first plug-in block.

Through adopting above-mentioned technical scheme, when the staff needs the main shaft connection structure of decoupling hydraulic coupler and breaker, the staff pulls the pull piece and moves to keeping away from coupling sleeve's direction, and the pull piece drives first pull rod and moves to keeping away from coupling sleeve's direction, and first pull rod removes and drives first spliced block and move to keeping away from the spliced groove direction, and when first spliced block kept away from the spliced groove, the tight piece is under the promotion of tight spring force of support, promotes the connecting pipe and moves to keeping away from coupling sleeve's direction to the staff of being convenient for separates connecting pipe and coupling sleeve.

Preferably, the support column is fixedly connected to the side wall of the connecting sleeve, the support block is rotationally connected to the side wall of the support column, and the slot for the support block to be inserted is formed in the side wall of the pull rod.

Through adopting above-mentioned technical scheme, in the in-process that the staff pulled the piece to remove far away, when the grafting groove was kept away from to first grafting piece, the staff rotated the supporting shoe, makes the supporting shoe insert in the slot to can fix the position of pull rod, and then be convenient for the staff to relieve the connection between adapter sleeve and the connecting pipe.

Preferably, rubber pads are arranged in the first guide groove and the second guide groove, and the rubber pads are abutted to the first guide block and the second guide block.

Through adopting above-mentioned technical scheme, when first guide block and second guide block rotate in first guide way and second guide way respectively, the rubber pad can reduce the material wearing and tearing between guide block and the guide way.

Preferably, a storage groove is formed in the inner wall of the second guide groove, a second plug-in block and a second spring are arranged in the storage groove, two ends of the second spring are fixedly connected to the second plug-in block and the inner wall of the storage groove, and the second plug-in block can be abutted to the second guide block; the second plug block is far away from an inclined plane at one end of the second spring, a second pull rod is arranged on the second plug block, and the pull rod penetrates through and is connected to the inner wall of the storage groove in a sliding mode.

Through adopting above-mentioned technical scheme, in the staff with the second guide block insert the in-process of second guide way, the second guide block promotes the second grafting piece through the inclined plane and compresses the second spring and remove to the holding vessel, when the second guide block kept away from the second grafting piece, the second grafting piece is under the elasticity promotion of second spring, the second grafting piece kept away from the holding vessel, the connecting pipe can stretch out and draw back on the output shaft along the guide way direction, and the second grafting piece can the butt in the second guide block, thereby can reduce the possibility that connecting pipe and output shaft take place to break away from; when the worker needs to release the connection between the connecting pipe and the output shaft, the worker pulls the second pull rod to move away from the connecting pipe, and the second pull rod can drive the second plug-in block to move into the storage tank, so that the worker can conveniently release the connection between the output shaft and the connecting pipe.

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

1. before the hydraulic coupler is installed, a worker places the hydraulic coupler beside the crusher, and a motor is placed beside the hydraulic coupler; after that, the staff connects the input end of the hydraulic coupler with the motor fixedly, the output end of the hydraulic coupler is connected with the main shaft of the crusher through the driving component, when the motor, the hydraulic coupler and the crusher are connected, the staff starts the motor, the rotating shaft of the motor rotates, under the action of the hydraulic coupler, the main shaft rotates, thereby driving the hammer crusher to start working, when the crusher is blocked, the main shaft stops rotating, and according to the working principle of the hydraulic coupler, the motor can continue rotating and is not influenced by the crusher, thereby reducing the possibility of locking of the motor and further reducing the possibility of damage of the motor;

2. before the connecting pipe is connected with the connecting sleeve, the abutting block abuts against the first plug-in block, the first plug-in block presses the first spring to be positioned in the storage groove, when the limiting effect of the limiting component on the first plug-in block is relieved by the connecting pipe in the process that a worker inserts the connecting pipe into the connecting sleeve, the first plug-in block is positioned above the plug-in groove, and at the moment, the first plug-in block is inserted into the plug-in groove under the pushing of the elastic force of the first spring, so that the possibility that the connecting pipe is separated from the connecting sleeve can be reduced;

3. in the process that the pull block is pulled to move far by the staff, when the first plug-in block is far away from the plug-in groove, the staff rotates the support block, so that the support block is inserted into the slot, the position of the pull rod can be fixed, and the connection between the connecting sleeve and the connecting pipe can be released by the staff conveniently.

