SK8201Y1 - Switching element and switching system for high voltage overhead lines - Google Patents

Abstract

The technical solution relates to a switching element for high voltage overhead lines which includes a solid insulator (1) and a rotationally mounted movable insulator (2). The axis of the fixed insulator (1) lies out of the plane determined by the axis of the movable insulator (2) in the tilted position and in the restrained position. The invention further relates to a switching system for overhead electrical lines with a planar arrangement of conductors including a crossbar (17) fastened by means of a clamping sleeve to a support point and three switching elements interconnected by a control shaft (18) provided with a lever (19) for connecting the control rod. The rigid insulators (1) of the switching elements are fastened from the top to the cross member (17) and the movable insulators (2) are fastened on the brackets (20) which are welded from the bottom to the crossbar (17) by means of the rotatable mounted socks. The length (t) of the brackets (20) is in the range of 110 to 200 mm.

Description

Technical field

The technical solution relates to a switching element for overhead high-voltage power lines and at the same time a switching system intended for overhead power lines in the so-called overhead line. planar arrangement, where on the poles or masts the electric conductors are arranged horizontally in one plane.

BACKGROUND OF THE INVENTION

Overhead high-voltage power lines are mounted on support points (columns or masts) equipped with a support system or a switching system. section switch disconnectors for disconnecting a certain section of the power line.

The most widespread is the system of planar arrangement of lines, where all electric conductors are arranged horizontally in one plane. Another system used is a triangular conductor arrangement which is described e.g. in utility models no. 6820 and 6978, which occupies a smaller footprint projection area while providing greater protection for the birds from setback.

The planar arrangement of the conductors comprises a support system consisting of a horizontal cross-member fixed by means of a clamp sleeve on the head of the support point and tension insulators which are horizontally fixed to the horizontal cross-member in the direction of the wires and to which the wires are fastened. If the support point is fitted with a section switch, then the wires are fastened by means of tension insulators on both sides of the crossbeam, and above the horizontal crossbeam of the support system is mounted another horizontal crossbeam carrying the switching system. The switching system is generally made up of three switching elements (one for each phase), which are jointly controlled by a single control shaft with a lever to which a control rod leading to the foot of the support point is connected, where it is operated by the operator.

A known design of a switching system for a flat conductor arrangement is described e.g. in utility model no. 24596. On a horizontal crossbar, three brackets, also called "pole beams", are welded from above, two on one side of the support point and a third on the other side of the support point. The connecting wires lead from the anchor terminals to the switching elements. Each bracket is fitted with a switching element in the line, which forms a rigid insulator carrying the main contact plug and a movable insulator carrying the contact knife in the line. The movable insulator is mounted on the actuator shaft, by turning of which the movable insulator is also rotated by an angle sufficient to engage the contact knife in the main contact fork of the fixed insulator when the switching element is closed. The procedure is reversed when disconnected.

In order to avoid the occurrence and burning of the electric arc between the fork and the contact knife of the main contact, a switching element equipped with a so-called. by-contact, the purpose of which is to prevent the occurrence of an electric arc during switching and disconnecting. One type of side contact used is an oil-filled arc chute, which is arranged on a rigid insulator, and a U-shaped swiveling arc extends. In this fork, a pulley is rotatably mounted at the end of the unloaded arm coupled to the movable insulator While the main contact extends substantially in the axis plane including the axis of the movable insulator and the axis of the fixed insulator, the secondary contact is arranged laterally outside this plane to achieve a safe distance between and side contacts. Another type of side contacts is called. a flagellar contact, e.g. in the utility models 14 169 and 14 767. The secondary contact in this type consists of a quenching spring with a swing arm arranged generally on a fixed insulator and a hook connected to the movable insulator and a tensioning spring when disengaging to the point where the spring is released. Overvoltage prevents the occurrence of an electric arc and stops at the lower or upper stop. In this case, the secondary contact is in the same plane as the main contact, i. j. in the plane comprising the axis of the fixed insulator and the axis of the movable insulator, but is arranged sufficiently high above the main contact to achieve a safe distance between the main and secondary contacts

A common disadvantage of the known switching elements lies in their arrangement with a fixed and movable insulator in a single line on a common console or in a single line. pole traverse. The line arrangement of the insulators is understood to be such an arrangement where the axis of the movable insulator during switching and disconnection always moves in common with the axis of the fixed insulator t. that the movable insulator mounted on a common pole cross-section with the fixed insulator moves against the fixed insulator. This construction requires a considerable length of the lower bracket (pole cross beam), which must also be adequately dimensioned and strength dimensioned so that it is not only long but also heavy. Depending on the weight of the switching elements, including the brackets, the horizontal cross member must also be dimensioned, so that the entire switching system for the plane arrangement is large and heavy using the known switching elements.

