CN214652994U

CN214652994U - Multidirectional-adjustment mine electromechanical equipment installation mechanism

Info

Publication number: CN214652994U
Application number: CN202120655519.9U
Authority: CN
Inventors: 高丽如; 王刚
Original assignee: Guizhou Ciyu Electronic Technology Co ltd
Current assignee: Guizhou Ciyu Electronic Technology Co ltd
Priority date: 2021-03-31
Filing date: 2021-03-31
Publication date: 2021-11-09
Anticipated expiration: 2031-03-31

Abstract

The utility model provides a multidirectional-adjustment mine electromechanical equipment installation mechanism, which relates to the technical field of mine electromechanical equipment and comprises a support frame and a base, wherein the support frame is welded at the top of the base, and a cross beam is welded at the top of the support frame; through installing the limiting plate, placing frame and crash pad, and through putting into equipment to the inside of placing the frame, the crash pad through the outer wall setting of placing the frame simultaneously, when rocking produced when lifting by crane equipment, can slow down the collision dynamics of placing between the frame through the crash pad, cushions the power that the limiting plate received through the spring simultaneously to slow down the impact that equipment received, prevent that equipment from appearing damaging.

Description

Multidirectional-adjustment mine electromechanical equipment installation mechanism

Technical Field

The utility model relates to a mining equipment technical field especially relates to a mine electromechanical device installation mechanism of multidirectional regulation.

Background

The mining electromechanical equipment is equipment for providing power for mine work, and is required to be installed at a specified position for use when the equipment is used, and is usually required to be hoisted when the equipment is installed;

through analysis, the following results are found: the current application number is: CN202020499824.9 is a hoisting mechanism for installing mine electromechanical equipment, reinforcing rods are welded on the periphery of the bottom of a connecting frame, hooks are arranged at the bottoms of the reinforcing rods through reinforcing steel ropes, and the mine electromechanical equipment is hoisted and installed;

the disadvantages are that: the mine electromechanical equipment hoisting device has the advantages that when multiple equipment is hoisted, the hoisting is only hung through the hooks, the shaking is easily caused when the hoisting is carried out, the collision among the equipment is caused, in addition, the electromechanical equipment is hooked and hoisted through the hooks when the hoisting is carried out, and the inclination phenomenon is easily caused due to the large weight of the mine electromechanical equipment in the hoisting process.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a multidirectional adjusting mine electromechanical device installation mechanism.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a multidirectional-adjusting mine electromechanical equipment installation mechanism comprises a support frame and a base, wherein the support frame is welded at the top of the base, a cross beam is welded at the top of the support frame and comprises a motor, a guide groove, a lead screw, a guide rod and a guide block, a controller is installed on the front face of the cross beam, the motor is fixed on the right side face of the cross beam, the guide groove is transversely formed in the cross beam, the guide block is movably matched with the guide block, the lead screw penetrates through the left and right threads in the middle of the guide block, the guide block penetrates through the guide rod, the left end of the lead screw is movably connected with the inner wall of the left side of the guide groove through a bearing, the right end of the lead screw penetrates through the right side of the cross beam and is welded to the output end of a first motor, a transmission assembly is fixed at the bottom of the guide block and comprises a second motor, a rotating rod and a steel rope, the second motor is connected to the rotating rod through a bevel gear, and the steel rope is wound on the surface of the rotating rod, the bottom end of the steel rope is fixed with a connecting frame;

the bottom of link has hoisting assembly through hinged joint, and hoisting assembly is including placing frame, crash pad, support sleeve, backup pad and limiting plate.

Preferably, the hoisting assembly is provided with three, and all is fixed in the bottom of link to the crash pad is all installed to the left and right sides of every frame of placing.

Preferably, the upper part and the lower part of the inner part of the placing frame are both fixed with supporting sleeves, the inner sides of the supporting sleeves are fixed with supporting plates, and the inner sides of the supporting plates are both arranged in an inwards concave arc surface.

Preferably, the left side and the right side of the inner wall of the placing frame are both fixed with limiting plates through springs, and the inner sides of the limiting plates are both concave arc surfaces.

