DE2648140C3 - Process for SZ stranding of individual stranding elements or stranding elements combined in bundles or twisted together - Google Patents

Description

x = / a ^rz ' ^a
he follows,
where χ = length of the accelerated distance,

/ = Total length of the displacement distance,

a -.

5. Device for carrying out the method according to one of claims 1 to 4, characterized in that the torsion lock (4) is shifted by means of separate link drives, one of which rotates at the shifting speed and a length corresponding to the first stranding path (I) and the other revolves at a higher speed than the displacement speed (V ^, preferably with the withdrawal speed (V ₀ ) , and has an engagement length corresponding to the route section (X) «! ₁ enables.

6. Apparatus according to claim 5, characterized in that that the torsion lock is an elongated hole

(10) having a backdrop (11) in which a the chain (7) of the upper link drive (6) fastened bolts (9) engages.

7. Apparatus according to claim 5 or 6, characterized in that the chain (14) of the lower Link drive (13) a driving pin (16) is attached to a stop body (17) the torsion lock (4) cooperates, and the two link drives (6, 13) in such a way to one another are synchronized that at the beginning of the first stranding section of the driving pin (16) on the strike body (17) the torsion lock (4) comes to rest

8. Device according to one of claims 5 to 7, characterized in that between the lower Link drive wheel (15) and the upper link drive wheel (8) or in the connected pair of wheels (20) a freewheel is switched on

The present invention relates to a method for stranding SZ individually or in bundles Twisted or untwisted summarized Verseüelemente for communication cables, with the constant With the help of a Rotating in the same direction of rotation, arranged between a pull-in nipple and a withdrawal nipple Stranding head are stranded and then wound up on stationary drums, the stationary stranding head rotates continuously and between the stranding head and one in and against the Withdrawal direction of the Verseüelemente mobile torsion lock lying, first effective stranding section of the Verseüelemente with a relative to their withdrawal speed in terms of amount smaller displacement speed periodically between two limit values in and against the withdrawal direction ti. "Verseüelemente is steadily reduced or enlarged and that between the stranding head and the pull-out nipple The second stranding section lying on the ground remains constant according to patent P 21 38 239.

In the case of the method according to the main patent, it has been found that in the stranded Verseüelemente of the cable bundle or the cable at the transitions from one twist direction to the other Form twist-free lengths, due to the reversal of the direction of displacement of the torsion lock at the two turning points of the first stranding section. Such twist-free lengths in the stranded bundle b ^ w. But cables are undesirable.

The invention is based on the object of providing these twist-free lengths, i. H. the twist reversal sections in Bundles or cables, to be shortened significantly, so that the parallel distance of the Verseüelemente is reduced.

According to the invention this is achieved in that the displacement speed after at least one The reversal point of the first stranding section is increased over a defined section.

By this measure, the difference between the withdrawal speed and the displacement speed is for a certain time very small, so that the twist

D =

ν - v _s

becomes very large for the period in which the speed of movement is increased. Thus, at the moment of the reversal, there is a faster one Transition from one twist direction to the other, whereby the parallel path of the stranding elements in the completely stranded bundle or cable is reduced.

It is useful if the displacement speed is increased to the size of the withdrawal speed, so that the relative speed between rope speed or withdrawal speed and displacement speed zero will. It can also be useful if the increase in the displacement speed on The reversal point of the first stranding section remote from the stranding head takes place, so that the time that is necessary to the relatively small twist when opening the stranding section into the relatively large twist when closing the To convert stranding distance is shortened. Increasing the speed of movement can be advantageous over a stretch of length

= I- a

l-fl

Here, χ means the length of the accelerated section starting at the reversal point of the first torsion section away from the stranding head and / the total length of the displacement section. The above relationship applies to the displacement speed equal to the withdrawal speed and a displacement speed of the torsion lock that is equal in terms of amount for the

Forward and reverse, a is the ratio - ^. On the basis of the above relationship, it is possible to determine the optimum length of the route section in which the displacement speed has to be increased for the respective withdrawal speed V ₀ , displacement _{speed v s and length of the displacement path / the optimal length of the route section.}

The following is based on the embodiment of a device shown in the drawing for carrying out the method according to the invention explained in more detail

The stranding device consists of a E: nzugsnippel I ₁ a rotating lay plate 2 and a pull-out nipple 3, as well as a displaceable between draw-in nipple and twisting torsion lock 4, which is formed from a perforated ring and a nipple, the torsion lock 4 is supplied with a certain constant Verschiebegeschwüidigkeit _{Ά ν} whose An amount less than the withdrawal speed of the stranding elements to be stranded in the device SZ is periodically moved back and forth between the pull-in nipple and the stranding head. The stranding head 2, driven by a toothed ring 5, rotates at a constant speed and direction of rotation.