This is understandably disadvantageous not only in terms of space requirements for storage and transport, increased installation requirements, but also in terms of the overall cost of the switching system, where

With K 8201 Yl, the cost of metal profiles means that any reduction in weight and size will result in significant cost savings for the purchased parts and hence the resulting price for the entire product.

A further disadvantage of the described switching elements and switching systems with line insulator arrangement then lies in that the main contacts are fixed on the fixed insulator and on the movable insulator by means of copper strips, because with respect to the geometry given by the line insulator arrangement these fasteners have to carry high current relatively long time, so it is necessary to use expensive copper material.

By dimensioning and other common design modifications of the switching element with line arrangement of insulators on a common console it is not possible to achieve the required savings of material, weight and dimensions of the switching element, because the geometry of switching and disconnecting process while maintaining all safety parameters to prevent jump, short circuit and shorten the axial distance between the fixed insulator and the movable insulator

The object of the invention is therefore to provide such a switching element and a switching system which would eliminate the above-mentioned drawbacks, would be less bulky, lighter, cheaper and would save both iron and precious metal components.

The essence of the technical solution

This object is solved by providing a switching element and a switching system according to the present invention.

The switch element for overhead high-voltage power lines comprises in a known manner a fixed insulator and a rotatable movable insulator, where the insulators carry on their heads the main contacts formed from the main fork and the contact knife and the secondary contacts formed from the arc quenching chamber and the pulley on the support arm, or formed from an extinguishing spring with a swing arm, a hook and at least one stop. The principle of the technical solution consists in that the axis of the fixed insulator lies outside the plane determined by the axis of the movable insulator in the on position and in the off position. In a preferred embodiment, the axis of the fixed insulator is at a distance L from the vertical plane defined by the axis of the movable insulator in the on position and in the off position, wherein the distance L is in the range of 80 to 180 mm. According to another preferred embodiment, the distance X of the insulator axes in diameter to the so-called vertical plane is less than the sum of the radius of the fixed insulator and the radius of the movable insulator, the radius of the insulator being the distance between its axis and the housing. That is, the movable insulator is not arranged on a common console with the fixed insulator and does not move in common with the fixed insulator when switching and disconnecting, as was the case with the prior art solutions, and the movable insulator is axially closer to the fixed insulator. The new solution enables shortening of the switching and disconnecting path and saving of material elements made of steel and precious metals.

In a preferred embodiment of the switching element, the axes of the fixed insulator and of the movable insulator are arranged substantially parallel in the on position and thus form an angle and lying in the range of 0 ° to 15 ° in the vertical plane.

In one preferred embodiment of the switching element, the housing of the fixed insulator at its largest diameter extends into the vertical plane defined by the housing of the movable insulator at the largest diameter location, in the on position and in the off position.

In another preferred embodiment of the switching element, the housing of the fixed insulator is at its largest diameter at a distance I from the vertical plane defined by the housing of the movable insulator at the largest diameter at the on position and off position where this distance is greater than zero and less than or equal to 60 mm .

Furthermore, it is preferred that the axes of the insulators in the uncoupled state enclose an angle lying in the range of 40 to 80 ° to each other.

In a further preferred embodiment of the switching element according to the invention, the main contact is arranged in the plane determined by the movable insulator in the on position and in the off position, the main plug being arranged on a spacer lateral from the fixed insulator, and provided with a connection mandrel.

The secondary arc quenching contact may be a known arc quenching chamber or so-called quenching chamber. with a flagellar contact

In a first preferred embodiment of the switching element of the invention, the secondary contact is formed by a quenching chamber with a rotating quenching fork fixed to the head of the fixed insulator and a pulley on a support arm mounted on the head of the movable insulator. a knife and a connecting mandrel for connecting the interconnecting conductor, and an upwardly extending upper portion which at its end carries a rotatably mounted pulley and an animal with an angle of between 55 and 85 ° to the movable insulator axis.