Preferably, the supporting sleeves are internally provided with springs, and the supporting plates are embedded into the supporting sleeves through the connecting rods.

To sum up, owing to adopted above-mentioned technical scheme, the beneficial effects of the utility model are that:

1. the utility model discloses in, through installing the limiting plate, placing frame and crash pad, and through putting into equipment to the inside of placing the frame, simultaneously through the crash pad of placing the outer wall setting of frame, when rocking produced when lifting by crane equipment, can slow down the collision dynamics of placing between the frame through the crash pad, cushion the power that receives the limiting plate through the spring simultaneously to slow down the impact that equipment received, prevent that equipment from appearing damaging.

2. Secondly, through installing supporting sleeve, backup pad and limiting plate, and through the inside spring bounce-back of supporting sleeve make the backup pad closely laminate in the top and the bottom of equipment when exerting pressure to the backup pad through equipment, closely laminate through the surface of limiting plate and equipment simultaneously for can effectually prevent when lifting by crane equipment that the slope phenomenon from appearing in equipment.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is an internal schematic view of the overall structure of the present invention;

FIG. 3 is a partial schematic view of the transmission assembly of the present invention;

fig. 4 is the local schematic view of the middle hoisting assembly of the present invention.

In fig. 1 to 4, the correspondence between the part names or lines and the reference numbers is:

the device comprises a support frame 1, a base 2, a cross beam 3, a first motor 301, a guide groove 302, a lead screw 303, a guide rod 304, a guide block 305, a transmission assembly 4, a second motor 401, a rotating rod 402, a steel rope 403, a connecting frame 5, a hoisting assembly 6, a placement frame 601, a crash pad 602, a support sleeve 603, a support plate 604 and a limit plate 605.

Detailed Description

Referring to fig. 1 to 4, the embodiment provides a multidirectional-adjustment mining electromechanical device installation mechanism, which includes a support frame 1 and a base 2, the support frame 1 is welded on the top of the base 2, a cross beam 3 is welded on the top of the support frame 1, the cross beam 3 includes a motor 301, a guide groove 302, a screw rod 303, a guide rod 304 and a guide block 305, wherein a controller is installed on the front surface of the cross beam 3, the motor 301 is fixed on the right side surface of the cross beam 3, the guide groove 302 is transversely arranged in the cross beam 3, a matched guide block 305 is movably arranged in the guide groove 302, the screw rod 303 penetrates through the left and right threads in the middle of the guide block 305, the guide rod 304 penetrates through the guide block 305, wherein the left end of the screw rod 303 is movably connected with the inner wall on the left side of the guide groove 302 through a bearing, the right end of the screw rod 303 penetrates through the right side of the cross beam 3 and is welded to the output end of the first motor 301, a transmission assembly 4 is fixed at the bottom of the guide block 305, the transmission assembly 4 comprises a second motor 401, a rotating rod 402 and a steel cable 403, wherein the second motor 401 is connected to the rotating rod 402 through a bevel gear, the steel cable 403 is wound on the surface of the rotating rod 402, and the connecting frame 5 is fixed at the bottom end of the steel cable 403;

the bottom of link 5 has hoist and mount subassembly 6 through hinged joint, and hoist and mount subassembly 6 is including placing frame 601, crash pad 602, support sleeve 603, backup pad 604 and limiting plate 605.

Further, hoist and mount subassembly 6 is provided with threely, and all is fixed in the bottom of link 5 to every left and right sides of placing frame 601 all installs crashproof pad 602, when hoist and mount during operation, can prevent through crashproof pad 602 to place frame 601 and lead to the mining equipment to damage when colliding mutually.

Further, the inside top and the below of placing frame 601 all are fixed with supporting sleeve 603, and supporting sleeve 603's inboard is fixed with backup pad 604, and wherein the inboard of backup pad 604 all is the setting of indent arc surface, laminates mutually with the low side the top of equipment through backup pad 604, can increase the stability of equipment placing frame 601 inside.

Furthermore, the left side and the right side of the inner wall of the placing frame 601 are both fixed with limiting plates 605 through springs, wherein the inner sides of the limiting plates 605 are both concave arc surfaces, and when mining equipment is placed inside the placing frame 601, the limiting plates 605 are tightly attached to the surface of the equipment through spring rebounding after the limiting plates 605 are pressed.

