RU161996U1 - WINDING MECHANISM FOR A DEVICE FOR WINDING A FIBER OPTICAL CABLE ON A CARRIER - Google Patents

Abstract

1. The winding mechanism for a device for winding a fiber optic cable onto a carrier containing a manual towing device, characterized in that it includes a sector gear located on the drive mechanism, pulleys mounted on horizontal axes and interacting with a reel in the form of a drum with a supply of fiber optic cable , gears mounted on horizontal axle shafts coaxially with pulleys with the possibility of permanent engagement with a sector gear mounted on the front of the device for winding ki from the side adjacent to the arrangement of the gears, and inside the sector gear placed the movable part of the drive bearing with a slot. 2. The mechanism according to claim 1, characterized in that with the constant gearing of the gears located inside the housing of the combined unit mounted on the horizontal axles with a sector gear, the movable part of the drive bearing with a slot is made with the possibility of creating a rotational movement for the undercarriage, the coil in in the form of a drum with a supply of fiber optic cable, a counterweight, a mechanism for tensioning and transporting fiber optic cable.

Description

The claimed design solution of the winding mechanism for a device for winding a fiber optic cable onto a carrier of a fiber optic cable, namely, structures for mounting a fiber optic cable on overhead lines. Known methods and devices for suspending fiber optic cables on a carrier, in particular, fiber optic cables can be wound onto a carrier, the role of which is a wire or cable. At the same time, the requirements for the allowable stretching of coiled fiber optic cables are significantly reduced, but at the same time, the requirements for their flexibility, as well as for low linear weight and small transverse dimensions, are increasing. The small transverse dimensions of the cables are, in particular, a factor in reducing the material consumption of cables and, consequently, the price, as well as reducing the dimensions of containers and technological bays.

The installation of fiber optic cable by the method of winding can be performed using a universal winding machine. For this purpose, specialized devices have been developed - winding machines (DE 3702781, IPC G02B 6/44, publ. 11.08.1988 and DE 3228227, IPC B65G 67/48, publ. 02.02.1984). Their principle of operation is as follows: one mechanism (traction) allows the device to move evenly along the cable, the second mechanism (winding) in this case rotates the drum mounted on the machine with a cable construction length around the cable. Fiber optic cable is simultaneously unwound from the drum and wound onto a cable.

A known unit for laying a fiber optic cable (FOC) on an overhead power line wire, comprising a towbar and a cable laying mechanism connected thereto via a coupling device (RU No. 2124256, IPC H02G 1/04, publ. 12/27/1998). The cable-laying mechanism comprises a housing with a frame mounted therein that is rotatable relative to the carrier wire and connected by a kinematic transmission to the drive roller, a brake and a coupling device connecting it to the towing vehicle. The drive roller is equipped with a reverse locking device, for example, a ratchet mechanism, and the kinematic transmission is made in the form of a conical pair, the output axis of which is connected to a cylindrical pair, the large gear of which is detachable with a hinged sector and is rigidly fixed to the swing frame. A hub is mounted on the rotary frame with the possibility of rotation on an axis perpendicular to the carrier wire, equipped with a brake and a device for attaching a coil with a cable. The towing unit includes a housing, an internal combustion engine connected by a kinematic transmission with a drive roller, a coupling device for communicating with the stacking mechanism, equipped with a pressure roller, a stop mechanism, a coil with a safety rope for manual towing and a control system. In the case of using a manual towing vehicle, it is first brought to its initial position, and then installed on the wire and connected to the stacking mechanism. After that, the unit is towed manually to the next power line support.

A known device and method for attaching an optical cable (RU No. 2171486, IPC G02B 6/48, publ. 07.27.2001). Only one connecting element is used to connect the optical cable to the cable. For this, a backup coil is provided, which is arranged to rotate around its longitudinal axis. The backup coil should rotate around an axis that is located symmetrically, that is, approximately in the middle between the cable and the optical cable. For this purpose, a rotary sleeve is installed on the split tubular sleeve, which serves as a holder for the backup coil. Thus, the backup coil due to the rotation of the rotary sleeve can be brought into rotation around the axis, since the flange having a tapered wheel is rigidly connected to the rotary sleeve. Power transmission thus occurs through one or more gears, with bevel gears being preferably used.