S E 8201 Yl

The arc chute is preferably fastened by means of screws to a support bracket which is bolted to the head of the rigid insulator, the support bracket being substantially open-ended " U " formed and integral with the main fork spacer. The support arm and / or the spacer holder and / or the support holder are preferably made of a steel profile, thereby saving copper strip.

In a second preferred embodiment of the switching element according to the invention, the secondary contact is formed from an extinguishing spring with a swing arm and a hook for tensioning and swinging the swing arm, and at least one stop to define the end position of the swing arm when swinging.

In this embodiment, the quenching spring is preferably mounted on a sheet steel molded body which is fastened to the head of the solid insulator by means of screws. In the upper part of the shaped body, a cut-out forming a lower stop is formed and at the same time an arm forming a stop is fixed to define the end position of the extinguishing arm of the arc quench spring. In the lower part of the molded body, the main contact of the main contact is fixed at the side, the hook being fixed on a vertical steel plate holder which is bolted to the head of the movable insulator and is equipped with a side arm on which the main contact contact knife is arranged. against the main fork.

The side arm is preferably also made of sheet steel and forms an integral unit with the vertical holder, the molded body is Z-shaped and is provided with a bend in the lower part forming a support for the coil spring.

The object of the technical solution is in addition to the switching element also a new construction of a switching system for overhead power lines with a planar arrangement of conductors, including a crossbar fastened by a clamp to a support point, and three switching elements interconnected by a control shaft equipped with a lever for connecting the control rod. The principle of the switching system according to the invention consists in that each of the switching elements is formed according to the present invention, wherein the fixed insulators of the switching elements are fastened from above to the crossbar and the movable insulators are fastened by means of rotatably mounted feet on brackets welded from below to the crossbar wherein the length of the brackets is in the range of 110 to 200 mm

The cross-member is preferably formed by a closed steel profile of a quadrangular cross-section, which is arranged at an angle to the bracket so that its underside adjacent to the bracket has an angle of between 10 and 30 ° with the bracket.

In a preferred embodiment of the switching system according to the invention, the bracket is formed by a steel "U" profile adjoining the open side to the crossbar, wherein the "U" profile bevels are provided with angled cuts at an angle between 10 and 30 ° in which they are arranged and welded the crossbar, and further the pivot foot has a "U" shape and is mounted on the "U" arms of the bracket profile with a pivoted pivot.

In a further preferred embodiment of the switching system according to the invention, the actuating shaft is formed by a steel closed profile of a rectangular cross-section which is detachably fastened to the rotating feet by means of tightening screw clamps and on which a lever is clamped by a clamping jaw.

Advantages of the switching element and the switching system according to the invention reside in particular in that the new arrangement and position of the insulators achieves the optimum geometry of the switching and disconnecting process, which makes it possible to minimize the distance of the fixed and movable insulators and thereby reduce the length of brackets. Furthermore, the bracket, in contrast to the known pole beam, carries only a movable insulator, the rigid insulator being mounted directly on the horizontal profile, which also allows shortening its length and using a cheaper "U" profile. The switching system is smaller than the known system, lighter and cheaper both in the carrier, where smaller and lighter profiles are used, and in the electrical part, where steel fasteners can be used instead of copper fasteners, given that they are exposed to current load for a shorter time.

Compared with the power switch type known in the prior art, the switching system according to the invention has a lower overall weight, moreover replacing the copper elements with metal ones, so that its total cost is considerably lower than with previously used switching systems.

BRIEF DESCRIPTION OF THE DRAWINGS

The technical solution will be explained in more detail by means of the drawings in which FIG. 1 is a perspective view of a known three-element switching system with insulators in a line configuration, FIG. 2 shows a side view of a switching system with three switching elements according to the invention, with arc chambers, the arms of which move along the lower arch, FIG. 3 is a perspective view of the switching system of FIG. 2 in the uncoupled state, FIG. 4 is a perspective view of the switching system of FIG. 2 in the closed state, FIG. 5 is a view of the switching system of FIG. 2 in the direction of the conductors, FIG. Fig. 6 is a side view of a switching system with three switching elements according to the invention, with arc chambers, the arms of which move along the upper arc; 7 is a perspective view of the switching system of FIG. 6 in the uncoupled state, FIG. 8 perspective

S 8201 is a view of the switching system of FIG. 6 in the closed state, FIG. 9 is a view of the switching system of FIG. 6 in the direction of the conductors, FIG. 10 is a side view of a switching system with three switching elements with a quenching spring and a hook; FIG. 11 is a perspective view of the switching system of FIG. 10 in the unlocked state, FIG. 12 is a perspective view of the switching system of FIG. 10 in the closed state, FIG. 13 is a view of the switching system of FIG. 11 in the direction of the conductors, FIG. 14 is a view of the switching system of FIG. 12 in the direction of the conductors, FIG. 15 shows a schematic representation of the position of insulators with overlapping sheaths, FIG. 16 is a schematic representation of the position of insulators with a distance (I) between the shells.