Drawings

Fig. 1 is a schematic diagram of a drive form of a hammer crusher.

Fig. 2 is a schematic structural view of a driving assembly according to an embodiment of the present application.

Fig. 3 is an enlarged view at a in fig. 2.

Fig. 4 is an enlarged view at B in fig. 2.

Reference numerals illustrate:

1. a motor; 2. a main shaft; 3. a fluid coupling; 4. an input sleeve; 5. an output shaft; 6. a drive assembly; 7. a connecting pipe; 8. a first guide block; 9. a second guide block; 10. a connection sleeve; 11. a first guide groove; 12. a second guide groove; 13. a spring is abutted tightly; 14. a tightening block; 15. a storage tank; 16. a first plug block; 17. a first spring; 18. a plug-in groove; 19. a first pull rod; 20. pulling blocks; 21. a support column; 22. a support block; 23. a slot; 24. a rubber pad; 25. a storage tank; 26. a second plug block; 27. a second spring; 28. a second pull rod; 29. and a limiting component.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-4.

The embodiment of the application discloses a driving mode of a hammer crusher. As shown in fig. 1, the hydraulic power generation device comprises a motor 1 and a main shaft 2, a hydraulic coupler 3 is arranged between the main shaft 2 and the motor 1, an output shaft 5 and an input sleeve 4 are respectively arranged at the left end and the right end of the hydraulic coupler 3, the output shaft 5 and the input sleeve 4 are both in a cylindrical shape, the axial lead direction extends along the horizontal direction, the input sleeve 4 of the hydraulic coupler 3 is detachably connected to a rotating shaft of the motor 1 through a bolt, and a driving assembly 6 is arranged between the main shaft 2 of the crusher and the output shaft 5 of the hydraulic coupler 3.

As shown in fig. 2, the driving assembly 6 includes a connection pipe 7, two first guide blocks 8, and two second guide blocks 9; the connecting pipe 7 is cylindrical, the axial lead of the connecting pipe is arranged along the horizontal direction, the first guide blocks 8 and the second guide blocks 9 are both cuboid, the two first guide blocks 8 are fixedly welded on the outer side wall of the connecting pipe 7, the positions of the two first guide blocks 8 are oppositely arranged, the connecting sleeve 10 is fixedly welded on the peripheral side wall of the main shaft 2 of the crusher, the connecting sleeve 10 is cylindrical, the axial lead of the connecting sleeve is arranged along the horizontal direction, the inner wall of the connecting sleeve 10 is provided with two first guide grooves 11 along the horizontal direction, and the two first guide grooves 11 are respectively used for the two first guide blocks 8 to be spliced; the two second guide blocks 9 are fixedly welded on the peripheral side wall of the output shaft 5, the positions of the two second guide blocks 9 are oppositely arranged, two second guide grooves 12 for inserting the second guide blocks 9 are formed in the inner wall of the connecting pipe 7 along the horizontal direction, rubber pads 24 are fixedly adhered to the inner walls of the first guide grooves 11 and the second guide grooves 12, and the connecting pipe 7 can slide on the output shaft 5 along the second guide blocks 9.

As shown in fig. 1 and 2, before the hydraulic coupler is installed, a worker fixes the hydraulic coupler 3 on the right side of the crusher, the motor 1 is fixed on the right side of the hydraulic coupler 3, and an input end of the hydraulic coupler is connected with a rotating shaft of the motor 1 through a bolt; the worker preferentially aligns the second guide groove 12 on the connecting pipe 7 with the second guide block 9 on the output shaft 5, inserts the connecting pipe 7 on the output shaft 5, then pulls the connecting pipe 7 towards the direction of the connecting sleeve 10, slides the connecting pipe 7 leftwards on the output shaft 5, and inserts the first guide block 8 into the first guide groove 11; in the case where the crusher, the motor 1 and the fluid coupling 3 are all fixed, the connection pipe 7 can be slid and extended on the output shaft 5, thereby facilitating the connection between the connection pipe 7 and the connection sleeve 10 by the staff.

