NO793341L - DEVICE FOR ATTACHING AN UNSOLIDATED WIRE ON AN ISOLATOR - Google Patents

Abstract

Device for attaching an uninsulated wire to an insulator.

Description

The present invention relates to the mechanical attachment of an uninsulated wire to an insulator and, more specifically, a fastening device designed for placement on carrier insulators and suspension insulators.

There are already numerous types of devices for attaching an uninsulated wire to an insulator. such devices are usually made of a fixed part in one piece with the insulator and a movable part attached to the fixed part, the fixed part being equipped with a groove that forms a bearing in which the wire in question can be placed, and the movable part has a locking position in which it retains the cable in the bearing.

In practical use, there is a need for a fastening device for

to hold a cable firmly up to a certain differential limit stretch (which means the difference between the tensile forces in the cable on both sides of the fastening device.) Above this limit stretch there is. preferably the fastening device allows the cable to slide in its longitudinal direction through the device. If e.g. ice or snow load falls off the cable on one side, but not on the other side of the fastening device, the differential tension should usually preferably be counteracted until the load also falls off on the other side. However, if a cable mast breaks down, it is advantageous

such that the cable slides through the fastening devices on the nearest cable masts to avoid damaging (bending or twisting) the insulator carriers on these masts.

A disadvantage of many previously known fastening devices is that their limits for wire slippage vary as a function of the total tensile stress on both sides of the fastening device. Equipment is therefore often provided for setting or regulating the boundary line, which also entails the disadvantage that human error can also occur.

The optimal ultimate tensile strength can be determined in advance as a function of the conductors' mechanical strength and/or the strength of the cable masts. Preferred embodiments of the present invention provide a fastening device in which the ultimate tensile stress for cable slippage is determined by the device's shape and size in relation to the cable that it must retain, in a way that is mainly independent of the tensile stresses in the cable when the fastening device is mounted.

In certain applications, it is actually possible by suitable embodiments of the present invention to release and there-

refastening the fastener while carrying a live wire, for the purpose of allowing the cable to return substantially unimpeded to its normal position after some abnormal event has caused the cable to slip in the fastener, the cause of the cable slippage thereupon being been removed.

The present invention thus relates to a device for attaching an uninsulated wire to an insulator, the device comprising a fixed part in one piece with the insulator as well as a movable part attached to the fixed part, the fixed part is equipped with a groove that forms a bed in which the cable in question can be placed and the movable part maintains the cable in a locked position in its bearing.

On this background of known technology, the fastening device according to the invention has as a distinctive feature that the fixed and the movable part have such contact surfaces against the wire to be fixed, that the wire in its locked position is exposed to increasing deformation of its cross-section in a first direction, mainly perpendicular to the locking movement of the movable part in the middle area of the bearing, and in another direction mainly perpendicular to the first direction in the outer areas of the bearing.

The device according to the invention can also have at least

one of the following characteristics:

The fixed part has a bearing whose cross-section changes along the bottom line of the bearing from a cross-section mainly in the form of a semi-ellipse whose largest axis lies perpendicular to the locking direction of the movable part at each inlet to the bearing, to a cross-section in the form of a semi-ellipse whose largest axis runs parallel to the locking direction in the middle area of the bearing.

At each inlet, the bearing has a cross-section which gradually changes from semi-elliptical to mainly semi-circular for a part of the line which is not yet in direct contact with the moving part.

The bottom line of the bed has a wave shape in the middle area of the bed.

The radius of curvature at the bottom of the middle area of the bearing is smaller

than the smallest bed radius that can be received by the fastening device, while the bending radius is sufficiently large that the deformation of the largest uninsulated cable that can be received in the bearing does not exceed 12%.

The movable part has only two contact areas with the cable to be attached, as these areas are mainly located at the two inlet parts of the bearing.

The moving part is connected to the fixed part by means of a pivotable component, which allows the moving part to be brought against the cable under elastic reaction force.

The fixed part is made up of a one-piece cap which is attached to the insulator head, the cap being equipped with a groove which forms a bearing, the movable part is made up of a piece of shoe which is pivotally connected to the cap by means of an elastic arm which locks the movable part, under which the groove is preferably arranged on the upper part of the cap, so that the wire to be attached is located on the upper side of the cap and near the central axis of the insulator head.

The fastening device can have a plane of symmetry, mainly perpendicular to the longitudinal direction of the wire and through the middle

the axis of the insulator head.

An exemplary embodiment of the present invention will now be described with reference to the attached drawings, on which: Fig. 1 shows a partial section view of a device according to the invention and with a fixed part in the form of a cap in a piece which is attached on the head of a bearing insulator,

fig. 2 is a plan view seen from above of the device in fig. 1 shown in the locked position, only part of the movable part being indicated.

fig. 3 shows a cross-section along the line III-III in fig. 2 with a cut away half of a movable shoe piece,

fig. 4 shows on a larger scale part of the longitudinal section in fig. 3,

and

fig. 5a, 5b, 5c and 5d show sections respectively along the lines a-a, b-b, c-c and d-d in fig. 4, to show the different sections of the varying deformation of the stuck wire.

