CN114955708B - Power cable winding and unwinding device - Google Patents

Abstract

A power cable winding and paying-off device comprises a far-end tray seat, a rack, a wire coil, a weighing mechanism, two rotary paying-off structures, a winding mechanism, a wire pulling mechanism and a wire winding counting structure. Each rotary paying-off structure comprises two stand seats, a first rotary shaft rotatably connected between the two stand seats and a plurality of limiting rings fixedly arranged on the outer circumferential wall of the first rotary shaft; the first rotating shaft is divided into a plurality of rolling areas between the first rotating shaft and the second rotating shaft through a plurality of limiting rings. The winding mechanism comprises a second rotating shaft, two fixed discs, at least two movable sleeves, two wire blocking discs and a fastening bolt. The invention can meet the working demands of wire coiling, wire outgoing, weighing, metering, wire coiling, sectioning and shipment of the wire coil, so as to achieve the processing effects of wire coiling, wire discharging and wire coiling of a running water type, the working efficiency of wire coiling is high, the participation of manual wire coiling is greatly reduced when the wire is discharged from a warehouse, the demands of precise wire discharging and wire coiling are met, and the working demands of precise wire coiling and warehouse discharging are effectively met.

Description

Power cable winding and unwinding device

Technical Field

The invention relates to the field of power construction equipment, in particular to a power cable winding and unwinding device.

Background

In the process of power construction maintenance, a large number of wires, cables or steel strands are often required to be carried, and for convenience in carrying, a winding operation of the wires, cables or steel strands is usually performed by using a winding frame.

At present, the winding work of electric wires, cables or steel strands is finished through a manual operation winding frame, a large amount of manpower and material resources are consumed in the paying-off and winding processes, the processing of pipelined winding cannot be realized, and the use requirement of electric power construction maintenance is not met.

Disclosure of Invention

Aiming at the problems that the winding work of a current wire, a cable or a steel strand is finished by manual operation, a large amount of manpower and material resources are consumed in the process of paying off and winding, the processing of pipelined winding cannot be realized, and the use requirement of electric power construction maintenance is not met, the invention provides a power cable winding and paying-off device.

The technical scheme of the invention is as follows: comprises a far-end tray holder, a rack and a wire coil;

further comprises:

a weighing mechanism disposed on the distal tray mount; the weighing mechanism is used for providing weighing for the wire coil;

two rotary paying-off structures, which are both installed on the weighing mechanism; each rotary paying-off structure comprises two stand seats, a first rotary shaft rotatably connected between the two stand seats and a plurality of limiting rings fixedly arranged on the outer circumferential wall of the first rotary shaft; the first rotating shaft is divided into a plurality of rolling areas between the limiting rings through the limiting rings; the wire coil is movably connected between the rolling areas corresponding to the two first rotating shafts;

the winding mechanism is movably arranged on the rack; the winding mechanism comprises a second rotating shaft, two fixed discs fixedly arranged on two sides of the outer circumferential wall of the second rotating shaft, at least two movable sleeves movably connected to the outer circumferential wall of the second rotating shaft, a wire blocking disc fixedly arranged on the outer circumferential wall of each movable sleeve and positioned between the two fixed discs, and a fastening bolt penetrating through the space between each movable sleeve and the second rotating shaft through threads;

the wire pulling mechanism is arranged on the rack; the wire pulling mechanism provides wire arranging for the winding wire wound on the wire coil on the second rotating shaft; and

and the winding counting structure is used for measuring the paying-off length of the winding wire of the coil.

The power cable winding and paying-off device is complete in functionality, and can meet the working requirements of wire coiling and outgoing on a wire coil, weighing, metering, wire coiling, sectioning and shipment, so that the processing effects of water-flowing type wire coiling and paying-off and wire coiling are achieved, the participation of manual wire coiling is greatly reduced during wire coiling and delivering, and the working requirements of wire coiling efficiency and accurate delivery are effectively met.

The weighing mechanism comprises four weighing sensors fixedly arranged on the far-end tray seat and a weighing table arranged between detection ends of the four weighing sensors; each stand is fixedly arranged on the weighing platform.

The remote tray seat is provided with a weighing data panel, and the weighing data panel is electrically connected with four weighing sensors through wires.

The outer circumferential wall of the second rotating shaft is provided with a plurality of threaded holes matched with the fastening bolts.

The wire pulling mechanism comprises an electric sliding rail and a wire conduit fixedly installed on the sliding block of the electric sliding rail, and the wire conduit is of an arc-shaped structure.

The coiled wire on the wire coil passes through the conduit and is coiled on the second rotational axis.

The coil counting structure comprises two fixed plates fixedly arranged on the inner side of the frame, a rotating rod rotatably connected between the two fixed plates, a magnet fixedly arranged on the outer circumferential wall of the rotating rod and a Hall sensor fixedly arranged on one fixed plate and having magneto-electric effect with the magnet; the winding wire on the wire coil is connected to the rotating rod in a transmission manner.

