HU223114B1 - Device for fixing current carrying cables in an increasing height and current carrying cables post - Google Patents

Abstract

Equipment for increasing the height above the ground of current conductors suspended on the poles of electric transmission lines, with the help of an insulating chain and a current connection that ensures electrical continuity. The current-carrying coils (1) are suspended on the column (15) in a way that reduces the force acting on the column in the direction of the track, with a device (4) that ensures movement in the direction of the track, and with insulating chains (2) arranged like a tension chain, with a current connection (7). Electric transmission line support column, which has a suspension of the current conductor wire according to the invention. The suspension is attached to the body (15) or trunk (15) of the support column, and the current connection (7) is designed to bypass the body (15) of the column using the column arm or auxiliary arm and/or insulating arm, or is routed through an opening formed on the body of the support column. An electric power line pole that has an auxiliary arm attached to the pole trunk (15) in the place freed by the lifting of the current-carrying wire, and has additional current-carrying wires suspended on the auxiliary arm. ŕ

Description

Scope of the description is 10 pages (including 4 pages)

EN 223 114 Bl

Field of the Invention The present invention relates to an apparatus for fastening electrical conductive wires of electric power lines and to an electric power line.

There are basically two types of columns used on high voltage power lines. Tension and support posts. Tension-insulating chains are used on the tensioning columns, supporting chains on the supporting columns. The tensioning columns and the support columns are both sized to withstand vertical (e.g., rake) and horizontal (eg wind) loads perpendicular to the track. The basic difference between the tensioning and support columns is the load bearing of the track forces.

The tensioning columns are sized to be suitable to withstand a degree of traction depending on their subset. For the tensioning columns, the conductive wires are secured by so-called tension-insulating chains, which extend approximately horizontally along both sides of the tensioning column, lengthening the conductive wires. The tension-insulating chain transfers tensile stress to the current conductor and keeps it tensioned. In the tensioning columns, the continuity of the conductive wires interrupted by the tension-insulating chains is restored by so-called current connections.

The support columns are not dimensioned to withstand track-side pulling, although they are also limited to bearing forces of this kind to a limited extent. In the operating columns, the support rods are approximately vertically located in the operating position, which hold the conductive wires by means of the fittings at their lower ends. The support insulating chains at their upper ends are pivotally secured to the columns, thereby enabling the lower ends to displace in the direction of the trail due to forces exerted on the track, for example, unevenly distributed within the tensioning space, and thereby reducing the force on the support column to an acceptable extent. For support columns, the conductive wires are continuous.

The minimum required distance of the conductive wires of power lines from the environment is determined by laws, standards and other regulations. The conductive wires are in the form of a rope curve between the suspension points and are defined by the distance of the suspension points, the characteristics of the material used, the temperature and the applied tension force. There are two reasons why you need to increase the height of the conductive wires above ground:

- a new clearance, such as a road, requires a greater safety distance than the existing one,

- they want to carry more power on the power line (either with existing or new wires), and due to the increased jet loss due to the higher current, the current of the conductive wire increases, the droop increases, so the altitude above the allowed value decreases.

The following procedures are currently known to increase the altitude above ground:

- use of an insulating chain shorter than the supporting column; only a few 10 cm lifting effects

increasing the tension force by reinforcing the tensioning columns as needed; also has some 10 cm lifting effect

- reducing electric load; is rarely used in practice and has only a few 10 cm lifting effects,

- use of other types of conductive wires; only a few 10 cm lifting effects

- elevating the existing column or columns or replacing the columns with the existing columns higher; the disadvantage is that it involves significant costs,

- incorporating new columns into or near the existing trail; The disadvantage is that it involves significant costs.

A solution close to the present invention is described in U.S. Patent No. 5,777,262. The known patent design of tension chain insulating chains on the supporting columns increases the ground height of the conductive wires. However, the known solutions only allow for the pathway displacement of the current conducting wires by incorporating a vertical insulating chain commonly used on the supporting columns, so that the height of the current conductor wire decreases with the size of the vertical insulating chain relative to the highest mounting point on the column. There is also a known solution that does not have a vertical insulating chain, in which case the direction-shifting of the current conductor wire is not ensured, so that there may be significant path-oriented forces on the supporting columns that the support columns have to withstand without damage. Thus, if the support column is not able to withstand significant traction forces, incorporating the vertical insulating chain will reduce the height of the conductive wire, and if the vertical insulation chain is not incorporated, the supporting columns will have to take up significant traction forces.

