FI80546B - Binding for a conductor in an insulated overhead power line - Google Patents

Abstract

This invention concerns an attachment for an insulated overhead power line conductor for its connection to a support insulator 4, which attachment comprises a conductor support 2 arranged on the conductor 1 at the position of the attachment and a binding wire 3 or the like arranged on this connected to the insulation of the conductor. In order to reduce vibration damage arising from vibrations caused by the wind, the conductor support 2 included in the attachment comprises two elongated strips 5, 6 and a web 7 which joins them together, which strips 5, 6, are essentially diametrically on opposite sides of the conductor 1 when the support 2 is arranged on the conductor 1. <IMAGE>

Description

1 80546

This invention relates to a bond for a coated overhead line conductor for connection to a support insulator, the bond comprising a conductor support disposed on the conductor at the bonding point and a bonding wire or the like disposed thereon binding the conductor to the insulator.

According to the observations made in the test installations of coated high-voltage overhead lines, i.e. PAS lines, this type of 10 j hazard is more sensitive to vibration than, for example, bright feral conductors. Vibration caused by the wind may, under certain conditions, cause fatigue damage to the conductor wires and even cause the conductor to break. Vibration damage usually occurs at the wire attachment-15. One way to solve the vibration problem is to hang the wires on the insulators via a freely movable support bracket. According to vibration tests, such a suspension method effectively prevents fatigue damage to the conductors. However, the method of suspension results in it being advantageous to mount the insulators 20 in an oblique position in order to provide sufficient clearance for the support holder in an angular situation. However, the downward position of the insulators increases the column length. The movement of the support holder also has the effect of increasing the dimensioning of the insulator. The extreme positions 25 of the support holder dictate the electrical and mechanical dimensioning of the structure. Thus, the use of such a mating method, although effective in preventing fatigue damage to conductors, is structurally relatively expensive and requires the use of both specially designed insulators and specially designed support brackets.

It is therefore an object of the present invention to provide a bond by means of which the oscillation problem can be solved by using cheap standard insulators, in which the normally used conductor bonding method does not in itself guarantee good oscillation resistance properties when using PAS conductors.

2 80546

It is known to reduce the stresses on the conductors and the risk of their damage by placing various tubular or helical accessories on the conductor in the contact area between the insulator and the conductor. Such supports 5 are, for example, a support formed of helically wound metal wires used on overhead lines. In the case of coated overhead lines, such a metal support would mean adding a piece of metal with a vague intermediate potential to the structure. As another known support structure, rubber sleeves have been used which have been relatively short and longitudinally split to allow them to be mounted on the conductor. However, such a rubber sleeve is only able to prevent the local notching effect and has little effect in preventing damage caused by conductor vibrations.

In particular, the present invention relates to a new type of conductor support which, when used in connection with preferred conventional type support insulators and conventional 20 type threaded ties or similar bonding wires, provides the desired vibration damage protective effect. This is achieved in connection with the bond according to the invention in that the conductor support included therein comprises two elongate strips and a base 25 connecting them, which strips, when the support is arranged on the conductor, are located substantially diametrically on opposite sides of the conductor. In order to obtain the conductor support tightly around the conductor, it is preferred that the surface of the conductor support against the conductor forms part of the cylinder pin. It is further preferred that the material thickness of the strips of conductor support decreases towards the ends of the strips as well as that the strips taper from their tips towards their rounded ends.

By suitably combining the above-mentioned form factors, and in particular by making the conductor support from a fiber-reinforced plastic, the main direction of the reinforcing fibers corresponding to the axial direction of the strips leads to a conductor support.

5 This makes it possible, on the one hand, to avoid high stresses at certain points and, on the other hand, to make sudden stress changes and to achieve a uniform stress profile.

The bond according to the invention will now be described in more detail with reference to the accompanying drawings, in which Figure 1 shows an exemplary embodiment of a conductor support included in a bond according to the invention, Figure 2 shows bonding a conductor to a using both the normal bonding method and the bonding of the invention.

Figures 1 and 2 show an exemplary embodiment of the connection according to the invention, Figure 1 showing more precisely the conductor support 2 included in the connection of Figure 2. As shown in Figure 2, the conductor support 2 is arranged around the conductor 1 at the point where the conductor rests in the apex groove. The conductor 1 with its conductor support 2 is connected to the apex groove of the support insulator 4 by a conductor 1 25 and a connection 3 wound around the conductor support 2, which according to Fig. 2 also passes through the neck of the support insulator 4. This bonding component 3 used in the bonding according to the invention can be any conventional type of bonding component, such as a threaded bandage or an aluminum wire or a plastic-coated aluminum wire. Its function is to attach the conductor 1 to the support insulator 4 in a conventional manner, either in its apex groove or in the neck, depending on whether the bond is located at a straight part of the conductor or at an angle. In addition, the purpose of the bonding wire 3 is to press the conductor support 2 35 tightly against the conductor 1. For this purpose, the shape of the inner surface of the conductor support 2 corresponds to the shape of the outer surface of the conductor 1, i.e. the surface of the conductor support 2 facing the conductor 1 forms part of the cylinder surface.