It will be understood that the shown embodiment of the device of the invention is only shown as an example. The main component, namely a slot in the form of a bearing with an associated clamping shoe, is here supported by a cap fixed on the head of a carrier insulator, but may also be supported by any other suitable carrier selected in an appropriate manner by professionals in the field in accordance with the present application or type of insulator in question. The invention, however, naturally covers all embodiment variants which only involve changing the carrier as such

this supports the basic component stated above. A person skilled in the art can thus easily use the present

technology according to the invention for fixing a wire" on the underside of a hanging insulator in connection with the lower part of the insulator chain.

Fig. 1 shows a fixed part 1 in a piece which is usually produced by stuffing. This part forms a cap 2 which is attached to the head 3 of a carrier insulator by means of asbestos cement 4.

On the upper side of the cap, the fixed part is equipped with a catch

5 which forms a bed, in which the wire to be fixed is inserted. In the vicinity of the groove, the cap is also provided with two knobs 6, only one of which is shown in fig. 1 and in which the outer ends of an elastic arm 7 are inserted. This arm 7 carries a clamping shoe 8 whose main function is to clamp the wire against the bottom of its bed with the shoe's contact surface 9 in the locking position (shown with dashed lines). Said arm 7 can be snapped into a protruding part 10 of the cap for locking the device. The cap can also be provided on the upper side with a thin projection 11 whose free upper edge serves as a structure and lining for a cable which is in a standby position against a section 12 of the protruding part 10 when the cable is to be placed in its bearing.

The groove 5 which forms the bearing and contact surface 9 on the associated clamping shoe will be described in more detail in the following, as the basic distinctive features of the invention lie in these components.

Fig. 2 and 3 show the cable 13 placed on its fastening device, which is shown in the locked position. The equipment for holding the clamping shoe 8 is more clearly shown in these figures. The clamping shoe is thus equipped with two projecting parts 14 (of which only one is shown here), which form rounded contact edges 15 against which the respective parts of the arm 7 are pressed by the arm's own elasticity, as well as two stoppers 16 which they deflect. rear ends of the arm 7 press against, as said stoppers are located immediately on the outside of the lugs 6 in which the outer ends of the arm are stored. As will be well known from prior art, the middle area of the bearing can have a curved bottom line (see fig. 3), but it should be noted that a fairly simple local chroming of the cable will not satisfactorily solve the problem of achieving a differential tension which is mainly independent of the mechanical tension force on either side of the fastening device. Such a wave part equipped with the distinctive groove according to the invention has, however, proven to be more favorable than a straight bottom line in the bed. The shape of the contact surface 9 on the movable press shoe 8 is then naturally adapted to the central undulating area of the bottom of the bearing.

According to the invention, the fixed part and the movable part have such contact surfaces in contact with the wire to be fixed that the wire in the locked position is exposed to varying deformation of its cross-section in a forward direction, mainly perpendicular to the direction corresponding to the locking movement of the movable part in the central area of the bed and in another direction, mainly perpendicular to the first direction at the two outer ends of the bed.

Instead of clamping the cable in a single direction corresponding to the clamping direction of the shoe, as with devices according to the prior art, the cable is thus deformed in two directions which are essentially perpendicular to each other, the deformation being gradually varying and produced by a single locking movement. What is known as double-increasing locking is thus achieved.

Fig. 4 and 5a - 5d show better how the device according to the invention allows deformation of the wire in a special way in the locked position.

The groove 5 in the fixed part 1 has a cross-section which gradually changes along the bottom line of the bearing, as this bottom line passes through a highest point at 17 and through two turning points 18 and 19 on both sides of said highest point or maximum. The cross-section is changed below from a cross-section in the form of a half-ellipse with its largest axis perpendicular to the locking straight edge of the movable locking shoe at each end of the bearing (point 19, cross-section b-b which is shown in Fig. 5b) to a cross-section in the form of a half-ellipse with the largest axis parallel to the locking direction in the middle area of the bearing (in point 17, cross-section along line d-d as shown in fig. 5d), the cross-section passing through a mainly semi-circular middle area (in point 18, cross-section along line c-c as shown in fig. 5c). At the outer ends of the bearing, it is also advantageous to have a cross-section that avoids damaging the cable in the event that it has a slight deflection. For this purpose, the outer ends of the bearing form an expanded rib opening whose cross-section varies from a semi-circular shape at the point of contact between the wire and the surfaces 5 and 9 (in point 20, cross-section along the line a-a as indicated in Fig. 5a) to the previously mentioned semi-elliptical shape of the bearing in point 19 (cross-section along the line b-b). The contact surfaces 9 on the clamping shoe have mainly a constant elliptical cross-section which corresponds to the cross-section of the bed at the first turning point 19, as it is not necessary here to produce a continuous contact surface in contact with the wire along the entire length of the bed. Namely, it is only necessary to form two contact zones which are mainly located at each of the outer ends of the bearing (the clamping forces are schematically shown by arrow 21 for the zone shown), as the tensile force in the wire and its own weight are sufficient to press it against the bottom of the groove in the middle area of the bearing and lock the wire in this position.

