DE4022476A1 - Electric cable for three=phase AC winding of linear motor - covers one phase by inner conducting layer surrounded by insulation and outer conducting layer - Google Patents

Abstract

The outer conducting layer (11) is made of conducting plastics material with a sheath also of plastics made conductable. An additional metallic screening (12) is fitted between the outer conducting layer and the sheath (15). The screening is completely interrupted at axial distances over the entire length of the cable. The screening consists of metallic strips (13) distributed regularly along a tape of insulating material. The tape, with gaps between turns, is wound spirally around the outer conducting layer so that the outer conducting layer and the sheath in the gap lie directly together. ADVANTAGE - Known cable further developed so that earth fault determination can be ensured quickly, reliably and with low sensitivity measuring units.

Description

The invention relates to an electrical cable for Use as a winding strand in a three-phase AC winding for linear motors, consisting of a metallic conductor designed as a conductor rope, an inner conductive layer surrounding it, one above this insulation, one the same surrounding, made of conductive plastic existing outer conductive layer and one above arranged jacket made of electrically conductive Insulating material (DE-PS 30 06 382).

Linear motors are for electric drives of different types have long been known. Your Areas of application include passenger transport, the conveyor and transport system, assembly lines, Luggage transport, mining, cranes, towing systems, Carriage of machine tools and the actuation of Sliders. A suitable linear motor has for example one in the grooves of an inductor arranged excitation winding that with alternating current is three-phase. The runner part then exists either from a rail made of good electrical conductivity Material such as copper or aluminum (asynchronous motor), or made of permanent magnetic material (synchronous motor). However, linear motors are also known in which the winding is arranged in the rotor part.  

If such a linear motor for example for driving a magnetic levitation train for long-distance express traffic then results for the stator and thus also for the winding a very long length. Because one Linear motor with a higher voltage, for example 10 kV is operated, the cables used must also be used an inner and an outer conductive layer be and have an umbrella. The umbrella of such electrical cable is for safe guidance capacitive charging currents, the earth fault detection, the Possibility of fault location and protection against Touching of live voltage Parts in the event of mechanical damage to the insulation required. Furthermore, it is said to be living beings from danger protect with high voltages.

When using such a cable in the very long Stator of a linear motor is on the screen inevitably induces a high longitudinal stress that for example with a stator length of 100 m far more than 1 kV. So that such high voltages are not the cable after the input mentioned DE-PS 30 06 382 the outer, from electrical jacket made of conductive insulating material. In the winding made up of three such cables the cables in the area of the end windings through one there arranged strand of electrically good conductive material connected to earth potential. The sheath of this cable thus also represents its screen. It has one relatively low electrical conductivity. Through the Combination of such a jacket with that of earth potential the strand to be connected results in an overall screen, which ensures good discharge of capacitive currents and also ensures that induced by Currents generated remain small. With winding produced such cables thus has overall a low power dissipation and the  Field influence becomes negligible. Since also no high tensions can arise Endangerment of living things excluded.

The very long winding one for driving one Linear motor used in magnetic levitation is in Food sections divided, which are then successively to the Feed network can be connected when a train joins one Dining section is approaching. Each dining section is also for security reasons in two independent Split windings. Due to the freedom from earth Feed network and the electrical division into two independent windings for each section of food can Driving operations are also briefly maintained, if one of the winding phases has a single-phase earth fault. But it must be avoided that this Geometrically expanded earth fault and for multi-phase Earth fault. The winding concerned must therefore be switched off. There is a winding on each Earth fault detection device connected to the Shutdown takes place as soon as a predetermined current in the Shield of the affected cable (winding strand) reached is. The conductivity of the screen of the DE-PS 30 06 382 described cable is so low that at its Use very sensitive and therefore sensitive to stray currents used appealing measuring devices Need to become. Nevertheless, it can be rough Magnetic railway operations happen because of the low Current an earth fault is recognized too late.

The invention is based on the problem, the beginning mentioned known cables while maintaining his Advantages so that a ground fault detection fast, safe and with less sensitive measuring devices can be guaranteed.

According to the invention, this object is achieved by that between the outer conductive layer and the jacket  additional metallic screen is attached to the the entire length of the cable at axial intervals is completely interrupted.