An exemplary embodiment

Specific embodiments of the invention described and illustrated are presented by way of illustration, not as a limitation of the invention to the examples given. Those skilled in the art will find or will be able to provide more or less equivalents to the specific embodiments of the invention described herein using routine experimentation. These equivalents will also be included within the scope of the following protection claims.

In FIG. 1 shows a switching system with three switching elements known from the prior art and intended for a flat arrangement of conductors. On a horizontal crossbar 17 provided with a support 21 for a clamp clamp not shown for clamping on a concrete column, three brackets 20, also called pole beams, are welded from above perpendicularly to the crossbar 17, which also have longer overhangs on one side and shorter overhang on one side. On the longer overhang, a fixed insulator 1 is mounted, on which the connecting pin 15 for the connecting conductors 15 is fastened to the copper fastening strip 26, and the main plug 4 of the main contact is fastened there. A quenching chamber 6 is also attached to the fastening strip 26, from which a rotating shaft with a swiveling quenching fork 7, moving with and following the lower arc, extends laterally.

At the other end of the bracket 20, on the side with a shorter overlap from the cross-member 17, there is a rotary shoe 3 according to FIG. 1 a pivotally mounted movable insulator 2 on which the copper connecting strip 26 'is mounted. carrying a connecting mandrel 15 'for connecting the connecting conductor, and a contact knife 5 engaging the main contact 4 of the main contact when it is closed. At the same time, on the movable insulator 2 there is an L-shaped holder which carries the support arm 9 with the pulley 8 engaging in the side contact rotating / extinguishing fork 7 when switched on. The insulators 1, 2 are in the linear configuration, at a great distance from each other, over the entire length of the bracket 20. In the on position, the insulators 1, 2 form an inverted "V" shape, in the off position a "U" open shape. The rotating feet 3 have flanges through which the steel shaft control shaft 18 passes, on which a lever 19 for a control rod (not shown) controlling the switching and disconnecting of the switching elements is mounted.

A first embodiment of a switching element and a switching system according to the invention is shown in FIG. 2 to FIG. 5. This is an example of a side contact formed by an arc chute 6 with a rotatable arc chute 7 that is rotatable on the lower arc from the on position to the on position as shown in FIG. 2. The second part of the secondary contact is formed by a swivel pulley 8 on the movable insulator 2, which fits into the swiveling fork 7. The basic frame of the switching system consists of a horizontal crossbar 17 formed by a steel galvanized Jäckl profile on which three short brackets 20 In the arms of the brackets 20 there are oblique cut-outs 22 at an angle γ = 20 °, in which the cross-member 17 is seated and welded, the lower and upper sides of which do not extend parallel to the plane of the brackets 20, but it is arranged obliquely at an angle γ. This makes it possible to achieve an optimum geometry of movement of the insulators 1, 2 during switching and disconnecting, in which the insulators 1, 2 in the open position are substantially V-shaped and in the closed position they are arranged substantially parallel. It is essential for the fitting of both the switching element and the switching system that, while the movable insulator 2 is mounted at the end of the bracket 20 by means of a U-shaped rotary shoe 3 with a pin 23, a fixed insulator! it is not mounted on the bracket 20, but directly on the crossbar 17 outside the plane defined by the movable insulator 2 in the on and off positions. This means that the rigid insulator 1 is arranged laterally from this plane in which the movable insulator 2 is moved. In a particular embodiment of the insulator axis 1, 2 in diameter in the direction of the brackets 20 are at a distance L = 135 mm, and the insulators 1, 2 are equidistant from each other at a distance of I = 35 mm The axes of the insulators 1 and 2 thus enclose an angle α = 60 °, with neither the fixed insulator 1 nor the movable insulator 2 arranged vertically in the disconnected position. The position of the crossbar 17 against the brackets 20. In plan view, this arrangement is shown in FIG. 16. The distance X of the axes of the insulators 1, 2 in diameter to the vertical plane defined by the axis of the movable insulator 2 in the on and off positions is less than the sum of the radius R1 of the fixed insulator 1 and the radius R _{2 of the} movable insulator 2. ₂ . The radius R 1, R ₂ is understood here as the distance of the axis of the insulator 1, 2 from its housing at the point of greatest diameter. It also applies here that L> R + a R ₂ = I, L - (+ Ri + _R2). In FIG. 15 shows another embodiment of the switching element to which a well defined fundamental relationship X <R-R _2, but coats insulators l 2SA in the top plan view of overlap, so that the operating I <Ri + _R2 and length I = L - (R + R ₂ ) is zero resp. negative compared to FIG. 16. In this example, there are axes

