CN217377179U - Female raw materials stack loading attachment that arranges - Google Patents

Abstract

The application provides female raw materials stack loading attachment that arranges includes: base and elevating system. Be equipped with the multiunit support frame along length direction on the base, the support frame is equipped with the crossbeam for stack female raw materials of arranging, the length direction mutually perpendicular of crossbeam and base. Elevating system locates on the base, and is located the crossbeam below, and elevating system moves the setting along the width direction of base, and elevating system is equipped with two sets of jacking subassemblies, and the jacking subassembly can rise simultaneously and descend for female row's raw materials jack-up upwards of stack on the crossbeam. Can carry out the stack to female raw materials copper and store to can be with the copper jacking of stacking to predetermined height, so that send into cutting device with the copper, can effectively prevent that the copper from bending, and avoid taking place the incident.

Description

Female raw materials stack loading attachment that arranges

Technical Field

The utility model belongs to the technical field of the female row of switch board is deposited and pay-off, especially, relate to a female raw materials stack loading attachment that arranges.

Background

The busbar of the power distribution cabinet is usually made of a thick copper plate, the length of the copper plate serving as the raw material of the busbar is usually longer, and the busbar is cut off according to the design size when the busbar needs to be made. And just because copper length dimension is great, for avoiding hoist and mount to lead to the copper to bend when sending into cutting device, adopt a plurality of workers to lift the workstation of cutting device on with the copper usually, not only comparatively consume physical power, still have the risk of dropping and bending moreover.

SUMMERY OF THE UTILITY MODEL

For solving prior art not enough, the utility model provides a female raw materials stack loading attachment that arranges can carry out the stack to female raw materials copper and store to can be with the copper jacking that the stack is good to predetermined height, so that send into cutting device with the copper, can prevent effectively that the copper from bending, and avoid taking place the incident.

In order to realize the purpose of the utility model, the following scheme is planned to be adopted:

a female raw materials stack loading attachment that arranges includes: base and elevating system.

Be equipped with the multiunit support frame along length direction on the base, the support frame is equipped with the crossbeam for stack female raw materials of arranging, the length direction mutually perpendicular of crossbeam and base.

Elevating system locates on the base, and is located the crossbeam below, and elevating system moves the setting along the width direction of base, and elevating system is equipped with two sets of jacking subassemblies, and the jacking subassembly can rise simultaneously and descend for female row's raw materials jack-up upwards of stack on the crossbeam.

Furthermore, the lifting mechanism also comprises a supporting plate, the supporting plate is movably arranged on the base, the jacking components are respectively arranged at two ends of the supporting plate, each jacking component comprises a first hinged plate and a second hinged plate, and one ends of the first hinged plate and the second hinged plate are hinged with each other; the other end of the first hinged plate is hinged to the end part of the supporting plate, the other end of the second hinged plate faces the middle part of the supporting plate and is hinged to a sliding trolley respectively, the sliding trolley moves along the length direction of the supporting plate, and the two groups of sliding trolleys can move towards opposite directions or opposite directions simultaneously.

Furthermore, a top plate is coaxially hinged above one end of the first hinged plate, which is hinged with the second hinged plate, in a hinged mode.

Further, the top surface and the bottom surface that the slip dolly corresponds the backup pad all are equipped with the gyro wheel, are rolling contact between gyro wheel and the backup pad.

Furthermore, a bidirectional screw rod is arranged in the middle section of the supporting plate in parallel, the bidirectional screw rod can be driven to rotate manually or by a motor, threads at two ends of the bidirectional screw rod are opposite in opposite directions, and two ends of the bidirectional screw rod are connected to the two sets of sliding trolleys respectively.

Furthermore, a worm wheel is coaxially arranged in the middle of the bidirectional screw rod, a worm is meshed with the worm wheel, and the worm is rotatably arranged on the supporting plate.

Further, one end of the worm is provided with a connecting part for connecting a driving shaft, and the driving shaft is used for connecting a driving source.

Furthermore, the crossbeam is equipped with many spacer bars along length direction, and the spacer bar perpendicular to base, and the spacer bar removes the setting along the length direction of crossbeam.

The beneficial effects of the utility model reside in that: the supporting frame can be used for stacking and storing raw materials of the busbar, and the stacked copper plates can be jacked to a preset height by using the lifting mechanism when the device is used, so that the copper plates can be conveniently sent to the cutting device, the copper plates can be effectively prevented from being bent, and safety accidents are avoided; and the lifting mechanism can be moved to the position below any row of stacked copper plates by sliding the lifting mechanism on the base, so that the row of copper plates can be lifted.

Drawings

The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.

Fig. 1 shows an overall configuration diagram of the present application.

