CN115609530A - High manganese steel casting assembly quality - Google Patents

Abstract

The invention relates to the technical field of high manganese steel casting assembly, in particular to a high manganese steel casting assembly device, which comprises a machine body, wherein the machine body is internally provided with: the left platform is fixedly arranged on the machine body, the moving groove is formed in the machine body, the right platform is arranged in the moving groove, and the right platform is used for placing a workpiece to be assembled; the transverse groove is formed in the left platform, and the left moving block and the right moving block are both arranged in the transverse groove; the limiting mechanism is used for limiting the high-manganese casting; and the driving mechanism is used for driving the high-manganese casting to be assembled with the workpiece to be assembled. According to the invention, the workpiece to be assembled is moved into the high-manganese casting under the simultaneous pushing of the left long rod and the right long rod, the third motor is started at the moment, the friction block and the side end of the workpiece to be assembled are in friction transmission to drive the workpiece to be assembled to rotate, the workpiece to be assembled and the high-manganese casting are rapidly assembled in a threaded manner, and the operation of large-batch assembly is carried out.

Description

High manganese steel casting assembly quality

Technical Field

The invention relates to the technical field of high manganese steel casting assembly, in particular to a high manganese steel casting assembly device.

Background

The high manganese steel casting assembling device disclosed by Chinese patent publication No. CN215701215U, the device comprises a base, the top of base is equipped with the bearing board, the top fixed mounting of base has the pneumatic cylinder, the high manganese steel casting after this scheme will process is fixed in two movable sleeves, prevent that the high manganese steel casting from rolling at will on the bearing board, and simultaneously, the slider can be along the lead screw do elevating movement, make the snap ring of slider one side and two movable sleeves be located same straight line, secondly, the staff promotes the intraductal high manganese steel casting of two movable sleeves to pillar direction department, can make the one end card of high manganese steel casting go into in the spare part of snap ring centre gripping, accomplish assembly work, still because the structure limits and lead to having following problem in the use:

when the high manganese steel casting and the workpiece to be assembled are assembled in a threaded mode, the high manganese steel casting and the workpiece to be assembled need to be aligned firstly, the workpiece to be assembled is moved into the high manganese steel casting, the workpiece to be assembled is driven to rotate, and threaded assembly of the high manganese steel casting and the workpiece to be assembled is completed.

Disclosure of Invention

The invention aims to solve the problem that the assembly of a large number of high manganese steel castings cannot be completed quickly in the prior art, and provides a high manganese steel casting assembly device.

In order to achieve the purpose, the invention adopts the following technical scheme:

a high manganese steel casting assembly quality, includes the organism, be provided with in the organism:

the high manganese casting assembling device comprises a left platform, a moving groove and a right platform, wherein the left platform is fixedly arranged on a machine body and used for placing a high manganese casting, the moving groove is formed in the machine body, the right platform is arranged in the moving groove, and the right platform is used for placing a workpiece to be assembled;

the device comprises a trapezoid groove, a falling port and a collecting box, wherein the trapezoid groove and the falling port are formed in a right platform and communicated with each other, the trapezoid groove is used for placing a plurality of workpieces to be assembled, the collecting box is fixedly connected to a machine body, and the collecting box is used for collecting the assembled high-manganese castings and the workpieces to be assembled;

the moving mechanism comprises a transverse groove, a left moving block and a right moving block, wherein the transverse groove is formed in a left platform, and the left moving block and the right moving block are both arranged in the transverse groove;

the limiting mechanisms are arranged in the left moving block and the right moving block and are used for limiting the high-manganese castings;

and the driving mechanism is arranged in the machine body and is used for driving the high manganese casting to be assembled with the workpiece to be assembled.

Preferably, the right platform is slidably sleeved in the moving groove, and the left moving block and the right moving block are slidably sleeved in the transverse groove.

Preferably, the limiting mechanism comprises:

the two first motors are respectively and fixedly arranged in the left moving block and the right moving block, the two driving shafts are respectively and rotatably arranged in the left moving block and the right moving block, the driving shafts are fixedly connected with the output end of the first motor, and the two driven shafts are respectively and rotatably arranged in the left moving block and the right moving block;

the driving gear is connected to the driving shaft in a keyed mode, the driven gear is connected to the driven shaft in a keyed mode, and the driven gear is connected with the driving gear in a meshed mode;

the left arc plate and the right arc plate are fixedly sleeved on the driving shaft and the driven shaft respectively;

the two cavities are respectively arranged in the left moving block and the right moving block, and the spring is arranged in the cavity;

the clamping device comprises a first clamping block and a second clamping block, wherein the first clamping block and the second clamping block are respectively arranged in two cavities and are corresponding to each other, the first clamping block is connected with a left arc plate and a right arc plate of a left moving block in a buckling mode, and the second clamping block is connected with a left arc plate and a right arc plate of a right moving block in a buckling mode.

