CN217708286U

CN217708286U - Raw material bundling mechanism of cable galvanized steel strand

Info

Publication number: CN217708286U
Application number: CN202221009805.9U
Authority: CN
Inventors: 徐磊
Original assignee: Yixing Jinzhi Technology Co ltd
Current assignee: Yixing Jinzhi Technology Co ltd
Priority date: 2022-04-28
Filing date: 2022-04-28
Publication date: 2022-11-01
Anticipated expiration: 2032-04-28

Abstract

The utility model discloses a raw material bundling mechanism of a cable galvanized steel strand, which comprises a raw material winding roll, a bundling roll and a reciprocating guide mechanism, wherein the reciprocating guide mechanism comprises a first vertical plate and a second vertical plate, a sliding guide rod and two screw rods are arranged between the first vertical plate and the second vertical plate, and the two screw rods are driven by a power mechanism to rotate in different directions; a sliding block is horizontally matched on the sliding guide rod in a sliding manner, a supporting frame is integrally arranged on the sliding block, a single-wire guide structure is arranged on the supporting frame, and a single wire on the raw material winding roller passes through the single-wire guide structure and then is wound on the winding roller; be provided with the switching-over piece in the carriage, go up cardboard and lower cardboard, be provided with the structure of cardboard sideslip about the drive on first riser and the second riser, can drive the switching-over piece up-and-down motion, make the switching-over hole in the switching-over piece change with it complex screw rod to realize the switching-over, drive the single line reciprocating motion on sliding block and the sliding block, thereby make the raw materials coil bundling of stranded conductor more even.

Description

Raw material bundling mechanism of cable galvanized steel strand

Technical Field

The utility model relates to a coil bundling technical field especially relates to raw materials bundling mechanism of cable galvanized steel strand wires.

Background

The stranding machine is a stranding mechanical device which can be widely applied to various soft/hard conductor wires, so that a plurality of single conductors are twisted into one strand to meet the process requirements of wires. Before a stranding machine is used for producing galvanized steel strands of cables, a raw material coil of the galvanized steel strands of the cables needs to be coiled, the raw material coil is coiled to a wire spool, and then the wire spool wound with the raw material coil is installed to the stranding machine to produce the stranded wires. When the traditional coil separating mechanism is used for separating the coil of the raw material, the single wire is difficult to be uniformly wound and needs to be improved.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the not enough of existence among the prior art, the utility model provides a raw materials bundling mechanism of cable galvanized steel strand wires is provided with reciprocal guiding mechanism, makes the raw materials coil bundling of stranded conductor more even.

The technical scheme is as follows: in order to achieve the purpose, the raw material unwinding mechanism of the cable galvanized steel strand comprises a raw material winding roller, a unwinding roller and a reciprocating guide mechanism arranged between the raw material winding roller and the unwinding roller, wherein the reciprocating guide mechanism comprises a first vertical plate and a second vertical plate which are oppositely arranged, a sliding guide rod and two screw rods are arranged between the first vertical plate and the second vertical plate, and the two screw rods are driven by a power mechanism to rotate in different directions; a sliding block is horizontally matched on the sliding guide rod in a sliding manner, a supporting frame is integrally arranged on the sliding block, a single-wire guide structure is arranged on the supporting frame, and a single wire on the raw material winding roller passes through the single-wire guide structure and then is wound on the winding roller; the supporting frame is internally provided with a reversing block which vertically slides, a vertical reversing hole is formed in the reversing block, two screw rods transversely penetrate through the reversing hole, and the upper end and the lower end of the reversing hole are respectively provided with a thread structure matched with the corresponding screw rods; an upper clamping plate is arranged on one side of the upper end of the reversing block, a lower clamping plate is arranged on the other side of the lower end of the reversing block, and the upper clamping plate and the lower clamping plate are respectively in horizontal sliding fit with the supporting frame; a first jacking inclined surface is arranged at the upper end of one side, facing the first vertical plate, of the reversing block, and a second jacking inclined surface is arranged at the lower end of one side, facing the second vertical plate, of the reversing block; the first vertical plate is provided with a first jacking part for driving the upper clamping plate to be close to the reversing block, a first transmission part for driving the lower clamping plate to be far away from the reversing block and a first elastic structure matched with the first jacking inclined plane; and a second jacking part for driving the lower clamping plate to be close to the reversing block, a second transmission part for driving the upper clamping plate to be far away from the reversing block and a second elastic structure matched with the second jacking inclined surface are arranged on the second vertical plate.

