JPS6118499B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for winding a cable in which a plurality of insulated core wires are twisted together and a plastic sheath is provided around the outer periphery.

Various automatic cable alignment and winding devices have been proposed so far.

However, in cables such as communication cables that have a plastic sheath on the outer periphery of a cable core made by twisting multiple insulated core wires, undulations occur in the cable due to internal stress that tries to untwist it. When winding onto a drum, the windings tend to run on adjacent pre-wound cables, or the distance between windings is too large, making automatic alignment winding impossible.

An object of the present invention is to provide a novel winding method that can eliminate the adverse effects of cable waviness during winding.

In the present invention, as a means for guiding the cable to the winding position, the first rotary pulley which can sufficiently hold the cable in its outer peripheral groove, and the diameter of which is approximately equal to or larger than the diameter of the winding drum of the winding drum are provided. A second rotary pulley having a width smaller than the outer diameter of the cable is used, and the cable is moved around the second rotary pulley by rotating the take-up drum in a direction opposite to the rotation direction of the second rotary pulley. The cable is wound approximately half the outer circumference and guided while being bent in the opposite direction to the bending direction when the cable is wound around the winding drum. The cable is wound while adjusting the distance between the rotary pulley and the winding drum according to the thickness of the cable.

An embodiment of the present invention will be described below with reference to the accompanying drawings.

1 is an explanatory plan view, FIG. 2 is an explanatory side view, and FIG. 3 is an explanatory front view of the rotary pulley.

1 is a cable, 2 is a winding drum, and the winding drum 2 consists of a winding drum 3 and a collar 4.

Reference numeral 5 denotes a stand which supports the winding drum 2, and is adapted to move up and down while supporting the winding drum 2 by means of a hydraulic lifting device 11. 6 is a screw shaft, and 7 is a traverser body, and the traverser body 7 is adapted to move left and right by rotation of the screw shaft. A first rotary pulley 9 and a second rotary pulley 10 are attached to the traverser body 7 via an arm 8, and these and the screw shaft 6 constitute a traverser T.

In this configuration, the winding drum 2 is raised to bring the winding drum 3 closer to the second rotary pulley 10, and the cable 1 is hooked around the first and second rotary pulleys 9, 10 in an S-shape, so that the cable 1 is not traveling. By winding the cable 1 while rotating the winding drum 2 in the opposite direction of the second rotary pulley 10, which is rotated by the second rotary pulley 10, it is possible to prevent the adverse effects of cable waviness.

That is, the cable 1 is wound in an S-shape around the first and second rotating pulleys 9 and 10, and the second rotating pulley bends the cable in the opposite direction to the bending direction when winding it around the winding drum. By being relaxed and guided very close to the winding drum 3 by the second rotary pulley 10, the winding can be wound accurately at a predetermined position on the winding drum 3, and it is possible to prevent the winding from running over or leaving too much space between the windings. be.

If the winding drum 2 is rotated in the same direction as the second rotary pulley 10, the length of the cable 1 wound around the first and second rotary pulleys 9, 10 will be shortened, and the undulation will be sufficiently alleviated. Moreover, the distance from when the cable 1 leaves the second rotary pulley 10 until it is wound around the winding drum 3 increases, making it impossible to wind the cable 1 at a predetermined position on the winding drum 3. The diameters of the first and second rotating pulleys 9 and 10 should be approximately equal to or slightly larger than the diameter of the winding drum 3 in order to reduce the undulation effect and prevent adverse effects on the cable 1. preferable. The cable 1 is moved to the winding drum 3 while rotating the screw shaft 6 so that the dry force main body 7 moves laterally by the outer diameter of the cable 1 for each rotation of the winding drum 2.
When the first stage winding is completed, the screw shaft 6 is reversed, the traverser main body 7 is moved in the opposite direction, and the second stage winding is started. At this time, at the same time as the winding of the first stage is completed, or slightly earlier, the hydraulic lifting device 11 is operated to lower the winding drum 2 by the outer diameter of the cable 1. The distance between the rotary pulley 10 and the cable layer wound in the first stage is kept equal to the distance between the second rotary pulley 10 and the winding drum 3 during winding of the first stage, and the cable is kept at a predetermined position. 1 can be wound up. Thereafter, each time the winding of each stage is completed, the winding drum 2 is lowered by the outer diameter of the cable 1, and the cable 1 of the required length is wound up.

Furthermore, in the present invention, the width W ₂ of the second pulley 10 is made smaller than the outer diameter D of the cable 1 so that the cable 1 can be tightly wound up to the edge of the collar 4, but if W ₂ <D. Second rotating pulley 10
There is a risk that the cable 1 may come off from the guide groove 13.

In particular, if cable 1 has undulations, it will easily come off. In order to solve this problem, the first rotary pulley 9 is provided, and the width W ₁ of the first rotary pulley 9 is made larger than the outer diameter D of the cable 1, so that the cable 1 is fully inserted into the guide groove 12. It is starting to be retained. Therefore, the undulation of the cable 1 is alleviated to some extent by the first rotary pulley 9, and the first rotary pulley 10 moves together with the second rotary pulley 10.
The second rotary pulley 9 prevents the second rotary pulley 10 from coming off.

Note that in the present invention, the first and second rotary pulleys may be fixed by moving the winding drum laterally, and instead of moving the winding drum up and down, the first and second rotary pulleys may be fixed.
The second rotary pulley may also be moved up and down, and is not limited to the above embodiment.

As explained above, according to the present invention, the cable undulation is alleviated by the rotating pulley, and the distance between the rotating pulley and the winding drum can be freely adjusted, so the cable can be guided close to the winding drum, and the cable can be guided to a predetermined position. It becomes possible to wind the cable in a certain position, and it becomes possible to automatically wind the cable in an aligned manner, which has conventionally been impossible.

Further, according to the present invention, it is possible to prevent winding disorder at the end of the winding drum, and to prevent the cable from coming off the rotating pulley.

[Brief explanation of the drawing]

The attached drawings are explanatory views of one embodiment of the present invention, in which Fig. 1 is an explanatory plan view, Fig. 2 is an explanatory side view, and Fig.
The figure is a front explanatory view of the rotating pulley. 1: cable, 2: winding drum, 3: winding drum,
4: Tsuba, 5: Stand, 6: Spiral shaft, 7: Traverser body, 8: Arm, 9: First rotating pulley, 1
0: second rotating pulley, 11: hydraulic lifting device,
T: Traversa.

Claims (1)

[Claims] 1. In a method of winding a cable in which a plurality of insulated core wires are twisted together and a plastic sheath is applied to the outer periphery on a winding drum, as a means of guiding the cable to the winding position, a groove that can sufficiently hold the cable in the outer peripheral groove is used. The winding drum is moved by using one rotary pulley and a second rotary pulley having a diameter approximately equal to or larger than the diameter of the winding drum of the winding drum and a width smaller than the outer diameter of the cable. By rotating the second rotary pulley in a direction opposite to the direction of rotation, the cable is wound around approximately half of the outer circumference of the second rotary pulley, and the cable is bent in the opposite direction to the bending when the cable is wound around the winding drum. While giving and guiding, and the first
The second rotary pulley integrally moves back and forth between both flanges of the winding drum, and winds the cable while adjusting the distance between these rotary pulleys and the winding drum according to the thickness of the winding. How to wind the cable.