Methods of manufacturing electric cable for transporting very high current at low voltage

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BRIEF DESCRIPTION OF THE DRAWINGS

Two electric cables in accordance with the invention are described by way of example with reference to the accompanying drawings, together with first and second manufacturing devices for performing the first and second manufacturing methods respectively.

FIG. 1 shows a first electric cable in accordance with the invention including a single multi-strand conductor.

FIG. 2 shows a second electric cable in accordance with the invention comprising three multi-strand conductors.

FIG. 3 shows a first device for performing a first method of cable manufacture.

FIGS. 4 and 5, and 6 and 7 show details of the FIG. 3 device.

FIG. 8 shows a second device for performing a second method of cable manufacture.

MORE DETAILED DESCRIPTION

FIG. 1 shows a cable 1 comprising a single multi-strand conductor 2, a perforated envelope 3 and an outer sheath 4. The envelope 3 comprises two distinct layers which are nevertheless fixed to each other, comprising an inner layer 5 in contact with the conductor 2 and an outer layer 7 which may be in contact with the outer sheath 4.

The inner layer 5 is constituted by a plurality of helical strips 6 and the outer layer 7 is constituted by a plurality of longitudinal strips 8. The strips 6 are non-continguous, as are the strips 8, thereby constituting a perforated envelope 3 enabling water to circulate along the cable 1. The water is then in contact with the conductor 2.

In FIG. 2, a cable 10 includes three multi-strand conductors 12, each conductor being covered by a perforated envelope 13 identical to the envelope 3 shown in FIG. 1. These three conductors provided with respective envelopes are placed inside an outer sheath 14 which is watertight and which has water flowing therealong. The sheath could naturally have two multi-strand conductors, or four or more.

The envelope 3 or 13 provides very low voltage electrical isolation and mechanical protection of the elementary strands.

The insulating envelope may naturally include an outer layer 7 constituted by helical strips turning in the opposite direction to the helical strips of the inner layer 5, or else the inner layer 5 may be constituted by longitudinal strips while the outer layer 7 is constituted by helical strips.

Naturally, the number of strips in each layer is arbitrary.

In FIG. 3, there is an extrusion machine 20 comprising a central body 21 having a filling funnel 22 for thermoplastic or elastomer material. A heating resistance 23 surrounds the funnel 22 and serves to maintain the material at its melting point. The central body 21 also includes a head 24 screwed to one end thereof and provided with another heating resistance 25. As it is screwed in, the head bears against a wedge 26. The head includes a fixed die 27 which is described in greater detail below with reference to FIGS. 4 and 5.

A cylindrical part 28 is pressed against a shoulder 29 in the central body 21, and the part 28 is fixed by three screws 30 which are circumferentially distributed at 120.degree. (only one screw is shown).

A plug 31 is inserted through the part 28. The length of the plug is adjustable by means of a plurality of circumferentially distributed screws 32 and it is locked by means of three screws 33 which are similarly distributed at 120.degree. (only one screw being shown).

The plug 31 supports two bearings 34 and 35 and a fixed stop 36. A hollow shaft 37 having a punch 38 screwed therein rotates on the two bearings 34, 35 and presses at the punch end against the fixed stop 36 and at the other end against a ball stop 39 via resilient conical washers 40 and a nut 41. The shaft is rotated by a motor 42 via a toothed pulley 43 which couples a drive wheel 44 of the motor 42 and a drive wheel 45 connected to the shaft 37 by a tapped socket 46. This device thus comprises a material inlet circuit constituted by the funnel 22, a circular groove and channels 50 which are circumferentially distributed between the body 21 and the part 22 and run from the circular groove to the die-punch assembly.

FIGS. 4 and 5 show the fixed die 27 in greater detail. The die includes grooves 27', each of which corresponds to a longitudinal strip 8 in the outer layer 7 of each envelope 3 or 13.

FIGS. 6 and 7 show the rotating punch 38 in greater detail. This punch includes grooves 38', each of which corresponds to a helical strip 6 in the inner layer 5 of each envelope 3 or 13.

An extrusion operation takes place as follows: a multi-strand conductor 2 or 12 is inserted into the hollow shaft 37 and passes through the punch 38. The punch and the shaft are caused to rotate by the motor 42. The thermoplastic or elastomer material is inserted into the funnel 22 and it follows the channels 50 to enter the die and the punch and cover the conductor 2 or 12 thus constituting a perforated envelope 3 or 13.

The punch 38 makes the helical strips 6 of the inner layer 5 by rotating, and the die 27 makes the longitudinal strips 8 of the outer layer 7 by being fixed. The two strip layers 5 and 7 are naturally fixed to each other at strip crossover areas since the material is still molten as it passes through the die and the punch.

This extruding machine could include a rotating die driven by known means to constitute an outer layer made of helical strips.

FIG. 8 illustrates an alternative process of manufacture which shows a device 60 for making the first tape layer 5, a device 70 for impregnating or hot gluing, and a device 80 for manufacturing the second tape layer 7.

The device 60 is constituted by a rotating plate 61 having a spooler 62 at its periphery and inclined to enable helical winding. The spooler 62 supports a reel 63 on which a tape 6 is wound. Rotation of the plate 61 and longitudinal displacement of the conductor 2 cause the tape 6 to wind around the conductor 2 in a helical manner with non-contiguous turns to allow water to circulate. The tape 6 constitutes the first layer 5. Naturally, it is very easy to provide a plurality of spoolers on the plate so as to make up the first layer 5 from a plurality of tapes 6.

The conductor 2 fitted with its layer 5 passes through the device 70 which may be a device, for example, using a hot melt or glue, or a device such as an oven for providing superficial melting.

The device 80 for fabricating the second tape layer 7 comprises eight spoolers 82 in this case, of which only two are shown, together with a die 84. Each spooler carries a reel 83 on which a tape 8 is wound. This figure shows a fixed device 80 for placing the tapes 8 longitudinally to constitute the layer 7.

Naturally, the device 80 could be mounted on a rotary plate to enable the layer 7 to be placed helically.

The two layers 5 and 7 constitute the perforated envelope 3.

The layers are put in place as follows: the conductor 2 is drawn along its axis and the first layer 5 is wound thereon by means of the rotating plate 61, the conductor 2 covered in the layer 5 is passed through the device 70 and then the second layer 7 is placed either longitudinally or helically non-aligned with the tape of the first layer and glued or hot melt fixed to said first layer tape at tape crossover areas. Cable manufacture is then terminated by placing the outer sheath.

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