The wire coiling data panel is arranged on the rack and is electrically connected with the Hall sensor.

The driving mechanism comprises a rotating motor fixedly arranged on the frame, a main belt pulley fixedly arranged at the output end of the rotating motor and a slave belt pulley fixedly arranged at one end of the second rotating shaft; the main belt pulley is connected with the auxiliary belt pulley through belt transmission.

In operation, the rotary paying-off structure, the weighing mechanism, the winding counting structure and the winding mechanism are arranged, so that the working requirements of dishing and wire outgoing, weighing, metering, winding, sectioning and shipment of coiled wires on a wire coil can be met, the processing effects of water-flowing type coiling and wire outgoing are achieved, and the working efficiency of winding is high; the invention has complete functions, greatly reduces the participation of manual winding, meets the requirements of accurate unwinding and winding, and effectively meets the working requirements of accurate winding and delivery.

Drawings

Figure 1 is a schematic view of the structure of the present invention,

figure 2 is a schematic diagram of the structure of the remote tray, weighing mechanism and rotary pay-off structure of the present invention,

figure 3 is a schematic view of the internal structure of the winding mechanism,

figure 4 is a schematic view of the structure of the wire pulling mechanism,

figure 5 is an enlarged view of a portion of figure 1 at a,

figure 6 is a schematic view of the structure of the frame and the winding mechanism,

in the figure: 1. a remote tray holder; 2. a frame; 3. wire coil;

4. a weighing mechanism; 41. a weighing sensor; 42. a weighing table;

5. rotating the paying-off structure; 51. a vertical seat; 52. a first rotation shaft; 53. a limiting ring;

6. a winding mechanism; 61. a second rotation shaft; 62. a fixed plate; 63. a movable sleeve; 64. a wire blocking disc; 65. a fastening bolt;

7. a wire pulling mechanism; 71. an electric slide rail; 72. a conduit;

8. a winding counting structure; 81. a fixing plate; 82. a rotating rod; 83. a magnet; 84. a hall sensor;

9. a driving mechanism; 91. a rotating electric machine; 92. a main belt wheel; 93. a slave pulley;

10. a weighing data panel; 11. a bearing seat; 111. a threaded hole; 12. and a coiling data panel.

Detailed Description

The invention is shown in figures 1-6, and comprises a far-end tray holder 1, a rack 2 and a wire coil 3; the winding wire on the wire coil 3 in the embodiment can be a winding wire of a cable or a steel strand;

the device also comprises a weighing mechanism 4, two rotary paying-off structures 5, a winding mechanism 6, a wire pulling mechanism 7, a wire winding counting structure 8 and a driving mechanism 9.

Referring to fig. 2 in combination, two rotary pay-off structures 5 are mounted on the weighing mechanism 4; each rotary paying-off structure 5 comprises two stand seats 51, a first rotary shaft 52 rotatably connected between the two stand seats 51 and a plurality of limiting rings 53 fixedly arranged on the outer circumferential wall of the first rotary shaft 52; the first rotation shaft 52 is divided into a plurality of rolling areas by a plurality of limiting rings 53; the wire coil 3 is movably connected between the rolling areas corresponding to the two first rotating shafts 52; the arrangement of the plurality of rolling areas, in which the wire coil 3 pulls the wire coil on the wire coil 3 based on the symmetrical rolling areas between the two first rotation shafts 52, the wire coil 3 can be rotated in place to pay out.

Specifically, the wire coil 3 is inserted into the two first rotating shafts 52 through a forklift, rotation limiting is achieved through limiting rings 53 corresponding to the periphery of the outer disc of the wire coil 3, and the wire coil 3 can be prevented from rotating to deviate in the process, so that the wire coil 3 can stably rotate and pay off.

Through the setting of a plurality of rolling areas, it can satisfy the drum 3 of many specification width dimensions and rotate spacing, and application scope is wide.

Wherein the weighing mechanism 4 is arranged on the far-end tray seat 1; the weighing mechanism 4 is used for providing weighing for the wire coil 3; the weighing mechanism 4 comprises four weighing sensors 41 fixedly arranged on the far-end tray seat 1 and a weighing table 42 arranged between detection ends of the four weighing sensors 41; each stand 51 is fixedly mounted on the weighing table 42;

the remote tray seat 1 is provided with a weighing data panel 10, and the weighing data panel 10 is electrically connected with four weighing sensors 41 through wires; the weighing data panel 10 in this embodiment is provided with a processor, which can be used to process the electrical signals that can be measured by the weighing sensor 41, so as to display the weight in the wire coil 3 in real time through the upper panel of the weighing data panel 10, and meet the measurement requirement of paying out.