Furthermore, the first jacking part and the second jacking part are both composed of hollow sleeve plates and elastic triangular plates transversely inserted in the hollow sleeve plates, and elastic parts are arranged between the elastic triangular plates and the corresponding hollow sleeve plates; and jacking triangular grooves which are in jacking press fit with the corresponding elastic triangular plates are respectively arranged below the upper clamping plate and above the lower clamping plate.

Furthermore, the first transmission piece and the second transmission piece are transversely arranged transmission triangular plates, and transmission triangular grooves in transmission fit with the corresponding transmission triangular plates are respectively arranged below the lower clamping plate and above the upper clamping plate.

Furthermore, the first elastic structure and the second elastic structure are both composed of a U-shaped plate and a jacking inclined block vertically matched with the U-shaped plate in a sliding manner, and a vertical spring part is arranged between the jacking inclined block and the corresponding U-shaped plate; the first jacking inclined surface and the second jacking inclined surface are respectively in jacking fit with the corresponding jacking inclined blocks.

Furthermore, a plurality of transverse guide holes are formed in the supporting frame, and transverse guide rods in sliding fit with the transverse guide holes are respectively arranged on one sides of the upper clamping plate and the lower clamping plate; a plurality of vertical guide rods are arranged in the supporting frame, and vertical guide holes in sliding fit with the vertical guide rods are arranged on the reversing block.

Furthermore, an upper jack is arranged on one side, away from the upper clamping plate, of the upper end of the reversing block, and the upper clamping plate is in inserted fit with the upper jack; one side of the lower end of the reversing block, which is far away from the lower clamping plate, is provided with a lower insertion hole, and the lower clamping plate is in insertion fit with the lower insertion hole.

Furthermore, the winding splitting roller is driven to rotate by a driving motor arranged on one side, and an output shaft of the driving motor is provided with a first driving disc; the end parts of the two screws are provided with gears which are meshed with each other, the end part of one of the screws is also provided with a second transmission disc, and the first transmission disc and the second transmission disc are connected in a transmission manner through a belt.

Furthermore, the number of the sliding guide rods is two, and the two sliding guide rods are in horizontal sliding fit with the sliding block.

Has the advantages that: the utility model discloses a raw materials bundling mechanism of cable galvanized steel strand wires, its beneficial effect is as follows:

1) The single-wire winding device is provided with a reciprocating guide mechanism which can carry out reciprocating motion on single wires so that the single wires are uniformly wound on the winding splitting roller;

2) The reciprocating guide mechanism and the winding splitting roller are driven by the same motor to move, so that the production cost is saved.

Drawings

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

FIG. 2 is a first schematic plan view of a support frame;

FIG. 3 is a schematic view of a first riser;

FIG. 4 is a schematic view of a second riser;

FIG. 5 is a schematic structural view of a second urging member;

FIG. 6 is a schematic view of a second spring structure;

FIG. 7 is a schematic diagram of the slider during commutation;

FIG. 8 is a second schematic plan view of the support frame;

FIG. 9 is a schematic structural view of an upper clamping plate and a lower clamping plate;

fig. 10 is a schematic structural view of the support frame.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

The raw material uncoiling mechanism of the cable galvanized steel strand as shown in the attached figures 1 to 10 comprises a raw material coiling roller 1, an uncoiling roller 2 and a reciprocating guide mechanism 3 arranged between the raw material coiling roller 1 and the uncoiling roller 2, wherein a raw material coil is prevented from being arranged on the raw material coiling roller 1, and a single wire on the raw material coil passes through the reciprocating guide mechanism 3 and then is coiled on the uncoiling roller 2. The reciprocating guide mechanism 3 is used for driving the single wire to reciprocate along the radial direction of the winding splitting roller 2, so that the single wire can be uniformly wound on the winding splitting roller 2.

Reciprocating guide mechanism 3 is provided with horizontally sliding guide 6 and two horizontally screw rods 7 including relative riser 4 and the second riser 5 that sets up between riser 4 and the second riser 5, two 7 vertical interval arrangements of screw rod, and two screw rods 7 are in the different rotation of turning down of power unit's drive.

Horizontal sliding fit has sliding block 8 on the sliding guide 6, an organic whole is provided with carriage 9 on the sliding block 8, is provided with single line guide structure 10 on the carriage 9, as shown in the embodiment in the attached figure 3, single line guide structure 10 comprises two vertical deflector rolls and a horizontal deflector roll, can lead the single line, and the single line on the raw materials winding up roller 1 is convoluteed on the bundling up roller 2 after passing single line guide structure 10 again.

