CN111056375B - Cable wire taking device - Google Patents

Abstract

The application relates to the technical field of cable branching, and particularly discloses a cable wire taking device which at least comprises a winding mechanism, wherein the winding mechanism comprises a base, a winding main shaft, a wire spool, a winding support rod, a sliding sleeve, a telescopic mechanism and a connecting rod, one end of the winding main shaft is rotatably and movably connected with the base, and the wire spool is fixedly connected with the winding main shaft; the winding main shaft is provided with a plurality of winding support rods, one ends of the winding support rods are hinged with the winding reel, the sliding sleeve is axially and slidably connected with the winding main shaft, one ends of the telescopic mechanisms are connected with the winding reel, and the other ends of the telescopic mechanisms are connected with the sliding sleeve; one end of the connecting rod is hinged with the position, close to the free end, of the winding support rod, and the other end of the connecting rod is hinged with the sliding sleeve. The cable wire taking device with the structure has the advantages that the wire taking and winding modes do not need to be manually participated, and the wire taking and winding efficiency is very high; the mode that cable reel and reel break away from thinks about ingenious, need not artifical the participation, degree of automation and efficiency are very high.

Description

Cable wire taking device

Technical Field

The application relates to the technical field of cable branching, in particular to a cable taking device.

Background

In the prior art, the electric power company is provided with a cable storage warehouse in which cables are stored. When a cable with a certain length is needed to be used for maintenance or rush repair, the cable is manually pulled out from the cable drum for a certain length and wound into a disc shape. Because some engineering cables are thicker, the manual branching and winding processes are high in pulling strength and low in efficiency, and particularly in rush repair, longer time is delayed.

The cable drum in the wire storage warehouse can be usually several meters in diameter, and wires are manually pulled from the cable drum when needed, so that the wire taking efficiency is low, and the labor intensity is high; in addition, some thicker cables are in a bending state after being wound on a cable drum, have certain bending stress, and are difficult to straighten in the manual wire taking process; meanwhile, the pulled cable is generally rewound into a new cable coil, and the winding process of the cable has the technical defects of low efficiency and high labor intensity.

Disclosure of Invention

The application aims to solve the technical problems of high labor intensity and low efficiency caused by manual branching of cables in a cable storage warehouse in the prior art.

In order to solve the technical problems, the technical scheme provided by the application is as follows: the utility model provides a cable thread take-up device, includes wire winding mechanism at least, wire winding mechanism includes at least:

the base is fixedly arranged;

the winding device comprises a winding main shaft, a base and a driving device, wherein one end of the winding main shaft is rotatably and movably connected with the base, and the driving device for driving the winding main shaft to rotate is arranged in the base;

the wire spool is fixedly connected with the wire winding main shaft;

the winding support rods are arranged around the winding spindle, and one end of each winding support rod is hinged with the wire spool;

the sliding sleeve is axially and slidably connected with the winding spindle;

one end of the telescopic mechanism is connected with the wire spool, and the other end of the telescopic mechanism is connected with the sliding sleeve;

the connecting rods are in one-to-one correspondence with the winding support rods, one ends of the connecting rods are hinged to positions, close to the free ends, of the winding support rods, and the other ends of the connecting rods are hinged to the sliding sleeves.

A preferred embodiment further comprises at least one wire clamping mechanism fixedly connected to the winding support rod.

The wire clamping mechanism at least comprises a fixed clamp body, a movable clamp body and a driving cylinder for driving the movable clamp body to move relative to the fixed clamp body, wherein the fixed clamp body and the driving cylinder are respectively and fixedly connected with a winding support rod, and the movable clamp body is connected to the output end of the driving cylinder.

A preferred embodiment further comprises a winding support, wherein the winding support is arranged around the winding support rod and fixedly connected with the winding disc.

In a preferred embodiment, the free end of the winding spindle is provided with a baffle.

