DE2921092A1 - Winding stranded cables for carrying high electric current - where initial, untwisted strands have sector-shaped cross=section, and cables have high transverse strength - Google Patents

Abstract

The SZ calbes use conductors with a sector-shaped cross-section (SX). The strands are unwound from coils and are fed through a stranding die (5) and then through two lay plates (6,8) which reciprocate in alternating directions of rotation; the calbe next travels through a traction unit (9) functioning as a stranding point (9). Traction units (4) drive each strand to die (5); and the distance (a+b) from the end of each unit (4) to layplate (6) is at max. equal to the lay length and pref. equal to half the lay length or less. The distance (a) between units (4) and die (5) can pref. be adjusted independently w.r.t. the adjustable distance (b) between die (5) and layplate (6). The traction units (4) pref. consist of rows of driven rolls. Exact geometry at the points where the direction of twist of the cables is reversed.

Description

Device for SZ stranding of power cable cores

with sector-shaped conductor cross-section The invention is in the field the production engineering of electrical cables and deals with the SZ stranding of high-voltage cable cores with sector-shaped conductor cross-section with special consideration here occurring mechanical forces.

For better space utilization of the cable cross-section it is with multi-core Power cables in the low and lower medium voltage range (e 10 kV) are common, Use cable cores with a sector-shaped conductor cross-section. These become one another Stranded with a constant twist to form the cable core. Sector cores can be used with and without pre-twist. Sector veins without pre-twist become without reverse rotation stranded together, with strong torsional stresses during the stranding process act on the sector cores. Sector veins with pre-twist become with each other with reverse rotation stranded; here the torsional stresses are relative small amount ('Cable and wire production', VEB cable works Oberspree combine, VEB-Verlag Technik Berlin, 1976, page 200). When stranding sector cores, it is common to use before the stranding nipple to arrange a forced guidance for each core in order to make their stranding to fix the required spatial position. Such a compulsory operation can multiply there are profiled roles arranged in a straight line one behind the other, between which the respective wire runs through (DE-OS 22 11 111).

In addition to the usual stranding of the sector cores with constant Twist direction is also known a type of stranding in which the sector cores with at intervals be stranded with alternating twist direction. Such a type of stranding has been used in the last Years under the name "SZ stranding" in the manufacture of telecommunication cables and power lines have found their way, but the SZ stranding machines developed for this purpose are Cannot be used for stranding sector cores without appropriate further development, because when stranding sector cores, due to the large conductor cross-sections ('35 mm2) large mechanical forces have to be controlled.

In a known device for SZ stranding of sector cores without pre-twist, the actual stranding tool is one in front of a stranding nipple arranged oscillating stranding disc provided with positive guides for the sector cores is coupled. With such a stranding device, of course only one to two twisting turns per twisting direction can be generated (DE-OS 25 14 033). Furthermore, it has already been proposed that those directed in front of the stranding nipple Sector cores with one arranged between the first and a second stranding nipple Stranding device to strand. This runs in sections alternating direction of rotation, so that the sector cores in the first stranding nipple be stranded in the same direction for the first time and a second time in the second stranding nipple.

The stranding device consists of one or two in a row arranged collet pullers.

If necessary, between the stranding points and the stranding device non-rotating collet deductions be arranged in order to achieve a constant Lay length always the same distances between the decisive for stranding to ensure fixed and rotating parts of the stranding device. the The direction of rotation of the stranding device is changed at intervals that are known in the art Way are matched to the storage capacity of the device (DE-OS 27 42 662).

For SZ stranding of round cable cores with a larger conductor cross-section In addition, an SZ stranding machine is known which contains two stranding tools, namely an oscillating perforated disc and an oscillating rotating stranding head in the form of a caterpillar haul-off or a three-roller device. While the perforated disc is arranged in front of a first stranding nipple, the stranding head is located between the first and a second stranding nipple (DE-OS 24 12 199).

There is also a for SZ stranding of cores for communication cables Stranding method known in which the stranding elements are stretched with the help of a Storage alternating rotational movement are stranded. The stretched memory exists consisting of two twisting heads arranged between two twisting nipples. The direction of rotation or the speed of the stranding heads is changed at intervals that correspond to the storage length of the stretched Memory are matched (FR-PS 14 47 458, DE-OS 22 30 972). Stranding heads can also be used for such stranding purposes, which are designed in the manner of a caterpillar haul-off (DE-OS 17 90 249) or from one Deflection pulley, which is looped around by the material to be stranded and arranged tangentially to the stranding axis exist (DE-OS 17 65 452).