Fig. 2 shows an enlarged view at a in fig. 1.

Fig. 3 is a schematic view showing a state where the present application stores a busbar material.

Fig. 4 shows a bottom structure of the present application when storing the busbar raw material.

The mark in the figure is: the lifting device comprises a base-1, a lifting mechanism-2, a jacking assembly-21, a first hinge plate-211, a second hinge plate-212, a support plate-22, a sliding trolley-23, a top plate-24, a bidirectional screw rod-25, a worm wheel-26, a worm-27, a connecting part-271, a drive shaft-28, a crank-29, a support frame-3, a cross beam-31, a spacing rod-32 and a sliding block-33.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following detailed description of the embodiments of the present invention is provided with reference to the accompanying drawings, but the described embodiments of the present invention are some embodiments of the present invention, not all embodiments.

Examples

As shown in fig. 1, 3 and 4, a busbar raw material stacking and feeding device includes: a base 1 and a lifting mechanism 2.

Specifically, as shown in fig. 1, a plurality of groups of support frames 3 are arranged on the base 1 along the length direction, the support frames 3 are provided with cross beams 31 for stacking the busbar raw materials, and the length direction of the stacked busbar raw materials is consistent with the length direction of the base 1. The two sides of the supporting frame 3 are also provided with upright columns to play a main role in limiting, supporting and connecting. The beam 31 is perpendicular to the longitudinal direction of the base 1.

Specifically, as shown in fig. 1, the lifting mechanism 2 is disposed on the base 1 and located below the cross beam 31, the lifting mechanism 2 is disposed along the width direction of the base 1, the lifting mechanism 2 is provided with two sets of jacking assemblies 21, the jacking assemblies 21 can simultaneously ascend and descend, and the lifting mechanism is used for jacking up the busbar raw material stacked on the cross beam 31 upwards and keeping the busbar raw material in a horizontal state.

More specifically, as shown in fig. 1, the lifting mechanism 2 further includes a supporting plate 22, the supporting plate 22 is movably disposed on the base 1, the jacking assemblies 21 are respectively disposed at two ends of the supporting plate 22, each jacking assembly 21 includes a first hinged plate 211 and a second hinged plate 212, one end of each of the first hinged plate 211 and the second hinged plate 212 is hinged to each other, and the end is used for jacking the busbar.

The other end of the first hinge plate 211 is hinged to the end of the support plate 22, and the other end of the second hinge plate 212 faces the middle of the support plate 22 and is hinged to a sliding trolley 23. The sliding carriages 23 are arranged to move along the length direction of the support plate 22, and the two sets of sliding carriages 23 can move towards the opposite direction or the opposite direction simultaneously.

When the two groups of sliding trolleys 23 move towards opposite directions, one end, hinged with each other, of the first hinge plate 211 and the second hinge plate 212 moves downwards, so that the jacking assembly 21 can be separated from the busbar; when the two sets of sliding trolleys 23 move in opposite directions, the hinged end of the first hinge plate 211 and the hinged end of the second hinge plate 212 move upwards, and the busbar can be jacked upwards.

Preferably, as shown in fig. 1, a top plate 24 is coaxially hinged above the end where the first hinge plate 211 and the second hinge plate 212 are hinged to each other. When the busbar raw material is jacked, the top surface of the top plate 24 is contacted with the bottom surface of the busbar raw material, so that the contact surface can be increased, and the stability is improved.

Preferably, the sliding trolley 23 is provided with rollers corresponding to the top surface and the bottom surface of the supporting plate 22, and the rollers are in rolling contact with the supporting plate 22, so that the resistance of the sliding trolley 23 during movement is reduced, and the sliding trolley 23 can move more smoothly.

More specifically, as shown in fig. 1 and 2, a bidirectional screw 25 is disposed in parallel at the middle section of the supporting plate 22, the bidirectional screw 25 can be driven to rotate by hand or by a motor, the threads at the two ends of the bidirectional screw 25 are opposite, and the two ends of the bidirectional screw 25 are respectively connected to the two sets of sliding trolleys 23. The bidirectional screw rod 25 is positioned below the second hinge plate 212, and the two sets of sliding trolleys 23 can move towards the opposite direction or the opposite direction simultaneously by rotating the bidirectional screw rod 25.

Preferably, as shown in fig. 2, a worm wheel 26 is coaxially disposed in the middle of the bidirectional screw 25, a worm 27 is engaged with the worm wheel 26, and the worm 27 is rotatably disposed on the support plate 22. The worm 27 is driven to rotate to drive the worm wheel 26 and the bidirectional screw rod 25 to rotate, so that the jacking height of the jacking assembly 21 is controlled. The worm gear mechanism has the function of preventing reverse rotation, and the jacking assembly 21 can be locked by using the function, so that the jacking assembly 21 is prevented from automatically falling; the worm 27 can be rotated manually or by a motor.