S K 8201 Y1 of the insulators 1, 2 closest to each other, the distance of the insulators 1, 2 is reduced as much as possible and space and material are saved.

The head assembly of the rigid insulator 1 is designed such that a support bracket 16 of galvanized steel sheet having a substantially open letter "U" shape is screwed onto the head of the rigid insulator 1. In the upper part of the support bracket 16 are bent with openings to which a quenching chamber 6 is screwed, from which a shaft with a rotating quenching fork 7, moving along the lower arc in the plane of movement of the movable insulator 2, is screwed to the side. formed by a shaped spacer 14 which carries the main fork 4 lined laterally from the fixed insulator 1, so that the main fork 4 is in the plane of movement of the movable insulator 2. Together with the main fork 4 the connecting mandrel 15 is fixed to the spacer 14 to anchor clamp to the main conductor fixed to the tensile insulator on the horizontal crossbar below the crossbar

17th

The head assembly of the movable insulator 2 is formed by a support arm 9, which is made of galvanized sheet steel, and is screwed to the head of the movable insulator 2. The lower part of the support arm 9 is straight and protrudes directly above the movable insulator 2. a knife 5 engaging the main contact 4 of the main contact, and on the opposite side from the contact knife 5, a connecting mandrel 15 'is mounted to connect an unconnected connecting conductor leading to the anchor terminal of the main conductor. The straight part of the support arm 9 is followed by an oblique part which projects obliquely upwards from the movable insulator 2 and the animal with the axis of the movable insulator 2 an angle β = 50 °. The upper edge of the inclined portion of the support arm 9 is provided with a stiffening rim At the end of the inclined portion of the support arm 9, a pulley 8 is rotatably mounted, which fits into the rotating arc-extinguishing fork 7 of the arc-extinguishing chamber 6.

The rotating feet 3 at the lower ends of the movable insulators 2 are provided with tightening screw couplings 24 in which the control shaft 18, which is not made of steel log but of a zinc-plated steel profile of closed quadrangular cross-section, is fastened. A lever 19 is attached to the control shaft 18 by means of a clamping jaw 25 for connecting a control rod (not shown) for controlling the switching and unlocking process. By the movement of the actuating rod, the pivoting-tilting movement of the movable insulators 2, which, when switched, approach the fixed insulators 1 until they are substantially parallel to them, is actuated via the lever 19 and the actuating shaft 18. In this case, the contact knife 5 engages in the main fork 4 of the main contact and the roller 8 engages in the rotary arc quenching fork 7 of the secondary contact. The rotary arc quench 7 moves by the pulley 8 during switching on the lower arc to the lower position as shown in FIG. 2. The movement is reversed when disconnecting.

An alternative second embodiment of a switching element according to the invention is shown in FIG. 6 to FIG. Again, this is an embodiment with a side contact formed by the arc chute 6 and pulley 8, but the arrangement of the switching element is such that the swivel arc quench fork 7 moves on the upper arc as shown in FIG. This is achieved both by changing the angular position of the mounting of the rotary arc quenching fork 7 on its shaft leading inwardly to the arc quenching chamber 6, and by the fact that the position of the insulators 1, 2 is laterally reversed relative to the first example as shown in FIG. 2 to FIG. 5. Thus, in a side view, the movable insulator 2 is not to the right of the fixed insulator 1, but is to the left of the fixed insulator U

In a further, not illustrated embodiment, the main contact arrangement may be the opposite, i. j. A rotating pulley 8 is supported on the fixed insulator 1 and a quenching chamber 6 is arranged on the movable insulator 2.