Further, springs are arranged inside the supporting sleeves 603, the supporting plates 604 are embedded into the supporting sleeves 603 through connecting rods, when mining equipment is placed inside the placing frame 601, the supporting plates 604 are pressed, and the mining equipment is fixed after the supporting plates 604 are released through elastic acting forces of the springs.

The first motor 301 and the second motor 401 are electrically connected to an external power source through power lines, and signal output ends of the first motor 301 and the second motor 401 are in signal connection with a signal receiving end of the controller.

The working principle is as follows:

during the use, at first, put into mining equipment to placing inside the frame 601, fix equipment through its backup pad 604 and limiting plate 605, prevent that it from appearing the slope phenomenon when hoist and mount, then, start second motor 401 and drive bull stick 402 and rotate, and make steel cable 403 drive link 5 and hoist and mount subassembly 6 and lift by crane, then, rocking that appears when equipment when hoist and mount, the crashproof pad 602 through placing frame 601 surface setting can slow down the impact that it received, immediately, cushion limiting plate 605 through the spring, and cushion backup pad 604 through supporting sleeve 603, can effectually slow down the striking that equipment received, prevent that equipment from receiving the damage, finally, start first motor 301 and drive lead screw 303 and rotate, make guide block 305 drive equipment and remove about guide arm 304 surface, reach and adjust when installing equipment.

Claims

1. A multidirectional-adjusting mine electromechanical equipment installation mechanism comprises a support frame (1) and a base (2), wherein the support frame (1) is welded at the top of the base (2), a cross beam (3) is welded at the top of the support frame (1), the cross beam (3) comprises a motor (301), a guide groove (302), a screw rod (303), a guide rod (304) and a guide block (305), wherein the front surface of the beam (3) is provided with a controller, the right side surface of the beam (3) is fixed with a motor (301), the inside of the beam (3) is transversely provided with a guide groove (302), a matched guide block (305) is movably arranged in the guide groove (302), the left and right threads in the middle of the guide block (305) penetrate through a screw rod (303), the guide block (305) penetrates through a guide rod (304), the left end of the screw rod (303) is movably connected with the inner wall of the left side of the guide groove (302) through a bearing, and the right end of the screw rod (303) penetrates through the right side of the cross beam (3) and is welded to the output end of the first motor (301);

a transmission assembly (4) is fixed at the bottom of the guide block (305), the transmission assembly (4) comprises a second motor (401), a rotating rod (402) and a steel rope (403), wherein the second motor (401) is connected to the rotating rod (402) through a bevel gear, the steel rope (403) is wound on the surface of the rotating rod (402), and a connecting frame (5) is fixed at the bottom end of the steel rope (403);

the bottom of link (5) has hoisting assembly (6) through hinged joint, and hoisting assembly (6) are including placing frame (601), crashproof pad (602), support sleeve (603), backup pad (604) and limiting plate (605).

2. The mining electromechanical device mounting mechanism with multidirectional adjustment as claimed in claim 1, wherein the hoisting assembly (6) is provided in three numbers, and is fixed to the bottom of the connecting frame (5), and crash pads (602) are mounted on the left and right sides of each placing frame (601).

3. The mining electromechanical device mounting mechanism with multidirectional adjustment as claimed in claim 1, wherein supporting sleeves (603) are fixed above and below the inside of the placing frame (601), supporting plates (604) are fixed on the inner sides of the supporting sleeves (603), and the inner sides of the supporting plates (604) are arranged in the shape of concave circular arcs.

4. The mining electromechanical device mounting mechanism with multidirectional adjustment as claimed in claim 1, wherein limiting plates (605) are fixed to left and right sides of the inner wall of the placing frame (601) through springs, and inner sides of the limiting plates (605) are concave arc surfaces.

5. The mining electromechanical device mounting mechanism according to claim 4, characterized in that springs are arranged inside the supporting sleeves (603), wherein the supporting plates (604) are embedded inside the supporting sleeves (603) through connecting rods.