CN211254957U - Hardware component production hoist and mount rigging for transportation - Google Patents

Abstract

The utility model discloses a hardware component production hoist and mount rigging for transportation, including the rectangle crossbeam, rectangle crossbeam below is equipped with compression control mechanism, compression control mechanism top is equipped with the bearing telescopic machanism. The beneficial effects of the utility model are that, transfer hardware component that can be in batches replaces manual operation, improves hardware component handling efficiency by a wide margin, reaches the effect that reduces the cost of manufacture.

Description

Hardware component production hoist and mount rigging for transportation

Technical Field

The utility model relates to a hardware component transportation technical field, more specifically say, relate to a hardware component production hoist and mount rigging for transportation.

Background

The rigging is a stressed tool tied between a hoisting machine and a hoisted object in order to realize object moving and a stressed member for stabilizing a space structure, and the metal rigging mainly comprises: wire rope slings, chain slings, shackle slings, hook slings, and the like.

The main structure of a traditional rigging, for example, patent No. 201820091594.5 named as a combined chain rigging, is composed of a hanging ring, a load-bearing rotating part and a chain, and although it is relatively stable, due to the structural limitation, the function is relatively single, and it is not possible to hoist hardware quickly.

SUMMERY OF THE UTILITY MODEL

To above defect, the utility model provides a hardware component production hoist and mount rigging for transportation to the problem of solution.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a hoisting rigging for hardware production and transportation comprises a rectangular cross beam, wherein a compression control mechanism is arranged below the rectangular cross beam, and a bearing telescopic mechanism is arranged above the compression control mechanism;

the compression control mechanism comprises a fixing hole at the lower end of the rectangular cross beam, the fixing hole is provided with a plurality of uniformly distributed lifting rings, lifting rings are arranged on the inner surface of the fixing hole, a first bearing chain is arranged in each lifting ring, a T-shaped connecting rod is arranged at the lower end of each bearing chain, the upper end of each T-shaped connecting rod is fixedly connected with the corresponding bearing chain, pin shafts are arranged on the opposite side surfaces of the lower end of each T-shaped connecting rod and fixedly connected with the corresponding T-shaped connecting rod, a bearing pipe is arranged at the lower end of each T-shaped connecting rod, connecting holes are formed; the upper surface of the bearing pipe is provided with a circular through hole, the inner surface of the circular through hole is provided with a sliding block, the upper surface of the sliding block is provided with a pressing plate, the side surface of the upper end of the sliding block is provided with a first retaining ring, the inner surface of the upper end of the bearing pipe is provided with a second retaining ring, and a compression spring is arranged between the second retaining ring and the sliding block;

the bearing telescopic mechanism comprises a transmission rod on the lower surface of the sliding block, and the upper end of the transmission rod is fixedly connected with the sliding block; the bearing pipe is characterized in that a rectangular opening is formed in the side surface of the lower end of the bearing pipe, three openings are uniformly distributed, a triangular rotating block is mounted on the inner surface of the rectangular opening, the lower end of the triangular rotating block is hinged with the rectangular opening, and a limiting plate is mounted on the side surface of the triangular rotating block; and one side of the upper end of the triangular rotating block is provided with a connecting rod, and two ends of the connecting rod are respectively hinged with the transmission rod and the triangular rotating block.

Further, the side surface of the bearing pipe is provided with a flange sample.

Furthermore, fixed rings are installed at two ends of the upper surface of the rectangular cross beam, a second bearing chain is installed on the inner surface of each fixed ring, and a hoisting ring is installed at the upper end of each second bearing chain.

Furthermore, the upper surface of the triangular rotating block is provided with a wear pad.

The utility model has the advantages that: the lifting appliance has the function of lifting common objects, and simultaneously can lift hardware parts, thereby enlarging the application range of the rigging and enhancing the practicability of the rigging.

Drawings

FIG. 1 is a schematic structural view of a hoisting rigging for production and transportation of hardware components according to the present invention;

FIG. 2 is a state diagram of the compression control mechanism;

FIG. 3 is a schematic view of a compression control mechanism;

FIG. 4 is a schematic top view of the load-bearing telescoping mechanism;

FIG. 5 is a schematic view of the condition of the load bearing telescoping mechanism;

in the figure, 1, a rectangular beam; 2. a fixing hole; 3. a first bearing chain; 4. a T-shaped connecting rod; 5. a pin shaft; 6. a load bearing tube; 7. connecting holes; 8. a circular through hole; 9. a slider; 10. a pressing plate; 11. a first check ring; 12. a second check ring; 13. a compression spring; 14. a transmission rod; 15. a rectangular opening; 16. a triangular turning block; 17. a limiting plate; 18. a connecting rod; 19. a flange sample; 20. a fixing ring; 21. a second bearing chain; 22. a hoisting ring; 23. a wear pad; 24. a lifting ring.