The invention is based on the object that has already been proposed Stranding device for SZ stranding of non-pre-twisted power cable cores to improve with sector-shaped conductor cross-section in such a way that the stranded material has an exact stranding geometry in the area of the reversal points of the twist direction and that these reversal points are made as short as possible.

The invention is therefore based on a device for SZ stranding from high-voltage cable cores with sector-shaped conductor cross-section that are fixed in space arranged wire supplies, from a first stranding nipple and in front of it arranged in a spatially fixed manner Forced guidance for each cable core and from a second stranding nipple (stranding point), from two between the stranding nipples and the two stranding nipples respectively assigned rotating devices rotating synchronously with alternating rotary motion (Stranding heads) and a take-off and take-up device and in which the distance between the first stranding nipple and the first point of application of the first Twist device is equal to or approximately equal to the distance between the last point of application of the second twisting device and the second stranding nipple. According to the invention it is provided that the twisting devices and the positive guides immediately behind or in front of the Corresponding stranding nipple or stranding point are arranged and that the distance between the last point of application of each restraint on a cable core and the first point of application of the first twisting device on the item to be stranded is less than or at most equal to that due to the take-off speed and the speed or

Speeds of the stranding device given lay length of the stranded material, preferably less than or at most equal to half the lay length.

With a device designed in this way, the sector cores effectively stranded together over a short distance, with the lengths of the torsion change points in the individual cable cores to the length of the twist alternation points with each other stranded cable cores are matched. In this regard, the invention goes under among other things based on the consideration that the second twist of the stranded association in the The area of the second stranding nipple then runs smoothly when the first twist has led to an exact stranding geometry in the area of the first stranding nipple, It is assumed here that the change in the rotational movement of the stranding heads is accurate on the distance between the two stranding nipples and stranding heads, i.e. on the storage length of the elongated accumulator formed by the stranding nipples and stranding heads is.

The most exact possible stranding geometry of the cable cores is obtained, when the torsion of the non-reversed cable cores and the formation of the torsion change points as well as the swirl change points take place on a route that is kept as short as possible and the forces required for this are not only applied to the outer surface of the to a strand combined cable cores, but also on the individual cable cores even as long as this are still untwisted, attack. The possible The short distance should not be greater than a lay length of the stranded cable cores.

Taking into account the usual lay lengths for sector conductor cables on the order of about 150 cm, this means that the distance between the Forced guidance and the stranding device is as much as possible 60 to 100 cm.

To optimize the spacing, depending on the type of strand to be stranded Sector cores, it is recommended to use the forced guides and / or the stranding heads in their local position relative to the stranding nipples can be changed independently of one another or adjustable.

To develop a clean stranding geometry, how already mentioned, the first rotating stranding head and the forced guides for the Cable cores must be spatially closely adjacent to one another. In this case the power flow runs from the rotating stranding head via the material to be stranded to the forced guidance via spatial relatively narrow lanes. So that no vein damage occurs here, must the individual machine elements are carefully dimensioned. To the forced guidance To be able to arrange it as close as possible to the stranding nipple, an embodiment is therefore recommended in the form of several profiled guide rollers, each along a wavy line are arranged on the inside of the wavy line. Here some of the two-sided The guide rollers arranged in the wavy line face each other in pairs or with a gap, especially in an area in which the wavy line changes its curvature. at Such a configuration of the positive guidance will be the case during the trigger movement of the cable cores acting longitudinal forces are converted into transverse forces.

Particularly large forces can be absorbed by a forced guidance if this consists of two deflection pulleys arranged one behind the other, on which the respective cable core with a wrap angle of at least 90 ° rests. Such deflection sheaves provided with a profile groove leave one special gentle treatment of the sector-shaped cable cores. To be too big here To avoid the distance between the last deflection pulley and the stranding nipple, this distance can be bridged by one or more profiled guide rollers will; these guide rollers are expediently arranged along a curved line, thus the respective cable core by converting longitudinal forces into transverse forces this profile rollers is pressed.

The stranding heads arranged behind or in front of the stranding nipples must also with regard to the transmission of the greatest possible forces and with regard to be designed to be as close as possible to the stranding nipples. Suitable caterpillar belt arrangements or clamping jaws or collet devices are used for this. It is also advantageous with regard to gentle treatment of the material to be stranded the use of a single-disc twister, in which the stranding head is made from one of the The material to be stranded once wrapped around it and arranged approximately symmetrically to the stranding axis Deflection pulley consists. Because the stranded material is deflected from the stranding axis in this case very large torsional forces can be exerted on the material to be stranded using the leverage effect be transmitted. To get as close as possible to the point of application of such a stranding head to the stranding nipple, it is necessary to attach the deflection disc to the Infeed and outfeed of the items to be stranded, each has to be assigned one or more guide rollers.

