CN216467844U - Mine train type bend pin tooth shunting machine - Google Patents

Abstract

The utility model discloses a mine train type curve pin tooth shunting machine which comprises a first device shell, a first guide rod, a second hinged ejector rod and a first sliding block, wherein driving motors are uniformly arranged at two ends of a central axis at the top end in the first device shell, second gears penetrating through the inner wall of the first device shell are arranged at output ends of the driving motors through bearings, and a transmission rod penetrating through the first device shell is uniformly arranged at the bottom end of one end of the first device shell through a bearing. This mine train formula bend round pin tooth shunting machine carries out the pivoted through the bull stick drive third gear, drives the fourth gear when the third gear is pivoted and rotates, drives nut drive lead screw through the fourth gear simultaneously and removes, drives the adjusting plate when the lead screw and removes for the width to the device that the device can be better when using is adjusted, makes the width that the device can cooperate the guide rail when using cooperate.

Description

Mine train type bend pin tooth shunting machine

Technical Field

The utility model relates to the technical field of shunting machines, in particular to a mine train type bend pin tooth shunting machine.

Background

Along with the development of society, the continuous progress of science and technology, along with the continuous progress of the energy, the continuous exploitation of mine when transporting the ore, needs to use the shunting machine to transport the ore, and traditional mine train formula bend pin tooth shunting machine can satisfy people's user demand basically, but still has certain problem, and concrete problem is as follows:

1. when most of mine train type curve pin tooth shunting machines in the current market are used, the devices cannot be well matched with rails for use when in use due to different widths of the rails, so that the devices are large in use limitation;

2. most mine train formula bend pin tooth shunting machine on the existing market can shake because the device can produce vibrations when transporting coal, just shakes the ore of device inside easily when the device produces vibrations to cause the waste.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a mine train type curve pin tooth shunting machine, which solves the problems that the device provided in the background art is large in use limitation and waste is caused by falling of ores due to vibration.

In order to achieve the purpose, the utility model provides the following technical scheme: a mine train type curve pin tooth shunting machine comprises a first device shell, a first guide rod, a second hinged ejector rod and a first sliding block, wherein driving motors are uniformly installed at two ends of a central axis at the top end in the first device shell, second gears penetrating through the inner wall of the first device shell are installed at output ends of the driving motors through bearings, a transmission rod penetrating through the first device shell is uniformly installed at the bottom end of one end of the first device shell through the bearings, first gears meshed with the second gears are installed on the outer sides of the transmission rod, idler wheels are installed at two ends of the transmission rod, cavities are formed in the idler wheels, a rotating rod penetrating through the cavities is installed at the middle position of one end of the idler wheel, away from the first device shell, through the bearings, third gears are installed on the outer sides of the rotating rod, nuts penetrating through the cavities are evenly installed at one end, away from the first device shell, of the idler wheel, and the outer side of the nut is provided with a fourth gear which is meshed with the third gear, one end of the outer side of the transmission rod, which is close to the roller wheel, is provided with an adjusting plate, the inner part of the adjusting plate is provided with a screw rod which penetrates through the nut, the top end of the first device shell is provided with a second device shell, the middle position of the inner bottom end of the second device shell is provided with a fourth device shell, the inner bottom end of the fourth device shell is provided with a second spring ejector rod, the top end of the second spring ejector rod is provided with an ejector rod body which penetrates through the top end of the fourth device shell, the top end of the ejector rod body is provided with a fixing plate which penetrates through the top end of the second device shell, the top end of the fixing plate is provided with a third device shell, the bottom end of the fixing plate is provided with a groove, the two ends of the inner part of the groove are both transversely provided with second guide rods, the outer side of each second guide rod is provided with a second spring body, and the outer sides of the second guide rods at the two ends of the second spring body are provided with second sliding blocks, and the bottom ends of the second sliding blocks are obliquely hinged with first hinge ejector rods hinged with the top end of the fourth device shell.

Preferably, the middle position of the bottom end in the second device shell is provided with a fixed block, and the inner side of the fixed block is transversely provided with a first guide rod.