Preferably, the two springs are respectively welded in the two cavities, the first clamping block and the second clamping block are respectively slidably sleeved in the two cavities, the first clamping block and the second clamping block are respectively fixedly connected with free ends of the two springs, and the first clamping block and the second clamping block are homopolar repulsion magnetic blocks.

Preferably, the drive mechanism comprises:

the two second motors are respectively and fixedly arranged at two side positions in the machine body, the two driving shafts are rotatably arranged in the machine body, and the driving shafts are fixedly connected with the output ends of the second motors;

the driving gear is connected to a driving shaft in a key mode, the two first guide grooves and the two second guide grooves are formed in the machine body, and one first guide groove and one second guide groove form a group;

the first moving rack and the second moving rack are respectively sleeved in a first guide groove and a second guide groove in one group in a sliding manner, the third moving rack and the fourth moving rack are respectively sleeved in a first guide groove and a second guide groove in the other group in a sliding manner, one driving gear is respectively meshed with the first moving rack and the second moving rack, and one driving gear is respectively meshed with the third moving rack and the fourth moving rack;

the first sliding chute and the second sliding chute are respectively arranged in two side positions outside the machine body;

the right long rod is sleeved in the first sliding groove in a sliding manner, and the third motor is fixedly arranged on the right long rod;

the rotating shaft is rotatably arranged on the right long rod and fixedly connected with the output end of the third motor, and the friction block is fixedly sleeved on the rotating shaft;

the lug is integrally formed on the right long rod, and the left long rod is sleeved in the second sliding groove in a sliding manner.

Preferably, the first moving rack is fixedly connected with the left moving block, and the third moving rack is fixedly connected with the right moving block.

Preferably, the right long rod is fixedly connected with the second movable rack, and the left long rod is fixedly connected with the fourth movable rack.

Compared with the prior art, the invention has the following advantages:

1. according to the invention, under the simultaneous pushing of the left long rod and the right long rod, the workpiece to be assembled moves into the high-manganese casting, and at the moment, the third motor is started to enable the friction block to be in friction transmission with the side end of the workpiece to be assembled so as to drive the workpiece to be assembled to rotate, so that the workpiece to be assembled and the high-manganese casting can be rapidly assembled in a threaded manner, and the operation of large-batch assembly can be carried out.

2. According to the high-manganese casting limiting device, the driving shaft drives the driving gear to rotate, the driving gear is in meshing transmission with the driven gear to drive the left arc plate and the right arc plate to deflect in opposite directions, the left arc plate and the right arc plate of the left moving block are connected with the first clamping block in a buckling mode, and the left arc plate and the right arc plate of the right moving block are connected with the second clamping block in a buckling mode so as to limit a high-manganese casting.

3. According to the invention, the right platform is driven to slide rightwards by reversely starting the second motor, so that the workpiece to be assembled loses support, and moves to the right end position of the left platform under the driving of the right moving block, so that the assembled high-manganese casting and the workpiece to be assembled fall into the collecting box, and the unassembled high-manganese casting and the workpiece to be assembled respectively move into the left moving block and the falling port to wait for the next assembly operation, and then the assembly operation is carried out uninterruptedly.

Drawings

FIG. 1 is a schematic structural diagram of a high manganese steel casting assembling device provided by the invention;

FIG. 2 is a schematic top view of the high manganese steel casting assembling device provided by the invention;

FIG. 3 is a schematic front sectional view of a high manganese steel casting assembling device provided by the invention;

FIG. 4 is an enlarged view of the portion A of FIG. 3 according to the present invention;

FIG. 5 is an enlarged view of the portion B of FIG. 3 according to the present invention;

FIG. 6 is an enlarged view of the structure of part C of FIG. 3 according to the present invention;

FIG. 7 is a schematic rear sectional view of the high manganese steel casting assembling device provided by the invention.

