CN214326722U - Cable binding device, system comprising same and cable cutting, winding and binding integrated device - Google Patents

Abstract

The utility model provides a prick cable device and including its system, cut out cable and prick cable integrated device around the cable, bundle cable device wherein can be used to realize bundle automation of cable, including lieing in the bundle wire inlet guide ware that fiber cable rolled up one side and setting up, rotate the bundle wire return wire guiding arm of installation, with bundle wire return wire guiding driver that the wire return wire guiding arm is connected, bundle wire feeding device, lie in bundle wire cutting device that sets up between bundle wire feeding device and the bundle wire inlet guide ware, it is used for cutting off the bundle wire, and bind the device, it is used for tying together the bundle wire both ends that lie in fiber cable book both sides; the binding wire return wire guide arm is arranged to rotate to the inner side of the fiber cable roll, and integrally forms a guide channel for the binding wire to be wound into the inner side of the fiber cable roll and to be wound out from the other side of the fiber cable roll with the binding wire inlet guide, and the binding wire supplied by the binding wire supply device can be wound into the channel from one side of the fiber cable roll and wound out from the other side of the fiber cable roll along the guide channel, so that the binding device can perform binding operation.

Description

Cable binding device, system comprising same and cable cutting, winding and binding integrated device

Technical Field

The present invention relates to a device for bundling optical fibres and a system comprising the same, which is adapted to handle the bundling of optical fibres and additionally at least one of cutting, winding the cables in an automated manner.

Background

In the traditional optical fiber cable industry, cable cutting work is generally carried out by the aid of a single machine, namely, a single-person-machine-single-process working mode. The semi-automatic apparatus used in this method can perform operations of drawing the length of the optical fiber and re-cutting, but requires manual work for winding and bundling the optical fiber later. The problems that the bundling operation is difficult to realize automation and the cable cutting operation and the cable winding operation are difficult to connect become main problems that the full automation of the optical fiber cable cutting and winding process is limited, so that the existing optical fiber cable cutting and winding operation inevitably uses a large amount of labor, the labor cost is high, and the production efficiency is low.

In the technical scheme disclosed by the patent document with the publication number of 'CN 210312854U', the name of the utility model of 'novel full-automatic optical fiber cable cutting equipment' and the publication date of 2020, 4 and 14, the automatic cable binding device is arranged at the front end of the equipment frame and comprises a cable winding device, a winding drum and a rotating frame, wherein the winding drum is connected to the rotating frame through a rotating shaft; the winding frame is connected in the equipment frame through a pushing air cylinder.

When the revolving drum revolves to reach the set number of meters, the automatic tightening is carried out, and when the cylinder on the revolving rotary shaft on the automatic tightening mechanism is loosened, the tightened optical fiber wire can be pushed into the receiving turnover boxes on two sides.

The technical scheme of patent literature with the publication number of 'CN 110275248A', the name of the utility model of 'an automatic cable cutting machine for optical fiber cables', the publication date of 2019, 9 and 24 includes a cable laying mechanism, a tensioning mechanism, a cable feeding mechanism, a cable winding mechanism and the like, wherein the cable winding mechanism winds the cable on a winding disc, and then the optical cable is pasted and fixed by a masking tape mechanism and a masking tape pasting mechanism by utilizing a cut masking tape glue section, so that the optical cable is not loose.

If the cable binding step of the optical fiber coil is carried out by adopting the binding wire, the masking tape mechanism and the masking tape pasting mechanism of the device can not play a corresponding role, so that the application range is limited.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an optic fibre cable binding device, it can use bundle line to bundle the cable of carrying out of optic fibre book.

Another object of the utility model is to provide a system, it includes aforementioned optic fibre cable binder to still including the device of at least one technology such as executable sanction cable, around the cable, from this through automatic operation, reduce the manpower and use, reduce the recruitment cost.

The cable bundling device comprises a bundling wire inlet guider, a bundling wire inlet guide arm, a wire return guide driver, a bundling wire supply device, a bundling wire cutting device and a bundling device, wherein the bundling wire inlet guider is arranged on one side of the fiber cable coil; the binding wire return wire guide arm is arranged to be rotatable to the inner side of the fiber cable roll, and forms a guide channel for the binding wire to be wound into the inner side of the fiber cable roll and to be wound out from the other side of the fiber cable roll with the binding wire inlet guide integrally, and the binding wire supplied by the binding wire supply device can be wound into the channel from one side of the fiber cable roll and wound out from the other side of the fiber cable roll along the guide channel, so that the binding device can perform binding operation.

In one embodiment, the wire tying severing device comprises a wire tying severing cutter configured to move in synchronism with the wire guide arm by movement output by the wire guide drive; in one stage of the synchronous movement, the binding wire cutting tool gradually approaches to the binding wire through hole, the binding wire return wire guide arm synchronously swings towards the inner side of the fiber cable roll, and a longer binding wire guide channel in an arc shape is gradually formed with the binding wire inlet guide device; in another phase of the synchronous motion, the binding wire cutting tool is pushed to cut the binding wire, the binding wire is cut by the binding wire cutting tool, the binding wire loop guiding arm and the binding wire entering guider form a final complete binding wire guiding channel, and the binding wire is guided to reach the position where the binding device can perform binding operation.

In one embodiment, the loop back line steering driver comprises: the loop driving slide block is arranged in a sliding way and is provided with a binding wire cutting force application inclined plane; the sliding block feeding driver is used for connecting and driving the loop driving sliding block; and a loop guiding transmission connecting rod is arranged between the loop driving sliding block and the binding loop guiding arm; the wire-binding wire-returning guide driver outputs and transmits the motion of the wire-binding wire-returning cutting tool by means of the wire-binding wire-cutting force application inclined plane, and outputs and transmits the motion of the wire-binding wire-returning guide arm by means of the wire-returning guide transmission connecting rod.

In one embodiment, the slider feed actuator comprises: the device comprises a slider feeding driving disk, a slider feeding driving motor, an eccentric connecting shaft and a slider feeding driving connecting rod, wherein the slider feeding driving disk is rotatably installed, the slider feeding driving motor is connected with the slider feeding driving disk, the eccentric connecting shaft is arranged on the slider feeding driving disk, and the slider feeding driving connecting rod is hinged between the eccentric connecting shaft and a loop driving slider; the slider feeding driving disc, the slider feeding driving connecting rod and the return wire driving slider form a crank slider mechanism.

In one embodiment, the wire binding cutting device further includes a wire binding cutting base and a wire binding passage hole provided in the wire binding cutting base, and the wire binding cutting tool cuts the return spring in the wire binding cutting base which is slidably provided and arranged.

In one embodiment, the binding wire return guide arm comprises: the wire binding device comprises a wire returning swinging section and a wire returning guiding section, wherein the wire returning swinging section is rotatably installed, the wire returning guiding section is fixedly arranged at the end part of the wire returning swinging section and is arranged in an arc shape, and the wire returning guiding section is used for forming a complete wire binding guiding channel with the wire binding and inserting guider.

In an embodiment, the wire loop guide section and the wire binding and inserting guide are provided with wire binding guide grooves.

In one embodiment, the binding wire guiding groove of the binding wire guiding device is inclined toward the other side of the fiber cable roll in a direction consistent with the forward swinging direction of the loop guiding section.

In one embodiment, the cable tie device further comprises a cable tie supply device, the cable tie supply device comprising: the binding wire clamping device comprises a binding wire supply driving wheel, a binding wire clamping seat and a binding wire pressing force applicator, wherein the binding wire supply driving wheel is rotatably installed, the binding wire pressing seat is slidably installed, a binding wire supply driven wheel is rotatably installed on the binding wire clamping seat and is arranged corresponding to the binding wire supply driving wheel, and the binding wire pressing force applicator drives the binding wire clamping seat to keep the pressing force of the binding wire supply driving wheel, so that the binding wire supply driven wheel and the binding wire supply driving wheel can form effective clamping on the binding wire.

In one embodiment, the cable tie device further comprises: the cable winding device comprises a cable binding base, a cable binding feeding seat which is arranged on the cable binding base in a sliding mode and faces the cable winding device in a sliding mode, and a cable binding feeding driver which is arranged between the cable binding feeding seat and the cable binding base.

In one embodiment, the binding device includes a binding spindle, one end of the binding spindle close to the fiber cable roll is fixedly provided with an S-shaped binding hook, two ends of the binding hook are respectively and fixedly provided with a binding wire cable hook, the binding spindle is connected with a binding driving motor, and the two binding wire cable hooks can firstly contact two ends of a binding wire before binding.