OBJECTS OF THE INVENTION The purpose of the invention is to fasten the conductive wires on the columns of electric power lines in such a way that their elevation above the support columns increases with or without the length of the conventional support insulating chain without the support or tensioning columns being rebuilt or the power conductor reinforced. surplus due to mechanical loads.

The increased positioning of the conductive wires in some cases provides an opportunity to place additional conductors on the columns of the power lines.

It is an object of the present invention to provide an apparatus that combines the properties of retaining and tension insulating chains for the solution of the problem.

In order to solve the problem, the requirements of insulation technology, mechanical and current management are required2

Bl must match at the same time. The insulation requirements are met through the use of tension-chain insulation chains. The mechanical requirements are met by the fact that the tension-insulating chains are not rigidly attached to the column, so that the possibility of the tension-insulating chains and the current-conducting wires attached thereto is provided in such a way that the column does not have a higher mechanical load. In order to meet the current conducting requirements, the tension-insulating chains are bridged by a current connection, thus providing the electrical continuity of the conductive wires.

According to the invention, several solutions can be provided for the suspension height of the insulating chains and the conductive wires. Two of these are preferred. A solution that uses rolling motion and uses the reverse T chain.

The essence of the rolling motion method is to place a roller or rollers which are substantially perpendicular to the longitudinal axis of the current conductor, which, by rolling motion, provides for the path of the current conducting wires to be displaced. The conductive wires are pulled by insulating chains, which are connected by connecting couplings suitably selected for corrosion, vibration and tensile forces, thus ensuring the continuity of the tensile force. By traction means, whatever its structure and material, is understood to be any flexible machine element (e.g., chain, wire rope, plastic rope) used for tensioning. The coupling members are held by a roller or roller that can rotate about an axis substantially perpendicular to the longitudinal axis of the current conductor, and the position of the rollers relative to one another is determined by a steel structure fixed to the stem of the column or the arm of the column, or by fixing points on the column. The electrical continuity of the current conducting wires is generated by a current circuit. Depending on the terrain and the location of the power line column, the rollers can be used to pull down the coupling elements connected to the conductive wires down or sideways. This may be advantageous, for example, in hilly terrain. The feature of the rolling motion method is that the current conductor strand does not have a position where the current conductor is automatically reset, so it is advisable to insert a spring or springs between the moving movement stop point fixed on the connecting drawbar and the stationary restraint point fixed on the steel frame or the column body or arm holding the rollers. . With this solution, it is not only possible to ensure that the conventional support columns can be found in a wire rope fastening, but that the force of this force can also be selected by means of a deflection. Different strength springs can be placed along the trail or on either side of a column, so that the directional movement of the current conductor can be influenced artificially, which can be a significant advantage on hilly terrain.

It is also possible to limit the traverse movement of the current conductor and the return force increasing by the direction of the track by using the linkage between the traction element and the roller. In this case, the directional displacement of the current conductor will result in rotation of the roller under all conditions. By limiting the rotation of the roller and / or the angle of rotation of the roller, an increasing force can be provided to limit the directional displacement of the current conductor and / or increasing return force as a function of the direction of the path.

The essence of the reverse T chain solution is that the conductive stranded conductor chains are pulled. The end of the insulating chains opposite the conductive strand is connected and a support structure is attached to this point through a hinge, which is fixed to the other end by a joint at the coupling point formed on the column. The directional displacement of the current conductor wire is made possible by the rotation of the support structure, thereby reducing the forces acting on the column. The electrical continuity is provided by a power supply. A specific feature of the reverse T chain method is that by varying the length of the support structure, the traversing ability of the current conducting wire can be varied. In accordance with the winter and summer operating conditions, the traction of the mains conductor of the transmission line can be adjusted by replacing the support structure or by replacing the support part.