Preferably, the top ends of the two ends in the second device shell are hinged with hinged plates hinged with the bottom ends of the two ends of the fixed plate, and the top ends of the hinged plates are uniformly provided with first spring ejector rods connected with the top end in the second device shell.

Preferably, the outer sides of the first guide rods are provided with first spring bodies, and the outer sides of the first guide rods at two ends of each first spring body are provided with first sliding blocks.

Preferably, the second gear is meshed with the first gear, and the second gear and the first gear form a transmission structure.

Preferably, the top end of the first sliding block is obliquely hinged with a second hinged ejector rod, and the top end of the second hinged ejector rod is hinged with the bottom end of one end of the second sliding block.

Compared with the prior art, the utility model has the beneficial effects that:

1. the screw rod, the adjusting plate and the third gear are arranged, the rotating rod drives the third gear to rotate, the fourth gear is driven to rotate when the third gear rotates, the nut is driven by the fourth gear to drive the screw rod to move, and the adjusting plate is driven by the screw rod to move, so that the width of the device can be adjusted better when the device is used, and the device can be matched with the width of the guide rail to be matched when the device is used;

2. meanwhile, the device is provided with a third device shell, a fixed plate and an ejector rod body, the fixed plate is driven by the third device shell to extrude the ejector rod body, then a second spring ejector rod in the fourth device shell is extruded by the ejector rod body, meanwhile, a second sliding block is extruded by the first hinged ejector rod, and when the second sliding block moves, the second spring body is extruded, so that the device can better avoid shock when in use, and ores are prevented from falling;

3. meanwhile, the device drives the second gear to rotate through the driving motor by installing the roller, the driving motor and the first gear, the second gear drives the first gear to rotate when rotating, the transmission rod is driven to rotate through the first gear, and the roller is driven to rotate when the transmission rod rotates, so that the device can be better driven when in use.

Drawings

FIG. 1 is a front sectional view of the present invention;

FIG. 2 is a schematic diagram of the right-view structure of the present invention;

FIG. 3 is a schematic front view of the present invention;

FIG. 4 is an enlarged view of portion A of FIG. 1 according to the present invention;

FIG. 5 is an enlarged view of the portion B of FIG. 1 according to the present invention.

In the figure: 1. a first device housing; 2. a second device housing; 3. a hinge plate; 4. a third device housing; 5. a first spring ejector rod; 6. a fixing plate; 7. a groove; 8. a fixed block; 9. a first spring body; 10. a first guide bar; 11. a mandril body; 12. a fourth device housing; 13. a second spring ejector rod; 14. A roller; 15. a screw rod; 16. a drive motor; 17. a first gear; 18. a transmission rod; 19. a second gear; 20. an adjustment plate; 21. a third gear; 22. a fourth gear; 23. a rotating rod; 24. a cavity; 25. a nut; 26. a first slider; 27. a first hinge ejector rod; 28. a second guide bar; 29. a second slider; 30. a second spring body; 31. the second hinge ejector pin.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, an embodiment of the present invention is shown: a mine train type bend pin tooth shunting machine comprises a first device shell 1, a first guide rod 10, a second hinged ejector rod 31 and a first sliding block 26, wherein driving motors 16 are uniformly installed at two ends of a central axis at the top end in the first device shell 1, the types of the driving motors 16 can be MSME-5AZG1, and second gears 19 penetrating through the inner wall of the first device shell 1 are installed at the output ends of the driving motors 16 through bearings;

the second gear 19 is meshed with the first gear 17, the second gear 19 and the first gear 17 form a transmission structure, the second gear 19 can be better driven to rotate by the driving motor 16 when the device is used, and the first gear 17 is driven to rotate when the second gear 19 rotates, so that the roller 14 can be better rotated when the device is used;