As shown in fig. 7 and 8, a vertically sliding reversing block 11 is arranged in the supporting frame 9, a vertical reversing hole 12 is arranged in the reversing block 11, the two screws 7 all transversely penetrate through the reversing hole 12, thread structures matched with the corresponding screws 7 are respectively arranged at the upper end and the lower end of the reversing hole 12, the two screws 7 are respectively an upper screw 43 and a lower screw 44, when the upper screw 43 is matched and connected with the thread structures at the upper end of the reversing hole 12, the sliding block 8 is driven to move towards the second vertical plate 5, and when the lower screw 44 is matched and connected with the thread structures at the lower end of the reversing hole 12, the sliding block 8 is driven to move towards the first vertical plate 4.

An upper clamping plate 13 is arranged on one side of the upper end of the reversing block 11, a lower clamping plate 14 is arranged on the other side of the lower end of the reversing block 11, the upper clamping plate 13 and the lower clamping plate 14 are horizontal plate bodies, and the upper clamping plate 13 and the lower clamping plate 14 are respectively in horizontal sliding fit with the supporting frame 9. As shown in fig. 9, a first pressing inclined surface 15 is provided at the upper end of the side of the reversing block 11 facing the first vertical plate 4, and a second pressing inclined surface 16 is provided at the lower end of the side of the reversing block 11 facing the second vertical plate 5.

As shown in fig. 3, the first vertical plate 4 is provided with a first pressing member 17 for driving the upper clamping plate 13 to be close to the reversing block 11, a first transmission member 18 for driving the lower clamping plate 14 to be far from the reversing block 11, and a first elastic structure 19 engaged with the first pressing inclined surface 15. As shown in fig. 4, the second vertical plate 5 is provided with a second pressing member 20 for driving the lower clamping plate 14 to approach the direction changing block 11, a second transmission member 21 for driving the upper clamping plate 13 to move away from the direction changing block 11, and a second elastic structure 22 cooperating with the second pressing inclined surface 16.

The first pressing part 17 and the second pressing part 20 are both composed of a hollow sleeve plate 23 and an elastic triangular plate 24 which is transversely inserted in the hollow sleeve plate 23, and an elastic part 25 is arranged between the elastic triangular plate 24 and the corresponding hollow sleeve plate 23; and jacking triangular grooves 26 which are in jacking fit with the corresponding elastic triangular plates 24 are respectively arranged below the upper clamping plate 13 and above the lower clamping plate 14. The structure of the second pressing member 20 is shown in fig. 5, and the structure of the first pressing member 17 is bilaterally symmetrical to that of the second pressing member 20.

The first transmission piece 18 and the second transmission piece 21 are both transversely arranged transmission triangular plates, and transmission triangular grooves 28 which are in transmission fit with the corresponding transmission triangular plates are respectively arranged below the lower clamping plate 14 and above the upper clamping plate 13.

The top triangular grooves 26 and the transmission triangular grooves 28 on the upper clamping plate 13 and the lower clamping plate 14 are shown in figure 9.

The first elastic structure 19 and the second elastic structure 22 are both composed of a U-shaped plate 29 and a jacking inclined block 30 vertically matched with the U-shaped plate 29 in a sliding manner, and a vertical spring piece 31 is arranged between the jacking inclined block 30 and the corresponding U-shaped plate 29; the first pressing inclined surface 15 and the second pressing inclined surface 16 are respectively matched with the corresponding pressing inclined blocks 30 in a pressing mode. The second elastic structure 22 is shown in fig. 6, and the specific structure of the first elastic structure 19 is symmetrical to the second elastic structure 22.

A plurality of transverse guide holes 32 are formed in the supporting frame 9, and transverse guide rods 33 in sliding fit with the transverse guide holes 32 are respectively arranged on one sides of the upper clamping plate 13 and the lower clamping plate 14 to ensure that the upper clamping plate 13 and the lower clamping plate 13 move horizontally. A plurality of vertical guide rods 34 are arranged in the supporting frame 9, and vertical guide holes 35 which are in sliding fit with the vertical guide rods 34 are arranged on the reversing block 11, so that the reversing block 11 is ensured to move vertically.

An upper jack 36 is arranged on one side of the upper end of the reversing block 11, which is far away from the upper clamping plate 13, and the upper clamping plate 13 is in inserted fit with the upper jack 36. When the upper clamping plate 13 is correspondingly inserted into the upper insertion hole 36, the top pressure limiting effect on the upper end of the reversing block 11 is better. One side of the lower end of the reversing block 11, which is far away from the lower clamping plate 14, is provided with a lower insertion hole 37, and the lower clamping plate 14 is in insertion fit with the lower insertion hole 37. When the lower clamping plate 14 is correspondingly inserted into the lower insertion hole 37, the pressing and limiting effects on the lower end of the reversing block 11 are better.