In the figure: 1. a body; 2. a left platform; 3. a moving groove; 4. a right platform; 5. a trapezoidal groove; 6. a drop opening; 7. a collection box; 8. a transverse groove; 9. a left moving block; 10. a right moving block; 11. a first motor; 12. a drive shaft; 13. a driven shaft; 14. a driving gear; 15. a driven gear; 16. a left arc plate; 17. a right arc plate; 18. a cavity; 19. a spring; 20. a first clamping block; 21. a second clamping block; 22. a second motor; 23. a drive shaft; 24. a drive gear; 25. a first guide groove; 26. a second guide groove; 27. a first moving rack; 28. a second moving rack; 29. a third moving rack; 30. a fourth moving rack; 31. a first chute; 32. a second chute; 33. a right long rod; 34. a third motor; 35. a rotating shaft; 36. a friction block; 37. a bump; 38. a left long rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-7, a high manganese steel casting assembling device comprises a machine body 1, wherein the machine body 1 is provided with:

the device comprises a left platform 2, a moving groove 3 and a right platform 4, wherein the left platform 2 is fixedly arranged on a machine body 1, the left platform 2 is used for placing high-manganese castings, the moving groove 3 is formed in the machine body 1, the right platform 4 is arranged in the moving groove 3, and the right platform 4 is used for placing workpieces to be assembled; an external conveyor belt can be arranged at the left platform 2, and unassembled high manganese castings are conveyed into a left moving block 9 so as to continuously feed the high manganese castings;

the device comprises a trapezoidal groove 5, a falling port 6 and a collecting box 7, wherein the trapezoidal groove 5 is of a structure with a wide upper part and a narrow lower part, after a workpiece to be assembled in the falling port 6 is moved out, the workpiece to be assembled falls down from the trapezoidal groove 5 so as to continuously feed the workpiece to be assembled, the trapezoidal groove 5 and the falling port 6 are both arranged in a right platform 4, the trapezoidal groove 5 is communicated with the falling port 6, the trapezoidal groove 5 is used for placing a plurality of workpieces to be assembled, the collecting box 7 is fixedly connected to a machine body 1, and the collecting box 7 is used for collecting assembled high-manganese castings and workpieces to be assembled;

the left moving block 9 and the right moving block 10 are arranged in the transverse groove 8;

the right platform 4 is slidably sleeved in the moving groove 3, and the left moving block 9 and the right moving block 10 are slidably sleeved in the transverse groove 8.

The limiting mechanisms are arranged in the left moving block 9 and the right moving block 10 and are used for limiting the high-manganese castings; referring to fig. 3 and 4, the following is detailed:

stop gear includes:

the servo motors with the product models of MSME-011G1 can be selected as the first motor 11, the driving shaft 12 and the driven shaft 13, the first motor 11, the second motor 22 and the third motor 34 are respectively and fixedly installed in the left moving block 9 and the right moving block 10, the two driving shafts 12 are respectively and rotatably installed in the left moving block 9 and the right moving block 10, the driving shafts 12 are fixedly connected with the output ends of the first motors 11, and the two driven shafts 13 are respectively and rotatably installed in the left moving block 9 and the right moving block 10;

the driving gear 14 is in key connection with the driving shaft 12, the driven gear 15 is in key connection with the driven shaft 13, and the driven gear 15 is in meshing connection with the driving gear 14;

the left arc plate 16 and the right arc plate 17, and the left arc plate 16 and the right arc plate 17 are respectively fixedly sleeved on the driving shaft 12 and the driven shaft 13;

the two cavities 18 are respectively arranged in the left moving block 9 and the right moving block 10, and the spring 19 is arranged in the cavity 18;

the high manganese casting clamping device comprises a first clamping block 20, a second clamping block 21, a first clamping block 20 and a second clamping block 21, wherein the first clamping block 20 and the second clamping block 21 are respectively arranged in two cavities 18, the first clamping block 20 corresponds to the second clamping block 21, the first clamping block 20 is connected with a left arc plate 16 and a right arc plate 17 of a left moving block 9 in a buckling mode, the second clamping block 21 is connected with a left arc plate 16 and a right arc plate 17 of a right moving block 10 in a buckling mode, and therefore the high manganese casting is limited in moving.