Fig. 1 shows an exemplary embodiment of a conductor support 2 included in a bond according to the invention, comprising two elongate strips 5 and 6 and a base 7 connecting them. As can be seen from Fig. 2, these elongate strips 5 and 6 are arranged on the conductor 1. -10 radially on opposite sides of conductor 1. In this way, the conductor support 2 itself remains firmly on the conductor 1, especially when the shape of its inner surface is chosen to correspond to the shape of the outer surface of the conductor 1, i.e. the cylindrical shape, and on the other hand it is dimensioned correctly with respect to the conductor 1 diameter. Due to the elasticity of the support 7 connecting the elongate strips 5 and 6 of the conductor support 2, the conductor support according to Fig. 1 can be arranged on some conductors with varying diameters. In order to make the operation of the conductor support 2 as desired, in the embodiment of Fig. 20 1 the material thickness of the strips 5 and 6 is reduced towards the ends of these strips and at the same time the strips are tapered towards their ends rounded. The aim has been to change the stiffness of the strips 5 and 6 of the conductor support 2 by said reductions 25 and thinnings so that a stiffness profile of the desired type in the axial direction is obtained for the conductor support 2. This will be described in more detail in connection with Figure 3.

The stiffness of the conductor support 2 is also significantly affected by its material, which is preferably a fiber-reinforced plastic, in which the main direction of the reinforcing fibers corresponds to the axial direction of the strips 5 and 6. In this way, the conductor support is reinforced to withstand bending, in particular in the direction of oscillation, which is illustrated by arrow 8 in Fig. 2. Glass fibers or carbon fibers can be preferably used as the reinforcing fibers. An exemplary material for the conductor support itself is, for example, an aromatic polyamide. Alternatives for manufacturing the conductor support 2 can be thought of as pressing it into a mold in which a desired amount of longitudinally reinforcing fibers has been pre-arranged, or alternatively it can be manufactured from a pipe of suitable diameter by sawing and grinding.

When the conductor support according to the invention is installed as shown in Fig. 2 so that the coated conductor 1 is peeled from the open side of the conductor support 2, the base of a potentially ignitable arc can move freely towards the arc shield 9, which is galvanically connected to the conductor.

Fig. 3 illustrates the operation of the dressing 15 according to the invention by showing the stress distribution caused by wind-induced vibration in the dressing area, curve A being intended to illustrate the stress distribution of a normal dressing method and curve B The curve of Fig. 3 of Fig. 20 is shown in the coordinate system, where the distance is shown on the horizontal axis and the stress on the vertical axis. As can be seen from curve A, a steep stress spike is generated at the support insulator when the normal bonding method is used. Curve B, on the other hand, shows that the stress generated in the bonding area has been able to be spread over a considerably longer distance when using the bond according to the invention, thus avoiding the occurrence of a high stress peak. It is clear that there will be considerably less fatigue damage in the bond according to curve B. In practical experiments, it has been found that the durability is at least an order of magnitude better.

The bond according to the invention has been described above in connection with only one exemplary embodiment and it is to be understood that several modifications may be made thereto without departing from the scope of the appended claims 6,80546. Thus, as already indicated above, in particular the shape of the ends of the conductor support strips can be changed to achieve the desired type of stress distribution, and it is clear that the dimensioning and material strengths of the conductor support 5 have to be adapted to the dimensions of the conductors used.

Claims (5)

7 80546 A connection for a coated open conductor conductor for connection to a support insulator (4), which connection comprises a conductor support (2) arranged at the connection point on the conductor (1) and a bonding wire (3) or the like arranged thereon, which binds to the conductor insulator. , that the conductor support (2) comprises two elongate strips (5, 6) and a base (7) connecting them, which strips (5, 10 6) with the support (2) arranged on the conductor (1) lie substantially diametrically with the conductor (1) on opposite sides. A bandage according to claim 2, characterized in that the surface of the conductor support (2) against the conductor (1) forms part of the cylinder surface. Bandage according to Claim 1 or 2, characterized in that the material thickness of the strips (5, 6) of the conductor support (2) decreases towards the ends of the strips. Bandage according to one of Claims 1 to 3, characterized in that the strips (5, 6) taper from their tips towards their rounded ends. Bandage according to one of the preceding claims, characterized in that the conductor support (2) is made of fiber-reinforced plastic, in which the main direction of the reinforcing fibers corresponds to the axial direction of the strips (5, 6). 8 80546