The unwinding roller 2 is driven to rotate by a driving motor 38 arranged on one side, and an output shaft of the driving motor 38 is provided with a first transmission disc 39; the ends of the two screws 7 are provided with gears 40 which are engaged with each other, the end of one of the screws 7 is further provided with a second transmission disc 41, and the first transmission disc 39 and the second transmission disc 41 are in transmission connection through a belt 42. The driving motor 38 can drive the unwinding roller 2 and the two screws 7 to rotate at the same time, so that the cost is saved.

The number of the sliding guide rods 6 is two, and the two sliding guide rods 6 are in horizontal sliding fit with the sliding block 8 to ensure that the sliding block 8 moves horizontally.

The working principle of the utility model is as follows: referring to fig. 7 and 8, wherein fig. 8 is a schematic plan view corresponding to fig. 7, in fig. 7 and 8, the upper clamping plate 13 and the upper insertion hole 36 are inserted correspondingly to limit and press the upper end of the reversing block 11, and the thread structure at the upper end of the reversing hole 12 is in thread fit connection with the upper screw 43, when the lower screw 44 rotates, the sliding block 8 is driven to move towards the second vertical plate 5, and when the supporting frame 9 approaches the second vertical plate 5, the transmission triangular plate of the second transmission member 21 is matched with the transmission triangular groove 28 on the upper clamping plate 13 to drive the upper clamping plate 13 to be drawn out from the upper insertion hole 36; meanwhile, the elastic triangular plate 24 on the second pressing member 20 is pressed correspondingly to the pressing triangular groove 26 on the lower clamping plate 14, and the elastic member 25 is compressed to accumulate energy because the end of the lower clamping plate 14 is pressed against one side of the reversing block 11 as shown in fig. 8; in addition, the second pressing inclined surface 16 at the lower end of the direction changing block 11 will press against the pressing inclined block 30 on the second elastic structure 22, and since the upper clamping plate 13 still stops at the upper end of the direction changing block 11, the spring element 31 in the second elastic structure 22 will be compressed and store energy.

Then, after the upper clamping plate 13 is completely separated from the upper end of the reversing block 11, the spring member 31 in the second elastic structure 22 pushes the reversing block 11 upwards, so that the thread structure at the lower end of the reversing hole 12 is in thread fit with the lower screw 44, and then the elastic member 25 in the second pushing member 20 drives the lower clamping plate 14 to move transversely and insert into the lower insertion hole 37, so as to push and limit the lower end of the reversing block 11, and ensure that the thread structure at the lower end of the reversing hole 12 can be tightly matched with the lower screw 44. Because the transmission directions of the upper screw 43 and the lower screw 44 are opposite, the sliding block 8 which originally moves towards the second vertical plate 5 can be converted into moving towards the first vertical plate 4, and the automatic reversing of the reciprocating guide mechanism 3 is realized, so that the reciprocating guide mechanism 3 can carry out reciprocating motion on single wires, and the single wires are uniformly wound on the winding roll 2. The working mode of each reversing structure on the first vertical plate 4 is the same as that of the second vertical plate 5, and details are not described here.

The above description is only a preferred embodiment of the present invention, and it should be noted that: for those skilled in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications should also be considered as the protection scope of the present invention.

Claims

1. The raw material bundling mechanism of cable galvanized steel strand, its characterized in that: the device comprises a raw material winding roller (1), a winding roller (2) and a reciprocating guide mechanism (3) arranged between the raw material winding roller and the winding roller, wherein the reciprocating guide mechanism (3) comprises a first vertical plate (4) and a second vertical plate (5) which are arranged oppositely, a sliding guide rod (6) and two screw rods (7) are arranged between the first vertical plate (4) and the second vertical plate (5), and the two screw rods (7) are driven by a power mechanism to rotate in different directions; a sliding block (8) is horizontally matched on the sliding guide rod (6) in a sliding manner, a supporting frame (9) is integrally arranged on the sliding block (8), a single-wire guiding structure (10) is arranged on the supporting frame (9), and a single wire on the raw material winding roller (1) passes through the single-wire guiding structure (10) and then is wound on the winding roller (2);