a transmission rod 18 penetrating through the first device shell 1 is uniformly installed at the bottom end of one end of the first device shell 1 through a bearing, a first gear 17 meshed with a second gear 19 is installed on the outer side of the transmission rod 18, rollers 14 are installed at two ends of the transmission rod 18, cavities 24 are formed in the rollers 14, a rotating rod 23 penetrating into the cavity 24 is installed at the middle position of one end, away from the first device shell 1, of the roller 14 through a bearing, a third gear 21 is installed on the outer side of the rotating rod 23, a nut 25 penetrating into the cavity 24 is uniformly installed at one end, away from the first device shell 1, of the roller 14 through a bearing, a fourth gear 22 meshed with the third gear 21 is installed on the outer side of the nut 25, an adjusting plate 20 is arranged at one end, close to the rollers 14, of the outer side of the transmission rod 18, and a screw rod 15 penetrating through the nut 25 is arranged in the adjusting plate 20, the top end of the first device shell 1 is provided with a second device shell 2;

the middle position of the bottom end in the second device shell 2 is provided with the fixed block 8, the inner side of the fixed block 8 is transversely provided with the first guide rod 10, and the position of the first guide rod 10 can be better fixed through the fixed block 8 when the device is used, so that the device can better guide the movement of the first slide block 26 when in use;

the top ends of the two ends in the second device shell 2 are hinged with hinged plates 3 hinged with the bottom ends of the two ends of the fixed plate 6, the top ends of the hinged plates 3 are uniformly provided with first spring ejector rods 5 connected with the top end in the second device shell 2, and the first spring ejector rods 5 can be better extruded when the hinged plates 3 move in use, so that the device can better absorb shock when in use;

the outer sides of the first guide rods 10 are provided with first spring bodies 9, the outer sides of the first guide rods 10 at two ends of each first spring body 9 are provided with first sliding blocks 26, and the first spring bodies 9 at the outer sides of the first guide rods 10 can be better extruded through the first sliding blocks 26 when the device is used, so that the device can be better buffered when the device is used;

the top ends of the first sliding blocks 26 are obliquely hinged with second hinged ejector rods 31, the top ends of the second hinged ejector rods 31 are hinged with the bottom end of one end of the second sliding block 29, and the second hinged ejector rods 31 can be driven by the second sliding blocks 29 to extrude the first sliding blocks 26 better when the device is used, so that the device can be extruded and controlled better when the device is used;

and the middle position of the inside bottom of second device shell 2 all installs fourth device shell 12, second spring ejector pin 13 is all installed to the inside bottom of fourth device shell 12, and ejector pin body 11 that runs through fourth device shell 12 top is all installed on second spring ejector pin 13 top, fixed plate 6 that runs through second device shell 2 top is installed on ejector pin body 11 top, and third device shell 4 is installed on the top of fixed plate 6, recess 7 is seted up to the bottom of fixed plate 6, and recess 7 inside both ends all transversely install second guide arm 28, the outside of second guide arm 28 all is provided with second spring body 30, and the outside of second guide arm 28 of second spring body 30 both ends all is provided with second slider 29, second slider 29 bottom all inclines to articulate has first articulated ejector pin 27 with fourth device shell 12 top looks articulated.

The working principle is as follows: when the mine train type curve pin tooth shunting machine is used, the second gear 19 is driven to rotate by the driving motor 16, the first gear 17 is driven to rotate when the second gear 19 rotates, at the same time, the first gear 17 drives the transmission rod 18 to rotate, the roller 14 is driven to rotate and the driving device moves, the rotating rod 23 drives the third gear 21 to rotate, when the third gear 21 rotates, the fourth gear 22 engaged with the third gear is driven to rotate, and the nut 25 is driven to rotate by the fourth gear 22, when the nut 25 rotates, the screw rod 15 is driven to rotate selectively, the adjusting plate 20 is driven to move through the screw rod 15, so that the width between the roller 14 and the adjusting plate 20 can be better adjusted when the device is used, and the device can be better adjusted when the device is used.