A preferred embodiment further comprises an auxiliary winding mechanism disposed opposite the winding mechanism, the auxiliary winding mechanism comprising at least:

the auxiliary base is provided with a driving system below for driving the auxiliary base to move relative to the base;

the auxiliary shaft is rotatably and movably connected with the auxiliary base;

the rotary disc is fixedly connected to the free end of the auxiliary shaft, and a cavity for accommodating the winding support rod to penetrate through is formed in one side of the rotary disc, which faces the wire spool;

the baffle disc is arranged at the center of the cavity, and the baffle disc is provided with a linear motion mechanism for driving the baffle disc to axially move along the auxiliary shaft.

In a preferred embodiment, the linear motion mechanism includes at least:

the piston cavity is arranged in the auxiliary shaft, one end of the piston cavity, which is close to the rotating disc, is open, and the piston cavity is connected with a hydraulic system or a pneumatic system;

the piston rod is axially movably connected with the piston cavity, and the free end of the piston rod is fixedly connected with the baffle disc.

In a preferred embodiment, the driving system at least comprises a rack, a driving gear, a power mechanism and a guiding mechanism, wherein the rack is fixedly arranged, the driving gear is meshed with the rack, the power mechanism is used for driving the gear to rotate, and the guiding direction of the guiding mechanism is parallel to the length direction of the rack.

A preferred embodiment further comprises a support, wherein the support is arranged between the winding mechanism and the auxiliary winding mechanism, and the upper surface of the support is an inclined plane.

The preferred embodiment further comprises a base, wherein the base is fixedly arranged, and the winding mechanism, the auxiliary winding mechanism and the support are all arranged on the base.

Compared with the prior art, the cable wire taking device has the following beneficial effects:

(1) One end of the cable is fixed on one of the winding support rods, and the winding reel is driven to rotate through rotation of the winding main shaft, so that the cable is wound on a winding frame formed by the winding support rods, the wire taking and winding mode is not needed to be manually participated, and the wire taking and winding efficiency is very high.

(2) Because the winding support rods are connected with the sliding sleeve through the connecting rods, the sliding sleeve can move along the axial direction of the winding main shaft through the telescopic mechanism, after winding is completed, the telescopic mechanism drives the sliding sleeve to move to one side of the winding disc, and then the free ends of the winding support rods are driven to be close to the axis of the winding main shaft, so that the winding frame formed by the winding support rods forms a cone-shaped structure, a cable coil after winding can fall off from the winding frame under the action of gravity.

(3) The auxiliary winding mechanism can move relative to the winding mechanism, so that the auxiliary winding mechanism and the winding mechanism can cooperatively control the width of the cable coil during winding; when the cable is separated from the winding frame after the winding of the cable is completed, the auxiliary winding mechanism moves in the opposite direction, so that the falling position of the cable roll is avoided, the position of the cable roll can be controlled and balanced, and the cable roll is prevented from falling.

(4) The cable winding device is characterized in that a support is arranged between the winding mechanism and the auxiliary winding mechanism, the upper surface of the support is an inclined surface, a cable which falls off from the winding mechanism can roll away from the cable taking device along the inclined surface under the action of gravity after falling on the support, and the cable winding movement mode is simple in structure, ingenious in technical conception, free of manual participation and high in automation degree and efficiency.

Drawings

Fig. 1 is a schematic structural diagram of a cable taking device according to the present embodiment;

fig. 2 is a schematic structural diagram of the winding mechanism in a winding state in the present embodiment;

fig. 3 is a schematic structural diagram of the winding mechanism in the embodiment in a state that the cable coil falls off after winding is completed;

FIG. 4 is a side view of the winding mechanism shown in FIG. 2;

fig. 5 is a schematic structural diagram of an auxiliary winding mechanism in the present embodiment;

FIG. 6 is a side view of the auxiliary winding mechanism of FIG. 5;

fig. 7 is a schematic structural view of a linear motion mechanism in the present embodiment;

fig. 8 is a schematic view of the structure of the support in this embodiment.

Detailed Description

The present application will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present application more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

As shown in fig. 1, a cable taking device of the present embodiment includes a winding mechanism 10, an auxiliary winding mechanism 20, a base 40, and a support 30. The base 40 is usually fixed on the ground, the winding mechanism 10 and the support 30 are fixedly connected to the base 40, the auxiliary winding mechanism 20 can move relative to the winding mechanism 10 on the base, and the support 30 is located between the winding mechanism 10 and the auxiliary winding mechanism 20.