The system comprises a cable binding device for realizing the purpose, and further comprises a cable winding device, wherein the cable binding device is any one of the cable binding devices; the cable winding device comprises a cable winding main shaft which is rotatably installed, at least two cable winding supporting arms which are uniformly distributed in the circumferential direction are fixedly arranged on the cable winding main shaft, a cable supporting movable rod which can move away from the cable winding main shaft is installed on at least one of the cable winding supporting arms, cable supporting fixed rods are fixedly arranged on the other cable winding supporting arms, and the cable supporting movable rods are connected with a cable winding tightness controller; a cable wrap surrounds the cable-winding support arm.

In one embodiment, the cable tie device further comprises: the device comprises a cable roll pull-out base, a cable roll pull rod, a roll pull-in-place driver and a cable roll pull-out driver, wherein the cable roll pull-out base is mounted in a sliding manner; the coil poking in-place driver can drive the cable coil poking rod to extend out to one side of the fiber cable coil, and the cable coil poking-out driver is used for controlling the cable coil poking-out base to integrally slide along the axial direction of the cable winding device, so that the fiber cable coil is allowed to be axially poked out of the cable winding device by the cable coil poking rod.

In one embodiment, the system further comprises a meter counting device, wherein the meter counting device comprises a meter counting fixed wheel which is rotatably installed, a meter counting pressure holding seat which is movably installed, and a meter counting movable wheel which is rotatably installed on the meter counting pressure holding seat and corresponds to the meter counting fixed wheel; wherein the meter-measuring pressure-holding seat is provided with a meter-measuring pressure-holding force applicator; the meter counting movable wheel or the meter counting fixed wheel is connected with a revolution sensor; or the meter counting device comprises a sensor and the cable winding device, and the sensor detects the rotating speed of the cable winding device.

In an embodiment, the system further comprises a cable cutting device and a cable feeding device, wherein the cable feeding device comprises a cable feeding displacement slide seat which is slidably mounted, a cable feeding and fiber taking slide seat is vertically and slidably mounted on the cable feeding displacement slide seat, a fiber taking clamp holder is arranged on the cable feeding slide seat, a fiber taking and feeding driver is arranged between the cable feeding slide seat and the cable feeding displacement slide seat, and the cable feeding displacement slide seat is provided with a cable feeding displacement driver; the cable feeding displacement sliding seat is arranged to slide between a first station and a second station, the first station is positioned on the upstream side of the cable cutting device, and the cable feeding device is used for clamping an optical fiber line before cutting at the first station; the second station is located on the cable winding device, and the cable feeding device is used for transferring the optical fiber line to a position which can be clamped by the cable winding device at the second station.

The cable bundling device is planned to be executed by the cable bundling supply device and supply with the action of bundling, the direction of going into of the guider of inserting the bundling, the direction of the rotation of the guide arm of the return wire of inserting the bundling forms the passageway that can roll up around the fine cable, is located the device is decided to the cable bundling supply device with the bundling that sets up between the guider of inserting the bundling, cuts off the bundling, and the device that binds together the both ends of the bundling that will be located fine cable book both sides at last, its spatial arrangement is compact, and the part of realization is small in quantity, can realize the automation of bundling.

The utility model discloses still provide full-automatic optic fibre technical scheme:

cable is cut out to full-automatic optic fibre and is pricked cable integrated device around cable, including the frame, wherein: a cable releasing device is arranged on one side of the rack, a cable winding device is arranged on the rack, a tensioning device, a metering device and a cable cutting device are sequentially arranged between the cable releasing device and the cable winding device on the rack, and a cable feeding device for feeding optical fibers from the cable cutting device to the cable winding device is arranged on the rack; the rack is provided with a cable bundling device corresponding to the cable winding device;

the cable binding device comprises a cable binding base arranged on the rack, a cable binding feeding seat arranged towards the cable winding device in a sliding mode is arranged on the cable binding base in a sliding mode, and a cable binding feeding driver is arranged between the cable binding feeding seat and the cable binding base; a binding wire inlet guider arranged on one side of the fiber cable coil is fixedly arranged on the binding cable feeding seat, a binding wire return wire guide arm is rotatably arranged on the binding cable feeding seat, and the binding wire return wire guide arm is connected with a return wire guide driver; a binding wire cutting device is arranged on the binding cable feeding seat and positioned between the binding wire feeding device and the binding wire feeding guider; and a binding device is arranged on the cable binding feeding seat.

In the full-automatic optical fiber cable cutting and cable winding and cable binding integrated device, the wire binding loop guide arm comprises a loop swinging section which is rotatably installed on the cable binding feeding seat, and the end part of the loop swinging section is fixedly provided with a loop guide section which is arranged in an arc shape.

In the full-automatic optical fiber cable cutting and cable winding and cable binding integrated device, the loop guiding driver comprises a loop driving slider which is slidably mounted on the cable binding feeding seat, the loop driving slider is connected with a slider feeding driver, and a loop guiding transmission connecting rod is arranged between the loop driving slider and the cable binding loop guiding arm.

In the full-automatic optical fiber cable cutting and cable winding and cable binding integrated device, the binding wire supply device comprises a binding wire supply driving wheel which is rotatably arranged on the binding cable feeding seat, and the binding wire supply driving wheel is connected with a binding wire supply driving motor; a binding wire pressing seat is slidably mounted on the binding cable feeding seat, and a binding wire supply driven wheel corresponding to the binding wire supply driving wheel is rotatably mounted on the binding wire pressing seat; and a binding wire pressing and holding force applicator is arranged between the binding wire pressing and holding seat and the binding cable feeding seat.

The cable is cut to full-automatic optic fibre wind cable bundle cable integrated device in, the device is decided including fixed the setting to the bundle cable on feeding the seat, and be located the base is decided to the bundle wire between the cable guiding device with the bundle wire of bundle wire income, the bundle wire is decided and is equipped with the bundle wire clearing hole on the base, the bundle wire is decided and is located on the base the terminal department slidable mounting of bundle wire clearing hole has the bundle wire to decide the cutter, the cutter is decided to the bundle wire is connected with the bundle wire and decides the controller.

In the full-automatic optical fiber cable cutting, winding and binding integrated device, the cable winding device comprises a cable winding main shaft which is rotatably installed on the rack, at least two cable winding supporting arms which are uniformly and circumferentially arranged are fixedly arranged on the cable winding main shaft, at least one of the cable winding supporting arms is provided with a cable supporting movable rod which can move away from the cable winding main shaft, the other cable winding supporting arms are fixedly provided with cable supporting fixed rods, and the cable supporting movable rods are connected with a cable winding tightness controller; and a cable winding initial end fixer is arranged on the cable winding main shaft.

In the full-automatic optical fiber cable cutting and cable winding and cable binding integrated device, a cable roll pulling-out base is slidably mounted on a rack, a cable roll pulling-out rod capable of extending to one side of a fiber cable roll is slidably mounted on the cable roll pulling-out base, a pulling-roll in-place driver is arranged between the cable roll pulling-out rod and the cable roll pulling-out base, and a cable roll pulling-out driver is arranged between the cable roll pulling-out base and the rack.

In the full-automatic optical fiber cable cutting, winding and cable binding integrated device, the metering device comprises a metering fixed wheel rotatably mounted on the rack, a metering pressure support is movably mounted on the rack, a metering movable wheel corresponding to the metering fixed wheel is rotatably mounted on the metering pressure support, and a metering pressure applicator is arranged between the metering pressure support and the rack; the meter counting movable wheel or the meter counting fixed wheel is connected with a revolution sensor.

In the full-automatic optical fiber cable cutting and cable winding and cable binding integrated device, the cable feeding device comprises a cable feeding shifting sliding seat which is slidably mounted on the rack, a cable feeding and fiber taking sliding seat is vertically and slidably mounted on the cable feeding shifting sliding seat, a fiber taking clamp holder is arranged on the cable feeding sliding seat, a fiber taking feeding driver is arranged between the cable feeding sliding seat and the cable feeding shifting sliding seat, and a cable feeding shifting driver is arranged between the cable feeding shifting sliding seat and the rack.