Exemplary embodiments of the new SZ stranding device are shown in the figures 1 to 4 shown.

The arrangements shown schematically in the figures exist essentially from construction elements as they are familiar to the skilled person, such as reel, perforated disc, deflection roller, forced guidance, stranding nipple, stranding head, Crawler belt or clamping jaw take-off, extruder, water cooling section, take-off and take-up device.

A structural representation of these components is therefore dispensed with.

The device shown in Fig. 1 is used to verb a treatment of three power cable cores 2 to form a stranded assembly 7. The plastic-insulated Cable cores 2 have a sector-shaped conductor cross-section and are not pre-twisted. They run from space-fixedly arranged wire supplies 1 and are over pulleys 3 and forced guides 4 are fed to the stranding nipple 5.

Behind the stranding nipple 5 and in front of the take-off device 9, the one Forming the stranding point is a stranding head that rotates with alternating rotary motion 6 resp.

8 arranged, the cable cores brought together in the stranding nipple encompassed frictionally from the outside and twisted or stranded together. Every stranding head consists of a caterpillar belt arrangement or an arrangement in the manner of a clamping jaw take-off. The caterpillar belts or clamping jaws are kept constant in the direction of the stranding axis Withdrawal speed v driven through stranded material, but can also be driven from the outside and the stranded material in the longitudinal direction of the stranding axis move. The rotational movement, i.e. H.

the speed or the direction of rotation of the stranding heads 6 and 8 changed synchronously at intervals that known way the running time of a longitudinal element of the item to be stranded from the first to the second stranding nipple respectively.

are matched from the first to the second stranding head.

Behind the stranding head 8, the material to be stranded is removed from the haul-off device 9 detected and wound onto the winder 10.

In the area between the stranding heads 6 and 8 there is a changing Direction of rotation of the stranding heads with a rope-up of the reversal points of the twist direction of the material to be stranded under the influence of tensile stress is not to be expected, since the cable cores 2 are plastically deformed in the area of the reversal points and thus for a stable stranding geometry care for. If necessary, however, between the stranding heads 6 and 8 special Be arranged guide elements for the Verseilgut. In addition, the trigger device 9 do not apply if one or both alternately rotating stranding heads have their function take over. A deflection pulley or the like is then used as the second stranding point to be provided.

The effective distance of the stranding head 6 from the stranding nipple 5 is with b denotes the effective distance of the forced guides 4 from the stranding nipple 5 with a. The sum of the distances a and b and thus also the length c between the stranding head 8 and the stranding point formed by the haul-off 9 should be less than a lay length is good to be stranded.

In the device shown in Fig. 1, there are compulsory guides 4 from pairs of opposing role groups, with the individual roles profiled and these profiles are precisely adapted to the cross-sectional shape of the sector cores 2. The profiling and the contact pressure between the roller groups prevent that the sector cores 2 rotate in the area of the forced guides 4. The longitudinal movement the sector veins is not obstructed.

In Fig. 2 positive guides 11 are shown, which are also profiled Deflection rollers 12 exist. However, these pulleys are on a wavy line, in particular an S-shaped curved line, arranged so that by this achieved deflection of the cable cores the longitudinal forces effective as a result of the withdrawal movement can be converted into shear forces. A special pressing of the profile rollers 12 on the cable cores is therefore not required. In the area of the change in curvature of the Wavy lines are opposite pulleys in pairs or with a gap. The advantage such an arrangement can be seen in the fact that a particularly small distance between the last guide role of a positive guide 11 and the stranding nipple 5 achieved can be.

Fig. 3 shows a positive guide 13, which absorb particularly large forces can. For this purpose, there are in each case two relatively large, profiled deflection disks 14 and 15 provided, which are arranged one behind the other and from a cable core via a Angle of about 180 ° each are wrapped around. The distance between the expiry point a cable core on the second deflection disk 15 and the stranding nipple 5 is expedient bridged with the help of one or more profiled guide rollers 16. It recommends here to arrange the guide roller 16 such that the cable core on the Guided away from the deflection disk 15 to the stranding nipple 5 on a curved line will.