A device is known for winding a wok on a supporting wire (RU No. 2309109, IPC B65H 81/08, publ. 10.27.2007). A device for winding a wok on a support wire comprises a frame connected to a rotation drive that is located outside the frame and rotatable around the support wire, and a wok winding coil mounted inside the frame to rotate perpendicular to the axis of rotation of the frame. When the device moves along the carrier wire, the wok is wound off the coil and spirally wound onto the carrier wire with a certain winding pitch. The coil is made in the form of two drums mounted on a common shaft symmetrically with respect to the carrier wire, while the shaft is attached at its ends to the frame from the inside. The wok is wound on both drums, and transitions of wok from one drum to another are provided in such a way that the angle between the point of departure of the wok from one drum and the point of entry of the wok to the other drum, in a projection onto a plane perpendicular to the axis of rotation of the coil, is about 180 degrees. The inner walls of the drums have cutouts of a certain shape with rounded edges, which provide smooth winding of the wok during the transition from one drum to another and provide a bend radius of the wok no less than the critical bend radius of the wok. To maintain the required tension of the wok, wound on the supporting wire, a weight is used.

The challenge facing the proposed technical solution is to expand the arsenal of technical means used as a winding mechanism in a device for winding a fiber optic cable onto a wire.

The problem is solved due to the fact that in the device for winding a fiber-optic cable onto a carrier (carrier rope, dielectric cable, leader cable), the winding mechanism comprising a manual towing device includes a sector gear located on the drive mechanism, pulleys mounted on horizontal axes and interacting with the reel in the form of a drum with a supply of fiber optic cable, gears mounted on horizontal axles coaxially with pulleys with the possibility of permanent engagement with the sector a toothed wheel fixed to the front of the apparatus for coiling the part adjacent to the gear arrangement. Inside the sector gear wheel there is a moving part of the drive bearing with a slot. With constant gearing of gears located inside the housing of the combined unit, mounted on horizontal half shafts, with a sector gear, the movable part of the drive bearing with a slot is made with the possibility of creating a rotational movement for the undercarriage, the reel in the form of a drum with a supply of fiber optic cable, counterweight, mechanism tensioning and transporting fiber optic cable.

The essence of the claimed technical solution is illustrated by drawings.

In FIG. 1 shows a general view of a device for winding a fiber optic cable onto a carrier (side view from the side of the coil).

In FIG. 2 shows a general view of a device for winding an optical fiber cable onto a carrier onto a carrier (side view from the counterweight side).

In FIG. Figure 3 shows a view of a device for winding a fiber optic cable onto a carrier (side angle view from the side of the coil).

In FIG. 4 shows a general view of a device for winding a fiber optic cable onto a carrier (side angle view from the counterweight side).

In FIG. 5 shows a general view of a device for winding a fiber optic cable onto a carrier (bottom view from the side of the coil).

Figure 6 presents a part of a General view of the device for winding a fiber optic cable onto a carrier (side view of the pulley system from the side of the coil).

Figure 7 shows a part of a general view of a device for winding a fiber optic cable onto a carrier (side view of the pulley system from the counterweight side).

On Fig presents a part of a General view of the device for winding fiber optic cable onto the carrier (view from the front of the device).

Figure 9 shows a part of a general view of a device for winding a fiber optic cable onto a carrier (side view, the front part is separated from the pulley system).

Figure 10 shows a part of a general view of a device for winding a fiber optic cable onto a carrier (rear view from the side of the coil).

11 shows a part of a general view of a device for winding a fiber optic cable onto a carrier (view of the pulley parts).

A device 1 for winding a fiber optic cable onto a carrier (carrier cable, dielectric cable, leader cable) comprises a running trolley 2, which has an elongated box-shaped U-shaped section and is made possible to place it on the carrier 3 passing through the cavity of the running trolley 2 . In the front part 4 of the device for winding fiber optic cable, a support roller 5 is installed to accommodate the undercarriage 2 on the carrier 3, in the rear part of the undercarriage 2 there is a sleeve 6 configured to bypassing the carrier 3 through the cavity of the running carriage 2. The running carriage 2 has two support points - the support roller 5 and the rear sleeve 6. The reel 7 in the form of a drum with a supply of fiber optic cable 8 is placed at one end of the axis 9 passing through the cavity of the running carriage 2, and the axis of the coil is perpendicular to the longitudinal axis of the box-shaped shape of the undercarriage 2. The counterweight 10 is mounted on the other end of the axis 9 of the reel 7. The tension mechanism of the fiber optic cable 8 is made in the form of a block 11, which is mounted on the undercarriage 2 between the reel 7 in the form of a drum and a front second part 4 of the device 1 for winding fiber optic cable. The motion drive is made, for example, in the form of a manual towing device 12, equipped with a towing hitch 13, attached to the meshing unit 14, located below the support roller 5 in the front part 4 of the device for winding fiber optic cable 1. The coil 7 in the form of a drum with a margin of fiber optic cable 8 is made with the possibility of using a patch cord or patch cable as a fiber optic cable. The coil 7 in the form of a drum with a supply of fiber optic cable 8 is equipped with a drive mechanism 15, which enables the controlled supply of fiber optic cable 8.