Drawings

The above and other features, properties and advantages of the present invention will become more apparent from the following description of the embodiments with reference to the accompanying drawings, in which:

the drawings are only intended to illustrate and explain the present invention and do not limit the scope of the invention. Wherein:

fig. 1 is an overall perspective view of an embodiment of the present invention;

FIG. 2 is a schematic perspective view of FIG. 1 from another perspective;

fig. 3 is a schematic perspective view of a meter counting device according to an embodiment of the present invention;

fig. 4 is a schematic cross-sectional structural view of a cable winding device according to an embodiment of the present invention;

fig. 5 is a schematic perspective view of a cable feeding device according to an embodiment of the present invention;

FIG. 6 is a schematic perspective view of the cable tying device and the cable feeding device according to the embodiment of the present invention;

FIG. 7 is an enlarged view of the structure at I in FIG. 6;

FIG. 8 is a front view of the cable tie device of FIG. 6;

FIG. 9 is a schematic view of an initial state of the cable tie device;

FIG. 10 is a schematic view of the cable tie device actuated to a state where the wire tie cutting blade contacts the wire tie;

FIG. 11 is a schematic view of the cable tying device in a state in which the wire tying guillotine cutter cuts the wire and the wire tying loop guide arm is in position;

FIG. 12 is a schematic view of a tying device of the cable tying device performing a tying operation;

FIG. 13 is a schematic view of the cable tie device being returned to its illustrated position after completion of the tying action;

FIG. 14 is a schematic view of a cable tie severing device;

FIG. 15 is a perspective view of the cutting device;

FIG. 16 is a cross-sectional view of the cutting device;

in the figure: 1-a frame;

2-a cable laying device; 21-a cable laying frame; 22-cable laying installation shaft; 23-a fiber reel; 24-a payout driving device; 25-a cable laying guide wheel;

3-a meter counting device; 31-meter fixed wheel; 32-meter pressing and holding seat; 33-meter counting movable wheels; 34-revolution sensor;

4-a tensioning device; 41-pressing the tensioning seat downwards; 42-pressing down the tension wheel;

5-cutting the cable device;

6-a cable winding device; 61-a cable winding main shaft; 62-a cable-wound support arm; 63-cable-stay fixing rod; 64-a cable-stay movable rod; 65-cable reel slack controller; 66-cable winding initial end fixer;

7-cable-connecting device; 71-transposition cable-continuing sliding seat; 72-transposition cable-continuing driver; 73-cable feeding displacement slide seat; 74-a tether displacement driver; 75-a cable-continuous fiber-taking sliding seat; 76-a fiber take-up feed drive; 77-fiber taking holder;

8-cable bundling device; 81-cable tie base; 811-transposition cable tie driver; 82-cable binding feeding seat; 821-cable tie feed drive; 83-a wire binding and guiding device; 84-a wire binding loop wire guide arm; 841-return line swing section; 842-loop guide section; 85-return wire driving slide block; 851-slider feed drive; 852-returning the wire to the transmission connecting rod; 86-a binder supply device; 861-bundling the thread to supply the driving wheel; 862-binding wire pressing and holding seat; 863-binding wire is supplied to the driven wheel; 864-ligature-holding forcer; 865-a cable spool; 87-cutting device for binding wire; 871-cutting the base by binding; 872-passing the binding through the hole; 873-cutting the binding wire; 874-cutting the driving wheel by binding; 875-cutting the return spring by binding; 876-cutting the binding wire to form a force application inclined plane; 88-binding the main shaft; 881-tying hook; 882-cable tie hook; 89-cable winding deflector rod; 891-reel-to-reel-in-place drive; 892-deflector rod feed block;

9-an optical fiber; 91-fiber cable roll.

Detailed Description

The invention is further explained below with reference to the drawings and examples. In the following detailed description, exemplary embodiments of the invention are described by way of illustration only. Needless to say, a person skilled in the art will recognize that the described embodiments can be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and not intended to limit the scope of the claims.

Fig. 1 and 2 show a system including a cable binding device, which may be referred to as a "full-automatic fiber cutting and cable winding and cable binding integrated device", and in the embodiments described below, includes a device capable of performing cable laying, cable cutting, cable feeding, cable winding and other processes.

The system comprises a frame 1 as a supporting base for the system. Conventionally, the frame 1 is an assembly of aluminum profiles and plates, which is well known to those skilled in the art and will not be described herein.

A fiber cable reel is a reel of fiber optic wire. The transmitted optical fiber line generally comprises optical fibers and a protective layer for coating the optical fibers, wherein the protective layer comprises a PVC inner layer, a reinforced spun rayon material and a PVC outer layer, and the two ends of the optical fiber line are connected with ceramic ferrules which can be used as optical fiber patch cords. In the following description, the optical fiber line is also referred to as an optical fiber for the sake of simplicity.

As shown in fig. 1 and 2, a cable laying device 2 is arranged on one side of a rack 1, a cable winding device 6 is arranged on the rack 1, a tensioning device 4, a meter counting device 3 and a cable cutting device 5 are sequentially arranged on the rack 1 between the cable laying device 2 and the cable winding device 6, and a cable continuing device 7 for conveying an optical fiber 9 from the cable cutting device 5 to the cable winding device 6 is arranged on the rack 1; the frame 1 is provided with a cable bundling device 8 corresponding to the cable winding device 6. When the optical fiber winding device works normally, the optical fiber 9 is discharged by the cable discharging device 2, the optical fiber 9 reaches the cable winding device 6 through the tensioning device 4, the meter counting device 3 and the cable cutting device 5 to be wound, after the meter counting device 3 counts a fixed length, the cable cutting device 5 cuts the optical fiber 9, and finally the optical fiber 9 is wound into a cable coil 91 through the cable winding device 6. The cable bundling device 8 performs a bundling operation on the cable roll 91. After the bundled fiber reel 91 is removed, the optical fiber 9 cut immediately before is sent from the cable cutting device 5 to the cable feeding device 7 by the cable feeding device 7, and the cable winding operation of the next fiber reel 91 is continued.

As shown in fig. 4 and 6, the cable winding device 6 includes a cable winding main shaft 61 rotatably mounted on the frame 1, and at least two cable winding support arms 62 uniformly arranged in the circumferential direction are fixedly disposed on the cable winding main shaft 61, which is illustrated in the present embodiment that the number of the cable winding support arms 62 is four. At least one of the cable-winding supporting arms 62 is provided with a cable-supporting movable rod 64 which can move away from the cable-winding main shaft 61, and the other cable-winding supporting arms 62 are fixedly provided with cable-supporting fixed rods 63. The cable-supporting movable rod 64 and the cable-supporting fixed rod 63 together enclose a winding structure in which the optical fiber 9 can be wound. The embodiment shows that two cable supporting arms 62 are provided with cable supporting movable rods 64, the other two cable supporting arms 62 are fixedly provided with cable supporting fixed rods 63, and the cable supporting movable rods 64 and the cable supporting fixed rods 63 are arranged in a staggered manner. The cable-supporting movable rod 64 is connected with a cable-roll tightness controller 65; the cable winding main shaft 61 is provided with a cable winding initial end fixer 66. Each support arm 62 is disposed generally parallel to the cable-winding main shaft 61. In fig. 6 only one cable reel 91 is shown wound on the cable winding device 6. As shown in fig. 1, each support arm 62 of the cable winder 6 provides a length for winding multiple cable reels 91 simultaneously.

After the optical fiber 9 is fed to the cable winding device 6, it is fixed by the cable winding initial end holder 66. The cable winding tightness controller 65 controls the cable supporting movable rod 64 to be far away from the cable winding main shaft 61, the cable winding main shaft 61 is driven to rotate, and light can be wound on the cable supporting movable rod 64 and the cable supporting fixed rod 63 in a circle. After winding and bundling are finished, the cable roll loosening controller 65 controls the cable support movable rod 64 to be close to the cable winding main shaft 61, and the fiber cable roll 91 is loosened and can be easily pulled out.

The present embodiment illustrates that the cable-supporting movable rod 64 is slidably mounted on the corresponding cable-winding supporting arm 62 through two rail-slider structures, and the sliding direction is along the radial direction of the cable-winding main shaft 61. The cable winding tightness controller 65 is a cable winding tightness control cylinder, a cylinder body of the cable winding tightness control cylinder is fixedly connected with the cable winding main shaft 61, and a piston rod of the cable winding tightness control cylinder is fixedly connected with the cable supporting movable rod 64. The movement of the cable-supporting movable rod 64 away from and close to the cable-winding main shaft 61 can be realized by stretching and retracting the cable-winding tightness control cylinder. Of course, in this embodiment, a movable rod swing arm may also be installed at the end of the cable-wound support arm 62 in a swinging manner, and a cable-stay movable rod 64 is fixedly arranged on the movable rod swing arm to realize the movable installation of the cable-stay movable rod 64; in this case, the cable winding slack controller 65 is an air cylinder or an electric cylinder or the like hinged between the movable lever swing arm and the corresponding cable winding support arm 62. This technical scheme also can realize propping keeping away from or being close to the action of cable movable rod 64, should be within the utility model's scope of protection equally.