Meanwhile, the fixed plate 6 is driven by the roller 14 to extrude the ejector rod body 11, the second spring ejector rod 13 in the fourth device shell 12 is extruded by the ejector rod body 11, the second slide block 29 is extruded by the first hinged ejector rod 27, the second spring body 30 outside the second guide bar 28 is pressed when the second slider 29 is pressed, so that the device can be better extruded when in use, and then the second hinge ejector rod 31 drives the first slide block 26 to extrude the first spring body 9 at the outer side of the first guide rod 10, so that the device can better absorb shock when in use, meanwhile, the first spring ejector rod 5 is extruded through the hinged plate 3, so that the device can better buffer the vibration of the device when in use, and the whole working principle of the utility model is described above.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The utility model provides a mine train formula bend round pin tooth shunting machine, includes first device shell (1), first guide arm (10) and articulated ejector pin of second (31), first slider (26), its characterized in that: the device is characterized in that driving motors (16) are uniformly installed at two ends of a central axis at the top end in the first device shell (1), second gears (19) penetrating through the inner wall of the first device shell (1) are installed at output ends of the driving motors (16) through bearings, transmission rods (18) penetrating through the first device shell (1) are uniformly installed at the bottom end of one end of the first device shell (1) through bearings, first gears (17) meshed with the second gears (19) are installed on the outer sides of the transmission rods (18), rollers (14) are installed at two ends of the transmission rods (18), cavities (24) are formed in the rollers (14), rotating rods (23) penetrating through the cavities (24) are installed at positions, far away from the middle position of one end of the first device shell (1), of the rollers (14) through bearings, and third gears (21) are installed on the outer sides of the rotating rods (23), the roller (14) is far away from one end of the first device shell (1), a nut (25) penetrating through the cavity (24) is uniformly installed at one end of the first device shell (1) through a bearing, a fourth gear (22) meshed with the third gear (21) is installed at the outer side of the nut (25), an adjusting plate (20) is arranged at one end, close to the roller (14), of the outer side of the transmission rod (18), a lead screw (15) penetrating through the nut (25) is arranged inside the adjusting plate (20), the second device shell (2) is installed at the top end of the first device shell (1), the fourth device shell (12) is installed at the middle position of the bottom end inside the second device shell (2), a second spring ejector rod (13) is installed at the bottom end inside the fourth device shell (12), and an ejector rod body (11) penetrating through the top end of the fourth device shell (12) is installed at the top end of the second spring ejector rod (13), the top end of the ejector rod body (11) is provided with a fixing plate (6) penetrating through the top end of the second device shell (2), the top end of the fixing plate (6) is provided with a third device shell (4), the bottom end of the fixing plate (6) is provided with a groove (7), the two ends inside the groove (7) are transversely provided with second guide rods (28), the outer sides of the second guide rods (28) are provided with second spring bodies (30), the outer sides of the second guide rods (28) at the two ends of each second spring body (30) are provided with second sliding blocks (29), and the bottom ends of the second sliding blocks (29) are obliquely hinged with first hinged ejector rods (27) hinged with the top end of the fourth device shell (12).

2. The mine train type curve pin tooth shunting machine according to claim 1, characterized in that: fixed block (8) are all installed to the intermediate position department of the inside bottom of second device shell (2), and first guide arm (10) are transversely installed to fixed block (8) inboard.

3. The mine train type curve pin tooth shunting machine according to claim 1, characterized in that: the top ends of the two ends in the second device shell (2) are hinged with hinged plates (3) hinged with the bottom ends of the two ends of the fixing plate (6), and first spring ejector rods (5) connected with the top end in the second device shell (2) are uniformly installed at the top ends of the hinged plates (3).

4. The mine train type curve pin tooth shunting machine according to claim 2, characterized in that: the outer sides of the first guide rods (10) are provided with first spring bodies (9), and the outer sides of the first guide rods (10) at two ends of each first spring body (9) are provided with first sliding blocks (26).

5. The mine train type curve pin tooth shunting machine according to claim 1, characterized in that: the second gear (19) and the first gear (17) are meshed with each other, and the second gear (19) and the first gear (17) form a transmission structure.

6. The mine train type curve pin tooth shunting machine according to claim 4, characterized in that: the top end of the first sliding block (26) is obliquely hinged with a second hinged ejector rod (31), and the top end of the second hinged ejector rod (31) is hinged with the bottom end of one end of the second sliding block (29).

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