a vertically sliding reversing block (11) is arranged in the supporting frame (9), a vertical reversing hole (12) is formed in the reversing block (11), the two screw rods (7) transversely penetrate through the reversing hole (12), and the upper end and the lower end of the reversing hole (12) are respectively provided with a thread structure matched with the corresponding screw rod (7);

an upper clamping plate (13) is arranged on one side of the upper end of the reversing block (11), a lower clamping plate (14) is arranged on the other side of the lower end of the reversing block (11), and the upper clamping plate (13) and the lower clamping plate (14) are respectively in horizontal sliding fit with the supporting frame (9); a first jacking inclined surface (15) is arranged at the upper end of one side, facing the first vertical plate (4), of the reversing block (11), and a second jacking inclined surface (16) is arranged at the lower end of one side, facing the second vertical plate (5), of the reversing block (11);

the first vertical plate (4) is provided with a first jacking part (17) for driving the upper clamping plate (13) to be close to the reversing block (11), a first transmission part (18) for driving the lower clamping plate (14) to be far away from the reversing block (11) and a first elastic structure (19) matched with the first jacking inclined plane (15); and a second jacking part (20) for driving the lower clamping plate (14) to be close to the reversing block (11), a second transmission part (21) for driving the upper clamping plate (13) to be far away from the reversing block (11) and a second elastic structure (22) matched with the second jacking inclined surface (16) are arranged on the second vertical plate (5).

2. The raw material coiling mechanism for the galvanized steel stranded wire of the cable according to claim 1, characterized in that: the first jacking part (17) and the second jacking part (20) are both composed of hollow sleeve plates (23) and elastic triangular plates (24) which are transversely inserted into the hollow sleeve plates (23), and elastic parts (25) are arranged between the elastic triangular plates (24) and the corresponding hollow sleeve plates (23); and jacking triangular grooves (26) which are in jacking fit with the corresponding elastic triangular plates (24) are respectively arranged below the upper clamping plate (13) and above the lower clamping plate (14).

3. The raw material coil separating mechanism of the galvanized steel strand of the cable according to claim 2, characterized in that: the first transmission piece (18) and the second transmission piece (21) are both transversely arranged transmission triangular plates, and transmission triangular grooves (28) which are in transmission fit with the corresponding transmission triangular plates are respectively arranged below the lower clamping plate (14) and above the upper clamping plate (13).

4. The raw material coiling mechanism for the galvanized steel strand of the cable according to claim 3, characterized in that: the first elastic structure (19) and the second elastic structure (22) are both composed of a U-shaped plate (29) and a jacking inclined block (30) which is vertically matched with the U-shaped plate (29) in a sliding manner, and a vertical spring piece (31) is arranged between the jacking inclined block (30) and the corresponding U-shaped plate (29); the first jacking inclined surface (15) and the second jacking inclined surface (16) are respectively in jacking fit with the corresponding jacking inclined blocks (30).

5. The raw material coiling mechanism for the galvanized steel strand of the cable according to claim 4, characterized in that: a plurality of transverse guide holes (32) are formed in the supporting frame (9), and transverse guide rods (33) which are in sliding fit with the transverse guide holes (32) are respectively arranged on one sides of the upper clamping plate (13) and the lower clamping plate (14); a plurality of vertical guide rods (34) are arranged in the supporting frame (9), and vertical guide holes (35) in sliding fit with the vertical guide rods (34) are formed in the reversing block (11).

6. The raw material coiling mechanism for the galvanized steel strand of the cable according to claim 5, characterized in that: an upper insertion hole (36) is formed in one side, away from the upper clamping plate (13), of the upper end of the reversing block (11), and the upper clamping plate (13) is in inserted fit with the upper insertion hole (36); one side of the lower end of the reversing block (11) far away from the lower clamping plate (14) is provided with a lower insertion hole (37), and the lower clamping plate (14) is in insertion fit with the lower insertion hole (37).

7. The raw material coiling mechanism for the galvanized steel stranded wire of the cable according to any one of claims 1 to 6, characterized in that: the unwinding roller (2) is driven to rotate by a driving motor (38) arranged on one side, and an output shaft of the driving motor (38) is provided with a first transmission disc (39); the end parts of the two screw rods (7) are provided with gears (40) which are meshed with each other, the end part of one screw rod (7) is also provided with a second transmission disc (41), and the first transmission disc (39) and the second transmission disc (41) are in transmission connection through a belt (42).

8. The raw material coiling mechanism for the galvanized steel stranded wire of the cable according to claim 1, characterized in that: the number of the sliding guide rods (6) is two, and the two sliding guide rods (6) are in horizontal sliding fit with the sliding block (8).