The additional metallic shield increases the conductivity of the cable shield, which consists of an outer conductive layer and a conductive jacket, to such an extent that it can carry sufficiently high currents to ensure simple and rapid detection of an earth fault. The resistance of the cable shield remains so high due to the large number of complete interruptions of the metallic shield over the entire cable length that no low-resistance secondary circuits leading to high losses occur. The advantages of the known cable according to DE-PS 30 06 382 are also given with this cable. Losses due to voltages and currents that are induced in the cable shield are negligible compared to other line losses. Since the outer conductive layer and the conductive sheath are not completely separated by the shield, but have further contact in the interruptions thereof, sufficiently small losses and yet sufficient conductivity for capacitive currents in the cable shield can be achieved with a conductivity of the materials for the outer conductive layer and sheath depending on the geometry of the cable in a range from 1 to 10 ⁵ Ohm × cm.

An optimum of electrical protection and negligible losses caused by induction, if the interruptions of the metallic screen one Have a distance that is approximately as large as the distance of the external earthing points from each other, in which the Sheath of the cable is connected to earth.

Further advantageous embodiments of the invention go from the subclaims.  

An embodiment of the subject of the invention is in shown the drawings.

Show it

Fig. 1 shows a section of an AC winding with cables according to the invention.

Fig. 2 shows a detail of Fig. 1 in an enlarged view.

Fig. 3 shows the cable according to the invention with sections removed layers in a further enlarged view.

FIGS. 4 and 5 show details of the cable in a schematic illustration.

With 1 , 2 and 3 , three electrical cables are designated, which are combined into a coherent winding for the stator of a linear motor. The inductor 4 of the stator consisting of layered sheets is indicated schematically in FIG. 1. In the area of the winding overhangs protruding from the inductor, metallic strands 5 and 6 are attached, which run over the entire length of the stator and consist of an electrically highly conductive material, such as copper. Cables 1 , 2 and 3 are in contact with strands 5 and 6 , which are connected to earth potential, via their conductive sheaths.

As can be seen from FIG. 2 in an enlarged representation, the cables 1 , 2 and 3 can be fastened to one another in the region of the winding heads at grounding points 7, for example with clips. These clips can also be used to press the strands 5 and 6 onto the sheaths of the cables 1 , 2 or 3 and thus to make the required good electrical contact. The strands 5 and 6 can, as shown in the drawings, be placed on one side of the winding overhangs and fixed there. However, it is also possible to pass the strands 5 and 6 between the cables at the crossing points of the cables 1 , 2 and 3 , respectively. In principle, it is sufficient if an electrically highly conductive strand 5 or 6 is attached to only one side of the inductor 4 .

The three cables 1 , 2 and 3 are firmly connected, for example, by way of prefabrication to the three-phase winding shown in FIG. 1. Due to their special structure, the cables 1 , 2 and 3 are particularly easy to deform into the meandering course of the winding. They keep their shape in the areas of the winding overhangs located outside the inductor 4 without additional effort. The conductor 8 is designed as a conductor rope, which consists of a large number of individual wires. In the event that the conductor 8 has two or more layers of individual wires, these can alternately have opposite lay directions. The conductor 8 can consist of aluminum wires. However, copper wires or wires made of an aluminum-copper composite could also be used.

An inner conductive layer 9 is extruded onto the conductor 8 . The extrusion process is coordinated so that the material of the conductive layer 9 also penetrates into the outer gusset, which are present between the individual wires of the outer layer of the conductor 8 . The conductive layer 9 is thereby firmly connected to the conductor 8 , since it is anchored to the same. The tight fit is so good that the conductive layer 9 is released from the conductor 8 neither by bending nor by axial stress. A material constructed on the basis of EPDM can preferably be used for the inner conductive layer 9 . It is a material based on a copolymer of ethylene and propylene. Highly active guide blacks are added to the base material, one guide black alone or several in a blend.

In the same operation with the application of the inner conductive layer 9 , the insulation 10 is also applied by extrusion over the same. The insulation 10 consists, for example, of a mixture based on EPR. Also in the same operation, the outer conductive layer 11 is extruded onto the insulation 10 , for which the same material as for the inner conductive layer 9 can be used. By anchoring the inner conductive layer 9 to the conductor 8 , the three layers 9 , 10 and 11 overall have a very good tight fit on the conductor 8 .

