DE29860C - Innovations in electrical cables and in mandrels for making the same - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 21: Electrical apparatus.

Patented in the German Empire on March 5, 1884.

The first part of the invention relates to electrical cables and is shown in Figs 1 is a perspective view of the improved cable and FIG Fig. 2 is a cross section through the same.

This part of the invention relates to certain innovations in composite electrical systems Cables and generally consists of a soft, round metal body Form-possessing cable through which the ducts enclosing the insulated conductors running, with these wires evenly spaced around the solid, soft metal core in are arranged in a manner described later.

In making these composite cables, it is desirable that the wires are as close to each other as possible, and that at the same time continuous, uninterrupted walls secured by encircling metal enclosing each of the various wires and that the greater part of the metal in the metal body is outside the wires or theirs Outside should be surrounding. Continuous and uninterrupted walls between the wires and enveloping them are necessary for two reasons, for electrical induction to prevent and to avoid any trace of moisture or other influences from the insulating material, which could be detrimental to the electrically insulating properties. For the latter purpose it is also desirable that the core of the cable preferably be connected to the soft metal of the body is filled because an annular channel in the middle is easy Can allow moisture and this moisture through condensation on the metal wall can get through the pores to the insulating material, thus providing the necessary elements would develop a weak but disruptive electrical or electrolytic action, which would be detrimental to the best gait of the cable. Such small openings or pores occur much more easily on inner than on outer surfaces, and this is the most dense Particularly difficult to manufacture when an annular channel is to be made in the middle.

In order to meet the requirements and secure the advantages mentioned above, the improved cable A is manufactured as follows:

A body α, preferably made of lead (although other soft, ductile metals or alloys can be used), is given a round shape by the die of the cable press. This body is solid, with the exception of the ducts, the latter being formed by the mandrel of the press holding the wire. Each of these channels contains an insulated wire c. Preferably, three equally spaced wires around the metal core a ² are enclosed in the cable, and this core is made in one piece with the metal body.

These wires can form an equilateral triangle, so to speak, through which the The middle of the cable axis. By

this arrangement is achieved so that the lead easily gets into the spaces between the wires can flow in, so that lead entering between the wires from opposite sides can fill the means completely and, when combined under pressure, complete uninterrupted Forms inner walls for cladding each wire and all wires.

With this arrangement three wires can be grouped so closely that they contain little more lead required for secure coverage than is usually required for a wire. Through this a great advantage and savings in manufacture are obtained, since the cost of lead constitute a great part of the total cost of such wires. This grouping of wires Also gives an advantageous method of manufacture of cables containing a great number of wires, dividing the wires in groups arranged in three and three, with each group essentially a replica of the one shown here and described cable forms, except that the cover body as a Is formed part of the others and as a component with the others, whereby such Unite groups into a common whole.

The second part of this invention relates to mandrels for making lead-clad electrical cables and is illustrated in Figures 3 to 6, Figure 3 being an end view of the improved mandrel looking towards the nozzles and Figure 4 being a longitudinal section on line xx of FIG Fig. S represents.

Fig. 5 is a cross-section along the line. ¹ -. « ¹ of Fig. 4 and Fig. 6 is a side view of the dome.

The requirements of this type of cable already mentioned earlier can be achieved by comparatively thin lead walls which separate one wire from the other, as shown at a ¹ between the wires c, FIGS. 1 and 2. But in order to secure the necessary protection against external damage and to obtain sufficient body of metal covering to make the cable permanent, it is important that the outer wall or the covering body be of considerably greater thickness than is the case for the inner walls between the Wires is required.

In the drawing, a mandrel for producing a three-wire cable, Fig. 1 and 2, is shown, and is in some respects preferable to this shape and number. The invention can but of course, at least in part, can be used for a greater number of wires, and therefore should not be limited to the particular shape and number shown.

The mandrel consists of a conical body of iron, steel or other suitable metal C which has a threaded sleeve c ¹ at its lower end for connection to the core rod D of the press.

In the sleeve c ^x there is an axial chamber C which is in communication with the annular channel of the core rod. From the bottom of the chamber to the conical tip of the mandrel body, three separate holes c ^{2 are} drilled, the relative positions of which correspond to the angles of an equilateral triangle. Grooves e ^{l are} formed along the conical outer sides of the body C , which run up to the point in a line between the holes or channels c * . At the outermost end, too, narrow and relatively shallow grooves e are cut, which connect the ends of the opposing grooves e ¹ between the openings of the wire channels <r ² .

The grooves e ¹ direct the influx of lead into the space between the wires, and the channels e produce openings into which the lead from each groove e 'flows sideways and, when combined, forms complete tubular sheaths of each wire before or when the lead leaves the tip of the spine and comes into direct contact with the wires.

It will be observed that, by virtue of the relative positions of the three wires in connection with the outer side grooves e ^x, almost the entire surface of the mandrel around each wire is exposed to the direct contact and pressure of the lead when the latter is brought or pressed onto the outer surface, whereby a comparatively small inner surface is left, which directly embraces the adjacent canals. The shallow incisions in the channels e also ensure that the lead is placed in tubular sheaths before it leaves the mandrel, whereby a harmful pressure of the lead on the wire is avoided, which, if too large, strips off the insulating sheath of the wires or damage it. In this construction, the wires in the cable A, Fig. 1 and 2 can be assembled close and still be left channels for filling the metal a ^x between the wires.

The thickness of the metal sheath forming the outside of the cable can be in the usual Way can be generated by the design and arrangement of the die opening through which the wires go on exiting the mandrel, and within which the lead puts the wires in is supplied in the usual way.

Claims (1)

P ATENT claims: i. A mandrel C for a cable press, which has a conical body with separate wire channels and between the line of the The wire channel has longitudinal grooves e ^l extending towards the tip, as well as shallow incisions or channels e at the end, the latter forming the grooves between the openings of the wire channels, essentially as described. For a cable press, a mandrel C of conical shape with three wire channels c ³ running through the same, which protrude at the tip in the angles of a triangle corresponding positions, and the mandrel on the outer surface between the wire channels with lengthwise running grooves or grooves e ^{1 is} provided, essentially as described.
For a cable press, a conical mandrel C with three wire channels running through the same, protruding at the tip in close proximity to each other and arranged in a position corresponding to the angles of a triangle and with the outside of the mandrel between the wire channels towards the tip and longitudinal grooves e ¹ and with the tip Incisions e crossing between the channel openings, essentially as described. For this purpose ι sheet of drawings.