Wherein, as shown in fig. 8, the upper surface of the support 30 is inclined. Therefore, when the cable coil slides onto the support, the cable coil can roll to a corresponding position along the inclined plane under the action of gravity.

A preferred embodiment of the winding mechanism 10 of the present embodiment, as shown in fig. 2-4, includes a base 19, a spool 11, and a winding spindle 13. Wherein, the base 19 is fixedly installed at one side of the base 40, and one end of the winding spindle 13 is rotatably and movably connected with the base 19.

The driving device for driving the winding spindle 13 to rotate is disposed in or on the side of the base 19, and it should be noted that the driving device is not an inventive point of the present application, and is generally composed of a servo motor and a decelerator according to the prior art, and the specific structure thereof will not be described herein.

In this embodiment, the spool 11 is fixedly connected to the winding spindle 13, and the back surface of the spool 11 is close to the base 19. The side of the wire spool 11 away from the base is provided with a plurality of winding support rods 12 surrounding the winding spindle, and the plurality of winding support rods 12 form the wire spool of the present embodiment.

As a modification of the present embodiment, the end of each winding support rod 12 is hinged to the spool 11. Correspondingly, a connecting rod 14 is arranged at the free end or the position close to the free end of each winding support rod 12, and the connecting rod 14 is hinged with the winding support rods 12.

In this embodiment, the winding spindle 13 is further provided with a sliding sleeve 15, and the sliding sleeve 15 is axially slidably connected with the winding spindle 13. Wherein the other end of each connecting rod 14 is hinged with the sliding sleeve 15.

In this embodiment, a telescopic mechanism 16 is further disposed between the sliding sleeve and the spool, one end of the telescopic mechanism is connected to the spool, and the other end is connected to the sliding sleeve. The telescopic mechanism 16 may be a hydraulic cylinder, an air cylinder, a linear motor, etc. in the prior art, which is not limited herein.

In this embodiment, the sliding sleeve is driven by the telescopic mechanism to slide along the axial direction of the winding spindle, and then the sliding sleeve drives the connecting rod to make the free ends of the winding support rods close to the winding spindle.

As shown in fig. 2 and 3, in this embodiment, at least one winding support rod is connected to a wire clamping mechanism 50, which includes a fixed clamp 51, a movable clamp 52, and a driving cylinder 53 for driving the movable clamp to move relative to the fixed clamp. Wherein, the fixed clamp body 51 and the driving cylinder 53 are respectively fixedly connected with the winding support rod 12, and the movable clamp body 52 is connected with the output end of the driving cylinder 53, wherein the driving cylinder 53 is used for driving the movable clamp body to move relative to the fixed clamp body so as to clamp the wire end of the cable through the movable clamp body and the fixed clamp body in the initial winding stage. After the wire heads of the cables are clamped, the cables can be wound on the winding frame formed by the winding support rods through rotation of the winding disc.

In this embodiment, the free end of the winding spindle 13 is provided with a baffle 17. Preferably, as shown in fig. 4, the baffle 17 is composed of rod-like structures corresponding to the winding support rods one by one, and the rod-like structures are radially arranged from the winding spindle.

In the structure, the baffle has two functions, namely, the limit position of the winding support rod which is closed is that the winding support rod contacts with the outer edge of the baffle in the process of closing the winding support rod to the center, and the baffle forms a support in the process of sliding off the cable coil while limiting the limit position, so that the winding support rod is prevented from being damaged due to overlarge stress; secondly, after the cable coil slides off the winding frame, the baffle plate can form a side support to prevent the cable coil from overturning in a gap between the winding support rod and the winding main shaft.

In this embodiment, as shown in fig. 2, a winding bracket 18 is further disposed around the periphery of the winding bracket, and the winding bracket is fixedly connected with the winding reel. Preferably, the number and positions of the winding brackets 18 are in one-to-one correspondence with the winding support bars, and the winding brackets 18 include an outer bracket bar 182, an inner bracket bar 183, and a radial bracket bar 181 connecting the outer bracket bar 182 and the inner bracket bar 183.