An additional metallic screen 12 is applied over the outer conductive layer 11 and is completely interrupted in many places in the axial direction. The outer conductive layer 11 is thus surrounded at intervals by strips 13 made of electrically highly conductive material, while it initially remains free in the gaps 14 between the strips 13 . After the screen 12 has been applied, the gaps 14 are covered by the jacket 15 , which is extruded onto the outer conductive layer 11 and screen 12 . It consists of electrically conductive insulating material and, in addition to the mechanical protection of the cable 1 , 2 or 3, also forms the electrical cable shield in cooperation with the outer conductive layer 11 and the shield 12. Examples of suitable materials for the jacket 15 are polymers based on them of acetate copolymers of ethylene, which have, for example, an acetate content of 30% to 70%. A combination of highly conductive carbon blacks is added to these polymers. The longitudinal conductivity of the outer conductive layer 11 is greater than that of the jacket 15 . The conductance for the outer conductive layer 11 is, for example, 1 to 10 mS × m and for the jacket 15 is 0.01 to 0.5 mS × m.

The shield 12 of the cables 1 , 2 and 3 can be applied to the outer conductive layer 11 in any suitable manner. The material used for the strips 13 can also be designed in any way. In principle, it would be possible, in order to produce the strips 13, to wind metal wires, in particular copper wires, around the outer conductive layer 11 at the required intervals.

The strips 13 of the screen 12 can be designed as rings, as shown in FIG. 3. However, they can also run at an angle to the cable axis. It only has to be ensured that the strips 13 are completely separated from one another at axial intervals, ie that the metallic screen 12 is completely interrupted at intervals. The distance between two interruptions of the screen 12 , that is to say the distance between two gaps 14 from one another, is expediently chosen to correspond to the distance A ( FIG. 1) of two earthing points 7 from one another. In practical terms it lies in the range of 10 cm to 50 cm.

In a preferred embodiment, a band 16 made of insulating material is used for the screen 12 , to which, for example, layers consisting of copper are applied to form the strips 13 . Such a band 16 can be produced continuously, the gaps 14 between the strips 13 also being easily adjustable in the desired width. The tape 16 can be wound onto the outer conductive layer 11 using conventional devices. This automatically results in the complete interruptions of the screen 12 at axial intervals.

So that the contact between the outer conductive layer 11 and the jacket 15 is not interrupted, the tape 16 is wound around the outer conductive layer 11 in such a way that a gap 17 remains between the turns. In a preferred embodiment, the tape 16 is wound onto the outer conductive layer 11 with a slope which is at most equal to five times the outer diameter of the outer conductive layer 11 . This ensures that the good flexibility of the cables 1 , 2 and 3 is not impaired by the screen 12 .

The gap 17 between the turns of the band 16 is dimensioned differently to adjust the required conductivity of the cable shield depending on the cable diameter. In practical embodiments, their width is between 2 mm and 10 mm.

Claims (4)

1.Electric cable for use as a winding phase in a three-phase AC winding for linear motors, consisting of a metallic conductor designed as a conductor cable, an inner conductive layer surrounding the same, an insulation arranged above it, an outer conductive layer surrounding it made of plastic and an over it arranged sheath made of electrically conductive insulating material, characterized in that between the outer conductive layer ( 11 ) and sheath ( 15 ) an additional metallic shield ( 12 ) is attached, which is along the entire length of the cable ( 1 , 2 , 3 ) at axial intervals is completely interrupted. 2. Cable according to claim 1, characterized in

• - That the screen ( 12 ) consists of metallic strips ( 13 ) which are spaced apart on a band ( 16 ) made of insulating material and
• - That the band ( 16 ) with a gap ( 17 ) between the turns is helically wound around the outer conductive layer ( 11 ), so that the outer conductive layer ( 11 ) and the jacket ( 15 ) in the gap ( 17 ) lie directly against each other .

3. Cable according to claim 1 or 2, characterized in that the band ( 16 ) is wound with a slope on the outer conductive layer ( 11 ) which is at most equal to five times the outer diameter of the outer conductive layer ( 11 ). 4. Cable according to one of claims 1 to 3, characterized in that the width of the gap ( 17 ) between the turns of the band ( 16 ) is between 2 mm and 10 mm depending on the cable diameter.