It is further preferable that one end of the worm 27 is provided with a connecting portion 271 for connecting the driving shaft 28, and the driving shaft 28 is used for connecting the driving source. The driving source can be a motor or a hand crank 29 as shown in fig. 1 and 3. Specifically, as shown in fig. 2, in the present embodiment, the connecting portion 271 is a hexagonal hole, and the front end of the corresponding driving shaft 28 has a hexagonal prism. Alternatively, the connecting portion 271 may be a hexagonal prism, and the front end of the corresponding driving shaft 28 is a hexagonal socket.

Preferably, as shown in fig. 1, 3 and 4, the cross beam 31 is provided with a plurality of spacing bars 32 along the length direction, and the spacing bars 32 are perpendicular to the base 1 and are used for spacing a plurality of rows of stacked busbars. And the spacing rods 32 are movably arranged along the length direction of the cross beam 31 so as to adapt to busbars with different widths.

Specifically, as shown in fig. 2, the cross beam 31 is provided with a sliding block 33 in a sliding manner along the length direction, and the spacing rod 32 is inserted into the sliding block 33 through a threaded connection structure, so as to increase or decrease.

The foregoing is only a preferred embodiment of the invention and is not intended to be the only or limiting embodiment of the invention. It should be understood by those skilled in the art that various changes and equivalent substitutions made herein may be made without departing from the scope of the invention as defined by the appended claims.

Claims (8)

1. The utility model provides a female raw materials stack loading attachment that arranges which characterized in that includes: a base (1) and a lifting mechanism (2);

a plurality of groups of supporting frames (3) are arranged on the base (1) along the length direction, the supporting frames (3) are provided with cross beams (31) for stacking busbar raw materials, and the length directions of the cross beams (31) and the base (1) are mutually vertical;

elevating system (2) are located on base (1), and are located crossbeam (31) below, and elevating system (2) remove the setting along the width direction of base (1), and elevating system (2) are equipped with two sets of jacking subassembly (21), and jacking subassembly (21) can rise simultaneously and descend for with the female raw materials of arranging of stack on crossbeam (31) jack-up that makes progress.

2. The busbar raw material stacking and feeding device according to claim 1, wherein the lifting mechanism (2) further comprises a supporting plate (22), the supporting plate (22) is movably arranged on the base (1), the jacking assemblies (21) are respectively arranged at two ends of the supporting plate (22), each jacking assembly (21) comprises a first hinged plate (211) and a second hinged plate (212), and one ends of the first hinged plate (211) and the second hinged plate (212) are hinged to each other; the other end of the first hinged plate (211) is hinged to the end of the supporting plate (22), the other end of the second hinged plate (212) faces the middle of the supporting plate (22) and is hinged to a sliding trolley (23) respectively, the sliding trolley (23) moves along the length direction of the supporting plate (22), and the two groups of sliding trolleys (23) can move towards opposite directions or opposite directions simultaneously.

3. Busbar material stacking and feeding device according to claim 2, wherein a top plate (24) is coaxially hinged above the end where the first hinge plate (211) and the second hinge plate (212) are hinged to each other.

4. The busbar raw material stacking and feeding device according to claim 2, wherein the sliding trolley (23) is provided with rollers corresponding to the top surface and the bottom surface of the support plate (22), and the rollers are in rolling contact with the support plate (22).

5. Busbar raw material stacking and feeding device according to claim 2, wherein a bidirectional screw rod (25) is arranged in parallel at the middle section of the supporting plate (22), the bidirectional screw rod (25) can be driven to rotate manually or by a motor, the threads at the two ends of the bidirectional screw rod (25) are opposite, and the two ends of the bidirectional screw rod (25) are respectively connected to the two sets of sliding trolleys (23).

6. Busbar raw material stacking and feeding device according to claim 5, wherein a worm wheel (26) is coaxially arranged in the middle of the bidirectional screw rod (25), a worm (27) is meshed with the worm wheel (26), and the worm (27) is rotatably arranged on the support plate (22).

7. Busbar material stack loading device according to claim 6, wherein one end of the worm (27) is provided with a connection part (271) for connecting a drive shaft (28), the drive shaft (28) being used for connecting a drive source.

8. Busbar raw material stacking and feeding device according to claim 1, wherein the cross beam (31) is provided with a plurality of spacing rods (32) along the length direction, the spacing rods (32) are perpendicular to the base (1), and the spacing rods (32) are movably arranged along the length direction of the cross beam (31).

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