DE1665537B1 - DEVICE FOR STRINGING CORES FOR MESSAGE CABLES - Google Patents

Description

The invention is concerned with stranding cores for communication cables to stranding units and with the simultaneous stranding of several of these stranding units to a stranding group.

In the manufacture of communication cables consisting of pairs, threesomes or fours are constructed and in which the cable core is made of stranded together There is primary and / or secondary bundles, it is known per se, for reasons of rationalization two consecutive work steps, for example the stranding of primary bundles and secondary bundles or the stranding of secondary bundles and cable core into one to unite a single operation. Stranding devices are used for this, with which the first stranding process is not continuous, but with alternating: Right and left twist is made. This stranding, which is sometimes used as pendulum stranding, more recently, however, has been referred to as SZ stranding, is carried out with the help of alternating stranding disks swinging back and forth through which the stranded Stranding elements passed through in groups and alternately after the one or in another direction (U.S. Patent 2,981,049; »The Engineert #, Western Electric, October 1961, 'Vol. V, No. 4). The alternating to and fro However, stranding disks of the known device must not be much more than + 180 °, otherwise the stranding element groups will be in front of the stranding disks twist too much and the Tear off or damage pre-twisted stranding elements. The maximum twist the stranding elements that result from this are therefore very small and should each Do not exceed a lay length in one and the other direction. It It has been shown that such small twists for stranding wires too For example, pairs, threesomes or foursomes are not enough to make a sufficient to achieve electrical decoupling of the stranding units formed from the cores.

Recently, an SZ stranding process has been developed that it allows for the combination of several previously carried out separately Stranding processes to a single operation also the stranding of wires Stranding units, such as pairs, threes or star fours, should also be recorded. With this SZ stranding process, the elements to be stranded are made in sections alternately by a multiple of twisting turns in one direction and then distributed in the other direction. To carry out this SZ stranding process a rotating buffer is required, for example from two with their Axes arranged transversely to the direction of travel can consist of roles and on the during the stranding, a twisting direction and twist length that is the same Section applied and then with a changed speed and / or direction of rotation of the intermediate storage device is withdrawn from it again (USA.-Patent 3,169 360).

Compared to the well-known SZ stranding process with alternating back and swinging stranding disc enables the SZ stranding method to be used a buffer store stranding the elements to be stranded by any amount many strokes alternating in one direction and the other. With the SZ stranding process using a rotating buffer, however, this buffer must with the speed around the stranding axis necessary to twist the stranding elements rotate. The production speed of such an SZ stranding device is therefore limited, especially since the buffer memory is very fast at periodic intervals must be braked and accelerated again.

The invention is based on the object of the known two-stage To make the stranding process more efficient, in particular a device for implementation to train such a stranding process so that the prerequisites for higher Manufacturing speeds are given.

The invention is based on a device for stranding Cores for communication cables to stranding units with twisting direction alternating in sections and for the simultaneous stranding of several of these produced in parallel operations Stranding units to form a stranding group with a group stranding device, in which the stranding of the cores to the stranding units with one circumferential, changing their rotational movement in sections, containing a buffer Stranding device takes place. According to the invention, those for stranding are the Cores used to form stranding units with twisting direction alternating in sections Temporary storage in the room fixedly arranged; for the invention is still It is essential that the wires to be stranded each have this buffer a twisting bracket can be supplied and removed again. By using space-fixed arranged intermediate storage and rotating brackets over which the to stranding cores fed to the fixed-space buffer stores and from these are carried away again, are those rotating when the wires are stranded Masses, especially those when reversing the rotational movement of the stranding device Masses to be braked and accelerated again, very small, so that high withdrawal speeds can be achieved.

Particularly high take-off speeds can be achieved if In a continuation of the inventive concept, the cores to be stranded the intermediate storage each over one of the veins both when feeding in and when discharging in a double stroke stranding brackets are supplied and removed again. The stranding of the veins takes place here in a four-fold twist, so that compared to a double twist stranding process only half the speed is necessary or the withdrawal speed at the same speed can be increased.

Another embodiment of the invention provides that the rotary movements the stranding bracket of the individual stranding devices at different times are changeable. This results in the most extensive decoupling of the later for Stranding group stranded stranding units at the reversal points of the twisting direction achieved. For this purpose, one can also proceed in such a way that the stranding units Path lengths covered between the stranding devices and the stranding units stranding group stranding device are of different lengths.

