DE1135067B - Steel-aluminum high-voltage solid conductors - Google Patents

Description

Steel-aluminum high-voltage solid conductors High-voltage solid conductors are known with flat top layer wires, which are on round wires or angular wires of the core conductor rest. The flat top layer wires are either on the narrow edges with special overlapping parts provided, or their seam flanks, z. B. partially inclined or round lateral boundary surfaces, overlap. The disadvantage of such a ladder is that the top layer wires do not connect exactly to each other because you neither have the core wires can still mathematically draw the top layer wires to size, is the core of the Head z. B. as a result of wear and tear of the drawing nozzles for the individual wires turned out thick, so the top layer wires do not close tightly at their seam edges, and there are gaps of different sizes in the seams in which there is hoarfrost and ice can build up, leading to large corona losses.

Also known are steel-aluminum full runners, in which the core of the The conductor is only loosely enclosed by the top layer wires, so as to be mutual To enable longitudinal displacement of the core and cladding. With these the express themselves outer layer wires as a result of the non-contacting steel core, especially at Curvatures of the conductor, in an out of round shape, and then arise between the top layer wires outside not only gaps in which ice can insert, but also free edges of the top layer wires. However, both lead to the very harmful corona losses.

But it is with regard to radiation losses, hoarfrost and Ice formation is very important that the top layer wires have a smooth, round, tightly fitting Form surface.

In order to achieve this in high-voltage full conductors, according to the invention the flat and wide cover layer wires have a conical, arcuate cross-section and 'lie with the thicker cross-sectional part on the core conductor in such a way that between the weaker cross-sectional part having an outer covering part between the top layer wire and the core conductor creates a hollow space and thereby a tight seal of the cover parts of the top layer wires can be achieved.

This training now enables on the one hand a firm support of the Top layer wires also on a steel core that is a bit too thin, so that the top layer wires cannot deform into an elliptical cross-sectional shape, and on the other hand the release of a space between the steel core and top layer wires into which a too thick steel cable can enter without the circumference of the top layer wires bursting so that the top layer wires always seal tightly to the outside, no matter whether the steel cable is slightly different from its nominal diameter in a positive or negative sense deviates. This is achieved in that the cross-sectionally conical top layer wires only rest with the thicker cross-sectional part on the steel core, on the other hand with the other cross-sectional part only on the adjacent top layer wire. The tightly squeezed Top layer and core parts ensure the cross-section that is always round, and the wedge-shaped voids between the top layer wires and the core make this possible Entry of a steel cable that is too thick. into this cavity without the top layer wires be lifted from each other and the jacket is leaking. Core ropes too thick can arise above all when the drawing tools gradually wear and tear have received nozzles that are a little too large. Such wear and tear on the drawing tools are included Use of the stressed top layer wires made largely harmless.

Further advantageous details are explained below.

In Fig. 1 to 4 high-voltage conductors according to the invention are half illustrated in cross section with differently designed top layer wires.

Fig. 1 shows such a conductor in cross section with overlapping cover layer wires 1 made of aluminum and the first layer of steel round wires 2 of the core. The overlap parts a, b are rectangular in cross section with rounded edges. The top layer wires have an arcuate, conical cross section and only rest on the core wires 2 at the thicker part at c.

FIG. 2 also shows a conductor with overlapping top layer wires. The outer overlap part is circular in cross section on the sides in this case limited. The top layer wire 1 has its thickest point at .x and its thickest point at y weakest cross-section. The transition from the strong to the weak cross-section is conically arcuate, so that a small hollow space z between the Top layer wire 1 and the core of the conductor results. Each top layer wire is at c on the core.

3 illustrates a conductor in which the top layer wires overlap one another in the circumferential direction by means of conical overlapping parts a ', b' with an undercut and are thus also fixed against displacement in the circumferential direction. If the outer layer wires are subjected to tensile stress in the circumferential direction by a core rope that is too thick, the overlapping parts a ', b' are pressed all the more tightly against one another and the formation of gaps is thus prevented. The top layer wires also run in a conical, arcuate cross-section. The lateral boundary surfaces of the overlaps are circular.

Fig.4 shows a conductor, the lateral boundary surfaces of the top layer wires overlap each other and by means of circular arc-shaped edge parts interlock. In this case too, the course of the cross-section is the top layer wires conical arcuate.

In all cases, the outer roundings of the covering parts a, ä prevent the occurrence of large radiation losses.

Inner or outer lateral boundary surface parts of the cover layer wires (at a, b; d or b ') , which are directed approximately radially to the entire conductor, prevent the cover layer wires from slipping in the circumferential direction if the core rope is a little too thin. The core conductor consists essentially of load-bearing round steel wires, but can also have outer layers of round or angular aluminum wires.

Claims (5)

PATENT CLAIMS: 1. Steel-aluminum high-voltage solid conductors with a core conductor with round wires and flat, wide cover layer wires that partially overlap at the narrow seam edges by means of lateral flaps or inclined boundary surfaces; characterized in that the flat cover layer wires are conically curved in cross-section and rest with the thicker cross-sectional part on the core conductor in such a way that a hollow space is created between the weaker cross-sectional part of the cover layer wire, which has an outer overlapping part, and the core conductor and thereby a tight seal of the overlapping parts the top layer wires can be achieved. 2. Full ladder according to claim 1, characterized in that that the overlapping tabs of the top layer wires are approximately rectangular in cross section are formed and have rounded edges. 3. Full ladder according to claim 1 or 2, characterized in that the outer end of the overlapping tabs in Cross-section is rounded circular. 4. Full conductor according to one of claims 1 to 3, characterized in that the overlapping tabs of the top layer wires are conical in cross section and overlap each other with an undercut. 5. Full ladder according to claim 1, characterized in that the overlapping lateral boundary surfaces are formed in the shape of an arc of a circle in cross section. Publications considered: (Austrian patent specification No. 125 044.