As shown in fig. 5 to 6, the auxiliary winding mechanism 20 of the present embodiment includes a sub base 25, a fixed base 26, a sub shaft 22, a rotating disk 21, and a shutter disk 24. Wherein, fixed base 26 and base 40 fixed connection are provided with actuating system between sub-base 25 and fixed base 26, and this actuating system makes the movable connection between the two, and sub-base 25 can move relative wire winding mechanism 10.

As shown in fig. 5 and 6, a preferred movement mode is shown, a rack 28 is disposed on the fixed base 26, a driving gear 27 meshed with the rack 28 is disposed on the auxiliary base 25, and the driving gear is connected with a driving device for driving the driving gear to rotate, which is not the application point, and the driving device in the prior art is generally composed of a servo motor and a speed reducer, and the specific structure thereof is not described herein.

In order to ensure the precision and structural stability of the movement of the auxiliary winding mechanism relative to the winding mechanism, two sets of guide mechanisms 29 are further arranged between the auxiliary base 25 and the fixed base 26, and the movement direction of the guide mechanisms 29 is parallel to the length direction of the racks. It should be noted that, the guide mechanism 29 adopts a structure in the prior art, for example, a guide rail is matched with an adaptive guide groove.

In this embodiment, the auxiliary shaft 22 is rotatably and movably connected with the auxiliary base 25. The auxiliary base 25 is provided with a driving device for driving the auxiliary shaft 22 to rotate, and it should be noted that the driving device is not an inventive point of the present application, and is generally composed of a servo motor and a speed reducer, and the specific structure thereof is not described herein.

In this embodiment, the rotary disk 21 is fixedly connected to the free end of the auxiliary shaft 22, and a winding sub-bracket 23 disposed opposite to the winding bracket 18 is disposed on a side of the rotary disk 21 facing the spool 11, and the winding sub-bracket 23 is preferably identical in structure to the winding bracket 18. Wherein, the interior of the winding auxiliary bracket 23 is formed with a cavity for accommodating the winding support rod to pass through.

In the above structure, the winding bracket 18 and the winding sub-bracket 23 are used for defining the width of the cable coil, and the opposite distance between the two is the width of the cable coil after winding is completed.

In this embodiment, the center of the cavity of the rotating disc is provided with a blocking disc 24, and the blocking disc 24 can move along the axial direction of the auxiliary shaft. The baffle disc has the function of preventing the cable from tilting into the cavity in the falling process of the cable from tilting after winding, and simultaneously has the function of preventing the cable from tilting fully.

Preferably, the linear motion mechanism for driving the axial motion of the baffle disc in the present embodiment is shown in fig. 7, and includes a piston cavity 221 disposed inside the auxiliary shaft, wherein one end of the piston cavity 221 close to the rotating disc is open, and a hydraulic system or a pneumatic system is connected to the piston cavity. An adapted piston rod 222 is arranged in the piston cavity 221, and is axially movably connected with the piston cavity, and the free end of the piston rod is fixedly connected with the baffle disc. The baffle disc can move along the axial direction of the auxiliary shaft through the driving of a hydraulic system or a pneumatic system.

In the cable taking device of the embodiment, before winding starts, the auxiliary winding mechanism moves to one side of the winding mechanism, a winding section for winding is formed between the winding support and the winding auxiliary support, the end part of the cable is fixed on the cable clamping mechanism, and the cable is wound on the winding support between the winding support and the winding auxiliary support in the rotating process of the winding main shaft and the auxiliary shaft to form a cable coil. After the winding is completed, the end part of the cable coil is processed, the auxiliary winding mechanism moves to one side far away from the winding mechanism, and the baffle disc moves along the axial direction of the auxiliary shaft until the front end of the baffle disc is approximately parallel to the front end surface of the winding auxiliary bracket; the telescopic mechanism drives the sliding sleeve to move to one side of the wire spool, and then drives the end part of the winding support rod to draw close to the winding main shaft, so that the wire spool is deformed into a conical structure. In this state, the cable reel slides down the spool under the force of gravity and falls onto the support and rolls down the transport position along the incline of the support.