In the manufacture of stranding groups for communication cables by the distribution of cores to stranding units and through them in the same operation subsequent distribution of these stranding units the stranding group it is known per se, the cores immediately before the entry into the stranding device to isolate in a joint operation (USA: Patent 3,169,360). in the The scope of the invention is now provided, this insulation of the wires in as well known way to make that the head of the veins in a thixotropic Dispersion to be immersed, its viscosity at the exit point of the ladder is reduced from the dispersion by the action of mechanical means (German Interpretation document 1204 723).

The invention is illustrated with the aid of the FIGS. 1 to 3 shown Embodiments explained in more detail.

F i g. 1 shows a stranding device for saponifying the cores 2, which are withdrawn from the storage drums 1, which are fixed with their axes in space, to the quads 3 and for the subsequent stranding of these quads to form the bundle 4. To strand the wires 2 to form the four-wire 3, the circumferential double brackets are used 5 trained stranding devices on which the deflection rollers 6 are arranged. On the axis of this double bracket are those as temporary storage for the foursome 3 serving free-running rollers 7 are provided, each one during the stranding process Section of a quad 3 with the same twist direction and the same twist length take up. With the help of the deflection device 8, which has the deflection rollers 9, are the two quads 3 produced parallel to one another have a common stranding point fed. For this purpose, the stranding device 10 is provided, which essentially from the stranding bracket 113 mounted on the bearing blocks 11 and 12 and the winding drum 114 consists. The Verseilbiege113 is here in rotation by motors (not shown) offset.

To produce the bundle 4 from the individual cores 2, the procedure is such that first the individual cores 2 are pulled overhead from the storage drums 1 fixed with their axes in space and fed to the nipple 15 for smoothing. Subsequently, the individual cores 2 run into the crossing device 16, in which two adjacent cores are crossed when a certain value of the k, coupling is exceeded, so that they exchange their position in the stranding element for a certain length. At the stranding point of the rotating double bracket 5, driven by the motor 17 via the gear 18, the individual cores 2 are saponified to form a quad 3 and a length section of the stranding element produced in this way with the same twist direction and twist length is wound onto the roller 7 serving as an intermediate storage device and then with a changed direction of rotation from this Intermediate storage withdrawn again.- In this way it is achieved that the quad 3 saponified with a right-hand twist when it enters the double bracket s is twisted again in the same sense when withdrawn from the intermediate storage, so that an advantageous double-lay SZ stranding results .

To pull it off, the saponified foursome passes over the pulleys 6 in the deflection device 8 and, together with the parallel to the first quad produced second quad by means of the pulleys 9 to the stranding point of the stranding device 10 supplied. By means of the circumferential twisting bracket, which is also designed as a double bracket 13, the two fours are saponified to form a bundle 4 and onto the winding drum 14 wound up. Essential for stranding the individual cores 2 to form a quad 3 by means of of the circumferential double bracket is that the rotary movement of this double bracket is periodic is changed and the time of constant rotary movement the passage of a section of the saponified foursome through the buffer. Because the double bracket has only a relatively low mass, so to generate the twist change points only these small masses need to be accelerated and decelerated, and there in addition, the stranding in the case of the one shown in FIG. 1 illustrated embodiment occurs in a double stroke, the withdrawal speed can be increased considerably will.

In contrast to the exemplary embodiment according to FIG. 1 is on hand the F i g. 2 schematically shows a method for stranding individual cores into bundles explained, in which the cores immediately before stranding with the help of the per se known dispersion method can be isolated. Here are the electrical Head isolated in one operation with the help of a thixotropic dispersion, their viscosity at the point of exit from the dispersion due to the action of mechanical forces Means is reduced. The advantage of this known isolation method is there in that a large number of electrical conductors by means of a single soaking bath can be isolated at the same time, so that this method in particular for production of communication cables is suitable in which the conductors in a joint operation isolated and then saponified to form stranding elements or stranding groups. About the pulleys 20, the individual wires 2 of the crossing device 16 and then the stranding point from the double bracket 5 as well as the intermediate storage Serving roller 7 supplied to existing stranding device. Also in this embodiment the single cores 2 are stranded to form a quad 3 in the SZ stranding process, whereby the The direction of rotation of the double bracket 5 is changed periodically. The parallel to each other manufactured quads 3, two of which are shown in the exemplary embodiment, are attached to the stranding nipple by means of the deflection device 8 via the deflection rollers 9 21 fed to the stranding device 22.