In the embodiment described later, the cable tying device 8 ties one cable reel 91 and then ties the next cable reel 91 by moving, that is, the cable tying devices 8 are shared for each cable reel 91, but in another embodiment, the cable tying devices 8 may be provided for each cable reel 91 if necessary for controlling the tempo of the system.

The cable binding device 8 comprises a cable binding base 81 arranged on the rack 1, a cable binding feeding seat 82 arranged towards the cable winding device 6 in a sliding mode is arranged on the cable binding base 81, and a cable binding feeding driver 821 is arranged between the cable binding feeding seat 82 and the cable binding base 81; a binding wire inlet guide 83 arranged on one side of the fiber cable coil 91 is fixedly arranged on the binding cable feeding seat 82, a binding wire return guide arm 84 is rotatably arranged on the binding cable feeding seat 82, and the binding wire return guide arm 84 is connected with a return wire guide driver; a binding wire feeding device 86 is arranged on the binding cable feeding seat 82, and a binding wire cutting device 87 is arranged on the binding cable feeding seat 82 and positioned between the binding wire feeding device 86 and the binding wire feeding guide 83; the cable binding feeding seat 82 is provided with a binding device. By providing the cable tie feeding seat 82, the cable tie device 8 can be positioned as close to the cable winding device 6 as possible, and the adjusting position can be moved to keep a proper distance from the cable winding device 6 when the cable winding device 6 acts. In another embodiment, the cable tie feeder 82 may be omitted, such as by displacing the cable winder 6 in lieu of displacing the cable tie feeder 82.

According to the embodiment shown in the figure, after the cable winding device 6 winds the fixed length optical fiber 9 into the cable roll 91, the cable feeding driver 821 firstly drives the cable feeding seat 82 to be close to the cable roll 91, and the cable guide 83 finally reaches the cable roll 91. The wire guide driver drives the wire binding wire guide arm 84 to rotate towards the inner side of the cable reel 91, and finally forms a complete wire binding guide channel with the wire binding wire guide 83. The cable feeder 86 can be easily wound in from one side of the cable spool 91 and out from the other side of the cable spool 91 along the complete cable guide path. After the binding wire is cut by the binding wire cutting device 87, a section of the binding wire located at the fiber cable reel 91 is entirely U-shaped by the complete binding wire guide passage, and the binding device can easily perform binding work using both ends of the section of the binding wire, and an embodiment of the binding device will be exemplarily described below.

The wire binding loop guide arm 84 of this embodiment includes a loop swinging section 841 rotatably mounted on the wire binding feeding base 82, an end of the loop swinging section 841 is fixedly provided with a loop guide section 842 in an arc shape, and the loop guide section 842 and the wire binding entry guide 83 can form a complete wire binding guide channel. Preferably, the wire guide guiding section 842 and the wire guiding guide 83 are provided with wire guiding grooves. The binding guide groove of the loop guide section 842 is inclined, as shown in fig. 8, the binding guide groove of the loop guide section 842 is inclined toward the left, i.e. toward the other side of the fiber cable roll 91, and is consistent with the forward swinging direction of the loop guide section 842, which is favorable for the binding to be stably guided from the right side to the left side of the fiber cable roll 91.

The loop guiding driver comprises a loop driving slider 85 slidably mounted on the cable binding feeding base 82, a slider feeding driver 851 is connected to the loop driving slider 85, and a loop guiding transmission link 852 is provided between the loop driving slider 85 and the cable binding loop guiding arm 84. The wire guide transmission link 852 may push the binding wire loop guide arm 84 to swing toward the inside of the cable reel 91 when the slide feed driver drives the loop driving slider 85 to feed the cable reel 91, and the loop guide transmission link 852 is shown as a rod shape in the illustrated embodiment, but is not limited thereto, and may be other members besides the rod shape as long as it can transmit the motion outputted from the loop driving slider 85 to the binding wire loop guide arm 84, for example, another embodiment of the loop guide transmission link 852 is a special-shaped groove corresponding to the trajectory of the end of the binding wire loop guide arm 84, and the special-shaped groove is engaged with the hinge of the loop guide transmission link 852. The slider feeding driver 851 according to the embodiment comprises a slider feeding driving disk 853 rotatably mounted on the cable tie feeding base 82, the slider feeding driving disk 853 is connected with a slider feeding driving motor 854, the slider feeding driving disk 853 is provided with an eccentric connecting shaft 855, and a slider feeding driving connecting rod 856 is hinged between the eccentric connecting shaft 855 and the loop driving slider 85. With the above structure, the slider feed drive disk 853, the slider feed drive link 856, and the loop drive slider 85 constitute a slider-crank mechanism. The slide feed drive motor 854 is blocked and only the end of the motor shaft is shown in the figure. The loop driving slider 85 can drive the binding loop guide arm 84 to swing toward the inside of the fiber reel 91 or drive the binding loop guide arm 84 to return within a stroke range by the slider feed driving motor 854. Of course, the slide block feeding driver 851 can also be directly realized by adopting an electric cylinder, an air cylinder or an electric motor matched with a screw transmission. The advantage of using the crank-slider mechanism as shown is that the wire return guide arm 84 can be driven and positioned in a number of positions and takes up a low length of space and also has the advantage of being low cost. In addition, the loop guiding driver can also be directly realized by adopting structures such as an electric cylinder or an air cylinder.

The wire binding feeding device 86 includes a wire binding feeding drive wheel 861 rotatably mounted on the wire binding feeding base 82, and a wire binding feeding drive motor, which is not shown but is hidden in the drawing, is connected to the wire binding feeding drive wheel 861. A binding wire pressing seat 862 is slidably mounted on the binding cable feeding seat 82, and a binding wire supply driven wheel 863 corresponding to the binding wire supply driving wheel 861 is rotatably mounted on the binding wire pressing seat 862; a binding wire pressing and applying force device 864 is arranged between the binding wire pressing seat 862 and the binding cable feeding seat 82. The binding wire pressing force applier 864 drives the binding wire pressing seat 862 to hold the pressing force of the binding wire supplying driving wheel 861, and the binding wire supplying driven wheel 863 and the binding wire supplying driving wheel 861 can effectively clamp the binding wire. When the binding wire supply driving motor drives the binding wire supply driving wheel 861 to rotate, the binding wire can be output and supplied. The ligature crimping applicator 864 may also be implemented using a spring or the like. In this embodiment, a cable reel 865 is mounted to the cable feeding block 82 or the cable base 81. The wire 100 is drawn out from the wire reel 865, passed through between the driving wheel 861 and the driven wheel 863 by a predetermined traction, sandwiched between the driving wheel 861 and the driven wheel 863, and subjected to friction transmission.

The wire tying device 87 includes a wire tying base 871 fixedly provided on the wire tying feeding base 82 and located between the wire tying device 86 and the wire inserting guide 83, a wire tying hole 872 is provided in the wire tying base 871, a wire tying cutter 873 is slidably mounted on the wire tying base 871 at the tip of the wire tying hole 872, a wire tying controller is connected to the wire tying cutter 873, and an embodiment of the wire tying controller will be described below by way of example. The binding wire passage hole 872 is linear and aligned in the tangential direction of the clamping position of the driving pulley 861 and the driven pulley 863, that is, the output direction of the binding wire.

The binding wire fed from the binding wire feeding device 86 first passes through the binding wire passage hole 872 and then reaches the binding wire guide 83. When the binding wire output length is sufficient, for example, in the state shown in fig. 9, the binding wire cutting controller controls the binding wire cutting blade 873 to slide. As shown in fig. 15, the binding wire cutter 873 and the end of the binding wire passage hole 872 can perform a cutting action on the binding wire 100. In this embodiment, the cross section of the wire cutting tool 873 is square, and the wire cutting base 871 is provided with a square slide hole corresponding to the wire cutting tool 873, thereby forming a slide attachment of the wire cutting tool 873. The wire binding passage hole 872 guides the wire binding to force the wire binding to be transferred to a position where the wire binding cutter 873 can reach. The binding wire passing hole 872 also plays a role of limiting the lateral movement of the binding wire, when the binding wire cutter 873 moves from right to left to reach the binding wire position, the cutting edge of the binding wire cutter 873 tends to push the binding wire to move, but the binding wire is limited by the lateral movement prevention of the binding wire passing hole 872, so that the binding wire does not move, and the binding wire cutter 873 continues to move to the left, thereby performing the cutting action on the binding wire. In another embodiment, the shape of the cable-passing hole 872 is not limited to a square shape and may be any other shape, with the hole having substantially the same meaning as the slot or groove or channel, and may be the inner surface of a continuous material or a hollowed-out material, so long as it functions as a lateral movement prevention and guide.