A link drive is used to move the torsion lock 4 at a certain displacement speed 6. This consists of a drive chain 7, which has two sprockets 8 at the beginning and end of the The first stranding section formed from the pull-in nipple and the versejlkopf runs on the side of the chain 7. Bolt 9 attached This bolt is guided within an elongated hole 10 of a gate 11, which is with the foot the torsion lock 4 is connected. The torsion lock 4 itself is guided with the aid of guide rods 12 To increase the speed of movement

To enable the torsion lock over a certain section χ of the first stranding section /, a further link drive 13 is arranged below the link drive 6, the length of which corresponds to section χ This second link drive 13 also consists of a chain 14 that runs over sprockets 15 of which one sprocket is motor-driven. One of the chain wheels 8 is drivingly connected to a chain wheel 15 of the link drive 13 via a gear wheel pair 18. A driving pin 16 is fastened to the chain 14 and cooperates with a stop element 17 of the link which can be pushed upwards by pins 9 . <jlissen drives 6 and i3 are synchronized with each other α h. If the torsion lock 4 is at the front reversal point that is the reversal point remote from the stranding head, the driver pin 16 of the lower link drive 13 is unnv.telbar under the torsion lock, so that the driver pin 16 comes to rest against the stop body 17 and takes the torsion lock with it a higher speed than the displacement speed v » Expediently, this increased speed of the lower link drive corresponds to the withdrawal speed of the stranding elements. The length of engagement of the lower link drive corresponds to the section x in which the torsion lock is moved at increased speed. This entrainment of the torsion lock through the lower link drive is possible in that a freewheel between the torsion lock and the upper link drive, for. B. is turned on in the upper gear 18 At the end of the length of engagement * of the lower link drive, the upper link drive takes over the We; forward movement of the torsion lock 4 with the displacement speed v »
The SZ stranding system is designed for pull-out speeds of up to 120 m / mia. The stranding head can be operated with speeds of up to 5000 rpm without any problems. For example, with a basic bundle lay length of 7000 mm and an expected SZ lay length in the basic bundle of 100mm

so the following operating conditions:

Withdrawal speed v = 120 m / min, displacement speed of the torsion lock Vs = 40 m / min,
D. number of stranding head n = 3430 rpm.

The sliding piece of the torsion lock has a Length of 1.8 m, which results in S and Z twist sections 5.4 m long.

1 sheet of drawings

Claims (4)

Patent claims: 1. A method for SZ stranding individual stranding elements or stranding elements for communication cables that are combined in a twisted or untwisted manner, with the stranding elements withdrawn from stationary storage drums at a constant withdrawal speed being stranded with the aid of a stranding head that rotates in the same direction of rotation and is arranged between a draw-in and an extractable nipple stationary drums are wound up, wherein the stationary lay plate rotates continuously and lying between the Verseükopf and a mobile in and against the drawing direction of the Verseüelemente torsion lock, first effective Verseüstrecke the Verseüelemente with respect to the take-off speed (v _o) with a value of smaller displacement velocity (v _s ) periodically between two limit values in and against the withdrawal direction of the Verseüelemente is steadily reduced or enlarged, the two lying between the stranding head and the pull-out nipple te stranding section remains constant, according to DE-PS 2138 239, characterized in that the displacement speed (v ₅ ) is increased after at least one reversal point of the first stranding section over a defined section (x) . 2. The method according to claim 1, characterized in that the increase in the displacement speed * (v _s ) takes place on the size of the withdrawal speed / front Verseüelemente. 3. The method according to claims 1 or 2, characterized in that the increase in the displacement speed (v _s ) takes place at the reversal point remote from the reversing point of the first reversing path. 4. The method according to any one of claims 1 to 3, characterized in that the increase in Shifting speed over a section of the length