Referring to fig. 3, the winding mechanism 6 is movably disposed on the frame 2; the winding mechanism 6 comprises a second rotating shaft 61, two fixed disks 62 fixedly arranged on two sides of the outer circumferential wall of the second rotating shaft 61, at least two movable sleeves 63 movably connected to the outer circumferential wall of the second rotating shaft 61, a wire blocking disk 64 fixedly arranged on the outer circumferential wall of each movable sleeve 63 and positioned between the two fixed disks 62, and a fastening bolt 65 penetrating through the space between each movable sleeve 63 and the second rotating shaft 61;

two bearing seats 11 are symmetrically and fixedly arranged on the frame 2, and a second rotating shaft 61 is rotatably connected between the two bearing seats 11; the bearing housing 11 is for providing a rotational support for the second rotation shaft 61;

the outer circumferential wall of the second rotating shaft 61 is provided with a plurality of threaded holes 111 which are matched with the fastening bolts 65; the plurality of threaded holes 111 are used to provide a plurality of threaded locating holes for the fastening bolts 65 to satisfy locking of the movable sleeve 63 based on different positions on the second rotation shaft 61.

Specifically, when the coiled wire on the coil 3 wound on the second rotating shaft 61 is required to be delivered, the movable sleeve 63 is adjusted to be based on the transverse position on the second rotating shaft 61, the coil blocking disc 64 can be adjusted based on the coil winding width between the two fixed discs 62 through the movable arrangement of the position of the movable sleeve 63 under the limited distance between the two fixed discs 62, and finally the fastening bolt 65 can be penetrated into the movable sleeve 63 and the second rotating shaft 61 to fix the position of the movable sleeve 63, so that the diameter changing requirement of coil winding and wire paying-out on the coil 3 can be met.

Due to the arrangement of the at least two wire blocking disks 64, the sections of the wire blocking disks 64 divided on the second rotating shaft 61 can be wound with different wires, so that sectional winding is achieved, and the use requirements of different occasions are met.

Referring to fig. 4, the wire pulling mechanism 7 is disposed on the frame 2; the wire pulling mechanism 7 provides wire management for the winding wires on the winding drum 3 on the second rotating shaft 61; the wire pulling mechanism 7 comprises an electric slide rail 71 and a wire conduit 72 fixedly arranged on a slide block of the electric slide rail 71, and the wire conduit 72 is in an arc-shaped structure; a conduit 72 provided in an arc-shaped structure, which can change the angle from the winding wire on the wire coil 3 to the winding mechanism 6; the electric slide rail 71 in this embodiment can be purchased directly in the market, and is a well-known device, and the structure and principle will not be described here.

The wound wire on the wire reel 3 passes through the conduit 72 and is wound on the second rotation shaft 61.

Specifically, when the winding mechanism 6 needs to wind the wire on the wire coil 3, firstly, one end of the wire on the wire coil 3 can pass through the conduit 72 and be bound on the second rotating shaft 61, and when the second rotating shaft 61 performs winding action, the wire passing through the conduit 72 can be uniformly coiled in the winding area on the second rotating shaft 61 by setting the linear distance between the electric sliding rail 71 and the distance between the wire winding areas on the winding mechanism 6 and by the reciprocating linear motion of the electric sliding rail 71.

Referring to fig. 5, the wire winding counting structure 8 is used for measuring the wire unwinding length of the wire wound by the wire reel 3; the winding counting structure 8 comprises two fixed plates 81 fixedly arranged on the inner side of the frame 2, a rotating rod 82 rotatably connected between the two fixed plates 81, a magnet 83 fixedly arranged on the outer circumferential wall of the rotating rod 82 and a Hall sensor 84 fixedly arranged on one fixed plate 81 and having magneto-electric effect with the magnet 83; the winding wire on the wire coil 3 is connected to the rotating rod 82 in a transmission manner;

the rack 2 is provided with a coiling data panel 12, and the coiling data panel 12 is electrically connected with the Hall sensor 84; a processor is also provided in the cord reel data panel 12 in this embodiment for receiving the electrical signal measurable by the hall sensor 84, and calculating the electrical signal to derive the length of cord wound on the cord reel mechanism 6.

When the traction wire is rotated by the second rotating shaft 61, the wire drives the rotating rod 82 to rotate circumferentially, the Hall sensor 84 can respond once based on the magnet 83 on the rotating rod 82, a measurable turn number signal can be calculated through the magneto-electric response of the Hall sensor 84, the length of the wire discharged by the wire coil 3 wound on the winding mechanism 6 can be obtained through predicting the diameter of the rotating rod 82, and the length can be displayed by the winding data panel 12.

Referring to fig. 6 in combination, the driving mechanism 9 includes a rotary motor 91 fixedly mounted on the frame 2, a main pulley 92 fixedly mounted on an output end of the rotary motor 91, and a sub pulley 93 fixedly mounted on one end of the second rotary shaft 61; the primary pulley 92 is in belt drive connection with the secondary pulley 93.