As shown in fig. 1 and 2, after a worker turns on the motor 1, under the action of the hydraulic coupler 3, the output shaft 5 of the hydraulic coupler 3 is driven to rotate, the rotation of the output shaft 5 can drive the connecting pipe 7 to rotate through the second guide block 9, the rotation of the connecting pipe 7 can drive the connecting sleeve 10 to rotate through driving the first guide block 8, and the rotation of the connecting sleeve 10 can drive the main shaft 2 of the crusher to rotate, so that the crusher can be driven to work, and meanwhile, when the first guide block 8 and the second guide block 9 respectively rotate, the rubber pad 24 can reduce the material abrasion between the guide blocks and the guide grooves; when the main shaft 2 fails in the crusher to stop rotating, the motor 1 can continue to rotate according to the working principle of the hydraulic coupler 3 and is not influenced by the crusher, so that the possibility of locking of the motor 1 is reduced, and the possibility of damage of the motor 1 is further reduced.

As shown in fig. 2 and 3, the inner walls of the two second guide grooves 12 are provided with storage grooves 25 along the vertical direction, the storage grooves 25 are internally provided with second plug-in blocks 26 and second springs 27, the second plug-in blocks 26 are cuboid, one end of each second plug-in block 26, which is close to the output shaft 5, is provided with an inclined plane, the second springs 27 are arranged along the vertical direction, two ends of each second spring 27 are fixedly welded on the inner walls of the second plug-in blocks 26 and the storage grooves 25, and the second guide blocks 9 can be abutted against the second plug-in blocks 26; the second pull rod 28 is fixedly welded at one end, far away from the second spring 27, of the second plug-in block 26, the second pull rod 28 is cuboid, the axial lead of the second pull rod 28 is arranged in the vertical direction, the second pull rod 28 penetrates through the second spring 27, and the second pull rod 28 penetrates through and is connected to the inner wall of the storage groove 25 in a sliding mode.

As shown in fig. 2 and 3, before the worker connects the connection pipe 7 with the connection sleeve 10, the worker first takes the connection pipe 7 and inserts the second guide block 9 into the second guide groove 12; in the process of inserting the second guide block 9 into the second guide groove 12, the second guide block 9 pushes the second insertion block 26 to compress the second spring 27 to move into the storage groove 25 through the inclined plane, when the second guide block 9 is far away from the second insertion block 26, the second insertion block 26 is pushed by the elastic force of the second spring 27, the second insertion block 26 enters the second guide block 9, the connecting pipe 7 can slide on the output shaft 5 in a telescopic manner along the horizontal direction, and the left end of the second insertion block 26 can be abutted against the right end of the second guide block 9, so that the possibility that the connecting pipe 7 is separated from the output shaft 5 can be reduced; when the worker needs to release the connection between the connecting pipe 7 and the output shaft 5, the worker pulls the second pull rod 28 to move away from the connecting pipe 7, and the second pull rod 28 can drive the second plug-in block 26 to move into the storage groove 25, so that the worker can conveniently release the connection between the output shaft 5 and the connecting pipe 7.

As shown in fig. 4, a storage groove 15 is formed in the inner wall of the top end of the connecting sleeve 10, the storage groove 15 extends along the vertical direction, a first plug block 16 and a first spring 17 are arranged in the storage groove 15, the first plug block 16 is in a cuboid shape, and the first spring 17 is arranged along the vertical direction; the two ends of the first spring 17 are fixedly welded on the top end of the first plug block 16 and the inner wall of the top end of the storage groove 15 respectively, the first plug block 16 is connected with the inner wall of the storage groove 15 in a sliding manner along the vertical direction, and a limiting assembly 29 for limiting the first plug block 16 is arranged in the connecting sleeve 10; the bottom end side wall of the first plug-in block 16 can abut against the peripheral side wall of the abutting block 14; the side wall of the connecting pipe 7 is provided with a plugging groove 18 for plugging the first plugging block 16, and the plugging groove 18 extends along the vertical direction.