It will be obvious that the radius of curvature for the bearing and the contact surfaces of the clamping shoe cannot be of arbitrary size, in order for the device according to the invention to work satisfactorily, especially since the device must be able to receive wires with different cross-sections, e.g. with diameter 7.5 and 9.45 mm. The bending radii at the outer ends of the bearing must therefore be greater than the cross-sectional radii of the cables, so that the cable to be attached is clamped flat to the appropriate degree against the bottom of the bearing in a locking style. Without such deformation, it is actually not possible to achieve satisfactory differential sliding tension, as the line is usually coated with lubricating grease. In the central area of the bed, the bending radius at the bottom of the bed must also be smaller than the smallest cross-sectional radius for wires that can be received in the fastening device, while the bending radius is sufficiently large that the degree of deformation of the thickest uninsulated wire that can counter-

taken does not exceed 12%. The cable is thus pressed together in the upper middle area of the bearing by virtue of its own weight and the effect of the movable clamping shoe in the adjacent clamping areas. If e.g. the tension in the cable increases, e.g.

under the influence of ice or snow, the cable will be pressed further into the upper part of the bed, and when it is tightened, the cable will tend to loft clamp-

the shoe against the action of the elastic forces imposed on the shoe by the moving arm. This increases the pressure in the clamping areas and consequently increases the pinching of the wire in the upper part of the bearing.

When the cable is deformed to varying degrees along the length of the bed, the fastening device according to the invention allows less local deformation of the cable for the same limit value of the differential tension. Such a device is particularly advantageous as a substitute for normal attachment by binding to insulators for medium voltage. Finally, it should be noted that the present device will have an improved ability to withstand vibrations compared to previously known devices.

It is self-evident that the present invention is not limited to the embodiment examples indicated above to illustrate the invention, but includes all embodiment variants that fall within the principle definition of the invention, which is stated in the following patents

claim. Besides the easy transfer to other carriers

other insulators, the locking shoe can be made of a shoe in one piece or be composed of two independent shoe pieces,

while the component which connects the clamping shoe with the fixed part and allows the locking shoe to be installed with yielding tensile forces, can just as easily be made of a steel pin which forms a spring as a torsion bar or any other corresponding components.

Claims (11)

1. Device for attaching an uninsulated wire to an insulator, the device comprising a fixed part in one piece with the insulator as well as a movable part attached to the fixed part, the fixed part is equipped with a groove that forms a bearing in which the concerned .-wire can be placed and the movable part maintains the wire in a locked position in its bearing, characterized in that the fixed and the movable part have such contact surfaces against the wire to be fixed, that the wire in the locked position is exposed to increasing deformation of its cross-section in a forward direction, mainly perpendicular to the locking movement of the movable part in the middle area of the bearing as well as in another direction, mainly perpendicular to the first direction in the two outer areas of the lease. 2.A arrangement as stated in claim 1, characterized in that the fixed part is equipped with a bearing whose cross-section changes gradually along the bottom line of the bearing from a cross-section in the form of an ellipse with its largest axis perpendicular to the locking movement of the movable part at each inlet to the bearing, to a cross-section in the form of a half-ellipse with its largest axis parallel to the locking movement in the middle area of the bearing. 3. Device as stated in claim 2, characterized in that the bed at each inlet has a cross-section that gradually changes from a semi-elliptical shape to a mainly semi-circular shape at a section of the line that is not yet exposed to direct contact with the moving part. 4. Device as stated in claim 2 or 3, characterized in that the bottom line of the bearing has a wave shape in the central area of the bearing. 5. Device as specified in claims 2-4, characterized in that the bending radius at the bottom of the central area of the bed is smaller than the smallest cross-sectional radius for an uninsulated cable that can be received by the fastening device, while the bending radius is sufficiently large that the degree of deformation for the thickest uninsulated cable that can be received does not exceed 12 %. 6. Device as specified in claims 2-5, characterized in that the movable part only has two contact areas with the wire to be attached, said contact areas being located mainly at the two inlet ends of the bed. 7. Device as stated in claims 2-6, characterized in that the movable part is connected to the fixed part by means of a pivotable component which allows the movable part to be pressed against the wire by means of elastic tensile forces. 8. Device as stated in claims 1-7, characterized in that the fixed part is made up of a cap in one piece which is attached to the insulator head, said cap being equipped with a groove that forms a bearing, while the movable part is made up of a locking shoe which is pivotally attached to the hood by means of an elastic arm which locks the movable part. 9. Device as stated in claim 8, characterized in that the upper part of the cap is equipped with a groove which forms a bed, so that it . cable to be attached is located on the upper side of the cap. 10. Device as stated in claim 9, characterized in that the groove which forms a bearing is located near the axis of the insulator head. 11. Device as specified in claims 1-10, characterized in that it has a plane of symmetry which is mainly perpendicular to the length of the wire and contains the axis of the insulator head.