Detailed Description

The utility model is described in detail with reference to the accompanying drawings, as shown in fig. 1-5, a hoisting rigging for hardware production and transportation comprises a rectangular beam 1, a compression control mechanism is arranged below the rectangular beam 1, and a bearing telescopic mechanism is arranged above the compression control mechanism;

the compression control mechanism comprises a fixing hole 2 at the lower end of a rectangular cross beam 1, the fixing hole 2 is provided with a plurality of uniformly distributed hanging rings 24, the inner surface of the fixing hole 2 is provided with a first bearing chain 3, the lower end of the first bearing chain 3 is provided with a T-shaped connecting rod 4, the upper end of the T-shaped connecting rod 4 is fixedly connected with the first bearing chain 3, the opposite side surface of the lower end of the T-shaped connecting rod 4 is provided with a pin shaft 5, the pin shaft 5 is fixedly connected with the T-shaped connecting rod 4, the lower end of the T-shaped connecting rod 4 is provided with a bearing pipe 6, the two sides of the upper end of the bearing pipe; a circular through hole 8 is formed in the upper surface of the bearing pipe 6, a sliding block 9 is installed on the inner surface of the circular through hole 8, a pressing plate 10 is installed on the upper surface of the sliding block 9, a first check ring 11 is installed on the side surface of the upper end of the sliding block 9, a second check ring 12 is installed on the inner surface of the upper end of the bearing pipe 6, and a compression spring 13 is installed between the second check ring 12 and the sliding block 9;

the bearing telescopic mechanism comprises a transmission rod 14 on the lower surface of the sliding block 9, and the upper end of the transmission rod 14 is fixedly connected with the sliding block 9; the side surface of the lower end of the bearing pipe 6 is provided with three rectangular openings 15, the rectangular openings 15 are uniformly distributed, triangular rotating blocks 16 are arranged on the inner surface of the rectangular openings 15, the lower ends of the triangular rotating blocks 16 are hinged with the rectangular openings 15, and limiting plates 17 are arranged on the side surface of the triangular rotating blocks 16; a connecting rod 18 is arranged on one side of the upper end of the triangular rotating block 16, and two ends of the connecting rod 18 are respectively hinged with the transmission rod 14 and the triangular rotating block 16.

The side surface of the bearing pipe 6 is provided with a flange sample 19.

Fixed rings 20 are installed at two ends of the upper surface of the rectangular cross beam 1, bearing chains II 21 are installed on the inner surfaces of the fixed rings 20, hoisting rings 22 are installed at the upper ends of the bearing chains II 21, and the balance of the whole device can be enhanced through the force application of the two bearing chains II 21.

The triangular turning block 16 is provided with a wear pad 23 on the upper surface, and the durability of the device can be increased through the action of the wear pad 23.

In the present embodiment, the range of application of the device is limited to hardware with holes, such as flange, bearing, sheave, etc., the description takes the flange as an example, the use of the device needs to satisfy two conditions, and the hardware needs to be in a stacked state when being stored, as shown in fig. 1; when the device is used, the device can be connected with hoisting equipment, such as a crown block and an electric hoist; when the device is used, firstly, the hoisting ring 22 is hung at the hoisting end of hoisting equipment manually, then the hoisting equipment is controlled to drive the whole device to move to a position right above the flange and descend to a proper height, the length of a bearing chain I3 can be increased according to actual conditions, and then the bearing pipe 6 is manually pulled to be inserted into an inner hole of the flange sample 19;

during insertion, due to the limitation of the inner hole of the flange sample 19, the sliding block 9 is manually pressed to move downwards during insertion, so that the sliding block 9 and the bearing pipe 6 move relatively, the sliding block 9 moves to drive the transmission rod 14 to press downwards, because the lower end of the triangular rotating block 16 is hinged with the rectangular opening 15, the transmission rod 14 pulls the connecting rod 18, the other end of the connecting rod 18 pulls the triangular rotating block 16 to rotate inwards while pulling the connecting rod 18, and finally the triangular rotating block 16 retracts into the bearing pipe 6, as shown in fig. 2 and 5, so that the triangular rotating block 16 and the inner hole of the flange sample 19 are prevented from being clamped together;