In another embodiment shown in FIG. 10 to FIG. 14, the switching system is made in the same manner as in the first embodiment, except that the secondary contact of each switching element is formed by a quench spring 10 and a hook 12 for tensioning and swiveling the swing arm 11 of the quench spring 10. the spring 10 with the swing arm 11 is arranged on the fixed insulator 1 and the hook 12 is arranged on the movable insulator 2, but in the other example not shown it is also possible to reverse the arrangement. Both variants of the ground plan arrangement of the insulators 1, 2 according to FIG. 15 and FIG. 16th

On the fixed insulator 1, the molded body 27 is screwed in the form of a "Z" -shaped steel sheet molding. The lower part of the molded body 27 carries the main fork 4 of the main contact, which is arranged on the side facing the movable insulator 2. The flat lower part of the molded body 27 is also provided with a bend 30 which supports the wound portion of the quenching spring 10. is a flat part with a cut-out, into which, after being released from the hook 12, the swing arm H and the cut-out thus form a lower stop 13 for the extinguishing spring 10. The U-shaped support extending from the top is also fastened to the upper part of the shaped body 27. of the shaped body 27 upwards and forms the upper stop 13 'for the swing arm 11 of the extinguishing spring 10.

On the movable insulator 2, a vertical bracket 28 formed by a steel sheet molding is fastened by means of screws, and to this bracket 28 is a vertically fastened hook 12 which engages the swing arm 11 of the arc spring 10 and deflects it in a predetermined position. position

With K 8201 Υ, the swing arm 11 is released from the hook 12 and swiveled back to its basic vertical position above the fixed insulator 1, pausing in the overlap by the lower stop 13 and the upper stop 13 '. At the same time, the vertical holder 28 also carries part of the main contact, namely the contact knife 5, which is fixed on the side facing the fixed insulator 1 against the main fork 4.

Industrial usability

The switching element and the switching system according to the invention can be used for above-ground high-voltage electrical lines, in particular for lines with a flat conductor arrangement.

S K 8201 Υί

Overview of reference numerals used in the drawings fixed insulator movable insulator shoe main fork contact knife arc chute rotary arc fork pulley support arm extinguishing spring swing arm hook stop spacer bracket connecting pin for connecting conductor connection

15 'connecting pin for connecting the connecting conductor support bracket crossbeam control shaft lever bracket support for clamping sleeve angled cut-out bolt clamping screw coupling clamping jaw copper clamping strap

26 'copper fastening strip shaped body vertical bracket side arm

L distance of the fixed insulator axis from the vertical plane defined by the movable insulator axis in the on position and in the off position

I insulator edge distance t console length and angle formed by insulator axes β support arm angle γ bevel angle in bracket

X distance of the insulator axes in diameter to the vertical plane defined by the axis of the movable insulator in the on and off positions

Ri radius of fixed insulator

R2 radius of movable insulator

Claims (19)