The two springs 19 are respectively welded in the two cavities 18, the first clamping block 20 and the second clamping block 21 are respectively sleeved in the two cavities 18 in a sliding mode, the first clamping block 20 and the second clamping block 21 are respectively fixedly connected with free ends of the two springs 19, and when the left moving block 9 and the right moving block 10 collide with each other, the locking of the left arc plate 16 and the right arc plate 17 is released by utilizing homopolar repulsion force between the first clamping block 20 and the second clamping block 21, and therefore the limiting of a high manganese casting is released.

The driving mechanism is arranged in the machine body 1 and is used for driving the high-manganese casting to be assembled with a workpiece to be assembled; referring to fig. 3-6, the following is detailed:

the drive mechanism includes:

the two second motors 22 are respectively and fixedly arranged in the two side positions in the machine body 1, the two driving shafts 23 are both rotatably arranged in the machine body 1, and the driving shafts 23 are fixedly connected with the output ends of the second motors 22;

the driving gear 24 is in key connection with the driving shaft 23, the two first guide grooves 25 and the two second guide grooves 26 are both arranged in the machine body 1, and one first guide groove 25 and one second guide groove 26 form a group;

the first moving rack 27, the second moving rack 28, the third moving rack 29 and the fourth moving rack 30 are respectively slidably sleeved in the first guide groove 25 and the second guide groove 26 in one group, the third moving rack 29 and the fourth moving rack 30 are respectively slidably sleeved in the first guide groove 25 and the second guide groove 26 in the other group, one driving gear 24 is respectively engaged with the first moving rack 27 and the second moving rack 28, and one driving gear 24 is respectively engaged with the third moving rack 29 and the fourth moving rack 30;

the first sliding chute 31 and the second sliding chute 32, the first sliding chute 31 and the second sliding chute 32 are respectively arranged at two outer side positions of the machine body 1; under the drive of the drive gear 24, the left long rod 38 and the right long rod 33 push the workpiece to be assembled to enter the high manganese casting, and then the friction block 36 drives the workpiece to be assembled to rotate so as to complete the thread assembly;

the right long rod 33 is slidably sleeved in the first sliding chute 31, and the third motor 34 is fixedly arranged on the right long rod 33; the left long rod 38 and the right long rod 33 are driven to move oppositely, so that the assembly position of the high manganese casting and the workpiece to be assembled is always positioned at the middle end of the machine body 1, and the assembled high manganese casting and the workpiece to be assembled fall into the collection box 7 at the middle end when the left long rod 38 and the right long rod 33 move reversely;

the rotating shaft 35 and the friction block 36 can increase the roughness of the surface of the friction block 36 so that the friction block 36 can drive a workpiece to be assembled, the rotating shaft 35 is rotatably installed on the right long rod 33, the rotating shaft 35 is fixedly connected with the output end of the third motor 34, and the friction block 36 is fixedly sleeved on the rotating shaft 35;

the lug 37 and the left long rod 38, the lug 37 is integrally formed on the right long rod 33, and the left long rod 38 is slidably sleeved in the second sliding groove 32; because the length of the lug 37 is less than that of the friction block 36 and the rotating shaft 35, the friction block 36 pushes the workpiece to be assembled to move leftwards, and then the lug 37 pushes the right platform 4 to move leftwards, so that the workpiece to be assembled can enter the high-manganese casting;

the first moving rack 27 is fixedly connected with the left moving block 9, and the third moving rack 29 is fixedly connected with the right moving block 10.

The right long rod 33 is fixedly connected with the second moving rack 28, and the left long rod 38 is fixedly connected with the fourth moving rack 30.

The invention can be illustrated by the following operating modes:

conveying the high-manganese casting to the left moving block 9 through an external transmission belt, starting a second motor 22, driving a driving shaft 23 to rotate by an output end of the second motor 22, driving a driving gear 24 to rotate by the driving shaft 23, and enabling one driving gear 24 to be respectively meshed with a first moving rack 27 and a second moving rack 28 for transmission, so that the first moving rack 27 and the second moving rack 28 respectively move in the first guide groove 25 and the second guide groove 26 in the opposite direction or the reverse direction, and meanwhile enabling a third moving rack 29 and a fourth moving rack 30 to move in the opposite direction or the reverse direction;

when the first moving rack 27 and the second moving rack 28 move in opposite directions, the first moving rack 27 drives the left moving block 9 to slide in the transverse groove 8, meanwhile, the third moving rack 29 and the fourth moving rack 30 move in opposite directions, and the third moving rack 29 drives the right moving block 10 to slide in the transverse groove 8, so that the left moving block 9 and the right moving block 10 slide in opposite directions;