Specifically, by starting the rotating motor 91, the output shaft of the rotating motor 91 drives the main pulley 92 to perform axial movement, so that the main pulley 92 can drive the auxiliary pulley 93 on the second rotating shaft 61 to perform axial rotation, thereby facilitating the winding of the wire coil 3 by the winding mechanism 6.

The foregoing is merely a preferred embodiment of the invention, and it is to be understood that the invention is not limited to the form disclosed herein but is not to be construed as excluding other embodiments, but is capable of numerous other combinations, modifications and environments and is capable of modifications within the scope of the inventive concept, either as taught or as a matter of routine skill or knowledge in the relevant art. And that modifications and variations which do not depart from the spirit and scope of the invention are intended to be within the scope of the appended claims.

Claims (9)

1. A power cable winding and unwinding device comprises a far-end tray holder (1), a rack (2) and a wire coil (3);

characterized by further comprising:

a weighing mechanism (4) arranged on the far-end tray seat (1); the weighing mechanism (4) is used for providing weighing for the wire coil (3);

two rotary pay-off structures (5) mounted on the weighing mechanism (4); each rotary paying-off structure (5) comprises two stand seats (51), a first rotary shaft (52) rotatably connected between the two stand seats (51) and a plurality of limiting rings (53) fixedly arranged on the outer circumferential wall of the first rotary shaft (52); the first rotating shaft (52) is divided into a plurality of rolling areas by a plurality of limiting rings (53); the wire coil (3) is movably connected between the rolling areas corresponding to the two first rotating shafts (52);

the winding mechanism (6) is movably arranged on the frame (2); the winding mechanism (6) comprises a second rotating shaft (61), two fixed discs (62) fixedly arranged on two sides of the outer circumferential wall of the second rotating shaft (61), at least two movable sleeves (63) movably connected to the outer circumferential wall of the second rotating shaft (61), a wire blocking disc (64) fixedly arranged on the outer circumferential wall of each movable sleeve (63) and positioned between the two fixed discs (62), and a fastening bolt (65) penetrating through the thread between each movable sleeve (63) and the second rotating shaft (61);

a wire pulling mechanism (7) which is arranged on the frame (2); the wire pulling mechanism (7) provides wire arrangement for winding wires wound on the wire coil (3) on the second rotating shaft (61); and

and the winding counting structure (8) is used for measuring the paying-off length of the winding wire of the wire coil (3).

2. A power cable wind-up and pay-off device according to claim 1, characterized in that the weighing mechanism (4) comprises four weighing cells (41) fixedly mounted on the distal tray deck (1) and a weighing table (42) mounted between the detection ends of the four weighing cells (41);

each stand (51) is fixedly mounted on the weighing table (42).

3. A power cable winding and unwinding device according to claim 2, characterized in that said remote tray (1) is provided with a weighing data panel (10), said weighing data panel (10) being electrically connected to four of said weighing sensors (41) by means of wires.

4. An electric cable winding and unwinding device according to claim 1, characterized in that said second rotation shaft (61) is provided with a plurality of threaded holes (111) on its outer circumferential wall adapted to said fastening bolts (65).

5. The electric cable winding and unwinding device according to claim 1, characterized in that said wire pulling mechanism (7) comprises an electric sliding rail (71) and a conduit (72) fixedly mounted on a sliding block of said electric sliding rail (71), said conduit (72) having an arc-shaped structure.

6. A power cable winding and unwinding device according to claim 5, characterized in that the winding wire on the wire reel (3) is passed through the conduit (72) and wound on the second rotation shaft (61).

7. A power cable winding and unwinding device according to claim 1, characterized in that said winding counting structure (8) comprises two fixed plates (81) fixedly mounted inside a frame (2), a rotating rod (82) rotatably connected between the two fixed plates (81), a magnet (83) fixedly mounted on the outer circumferential wall of said rotating rod (82), and a hall sensor (84) fixedly mounted on one of the fixed plates (81) and having a magneto-electric effect with said magnet (83);

the winding wire on the wire coil (3) is connected to the rotating rod (82) in a transmission manner.

8. The power cable winding and unwinding device according to claim 7, characterized in that a winding data panel (12) is arranged on the rack (2), and the winding data panel (12) is electrically connected with the hall sensor (84).

9. A power cable winding and unwinding device according to claim 8, characterized by further comprising a driving mechanism (9), said driving mechanism (9) comprising a rotating electric machine (91) fixedly mounted on said frame (2), a master pulley (92) fixedly mounted at the output end of said rotating electric machine (91) and a slave pulley (93) fixedly mounted at one end of said second rotating shaft (61);

the main belt wheel (92) is connected with the auxiliary belt wheel (93) through belt transmission.