As shown in fig. 4, the limiting component 29 includes a supporting spring 13 and a supporting block 14, the supporting spring 13 is arranged along the horizontal direction, the supporting block 14 is in a cylindrical shape, and the axial line direction of the supporting block is arranged along the horizontal direction; both ends of the abutting spring 13 abut against the left side of the abutting block 14 and the left side inner wall of the connecting sleeve 10, respectively, the abutting block is slidably connected to the inner wall of the connecting sleeve 10 in the horizontal direction, and the right side of the abutting block 14 can abut against the connecting pipe 7.

As shown in fig. 4, a first pull rod 19 is fixedly welded on the top end of the first plug-in block 16, the first pull rod 19 is in a cuboid shape, the first pull rod 19 is arranged in a penetrating manner on the first spring 17 in a penetrating manner along the vertical direction, the top end 19 of the first pull rod is connected to the inner wall of the storage groove 15 in a sliding manner, a pull block 20 is fixedly welded on the side wall of the top end of the first pull rod 19, the pull block 20 is in a cylinder shape, and the axial lead of the pull block 20 is arranged along the vertical direction; the support column 21 is fixedly welded on the outer side wall of the connecting sleeve 10, the support column 21 is in a cylindrical shape, the axial lead of the support column 21 is arranged along the vertical direction, the support block 22 is rotationally connected with the peripheral side wall of the support column 21, the support block 22 can rotate around the support column 21, the left side wall of the pull rod is provided with the slot 23 for inserting the support block 22, and the slot 23 extends along the horizontal direction.

As shown in fig. 4, before the connecting pipe 7 is inserted into the connecting sleeve 10, the abutting block 14 abuts against the first inserting block 16, the first inserting block 16 compresses the first spring 17 to be located in the storage groove 15, during the process that the connecting pipe 7 is inserted into the connecting sleeve 10 by a worker, the first guiding block 8 on the connecting pipe 7 slides leftwards in the first guiding groove 11, the left side of the connecting pipe 7 abuts against the abutting block 14 and pushes the abutting block 14 to compress the abutting spring 13 to move, the connecting pipe 7 stops moving, at this time, the side wall of the connecting pipe 7 pushes the abutting block 14 away from the first inserting block 16, meanwhile, the side wall of the connecting pipe 7 continuously abuts against the first inserting block 16, and when the first inserting block 16 is located above the inserting groove 18, the first inserting block 16 is pushed by the elastic force of the first spring 17 to be inserted into the inserting groove 18, so that the possibility that the connecting pipe 7 is separated from the connecting sleeve 10 can be reduced.

As shown in fig. 4, when the worker needs to release the connection structure of the hydraulic coupler 3 and the main shaft 2 of the crusher, the worker pulls the pull block 20 upwards, the pull block 20 drives the first pull rod 19 to move upwards, the first pull rod 19 moves to drive the first plug block 16 to move upwards, when the first plug block 16 is far away from the plug groove 18, the worker rotates the support block 22 to enable the support block 22 to be inserted into the slot 23, so that the position of the pull rod can be fixed, and meanwhile, the abutting block 14 pushes the connecting pipe 7 to move rightwards under the pushing of the elastic force of the abutting spring 13, so that the worker is convenient for separating the connecting pipe 7 from the connecting sleeve 10.