meanwhile, the second moving rack 28 drives the right long rod 33 to slide leftwards in the first sliding groove 31, the fourth moving rack 30 drives the left long rod 38 to slide rightwards in the second sliding groove 32, the distance between the left moving block 9 and the right moving block 10 is continuously shortened due to the fact that the left moving block and the right moving block move in opposite directions, and at the moment, the left long rod 38 pushes the high manganese casting to enter the right moving block 10;

the first motor 11 is started, the first motor 11 drives the driving shaft 12 to rotate, the driving shaft 12 drives the driving gear 14 to rotate, the driving gear 14 is in meshing transmission with the driven gear 15 to drive the driven shaft 13 to rotate, the left arc plate 16 and the right arc plate 17 are driven to deflect oppositely, the left arc plate 16 and the right arc plate 17 of the left moving block 9 are connected with the first clamping block 20 in a buckling mode, and the left arc plate 16 and the right arc plate 17 of the right moving block 10 are connected with the second clamping block 21 in a buckling mode to limit the high-manganese casting;

the workpiece to be assembled is pushed by the right long rod 33 in the falling opening 6 and slides a certain distance leftwards, then under the pushing of the convex block 37, the right platform 4 slides leftwards in the moving groove 3, under the pushing of the left long rod 38 and the right long rod 33, the workpiece to be assembled moves to a high manganese casting, at the moment, the third motor 34 is started, the output end of the third motor 34 drives the rotating shaft 35 to rotate, the rotating shaft 35 drives the friction block 36 to rotate, the friction block 36 is in friction transmission with the side end of the workpiece to be assembled so as to drive the workpiece to be assembled to rotate, and the workpiece to be assembled and the high manganese casting are subjected to thread assembly;

after the workpiece to be assembled and the high-manganese casting are assembled, the third motor 34 is turned off, the left moving block 9 and the right moving block 10 continue to move in opposite directions, the left moving block 9 and the right moving block 10 are in collision, and the first clamping block 20 and the second clamping block 21 are homopolar repelling magnetic blocks, so that the first clamping block 20 and the second clamping block 21 respectively slide into the cavity 18, the spring 19 is extruded, the locking of the left arc plate 16 and the right arc plate 17 is released, the first motor 11 is started in the reverse direction, the left arc plate 16 and the right arc plate 17 are deflected in the reverse direction, and the limitation of the high-manganese casting is released;

the second motor 22 is started reversely, the right platform 4 is driven to slide rightwards, the workpiece to be assembled is enabled to lose support, the left moving block 9 and the right moving block 10 move reversely, the left end of the high manganese casting is enabled to lose support, the high manganese casting and the workpiece to be assembled are driven by the right moving block 10 to move to the right end position of the left platform 2, the assembled high manganese casting and the assembled workpiece are enabled to fall into the collecting box 7, and the unassembled high manganese casting and the unassembled workpiece are respectively moved into the left moving block 9 and the falling port 6 to be assembled for next assembling operation.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (7)

1. A high manganese steel casting assembly device, includes organism (1), its characterized in that is provided with in the organism (1):

the high manganese casting assembling device comprises a left platform (2), a moving groove (3) and a right platform (4), wherein the left platform (2) is fixedly arranged on a machine body (1), the left platform (2) is used for placing high manganese castings, the moving groove (3) is formed in the machine body (1), the right platform (4) is arranged in the moving groove (3), and the right platform (4) is used for placing workpieces to be assembled;

the device comprises a trapezoidal groove (5), a falling port (6) and a collecting box (7), wherein the trapezoidal groove (5) and the falling port (6) are formed in a right platform (4), the trapezoidal groove (5) is communicated with the falling port (6), the trapezoidal groove (5) is used for placing a plurality of workpieces to be assembled, the collecting box (7) is fixedly connected to a machine body (1), and the collecting box (7) is used for collecting assembled high-manganese castings and workpieces to be assembled;

the device comprises a transverse groove (8), a left moving block (9) and a right moving block (10), wherein the transverse groove (8) is formed in a left platform (2), and the left moving block (9) and the right moving block (10) are arranged in the transverse groove (8);

the limiting mechanism is arranged in the left moving block (9) and the right moving block (10) and is used for limiting the high-manganese casting;

the driving mechanism is arranged in the machine body (1) and is used for driving the high-manganese casting to be assembled with a workpiece to be assembled.