Fig. 3 shows at the same time an advantageous embodiment of a rear the stranding nipple 5 arranged rope head 17. This one is constructed like a single-disc twister and consists of that of the stranded material 7 once looped deflecting pulley 18, each for supplying and removing the items to be stranded two guide rollers 19 are assigned. Such a stranding head requires relatively large transverse dimensions depending on the diameter of the material to be stranded, with consideration of the for cable cores with a conductor cross-section of, for example, 150 mm2 However, a lay length of about 1.5 m results at a withdrawal speed of for example 40 to 75 m / min speeds of the stranding head in the order of magnitude from 10 to 60 rpm. The inertial forces that occur during the stranding process However, the stranding head is much smaller than in the case of a conventional one Stranding with revolving spools.

The profile of the deflection pulley 18, which may also be used as a take-off pulley can be designed is slightly conical. Preferably the The center of gravity of the deflection pulley 18 is somewhat outside the stranding axis.

Fig. 4 shows a device in which the stranding of the cable cores 2 to form a stranded assembly 7 with an extrusion process for applying a cable sheath is linked and with which a complete cable 25 is therefore made from cable cores 2 can be. This is followed by the stranding part, which is essentially connected to the in Fig. 1 and Fig. 3 corresponds to the devices shown and the two stranding heads 17 and 20 contains one formed from the extruder 23 and the water cooling trough 24 Extrusion line that runs parallel to the stranding path and that of the stranded structure 7 is fed via the deflection pulleys 21 and 22 0 In a modification of this exemplary embodiment also exists Possibility of stranding the cable cores 2 with Connect the extrusion of the core insulation by pulling from the storage drums 1 conductors run off, which immediately afterwards with the help of an extruder and a water cooling section, as described in patent application P 28 33 702.2 is described.

For SZ stranding of sector cores using a stranding device, whose stranding heads only change the speed, but not the rotary movement, withdrawal speed and speeds can be coordinated so that the lay length of the material to be stranded in the area of the stranding device, for example is alternately + 66 cm and + 200 cm, so that one lay length in the finished stranded material of + 100 cm is available. With the same lay direction within the stranding device it is guaranteed that the stranding heads exert large transverse forces on the material to be stranded can be transmitted without the stranding elements (sector cores) in the area Place the twist change points parallel in one plane.

7 claims 4 figures Blank page

Claims (7)

Claims device for SZ stranding of power cable cores with sector-shaped conductor cross-section, consisting of permanently arranged wire supplies, from a first stranding nipple and in front of it, fixedly arranged forced guidance for each cable core and from a second stranding nipple (stranding point), from two between the stranding nipples arranged and respectively assigned to the two stranding nipples, rotating rotating devices (stranding heads) synchronously with alternating rotary motion and from a take-up and take-up device, in which the distance between the first stranding nipple and the first point of application of the first twisting device is the same or approximately the same as the distance between the last point of attack the second twisting device and the second stranding point, characterized in that that the twisting devices (6,8) and the positive guides (4) immediately behind or are arranged in front of the respective stranding nipple (5.9) and that the distance (a + b) between the last point of application of each forced guidance (4) on a cable core and the first point of application of the first twisting device (6) on the material to be stranded is less than or at most equal to that of the withdrawal speed and the rotational speed or speeds of the stranding device given lay length of the material to be stranded, preferably less than or at most equal to half the lay length. 2. Apparatus according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the distance (a) between each positive guide (4) and the stranding point (5) and the distances (bus) between the stranding points (5,9) and the stranding devices (6,8) can be set independently of one another 3. Device according to Claim 1 or 2, d a d u r c h g e k e n n n z e i c h n e t that any forced operation (11) consists of several profiled guide rollers (12) which run along a wavy line are each arranged on the inside of the wavy line. 4. Apparatus according to claim 3, d a d u r c h g e k e n n z e i c h n e t that some of the guide rollers arranged on both sides of the wavy line (12) face each other in pairs or with a gap. 5. Apparatus according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that each positive guide (13) consists of two deflection disks (14, 15), on which the respective cable core (2) with a wrap angle of at least 90 ° rests. 6. Apparatus according to claim 5, d a d u r c h g e k e n n z e i c h n e t that between the second deflection disc (15) and the stranding nipple (5) one or more profiled guide rollers (16) are arranged. 7. Device according to one of claims 1 to 6, d a d u r c h g e it is not noted that each rotating device (17, 20) consists of one of the Material to be stranded (7) once looped around and arranged approximately symmetrically to the stranding axis There is a deflection disk (18) that is used to supply and remove the items to be stranded (7) one or more guide rollers (19) are assigned.