The wire binding return guide arm 84 and the wire binding guide 83 of this embodiment are located on the same side of the cable spool 91. The wire binding cutting controller comprises a wire binding cutting driving wheel 874 rotatably installed on a wire binding cutting cutter 873, a wire binding cutting force application inclined plane 876 corresponding to the wire binding cutting driving wheel 874 is arranged on the loop driving slider 85, and a wire binding cutting return spring 875 is arranged between the wire binding cutting cutter 873 and the wire binding cutting base 871. In the binding operation, the binding wire supplying device 86 first outputs the binding wire and causes the end of the binding wire to reach the binding wire introducing guide 83. The loop wire driving slider 85 is driven to approach the fiber reel 91, the binding wire cutting bias 876 thereon passes through the binding wire cutting transmission wheel 874, and the binding wire cutting blade 873 is gradually brought close to the binding wire passing hole 872, and fig. 9 can be used as an exemplary starting point of the binding wire cutting blade 873, and in the state shown in fig. 10, the binding wire cutting blade 873 is moved a distance leftward from the starting point, and the cutting edge of the binding wire cutting blade 873 comes into contact with the binding wire passing through the binding wire passing hole 872. The binding wire return guide arm 84 synchronously swings toward the inside of the fiber reel 91 and gradually forms a longer binding wire guide channel in a curved arc shape with the binding wire guide 83, the binding wire return guide arm 84 in fig. 9 is also in an initial state, and the binding wire return guide arm 84 in fig. 10 already guides the binding wire. In the process from the state shown in fig. 9 to the state shown in fig. 10, the binding wire is transferred downward while the binding wire loop guide arm 84 swings leftward, and the binding wire is guided while the binding wire loop guide arm 84 swings. With reference to fig. 9 and 10, the binding wire continuously fed out by the binding wire feeding device 86 is bent along with the longer and longer curved wire guide passage, and the bent binding wire is protruded from the other side of the cable reel 91 under the influence of the plastic deformation of the binding wire and the longer and longer wire guide passage. Finally, as the loop driving slider 85 slides down to the lower limit position or the lower limit position, as shown in fig. 11, the binding wire cutting biasing inclined surface 876 pushes the binding wire cutting blade 873, so that the binding wire cutting blade 873 moves further leftward with respect to the position shown in fig. 10, and further cuts the binding wire, the binding wire loop guide arm 84 further swings leftward, that is, swings in the advancing direction, and also forms a final complete binding wire guide path with the binding wire guide 83, and the cut binding wire forms a winding shape, for example, a U shape, at the fiber reel 91, and both ends of the binding wire pass through the binding device, that is, reach a position where the binding device can perform binding work.

In one embodiment, the tying device includes a tying spindle 88 mounted on the tying cable feeding seat 82, an S-shaped tying hook 881 is fixedly disposed at one end of the tying spindle 88 close to the fiber cable reel 91, tying cable hooks 882 are respectively fixedly disposed at two ends of the tying hook 881, and a tying driving motor is connected to the tying spindle 88. When the binding wire at the position of the fiber cable roll 91 forms a U shape, the binding driving motor drives the binding main shaft 88 to rotate, the two binding wire hooks 882 firstly contact the two ends of the U-shaped binding wire and tie the binding wire to rotate around the binding main shaft 88, in the rotating process, the two ends of the U-shaped binding wire form interaction in a spiral mode and are close to the binding hooks 881, in the continuous rotation of the binding main shaft 88, the two ends of the binding wire are finally bound in the spiral binding mode, and the binding driving motor is stopped.

Fig. 12 shows a state after the bundling of the bundling device is completed, and during the bundling, the wire return driving slider 85 is normally kept stationary, and accordingly, the wire binding cutter 873 and the wire binding return guide arm 84 are kept stationary, and the wire binding return guide arm 84 maintains the stable position of the wire binding. In another embodiment, the wire returning driving slider 85 may be controlled to perform the retracting operation in advance during the spiral binding process of the binding apparatus, i.e., after the two ends of the binding wire are spirally wound. After the bundling is normally completed, the wire returning drive slider 85 is driven to return, the wire binding wire returning guide arm 84 returns, the wire binding cutter 873 returns by the wire binding cutter return spring 875, the wire binding cable feeding driver 821 drives the wire binding cable feeding base 82 to return, and the fiber cable reel 91 can be easily removed from the cable winding device 6. In the state shown in fig. 13, compared with the state shown in fig. 9, the wire cutter 873 and the wire loop guide arm 84 are both in the exemplary initial state, and the loop driving slider 85 is positioned at the top dead center or the top limit position, and in fig. 13, the wire supplying device 86 waits for a control command to perform a wire supplying operation, which is normally performed after the fiber reel 91 is pulled out.

As shown in fig. 6, a cable roll pulling-out base 893 is slidably mounted on the frame 1, a cable roll pulling-out lever 89 capable of extending to one side of the cable roll 91 is slidably mounted on the cable roll pulling-out base 893, a pulling-in position driver 891 is disposed between the cable roll pulling-out lever 89 and the cable roll pulling-out base 893, and a cable roll pulling-out driver is disposed between the cable roll pulling-out base 893 and the frame 1, as will be understood from the following description, the cable roll pulling-out driver and the transposition cable binding driver 811 are disposed as the same driver, and accordingly the cable roll pulling-out base 893 and the cable binding base 81 are different parts of the same base, which is driven by the aforementioned driver and is moved and adjusted in the front-back direction shown in fig. 6, and one embodiment of the driver is that the motor is connected to a ball screw mechanism 8112, and the motor can be replaced by other rotation output devices, such as a belt mechanism 8810. After the fiber cable roll 91 is bundled, the two cable roll tightness controllers 65 respectively control the corresponding cable support movable rods 64 to move close to the cable winding main shaft 61, and the fiber cable roll 91 is loosened. The coil-pulling-in-place driver 891 drives the cable coil pulling rod 89 to extend out, as shown in fig. 6, two cable coil pulling rods 89 are connected to the upper and lower sides of the same pulling rod feeding seat 892 in the vertical direction, and the pulling rod feeding seat 892 is slidably disposed on the cable coil pulling base 893 through a sliding rail mechanism. Because a large space exists between the cable supporting movable rod 64 and the cable supporting fixed rod 63, the upper and lower cable roll deflector rods 89 can easily reach one side of the cable roll 91. Then the cable roll pulling-out driver controls the cable roll pulling-out base 893 to slide integrally, and the cable roll pulling-out rod 89 can pull out the optical fiber cable roll 91 from the cable winding device 6 to form automatic rolling-down operation. In another embodiment, the coil-pulling-in-place driver 891 may be implemented by an electric cylinder or an air cylinder, and the cable-reel-pulling-out driver may be implemented by an electric cylinder, an air cylinder, or an electric motor in combination with a screw drive. Because the deflector rod feeding seat 892 is slidably mounted on the cable coil withdrawing base, the coil withdrawing in-place driver 891 is arranged between the deflector rod feeding seat 892 and the cable coil withdrawing base, and the deflector rod feeding seat 892 is fixedly provided with two cable coil deflector rods 89, thereby forming a better shifting effect on the fiber cable coil 91. The cable pulling-out base 893 or the cable tying base 81 is provided with such a cable pulling mechanism on both the front and rear sides thereof corresponding to the plurality of tied cable reels 91, so that the plurality of cable reels 91 can be pulled out from the cable winding device simultaneously in one cable pulling operation.

As mentioned above, the system comprising the cable binding device is exemplified by a fully automatic integrated device for cutting and winding the optical fiber cable and the system further comprises a device for implementing cable laying, cable cutting and cable continuing.

According to the embodiment shown in fig. 1 and 2, the optical fiber 9 released by the cable releasing device 2 reaches the metering device 3 through the tension device 4, and the start end of the optical fiber 9 is held by the fiber taking holder 77 in the cable feeding device 7, and at this time, the metering device 3 clears the number of rotations of the length of the optical fiber 9. The optical fiber 9 is then sent from the cable feeding device 7 to the cable winding initial end holder 66 of the cable winding device 6 over the cable cutting device 5, and counting is started at the meter counting device 3 during cable feeding. After the initial end of the optical fiber 9 is fixed, the cable feeding device 7 returns to the original position and is driven to rotate around the cable main shaft 61, and the optical fiber 9 can be wound on the cable supporting fixed rod 63 and the cable supporting movable rod 64. When the meter counting means 3 detects the specified number of turns, the winding of the optical fiber 9 reaches a specified length. The optical fiber 9 between the cable cutting device 5 and the length counting device 3 is clamped by a fiber taking clamp 77 on the cable continuing device 7, and the position of the clamping is the position of the last clamping of the optical fiber 9. The cable cutting device 5 cuts the optical fiber 9, and stops rotating after a certain time delay around the cable main shaft 61, so that the optical fiber 9 forms a fiber cable roll 91 at the cable main shaft 61. The cable bundling device 8 bundles the optical fiber cable coil 91, the cable bundling device 8 returns after the bundling is finished, the optical fiber cable coil 91 is pulled out by the cable coil driving lever 89, and the cable continuing device 7 sends the optical fiber 9 to the cable winding initial end fixer 66 of the cable winding device 6 again to perform the next cable winding operation. The cable is cut out, the cable is wound and the cable is tied up to the embodiment, so that full-automatic operation is realized, manpower use is reduced, labor cost is reduced, and production efficiency is improved.