PROTECTION REQUIREMENTS Switching element for overhead high-voltage power lines, comprising a fixed insulator (1) and a rotatable movable insulator (2), wherein the insulators (1, 2) carry on their heads the main contacts consisting of the main fork (4) and the contact knife (5) ) and secondary contacts consisting of a quenching chamber (6) with a rotating quenching fork (7) and a pulley (8) on the support arm (9), or consisting of a quenching spring (10) with a swing arm (11), of a hook (12) and at least one stop (13), characterized in that the axis of the fixed insulator (1) lies outside the plane determined by the axis of the movable insulator (2) in the on position and in the off position. Switch element according to claim 1, characterized in that the axis of the fixed insulator (1) is at a distance (L) from the vertical plane defined by the axis of the movable insulator (2) in the on position and in the off position, ranging from 80 to 180 mm Switch element according to claim 1 or 2, characterized in that the relative distance (X) of the axes of the insulators (1, 2) in the vertical plane is smaller than the sum of the radius (Ri) of the fixed insulator (1) and the radius (R2). a movable insulator (2), wherein the radius (R1, R2) of the insulator (1, 2) is the distance between its axis and the housing at the location of the largest diameter of the insulator (1, 2). Switching element according to one of Claims 1 to 3, characterized in that, in the switched-on position of the axes of the movable insulator (2), the axis of the fixed insulator (1) is at an angle to the vertical plane in the vertical plane of 0 to 15 °. Switch element according to one of Claims 1 to 4, characterized in that the housing of the fixed insulator (1) at its largest diameter extends into the vertical plane defined by the housing of the movable insulator (2) at the largest diameter at the on and off positions. Switching element according to one of claims 1 to 4, characterized in that the housing of the fixed insulator (1) is at its largest diameter at a distance (I) from the vertical plane defined by the housing of the movable insulator (2) at its largest diameter in the on position unlocked position where this distance (I) is greater than 0 and less than or equal to 60 mm. Switching element according to one of Claims 1 to 6, characterized in that the axes of the insulators (1, 2) in the disconnected position form an angle (α) relative to one another in the range of 40 to 80 °. Switching element according to one of Claims 1 to 7, characterized in that the main contact is arranged in the plane determined by the movable insulator (2) in the on and off positions, the main plug (4) being arranged on a spacer (14). laterally from the fixed insulator (1) and is provided with a connecting mandrel (15) for connecting the connecting conductor. Switching element according to one of Claims 1 to 8, characterized in that the secondary contact is formed by a quenching chamber (6) with a rotary quenching fork (7) fixed to the head of the fixed insulator (1) and a roller (8) on the support arm (8). 9), mounted on the head of the movable insulator (2), the support arm (9) having a straight lower time to which the contact knife (5) and the connecting mandrel (15 ') for attaching the connecting conductor are fastened, and a part which at its end carries a rotatably mounted pulley (8) and an animal with an axis of the movable insulator (2) an angle (β) lying in the range of 55 to 85 °. Switching element according to claim 8 or 9, characterized in that the arc chute (6) is fastened by means of screws to a support bracket (16) which is fastened to the head of the fixed insulator (1) by means of screws, the support bracket (16) it has essentially the shape of an open letter "U" and forms an integral unit with the spacer (14) of the main fork (4). Switch element according to one of claims 8 to 10, characterized in that the support arm (9) and / or the spacer (14) and / or the support holder (16) are made of a steel profile. Switching element according to one of Claims 1 to 8, characterized in that the secondary contact consists of a quenching spring (10) with the swing arm (11) and a hook (12) for tensioning and swiveling the swing arm (11), and at least one a stop (13, 13 ') for defining the end position of the swing arm (11) at the swing. Switching element according to claim 12, characterized in that the extinguishing spring (10) is fastened to a molded sheet steel body (27) which is fastened to the head of the solid insulator (1) by bolts in the upper part of the molded body (27) 1), a cutout forming a lower stop (13) is formed and at the same time an arm forming the upper stop (13 ') is fixed to define the end position of the swing arm (11) of the quenching spring (10), and to the bottom of the shaped body (27) a main contact fork (4) mounted, the hook (12) being mounted on a vertical steel plate holder (28) which is bolted to the head of the movable insulator (2) and is provided with a side arm (29) on which a main contact contact knife (5) is mounted opposite the main fork (4). Switching element according to claim 13, characterized in that the side arm (29) is also made of sheet steel and forms an integral unit with the vertical holder (28), and the shaped body (27) has the shape of a letter, Z and at the bottom it is provided with a bend (30) forming a support for the coil part of the extinguishing spring (10). S E 8201 Yl Switching system for overhead power lines with a planar arrangement of conductors, comprising a cross-member (17) attachable by means of a clamp to a support point and three switching elements interconnected by a control shaft (18) equipped with a lever (19) for connecting the control rod, each of the switching elements being formed according to any one of claims 1 to 14, wherein the fixed switching element insulators (1) are fastened to the crossbar (17) and the movable insulators (2) are fastened to the brackets (20) by means of rotatably mounted feet (3). which are welded from below to the cross-member (17), the length (t) of the brackets (20) being in the range of 110 to 200 mm Switching system according to claim 15, characterized in that the cross-member (17) is formed by a closed steel profile of a rectangular cross-section which is arranged obliquely with respect to the bracket (20) so that its underside adjoining the bracket (20) γ) lying between 10 and 30 °. Switching system according to claim 16, characterized in that the bracket (20) is formed by a steel "U" profile adjoining the open side to the cross-member (17), wherein inclined cut-outs (22) are formed at an angle ( γ) lying between 10 and 30 ° in which the cross-member (17) is arranged and welded. Switching system according to claim 17, characterized in that the rotating shoe (3) has a "U" shape and is mounted on the "U" legs of the bracket profile (20) pivotable on the pin (23). Switching system according to one of Claims 15 to 18, characterized in that the control shaft (18) is formed by a steel closed profile of a rectangular cross-section which is detachably fastened to the rotating feet (3) by means of tightening screw clamps (24) and on which is a clamping jaw (25) fastened by a lever (19).