when the bearing pipe 6 is inserted to the bottom, the pressing plate 10 can be released, the sliding block 9 can be jacked upwards under the action of the compression spring 13, the sliding block 9 drives the transmission rod 14 to move upwards, the transmission rod 14 moves to push the connecting rod 18 and the triangular rotating block 16, the connecting rod 18 is in a horizontal state, the triangular rotating block 16 protrudes out of the rectangular opening 15, the upper surface of the triangular rotating block 16 clamps the inner hole of the flange sample 19, and as shown in fig. 3 and 4, after the bearing pipe 6 is successively inserted into the flange sample 19, external hoisting equipment is controlled to move, so that the purpose of batch movement is achieved; the sliding position of the sliding block 9 can be limited through the action of the first retainer ring 11 and the second retainer ring 12, the rotating position of the triangular rotating block 16 is indirectly controlled, and the transmission rod 14 adopts a structure with a thick upper part and a thin lower part, so that the interference with the triangular rotating block 16 is avoided while the structural strength of the transmission rod 14 is enhanced; when a common object needs to be hoisted, the hoisting ring 24 can be disassembled to separate the first bearing chain 3 from the hoisting ring 24, so that the hoisting ring 24 can hoist other objects.

Above-mentioned technical scheme has only embodied the utility model discloses technical scheme's preferred technical scheme, some changes that this technical field's technical personnel probably made to some parts wherein have all embodied the utility model discloses a principle belongs to within the protection scope of the utility model.

Claims (4)

1. A hoisting rigging for hardware component production and transportation comprises a rectangular cross beam (1), and is characterized in that a compression control mechanism is arranged below the rectangular cross beam (1), and a bearing telescopic mechanism is arranged above the compression control mechanism;

the compression control mechanism comprises a fixing hole (2) at the lower end of a rectangular cross beam (1), the fixing hole (2) is provided with a plurality of uniformly distributed fixing holes, a lifting ring (24) is installed on the inner surface of the fixing hole (2), a first bearing chain (3) is installed in the lifting ring (24), a T-shaped connecting rod (4) is installed at the lower end of the first bearing chain (3), the upper end of the T-shaped connecting rod (4) is fixedly connected with the first bearing chain (3), pin shafts (5) are installed on opposite side surfaces of the lower end of the T-shaped connecting rod (4), the pin shafts (5) are fixedly connected with the T-shaped connecting rod (4), a bearing pipe (6) is arranged at the lower end of the T-shaped connecting rod (4), connecting holes (7) are formed in two sides of the; a circular through hole (8) is formed in the upper surface of the bearing pipe (6), a sliding block (9) is installed on the inner surface of the circular through hole (8), a pressing plate (10) is installed on the upper surface of the sliding block (9), a first check ring (11) is installed on the side surface of the upper end of the sliding block (9), a second check ring (12) is installed on the inner surface of the upper end of the bearing pipe (6), and a compression spring (13) is installed between the second check ring (12) and the sliding block (9);

the bearing telescopic mechanism comprises a transmission rod (14) on the lower surface of the sliding block (9), and the upper end of the transmission rod (14) is fixedly connected with the sliding block (9); the bearing pipe is characterized in that rectangular openings (15) are formed in the side surface of the lower end of the bearing pipe (6), the rectangular openings (15) are three and evenly distributed, triangular rotating blocks (16) are installed on the inner surface of the rectangular openings (15), the lower ends of the triangular rotating blocks (16) are hinged to the rectangular openings (15), and limiting plates (17) are installed on the side surface of the triangular rotating blocks (16); a connecting rod (18) is installed on one side of the upper end of the triangular rotating block (16), and two ends of the connecting rod (18) are hinged to the transmission rod (14) and the triangular rotating block (16) respectively.

2. The hoisting rigging for hardware production and transportation according to claim 1, wherein the side surface of the load-bearing pipe (6) is provided with a flange sample (19).

3. The hoisting rigging for hardware component production and transportation according to claim 1, wherein two ends of the upper surface of the rectangular cross beam (1) are provided with fixing rings (20), the inner surface of each fixing ring (20) is provided with a second bearing chain (21), and the upper end of each second bearing chain (21) is provided with a hoisting ring (22).

4. The hardware component production transportation lifting rigging of claim 1, wherein a wear pad (23) is mounted on an upper surface of the triangular turning block (16).

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