The cable laying device 2 comprises a cable laying frame 21, the cable laying frame 21 can be arranged integrally with the machine frame 1 or can be separately arranged and then is fixedly arranged relative to the machine frame 1, and the embodiment is illustrated according to the latter. The cable releasing rack 21 is rotatably provided with a cable releasing mounting shaft 22, the cable releasing mounting shaft 22 is provided with an optical fiber winding drum 23, and the cable releasing mounting shaft 22 is connected with a cable releasing driving device 24. The cable laying driving device 24 drives the cable laying mounting shaft 22 to rotate, and the optical fiber 9 is laid out. When the optical fiber 9 on the optical fiber reel 23 is completely wound, the optical fiber can be replaced by manpower.

The meter counting device 3 comprises a meter counting fixed wheel 31 which is rotatably arranged on the frame 1, a meter counting pressure holding seat 32 is movably arranged on the frame 1, a meter counting movable wheel 33 which corresponds to the meter counting fixed wheel 31 is rotatably arranged on the meter counting pressure holding seat 32, and a meter counting pressure holding force applicator is arranged between the meter counting pressure holding seat 32 and the frame 1; the meter counting movable wheel 33 or the meter counting fixed wheel 31 is connected with a revolution sensor 34. Under the action of the meter-measuring pressure-holding force applicator, the meter-measuring pressure-holding seat 32 enables the meter-measuring movable wheel 33 and the meter-measuring fixed wheel 31 to effectively clamp the optical fiber 9. When the optical fiber 9 advances under the action of the cable, the meter-counting movable wheel 33 and the meter-counting fixed wheel 31 can be driven to rotate, and the advancing length of the optical fiber 9 can be obtained by multiplying the circumference of the meter-counting movable wheel 33 or the meter-counting fixed wheel 31 by the corresponding revolution. The present embodiment shows that the number of turns sensor 34 is provided on the meter-m movable sheave 33, and the length of the optical fiber 9 is obtained by multiplying the circumference of the meter-m movable sheave 33 by the number of turns. Of course, the revolution sensor 34 is connected with an electric controller by signals, and the output end of the electric controller is connected with the cable cutting device 5 by signals.

In the embodiment, the meter-counting pressure-holding seat 32 is installed on the frame 1 in a swinging manner and is positioned above the meter-counting movable wheel 33, and the meter-counting pressure-holding seat 32 is also used as a meter-counting pressure-holding force applicator. The metering movable wheel 33 and the metering fixed wheel 31 form a clamping effect on light rays by the gravity action of the metering pressure holder 32 and structures such as the metering movable wheel 33, the revolution sensor 34, the bearing and the like on the metering pressure holder. Of course, the meter-measuring pressure-holding force applying device of the embodiment can also be a meter-measuring pressure-holding force applying spring which is independently arranged between the meter-measuring pressure-holding seat 32 and the frame 1, and the clamping action of the meter-measuring movable wheel 33 and the meter-measuring fixed wheel 31 is further enhanced through the spring force action. In addition, the meter-measuring pressure holder 32 of the present embodiment can also be slidably mounted on the frame 1, and the meter-measuring pressure holder 32 is close to the meter-measuring fixed wheel 31 under the action of the meter-measuring pressure applicator, and can also form the clamping action between the meter-measuring movable wheel 33 and the meter-measuring fixed wheel 31. The technical proposal also falls within the protection scope of the utility model.

In an alternative embodiment, the meter device comprises a sensor and the cable winding device, the sensor counts the rotating speed of the cable winding device, and the length of the optical fiber cable which is transmitted or wound is calculated according to the rotating speed of the cable winding device. This alternative embodiment eliminates the metering casters and the pressure holders, etc., and therefore has a simpler structure and lower design, manufacturing and maintenance costs.

The tensioning device 4 comprises a pressing tensioning seat 41 vertically and slidably mounted on the frame 1, and a pressing tensioning wheel 42 is rotatably mounted on the pressing tensioning seat 41. The optical fiber 9 fed out by the cable laying device 2 reaches the meter counting device 3 upwards after pressing the tension wheel 42 downwards. The tensioning of optic fibre 9 is realized to this embodiment through the action of gravity of pushing down tensioning seat 41 and pushing down tensioning wheel 42, and this action of gravity is less, is difficult to damage optic fibre 9 structure. This embodiment shows that the cable-laying guide wheel 25 is arranged higher than the tension device 4 on the cable-laying frame 21, so that the sliding of the pressing tension seat 41 is smoother and the tension seat is more effective. The lower pressure tension base 41 of the present embodiment is vertically slidably mounted by two guide rods.

In actual use, the cable winding speed of the cable winding device 6 and the cable unwinding speed of the cable unwinding device 2 are not necessarily matched accurately. When the cable winding speed of the cable winding device 6 is greater than the cable releasing speed of the cable releasing device 2, the length of the optical fiber 9 at the tensioning device 4 is shortened, and the tensioning force of the optical fiber 9 drives the downward tensioning seat 41 to rise. On the contrary, when the cable winding speed of the cable winding device 6 is lower than the cable unwinding speed of the cable unwinding device 2, even when the cable winding speed of the cable winding device 6 is zero, such as when the cable tying device 8 ties up the cable after the cable cutting device 5 cuts off, the length of the optical fiber 9 at the tensioning device 4 increases, and the downward pressing of the tensioning seat 41 decreases. To avoid that the optical fibre 9 at the tensioning device 4 is too short or too long, causing unnecessary problems.

On the other hand, as the amount of cable laying increases, and the cable laying rotation speed of the cable laying device 2 is not changed, the thickness of the cable is reduced, so that the cable laying amount is reduced, which corresponds to the change of the cable winding speed and the cable laying speed between the cable winding device 6 and the cable laying device 2, and the cable winding speed and the cable laying speed can also cause that the cable winding speed and the cable laying speed cannot be matched. By means of the tensioning device 4, the tensioning device 4 moves up and down, and the amount of the up and down movement is the buffer length of the buffer optical fiber line, and the buffer length is used for dynamically and adaptively adapting to the changes of the cable winding speed of the cable winding device 6 and the cable unwinding speed of the cable unwinding device 2.

The frame 1 of this embodiment is provided with the highest position sensor and the lowest position sensor corresponding to the lower tension seat 41, and the highest position and the lowest position of the lower tension seat 41 are respectively detected, so that the length of the optical fiber 9 at the tensioning device 4 is always kept within a certain range. Of course, the highest position sensor and the lowest position sensor are also connected with the electric controller through signals, and the output end of the electric controller is connected with the cable laying device 2 through signals. The arrangement of the highest position sensor and the lowest position sensor, which is not illustrated in the figure, may be selected from a photoelectric sensor, a hall sensor, or other position sensors.