2. The high manganese steel casting assembling device according to claim 1, characterized in that the right platform (4) is slidably sleeved in the moving groove (3), and the left moving block (9) and the right moving block (10) are both slidably sleeved in the transverse groove (8).

3. The high manganese steel casting assembly apparatus of claim 1, wherein said stop mechanism comprises:

the device comprises a first motor (11), a driving shaft (12) and driven shafts (13), wherein the two first motors (11) are fixedly arranged in a left moving block (9) and a right moving block (10) respectively, the two driving shafts (12) are rotatably arranged in the left moving block (9) and the right moving block (10) respectively, the driving shaft (12) is fixedly connected with the output end of the first motor (11), and the two driven shafts (13) are rotatably arranged in the left moving block (9) and the right moving block (10) respectively;

the driving gear (14) is in key connection with the driving shaft (12), the driven gear (15) is in key connection with the driven shaft (13), and the driven gear (15) is in meshing connection with the driving gear (14);

the left arc plate (16) and the right arc plate (17), wherein the left arc plate (16) and the right arc plate (17) are respectively fixedly sleeved on the driving shaft (12) and the driven shaft (13);

the two cavities (18) are respectively arranged in the left moving block (9) and the right moving block (10), and the spring (19) is arranged in the cavity (18);

the clamping device comprises a first clamping block (20) and a second clamping block (21), wherein the first clamping block (20) and the second clamping block (21) are respectively arranged in two cavities (18), the first clamping block (20) corresponds to the second clamping block (21), the first clamping block (20) is connected with a left arc plate (16) and a right arc plate (17) of a left moving block (9) in a buckling mode, and the second clamping block (21) is connected with a left arc plate (16) and a right arc plate (17) of a right moving block (10) in a buckling mode.

4. The high manganese steel casting assembling device according to claim 3, characterized in that the two springs (19) are welded in the two cavities (18), the first clamping block (20) and the second clamping block (21) are slidably sleeved in the two cavities (18), the first clamping block (20) and the second clamping block (21) are fixedly connected with free ends of the two springs (19), and the first clamping block (20) and the second clamping block (21) are magnets with like poles repelling each other.

5. A high manganese steel casting assembly apparatus according to claim 1, wherein said drive mechanism includes:

the two second motors (22) are fixedly arranged in two inner side positions of the machine body (1) respectively, the two driving shafts (23) are rotatably arranged in the machine body (1), and the driving shafts (23) are fixedly connected with the output ends of the second motors (22);

the driving gear (24) is in key connection with the driving shaft (23), the two first guide grooves (25) and the two second guide grooves (26) are arranged in the machine body (1), and one first guide groove (25) and one second guide groove (26) form a group;

the device comprises a first moving rack (27), a second moving rack (28), a third moving rack (29) and a fourth moving rack (30), wherein the first moving rack (27) and the second moving rack (28) are respectively slidably sleeved in a first guide groove (25) and a second guide groove (26) in one group, the third moving rack (29) and the fourth moving rack (30) are respectively slidably sleeved in a first guide groove (25) and a second guide groove (26) in the other group, one driving gear (24) is respectively meshed with the first moving rack (27) and the second moving rack (28), and one driving gear (24) is respectively meshed with the third moving rack (29) and the fourth moving rack (30);

the first sliding chute (31) and the second sliding chute (32), wherein the first sliding chute (31) and the second sliding chute (32) are respectively arranged at two positions outside the machine body (1);

the right long rod (33) is slidably sleeved in the first sliding groove (31), and the third motor (34) is fixedly mounted on the right long rod (33);

the rotating shaft (35) is rotatably mounted on the right long rod (33), the rotating shaft (35) is fixedly connected with the output end of the third motor (34), and the friction block (36) is fixedly sleeved on the rotating shaft (35);

the long rod comprises a convex block (37) and a left long rod (38), wherein the convex block (37) is integrally formed on the right long rod (33), and the left long rod (38) is slidably sleeved in the second sliding groove (32).

6. A high manganese steel casting assembling device according to claim 5, characterized in that said first moving rack (27) is fixedly connected with the left moving block (9), and said third moving rack (29) is fixedly connected with the right moving block (10).

7. A high manganese steel casting assembly apparatus according to claim 5 wherein said right long bar (33) is fixedly attached to the second moving rack (28) and said left long bar (38) is fixedly attached to the fourth moving rack (30).

Images