In order to adapt the stranding speed of the stranding device 22 to the dispersion insulation process, the stranding device is expediently designed so that it rotates relatively slowly. This stranding device, known per se, consists of the revolving haul-off disk 23, which is arranged in the revolving stranding basket 24 and is driven via a planet gear 25 and the alternating drive 26. The revolving stranding basket 24 is mounted on the hollow shaft 27.

The bundle 4 saponified in the nipple 121 passes over the pulley 28 on the take-up drum 29, which is arranged in the stationary take-up magazine 30 is. This winding magazine 30 consists of the support column 31 on which the winding drums 29 and the supply reel 32 are arranged to be pivotable by 180 °. The speed of the The winding drum29 can be greater or less than the speed of the stranding basket be.

In FIG. Finally, FIG. 3 is an exemplary embodiment for production a message cable made up of saponified stranding groups is shown at which are saponified in four stranding devices arranged parallel to one another The cores are then saponified and bundled in a single stranding device on Winding drums are wound up. Notwithstanding the Embodiments according to FIGS. 1 and 2 become the stranded cores or stranding elements that accommodate a section of the same twist length and twist direction Intermediate storage, which is arranged within the revolving stranding device, fed in a double stroke and from this buffer also in a double stroke deducted. The circumferential frame-shaped Verseilbügel34 serves for this purpose Axis is the free-running, spatially-mounted roller that serves as an intermediate storage device 36 is arranged. To guide the four-wire 3 consisting of the individual wires 2 the deflection rollers 37, which are arranged on the stranding bracket 35. The roller 36 of the Intermediate storage, the axis of which is arranged perpendicular to the stranding axis, is used by the U-shaped curved frame 38 held with the guide rollers 39 for the stranded foursome 3 is equipped.

The four individual cores 2 are removed from the twisting bracket when they run into the existing stranding device and then stranded by means of the pulleys 37 routed around the buffer and against the withdrawal direction on the Roll 36 wound up. The foursome is 3 again in the same direction twisted so that a double-lay stranding results in a known manner.

The same direction of twist is applied to the roller 36 of the intermediate store and the twist length having section of such a quad is applied and then deducted from this if the direction of rotation is changed. The stranded one is used to pull it off Four 3 over the pulleys 37 in the Verseilbügel 35 and is there opposite have changed the direction of rotation or the speed of rotation during the first stranding, in a double lay stranded so that the stranding element running out of this stranding device finally is twisted in quadruple lay. Such a method has the advantage that compared to the double-twist stranding process illustrated in exemplary embodiments 1 and 2 only half the speed is necessary and thus the withdrawal speed is increased can be. This is especially true if a section is being pulled off same twist length and twist direction to the intermediate storage in double twist at the same time the subsequent section of the stranded cores or stranding elements to the intermediate storage is fed in a double lay, the speed or direction of rotation of the stranding device expediently changes periodically.

If, for example, the twisting bracket 35 is rotated to the left at the speed n and the quad 3 is withdrawn from the twisting device at constant speed, the individual cores receive a right-hand twist, in each case correspondingly where v is the take-off speed and n is the speed of rotation of the bracket. When running onto the buffer, the quad 3 is provided again in a manner known per se, so that a stroke of results. If the direction of rotation of the stranding device is reversed as soon as the intermediate store is wound with a section of cores twisted to the right, the quad 3 within the twisting bracket 35 is initially acted upon with a left-hand twist and then with a right-hand twist. The twist direction of the stranded quad 3 when it leaves the stranding device is thus also to the right, so that the lay length is accordingly.

Instead of To allow the twisting brackets 135 to rotate with different directions of rotation, it is also possible to select a speed of the stranding device that differs from the speed of the stranding device while simultaneously feeding in a section of the quads 3 for the intermediate storage and removing a section from the intermediate storage when the stranding element passes through the twisting brackets 135 Stranding device differs when passing through the quad 3 through the upper part of the Verseilbügel 35. So you can choose either the speed of the stranding device when pulling the section from the intermediate store to be smaller or larger than that at which the section of the stranding element is wound onto the intermediate store. Provided that the withdrawal speed is constant, the lay length is then inversely proportional to the difference between the two speeds. A large speed difference then also results in a very different lay length of the successive sections.