The cable cutting device 5 mainly has a structure that two cutting blades cut the optical fiber 9. As shown in fig. 15 and 16, the cable cutting device 5 includes a fixed blade holder 54 and a movable blade holder 52, the fixed blade holder 54 provides a moving passage 540, and the movable blade holder 52 is disposed in the moving passage 540. The fixed knife holder 54 is provided with a wire passing groove 541 and a wire cutting knife 55, the edge of the wire cutting knife 55 extends to the wire passing groove 541, accordingly, the movable knife holder 52 is provided with a plurality of wire cutting knives 56, and the wire cutting knives 56 can move to a position meeting the wire cutting knife 55, which is positioned in the wire passing groove 541. The movable blade holder 52 is driven by a thread cutting drive 51. One embodiment of the tangent drive 51 is an air cylinder. When the movable blade holder 52 moves to separate the two wire cutters 55 and 56, the optical fiber 9 can pass through the wire passing groove 541, and when the two wire cutters 55 and 56 meet and are staggered again when the movable blade holder 52 moves, the optical fiber 9 in the wire passing groove 541 is cut off. As will be understood from the following description, the end of the cut optical fiber 9 on the upstream side of the cable cutting device 5 is held by the cable feeding device 7, i.e., by the fiber take-up holder 77, and then the cable feeding device 7 draws the optical fiber 9 through the wire passage groove 541, transfers it to the cable winding device 6, is held by the cable winding device 6, and starts cable winding. The power transmitted forward by the optical fiber 9 is only provided by the cable winding device 6, so many parts for driving the optical fiber 9 in the middle, such as a stepping motor, a driving wheel, a driven wheel, a pressing cylinder, a cable feeding roller, a cable feeding nozzle and the like, can be omitted, the structural parts of the mechanism are effectively simplified, and because one station of the cable continuing device 7 is arranged at the upstream side of the cable cutting device 5, even if the optical fiber 9 is cut by the cable cutting device 5 and loses the driving power, the optical fiber 9 is also kept in a tensioned state, and simultaneously, in cooperation with the cache system, the optical fiber 9 can be kept in the tensioned state continuously before being drawn to the cable winding device 6 by the cable continuing device 7 for cable winding.

The cable start end holder 66 is used to hold the optical fiber 9 at the start end of the cable winding device 6 and prevent it from slipping during winding. The cable winding start end holder 66 in this embodiment is a finger cylinder fixedly disposed on the cable winding spindle 61, and the two fingers of the finger cylinder are respectively disposed with a clamping block, which is easily understood by those skilled in the art from the description and the prior art, and will not be described herein again. This embodiment illustrates two cable-winding start anchors 66 symmetrically disposed about the cable main shaft 61. When the cable winding device 6 finishes one cable winding operation, the cable winding initial end fixer 66 is preferably controlled to be in a vertical state, which facilitates the initial end fixing directly after the cable continuing device 7 sends the initial end of the next wave optical fiber 9.

The cable feeding device 7 comprises a cable feeding displacement slide carriage 73 slidably mounted on the rack 1, a cable feeding and fiber taking slide carriage 75 is vertically slidably mounted on the cable feeding displacement slide carriage 73, a fiber taking clamp 77 is arranged on the cable feeding and fiber taking slide carriage 75, a fiber taking and feeding driver 76 is arranged between the cable feeding and fiber taking slide carriage 75 and the cable feeding displacement slide carriage 73, and a cable feeding displacement driver 74 is arranged between the cable feeding displacement slide carriage 73 and the rack 1. Before the optical fiber 9 is cut by the cable cutting device 5, the cable feeding displacement driver 74 drives the cable feeding displacement slide carriage 73 to slide to the upper part of the cable cutting device 5 (the first station), the fiber taking and feeding driver 76 drives the cable feeding slide carriage 75 to descend, and the fiber taking clamper 77 clamps the optical fiber 9 positioned in front of the cable cutting device 5. After the cable cutting device 5 is cut off, the clamping function of the fiber taking clamp 77 can ensure that the optical fiber 9 between the fiber taking clamp 77 and the cable laying device 2 cannot be disturbed. When the bundled fiber reel 91 is pulled out and the next wave optical fiber 9 is to be wound, the fiber take-out feeding driver 76 drives the continuous cable take-out sliding base 75 to rise, and the continuous cable shift driver 74 drives the continuous cable shift sliding base 73 to slide to the cable winding device 6 (second station). The portion of the optical fiber 9 held by the fiber holding unit 77 is the start end of the aforementioned wound cable. The fiber take-up feeder driver 76 drives the continuous cable take-up slider 75 to move up and down in a predetermined manner according to the height of the cable-winding start end anchor 66. Finally, the start end of the optical fiber 9 held by the fiber holding device 77 is positioned on the cable winding start end holder 66, and after the start end is fixed by the cable winding start end holder 66, the fiber holding device 77 is released from holding, the cable feeding device 7 returns to the original position, and the cable winding device 6 can perform cable winding operation.

The cable feeding displacement driver 74 and the fiber taking and feeding driver 76 can be realized by adopting an air cylinder, an electric cylinder or a motor to match with screw transmission and the like, and the fiber taking clamp holder 77 is also realized by a finger air cylinder.

According to the embodiment shown in fig. 1 and 2, the above-mentioned cable laying, cable cutting, cable feeding, cable winding and cable tying can be performed in parallel in a plurality of paths. In the cable laying device 2 of the present embodiment, the cable laying frame 21 is provided with six optical fiber reels 23, and the cable laying frame 21 is divided into two sides, that is, three optical fiber reels 23 on each side, and three optical fiber reels 23 on the same side are laid synchronously.

Three tensioning devices 4 and three metering devices 3 are respectively arranged corresponding to the optical fibers 9 discharged from the three optical fiber reels 23 on each side; the lengths of the cable supporting fixed rod 63 and the cable supporting movable rod 64 are lengthened, and three pairs of cable winding initial end fixing devices 66 are arranged on the cable winding main shaft 61; three fiber taking clamps 77 are arranged on the continuous cable taking slide carriage 75 in the continuous cable device 7.

In the cable feeding device 7, a transposition cable feeding sliding seat 71 is arranged between the cable feeding shifting sliding seat 73 and the rack 1, and the cable feeding shifting sliding seat 73 is slidably mounted on the transposition cable feeding sliding seat 71; the transposition cable-continuing sliding seat 71 is transversely slidably mounted on the machine frame 1 and can move between the cable cutting devices 5 on the two sides, and a transposition cable-continuing driver 72 is arranged between the transposition cable-continuing sliding seat 71 and the machine frame 1. The transposition cable-continuing driver 72 drives the transposition cable-continuing slide carriage 71 to slide, so that the cable-continuing device 7 can continue three optical fibers 9 on one side to the other side after three optical fibers 9 on the other side.

Similarly, in the cable tie device 8 of the present embodiment, the cable tie base 81 is transversely slidably mounted on the frame 1, and the transposition cable tie driver 811 is disposed between the cable tie base 81 and the frame 1. The transposition cable driver 811 drives the cable base 81 to slide, so that the cable base 81 can sequentially perform the bundling operation on three cable rolls 91 on one side and then sequentially perform the bundling operation on the other three cable rolls 91 on the other side.

Based on the slidable mounting of the cable bundling base 81, the cable winding-out base and the cable bundling base 81 are fixedly connected, namely, the cable bundling base 81 is also used as the cable winding-out base, and the transposition cable bundling driver 811 is also used as the cable winding-out driver, so that the structure of the embodiment is more compact. After the cable bundling device 8 finishes the bundling operation of the three cable rolls 91 on one side, the cable bundling structure in the cable bundling device 8 returns, the transposition cable bundling driver 811 drives the cable bundling base 81 to reach the sides of the three cable rolls 91 on the side, the coil poking and positioning driver 891 drives the cable roll poking rod 89 to extend out, the transposition cable bundling driver 811 drives the cable bundling base 81 to slide, and the cable roll poking rod 89 pokes out the three cable rolls 91 on the side. In order to facilitate the pulling out of the two side fiber cable coils 91, a pulling rod feeding seat 892 is slidably installed on each of the two sides of the cable bundling base 81, and each pulling rod feeding seat 892 is respectively matched with a hot coil pulling rod 89 and a pulling coil in-place driver 891. After the cable is pulled out, the cable roll deflector rod 89 returns, and the transposition cable binding driver 811 drives the cable binding base 81 to the three cable rolls 91 on the other side to be in place.

Through above-mentioned structural optimization, this embodiment one side is cutting out the cable, is pricked the cable, the cable is rolled up and is dialled out and continue the in-process of cable, and the opposite side can wind the cable simultaneously, so form not stopping the operation around the cable, improve optic fibre 9 greatly and cut out the whole efficiency that the cable was pricked around the cable. The transposition cable-continuing driver 72 and the transposition cable-bundling driver 811 can be realized by adopting structures such as an electric cylinder, an air cylinder or a motor matched with screw transmission.

The embodiment realizes the full-automatic operation of the optical fiber 9 cable binding, especially realizes the full-automatic operation of the whole process from cable laying to cable binding, reduces the manpower use, reduces the labor cost and improves the production efficiency. And through reasonable structural arrangement, the overall efficiency of automatic operation is greatly improved, and the automatic operation device has higher economic value and social value.