The block of the tension mechanism 11 of the fiber optic cable 8 is equipped with a protective plate 16 and is made in the form of a group of pulleys 17, 18, 19 and 20, placed on the surface of the block 11, and two pulleys 18 and 19 are placed on the horizontal surface of the block 11, and two others 17 and 20 are located on the sides of the housing of the block 11.

The pulleys 17, 18, 19 and 20 are interconnected by a cable 8, with the possibility of rotation with the same linear speed in the contact zone with the fiber optic cable and have guide grooves of the same diameter. Each of the pulleys 17, 18, 19 and 20 is equipped with at least two stops 21 mounted on the housing of the unit 11. Each of the pulleys 17, 18, 19 and 20, to enable the optical fiber cable 8 to be inserted into the guide groove, is provided with a slot 22 .

The diameter of the pulleys 17, 18, 19 and 20 is selected so that it must be larger than the minimum diameter of the pulley, which corresponds to the minimum bending radius of the fiber optic cable specified in the technical documentation for a particular brand of cable.

The winding mechanism comprising a manual towing device 12 includes a sector gear 23 located on the drive mechanism, pulleys 17 and 20 mounted on horizontal axes and interacting with a coil 7 in the form of a drum with a supply of fiber optic cable 8, gears 24 and 25 mounted on horizontal the semiaxes are coaxial with the pulleys 17 and 20 with the possibility of permanent engagement with the sector gear 23 mounted on the front of the device for winding from the side adjacent to the arrangement of gears 24 and 25.

With the constant gearing of the gears 24 and 25 located inside the block 11 mounted on the horizontal half shafts 26 and 27, with a sector gear 23, the drive part of the movable bearing with a slot 28 is made possible to create a rotational movement for the undercarriage 2, coil 7 in the form of a drum with a supply of fiber optic cable 8, a counterweight 10, a tension and transportation mechanism 11 of the fiber optic cable 8.

Preparation for using the winding device begins with the installation of a coil 7 with fiber optic cable 8 on device 1. Fiber optic cable 8 is laid in the guide groove of the pulley 17. To lay the cable, a slot 22 is installed on the pulley opposite the corresponding limiter 21. Then, cable 8 is laid in the guide grooves of the pulleys 18 and 19. Next, lay the cable 8 in the guide groove of the pulley 20 and direct it to the tail of the device 1.

After preparing the carrier 3, the device 1 is lifted to the pillar support. Then open the locks of the device 1 in the front and rear parts of the device 1. Put on the front of the device 1 on the carrier 3 and close the lock. Then install the back of the device 1 on the carrier 3 and close the lock. The towing hitch 13 is attached to the meshing unit 12 of the device 1. The length of the hitch 13 is set sufficient to provide an angle of approximately 45 ° between the axis of the carrier 3 and the hitch line 13. During winding, the operator must visually check for obstacles and the ability to bring device 1 as close to pillar support.

Claims (2)

1. The winding mechanism for a device for winding a fiber optic cable onto a carrier containing a manual towing device, characterized in that it includes a sector gear located on the drive mechanism, pulleys mounted on horizontal axes and interacting with a reel in the form of a drum with a supply of fiber optic cable , gears mounted on horizontal axle shafts coaxially with pulleys with the possibility of permanent engagement with a sector gear mounted on the front of the device for winding ki from the side adjacent to the arrangement of the gears, and inside the sector gear placed the movable part of the drive bearing with a slot. 2. The mechanism according to p. 1, characterized in that with the constant gearing of the gears located inside the housing of the combined unit mounted on the horizontal axles with a sector gear, the movable part of the drive bearing with a slot is made with the possibility of creating a rotational movement for the undercarriage, reels in the form of a drum with a supply of fiber optic cable, a counterweight, a mechanism for tensioning and transporting fiber optic cable.

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