The implementation principle of the embodiment of the application is as follows: the staff connects the input end of the hydraulic coupling with the rotating shaft of the motor 1, and the output shaft 5 of the output end of the hydraulic coupling 3 is connected with the main shaft 2 of the hammer crusher through the driving component 6; after that, the staff starts the motor 1, and the rotating shaft of the motor 1 rotates, and under the action of the hydraulic coupler 3, the main shaft 2 rotates, so that the hammer crusher is driven to start working, when the crusher is clamped, the main shaft 2 stops rotating, and according to the working principle of the hydraulic coupler 3, the motor 1 can continue rotating and is not influenced by the crusher, so that the possibility of locking of the motor 1 is reduced, and the possibility of damage of the motor 1 is further reduced.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides a hammer crusher transmission form, includes motor (1) and main shaft (2), its characterized in that: the novel hydraulic spindle is characterized in that a hydraulic coupler (3) is arranged between the spindle (2) and the motor (1), an input sleeve (4) and an output shaft (5) are respectively arranged at two ends of the hydraulic coupler (3), a rotating shaft of the motor (1) is detachably connected with the input sleeve (4), and a driving assembly (6) is arranged between the spindle (2) and the output shaft (5).

2. A hammer crusher transmission according to claim 1, characterized in that: the driving assembly (6) comprises a connecting pipe (7), a first guide block (8) and a second guide block (9); the first guide block (8) is fixedly connected to the connecting pipe (7), the main shaft (2) is fixedly connected with a connecting sleeve (10), and a first guide groove (11) for the first guide block (8) to be inserted is formed in the inner wall of the connecting sleeve (10); the second guide block (9) is fixedly connected to the output shaft (5), and a second guide groove (12) for inserting the second guide block (9) is formed in the connecting pipe (7).

3. A hammer crusher transmission according to claim 2, characterized in that: a storage groove (15) is formed in the inner wall of the connecting sleeve (10), and a first plug-in block (16) and a first spring (17) are arranged in the storage groove (15); the two ends of the first spring (17) are respectively and fixedly connected to the first plug-in block (16) and the inner wall of the storage groove (15), the first plug-in block (16) is slidably connected to the inner wall of the storage groove (15), and a limiting assembly (29) for limiting the first plug-in block (16) is arranged in the connecting sleeve (10); the side wall of the connecting pipe (7) is provided with a plugging groove (18) for plugging the first plugging block (16).

4. A hammer crusher drive as claimed in claim 3, wherein: the limiting assembly (29) comprises a propping spring (13) and a propping block (14), and two ends of the propping spring (13) are respectively propped against the propping block (14) and the inner wall of the connecting sleeve (10); the abutting block (14) is slidably connected to the inner wall of the connecting sleeve (10), and the abutting block (14) can abut against the first plug-in block (16).

5. A hammer crusher drive as claimed in claim 3, wherein: the novel storage tank is characterized in that a first pull rod (19) is fixedly connected to the first plug-in block (16), the other end of the first pull rod (19) penetrates through and is connected to the inner wall of the storage tank (15) in a sliding mode, and a pull block (20) is fixedly connected to one end, away from the first plug-in block (16), of the first pull rod (19).

6. A hammer crusher drive as claimed in claim 5, wherein: the connecting sleeve is characterized in that a supporting column (21) is fixedly connected to the side wall of the connecting sleeve (10), a supporting block (22) is rotatably connected to the side wall of the supporting column (21), and a slot (23) for inserting the supporting block (22) is formed in the side wall of the pull rod.

7. A hammer crusher transmission according to claim 2, characterized in that: rubber pads (24) are arranged in the first guide groove (11) and the second guide groove (12), and the rubber pads (24) are abutted to the first guide block (8) and the second guide block (9).

8. A hammer crusher transmission according to claim 2, characterized in that: the storage tank (25) has been seted up to second guide way (12) inner wall, be equipped with second plug block (26) and second spring (27) in storage tank (25), the both ends fixed connection of second spring (27) in second plug block (26) with storage tank (25) inner wall, second plug block (26) are kept away from be equipped with the inclined plane of second spring (27) one end, be equipped with second pull rod (28) on second plug block (26), second pull rod (28) wear to establish and sliding connection in storage tank (25) inner wall.