In summary, the foregoing description is only of the preferred embodiments of the application, and is not intended to limit the application to the particular embodiments disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the application.

Claims (9)

1. A cable take-up device comprising at least a winding mechanism (10), said winding mechanism comprising at least:

a base (19) fixedly arranged;

a winding main shaft (13), wherein one end of the winding main shaft is rotatably and movably connected with a base, and a driving device for driving the winding main shaft to rotate is arranged in the base;

the wire spool (11) is fixedly connected with the wire winding spindle;

a plurality of winding support rods (12) are arranged around the winding spindle, and one end of each winding support rod is hinged with the wire spool;

the sliding sleeve (15) is axially and slidably connected with the winding spindle;

one end of the telescopic mechanism (16) is connected with the wire spool, and the other end of the telescopic mechanism is connected with the sliding sleeve;

the connecting rods (14) are in one-to-one correspondence with the winding support rods, one end of each connecting rod is hinged with the position, close to the free end, of each winding support rod, and the other end of each connecting rod is hinged with the sliding sleeve;

an auxiliary winding mechanism (20) comprising at least: the auxiliary base (25), the auxiliary shaft (22) and the rotary disk (21), wherein a driving system for driving the auxiliary base to move relative to the base is arranged below the auxiliary base, the auxiliary shaft is rotatably and movably connected with the auxiliary base, and the rotary disk is fixedly connected with the free end of the auxiliary shaft;

characterized by further comprising:

the winding support (18) is arranged around the winding support rod and fixedly connected with the wire spool;

the baffle (17) is arranged at the free end of the winding spindle (13), and the limit position of the winding support rod towards the center is that the winding support rod contacts with the outer edge of the baffle;

a winding auxiliary bracket (23) is arranged on one side of the rotating disk, which faces the wire spool, and is opposite to the winding bracket, and a cavity for accommodating the winding support rod to pass through is formed in the winding auxiliary bracket;

and the baffle disc (24) is arranged at the center of the cavity, and the baffle disc is provided with a linear motion mechanism for driving the baffle disc to move along the axial direction of the auxiliary shaft.

2. The cable taker device of claim 1 further including at least one wire clamping mechanism (50) fixedly attached to said winding support bar.

3. The cable taking-out device according to claim 2, wherein the wire clamping mechanism at least comprises a fixed clamp body (51), a movable clamp body (52) and a driving cylinder (53) for driving the movable clamp body to move relative to the fixed clamp body, the fixed clamp body and the driving cylinder are respectively fixedly connected with the winding support rod, and the movable clamp body is connected with the output end of the driving cylinder.

4. A cable take-off according to any one of claims 1-3, wherein the linear motion mechanism comprises at least:

the piston cavity (221) is arranged in the auxiliary shaft, one end of the piston cavity, which is close to the rotating disc, is open, and is connected with a hydraulic system or a pneumatic system;

the piston rod (222) is axially movably connected with the piston cavity, and the free end of the piston rod is fixedly connected with the baffle disc.

5. A cable take-up device according to any one of claims 1-3, wherein the drive system comprises at least a rack, a drive gear, a power mechanism and a guiding mechanism, the rack being fixedly arranged, the drive gear being in engagement with the rack, the power mechanism being arranged to drive the gear in rotation, the guiding mechanism being oriented in a direction parallel to the length of the rack.

6. The cable take-off device of claim 4, further comprising a support (30) disposed between the winding mechanism and the auxiliary winding mechanism, an upper surface of the support being a bevel.

7. The cable take-off of claim 6, further comprising a base, wherein the base is fixedly disposed, and wherein the winding mechanism, the auxiliary winding mechanism, and the support are disposed on the base.

8. The cable take-off device of claim 5, further comprising a support (30) disposed between the winding mechanism and the auxiliary winding mechanism, an upper surface of the support being a bevel.

9. The cable take-off of claim 8, further comprising a base, the base being fixedly disposed, the winding mechanism, the auxiliary winding mechanism, and the support being disposed on the base.