To produce the bundle 40 from the four quads 3, these are fed to the stranding point of the rotating group stranding device 43 via the deflection device 41, which is equipped with the deflection rollers 42. This consists essentially of the two storage rollers 44 and 45 over which the stranded element is wound, stranded by periodically changing the direction of rotation of the stranding device in a double twist and then wound over the pulleys 46 onto the winding drum 47 fixed with its axis in space.

With the aid of FIG. 3 explained method of manufacture of a communication cable by stranding the individual cores initially to form four and then bundling can increase the production speed considerably will. This arises on the one hand through the use of the stranding device 35, at the only relatively small masses braked according to the direction of rotation and need to be accelerated, as well as by the fact that this stranding device A stranding in four-fold is permitted, which is different from the conventional Process quadruples or doubles the take-off speed. Because the Stranding of cores up to bundles is done in one operation, it is possible to the twist required for decoupling the individual wires during production to determine without the need to keep stranding elements with different Twist is required.

In order to avoid that in the case of the FIG. 1 to 3 explained Stranding process the twist reversal points of the four are at a single point are located in the stranding element, either the lengths of the path between the individual Stranding devices and which strand the individual stranding elements into a group Group stranding device made different sizes, or the rotary movements the individual stranding devices are chosen so that they lead to different Times change direction.

For feeding a section of the same twist length and twist direction for the intermediate storage as well as for removing such a section from the intermediate storage serve, as shown in the exemplary embodiments, to circulate the buffer memory frame-shaped Stranding bracket. It is useful as a buffer a free-running roller is used, which is fixed in space on the axis of the Verseilbügel is stored. The roller is advantageous to facilitate unwinding and winding conical. Instead of making the intermediate storage unit from a single roller, it is also possible to arrange several rollers next to each other, of which for example one of which can be provided with grooves and thus serves as a laying roller. The reels can also be arranged with their axes obliquely in space.

To produce a main bundle from, for example, five basic bundles can be carried out in the implementation of the inventive concept, for example, with the in F i g. 3 proceed so that initially parallel to each other with Help four by four stranding devices working in parallel in a four-fold twist and four stranding devices for stranding in bundles, the four basic bundles are produced will. The basic bundles thus produced are then placed in a main bundle stranding device together with that in the same operation in a stranding device, for example according to the embodiment of FIG. 3, established fifth basic bundle stranded to form the main bundle and wound onto a winding drum. Because of this Procedure, the stranding effort and the production time are significantly reduced.

Claims (6)

Claims: 1. Device for stranding wires for communication cables to stranding units with twisting direction alternating in sections, each with a rotating buffer that changes its rotational movement in sections containing stranding device and for the simultaneous stranding of several of these Stranding units produced in parallel operations to form a stranding group with a group stranding device, characterized in that the for stranding of the cores (2) to stranding units (3) with alternating twisting direction in sections buffer (7) used are fixed in space and that the cores to be stranded (2) these intermediate stores each via a stranding bracket (5) to be supplied and discharged again. 2. Device according to claim 1, characterized in that that the wires to be stranded (2) each have a buffer (36) strand the cores (2) in a double lay both when feeding in and when discharging Verseilbügel (35) are supplied and removed again. 3. Apparatus according to claim 1 or?, Characterized in that the rotary movements of the twisting brackets (5, 35) of the individual stranding devices can be changed at different times are. 4. Apparatus according to claim 1 or 2, characterized in that the of the stranding units (3) covered path lengths between the one intermediate storage containing stranding devices (5, 6, 7, 18; 35, 36, 18) and the stranding units (3) stranding group stranding device (10, 43) are of different lengths. 5. Device according to one of Claims 1 to 4, characterized in that the group stranding device (43) also contains a buffer (44, 45). 6. Device after one of claims 1 to 5, characterized in that as a temporary storage a free running roller (7, 36) is used, which is on the axis of the respective Verseilbügel (5. 35) is fixed in space.