The basic principles, main features and advantages of the present invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (16)

1. Cable bundling device for the fine cable book on the cable winding device is pricked, its characterized in that includes:

a binding wire supply device,

a binding wire inlet guider arranged at one side of the fiber cable roll,

a binding wire return wire guide arm is rotatably installed,

a wire return guide driver connected with the wire binding wire return guide arm,

a binding wire cutting device arranged between the binding wire supply device and the binding wire feeding guide for cutting the binding wire, and

the binding device is used for binding two ends of the binding wires positioned on two sides of the fiber cable roll together;

the binding wire return wire guide arm is arranged to be rotatable to the inner side of the fiber cable roll, and forms a guide channel for the binding wire to be wound into the inner side of the fiber cable roll and to be wound out from the other side of the fiber cable roll with the binding wire inlet guide integrally, and the binding wire supplied by the binding wire supply device can be wound into the channel from one side of the fiber cable roll and wound out from the other side of the fiber cable roll along the guide channel, so that the binding device can perform binding operation.

2. The cable tie device of claim 1, wherein the wire tie severing device includes a wire tie severing cutter, the wire tie severing cutter and the wire tie loop guide arm configured to move in synchronization by movement of the loop guide driver output;

in one stage of the synchronous movement, the binding wire cutting tool gradually approaches to the binding wire through hole, the binding wire return wire guide arm synchronously swings towards the inner side of the fiber cable roll, and a longer binding wire guide channel in an arc shape is gradually formed with the binding wire inlet guide device;

in another phase of the synchronous motion, the binding wire cutting tool is pushed to cut the binding wire, the binding wire is cut by the binding wire cutting tool, the binding wire loop guiding arm and the binding wire entering guider form a final complete binding wire guiding channel, and the binding wire is guided to reach the position where the binding device can perform binding operation.

3. The cable tie device of claim 2, wherein the loop guide driver comprises:

the loop driving slide block is arranged in a sliding way and is provided with a binding wire cutting force application inclined plane;

the sliding block feeding driver is used for connecting and driving the loop driving sliding block; and

a loop wire guiding transmission connecting rod is arranged between the loop wire driving sliding block and the wire binding loop wire guiding arm;

the wire-binding wire-returning guide driver outputs and transmits the motion of the wire-binding wire-returning cutting tool by means of the wire-binding wire-cutting force application inclined plane, and outputs and transmits the motion of the wire-binding wire-returning guide arm by means of the wire-returning guide transmission connecting rod.

4. The cable tie apparatus of claim 3, wherein the slider feed drive comprises:

a slider feed drive disk is rotatably mounted,

a slide block feeding driving motor connected with the slide block feeding driving disc,

an eccentric connecting shaft provided on the slider feed drive disk, an

The sliding block feeding driving connecting rod is hinged between the eccentric connecting shaft and the return wire driving sliding block;

the slider feeding driving disc, the slider feeding driving connecting rod and the return wire driving slider form a crank slider mechanism.

5. The cable tie device according to claim 2, wherein the cable tie cutter further comprises a cable tie cutting base and a cable tie passing hole provided in the cable tie cutting base, and the cable tie cutter is provided with a cable tie cutting return spring provided to slide on the cable tie cutting base.

6. The cable tie device of claim 1, wherein the wire tie loop guide arm comprises:

a rotationally mounted return line swing section, and

a loop guiding section which is arranged in an arc shape is fixedly arranged at the end part of the loop swinging section,

the loop guiding section is used for forming a complete binding guiding channel with the binding wire inlet guider.

7. The cable tie device of claim 6, wherein the loop guide segment and the wire tie entry guide are provided with wire tie guide grooves.

8. The cable tie device of claim 7, wherein the cable tie guide groove of the cable tie-in guide is inclined toward the other side of the cable spool in accordance with the swinging direction of the wire return guide section.

9. The cable tie device of claim 1, further comprising a cable tie supply device, the cable tie supply device comprising:

the binding wire which is rotatably arranged is supplied to the driving wheel,

a binding wire pressing and holding seat which is installed in a sliding way,

a binding wire supply driven wheel rotatably mounted on the binding wire pressure holding base and disposed corresponding to the binding wire supply driving wheel, an

And the binding wire pressing and holding force applicator drives the binding wire pressing and holding seat to keep the pressing and holding force of the binding wire supply driving wheel, so that the binding wire supply driven wheel and the binding wire supply driving wheel can form effective clamping on the binding wire.

10. The cable tie device of claim 1, further comprising:

a cable binding base is arranged on the base,

a cable tie feed shoe slidably mounted on the cable tie base and slidably disposed toward the cable winding device, an

And a cable tie feeding driver is arranged between the cable tie feeding seat and the cable tie base.

11. The cable bundling device according to claim 1, wherein the bundling device comprises a bundling spindle, one end of the bundling spindle close to the fiber cable roll is fixedly provided with an S-shaped bundling hook, two ends of the bundling hook are respectively and fixedly provided with a bundling wire holding hook, the bundling spindle is connected with a bundling driving motor, and the two bundling wire holding hooks can firstly contact with two ends of a bundling wire before bundling.

12. A system comprising a cable tie device, further comprising a cable winding device, wherein the cable tie device is a cable tie device according to any one of claims 1 to 11;

the cable winding device comprises a cable winding main shaft which is rotatably installed, at least two cable winding supporting arms which are uniformly distributed in the circumferential direction are fixedly arranged on the cable winding main shaft, a cable supporting movable rod which can move away from the cable winding main shaft is installed on at least one of the cable winding supporting arms, cable supporting fixed rods are fixedly arranged on the other cable winding supporting arms, and the cable supporting movable rods are connected with a cable winding tightness controller; a cable wrap surrounds the cable-winding support arm.

13. The system of claim 12, wherein the cable tie device further comprises:

the cable roll which is mounted in a sliding manner is pulled out of the base,

a cable roll deflector rod which is arranged on the cable roll deflector base in a sliding way,

a coil-poking in-place driver for driving the cable coil poking rod, an

A cable roll pullout driver that drives the cable roll pullout base;

the coil poking in-place driver can drive the cable coil poking rod to extend out to one side of the fiber cable coil, and the cable coil poking-out driver is used for controlling the cable coil poking-out base to integrally slide along the axial direction of the cable winding device, so that the fiber cable coil is allowed to be axially poked out of the cable winding device by the cable coil poking rod.

14. The system of claim 12, further comprising a meter device, the meter device comprising:

a meter-counting fixed wheel is rotatably arranged,

a meter-counting pressure-holding seat which is movably arranged,

the meter-counting movable wheel is rotatably arranged on the meter-counting pressure holding seat and corresponds to the meter-counting fixed wheel;

wherein the meter-measuring pressure-holding seat is provided with a meter-measuring pressure-holding force applicator; the meter counting movable wheel or the meter counting fixed wheel is connected with a revolution sensor;

or the meter counting device comprises a sensor and the cable winding device, and the sensor detects the rotating speed of the cable winding device.

15. The system of claim 12, further comprising a cable cutting device and a cable feeding device,

the cable feeding device comprises a cable feeding shifting sliding seat which is slidably mounted, a cable feeding and fiber taking sliding seat is vertically and slidably mounted on the cable feeding shifting sliding seat, a fiber taking clamp holder is arranged on the cable feeding and fiber taking sliding seat, a fiber taking and feeding driver is arranged between the cable feeding and fiber taking sliding seat and the cable feeding shifting sliding seat, and the cable feeding shifting sliding seat is provided with a cable feeding shifting driver;

the cable feeding displacement sliding seat is arranged to slide between a first station and a second station, the first station is positioned on the upstream side of the cable cutting device, and the cable feeding device is used for clamping an optical fiber line before cutting at the first station; the second station is located on the cable winding device, and the cable feeding device is used for transferring the optical fiber line to a position which can be clamped by the cable winding device at the second station.

16. Cut out cable and prick cable integrated device around cable, including the frame, its characterized in that: a cable releasing device is arranged on one side of the rack, a cable winding device is arranged on the rack, a tensioning device, a metering device and a cable cutting device are sequentially arranged between the cable releasing device and the cable winding device on the rack, and a cable feeding device for feeding optical fibers from the cable cutting device to the cable winding device is arranged on the rack; the rack is provided with a cable bundling device corresponding to the cable winding device;

the cable binding device comprises a cable binding base arranged on the rack, a cable binding feeding seat arranged towards the cable winding device in a sliding mode is arranged on the cable binding base in a sliding mode, and a cable binding feeding driver is arranged between the cable binding feeding seat and the cable binding base; a binding wire inlet guider arranged on one side of the fiber cable coil is fixedly arranged on the binding cable feeding seat, a binding wire return wire guide arm is rotatably arranged on the binding cable feeding seat, and the binding wire return wire guide arm is connected with a return wire guide driver; a binding wire cutting device is arranged on the binding cable feeding seat and positioned between the binding wire feeding device and the binding wire feeding guider; and a binding device is arranged on the cable binding feeding seat.

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