The roller and reverse T chain solution also allows the individual conductor wires to be raised to varying degrees. This may in some cases be a preferred design. Both fastening modes have the advantage that the pivoting length on the support columns decreases with the length of the insulating chain. Thus, the point of attachment of the current conductor wire may be closer to the stem of the column of the electric power line. In some cases, the conductive strand can be fixed to the trunk or inside the trunk by means of a roller, only by the use of an auxiliary arm known otherwise is it necessary to maintain the electrical continuity circuit. By tightening the point of attachment of the current conductor to the stem of the column, the safety zone decreases. The column is subjected to a more favorable mechanical stress, the closer the strap of the current conductor is fixed to the stem of the column, the smaller the arm of the twist, and the lower the strain on the column. A further advantage is that in some cases, smaller phase distances can be formed between the conductive wires.

By increasing the fastening points of the conductive wires, space is released under the current conductors, which can be used not only for the placement of landmarks or artefacts, but also for placing new conductive wires on the columns. This is possible by installing new levers in the released space, on which new conductive wires are placed. Thus, new power lines can be created on the old columns without a new trail. If the goal is to reduce the field strength, then either grounded wires or voltage less than the original voltage level of the power line3

HU 223 Level 114B1 cables are placed under the original wires. Of course, not only can we add new arms to the column by installing new arms, but we can also choose the other solution mentioned above, by means of rollers we can use the rollers to place the current conducting wires 5 by means of auxiliary arms, using the original arms, spacers, or the column. We provide a sufficient size in the body of the strain.

The apparatus according to the invention is used to increase the height of the current conducting wires suspended on the columns of the electric power line 10 by means of an insulating chain and a power continuity circuit. The current conducting wires are suspended on the column in a manner that reduces the force exerted on the column by means of a displacement means arranged in the direction of the track 15, by a current chain, and by means of a current coupled to the column.

In one embodiment of the apparatus, there is a tensioning roller or roller, which is secured to the steel structure or the column by a bearing which is substantially perpendicular to the longitudinal axis of the wire between the insulating chains connected to the current conductor and the point or points on the column. 25

In a further embodiment of the apparatus, a spring or springs having deformation are positioned between the insulating chain or chains and the stationary restraint or standing restraints connected to the clamping point due to the direction of the path of the current conductor.

A further embodiment of the device is a support structure rotatable at both ends of the wire between the insulating chains connected to the current conductor and the clamping point on the column as a result of the warp movement of the wire.

The electric power line column according to the invention is provided with a current conductor wire suspension according to the invention. The power line column has different current conducting wires with elevated degrees. 40

On the power line column, the suspension of the current conductor wire is fixed to the stem or trunk of the column, and the current connection lever, using the original arm or spacer insulator, is guided by the bypass of the column or through a sufficient needle opening on the column body.

In the space released on the power line column by the lifting of the current conductor, an additional arm is secured to the column body and additional conductive wires are attached to the additional arm. 50

The embodiment of the invention according to the invention is illustrated in detail in the accompanying drawings, in which: FIG.

Figure 1 shows a roller current conductor suspension, a

Figure 2 shows an embodiment using the inverse T chain, a

Figures 3 and 4 show the reconstruction of the original column

5 and 6 show the suspension of the current conductor in the column body.

Figure 1 shows a roller current guide wire suspension 1 for suspending a current conductor strand 15 on a column stem or column arm, or on an additional lever 14. The current conductor 1 is connected to 2 insulation chains from both directions of the track.

The insulating chains 2 are connected by a flexible traction element 3. The traction element 3 is guided onto roller 4 or rollers. The roller 4 or the rollers 4 are mounted on a bearing 5 through a steel structure or directly on a clamping point 6. The electrical continuity is provided by 7 power connections. Given that, in such a suspension, the current conductor strand has no centrally-oriented center position, it is preferred that the moving element 8 on the traction member 8 and the stationary stop 9 on the steel structure 5 connected to the rollers 4 be subjected to deformation by a traction element, preferably 10 springs may be provided, which may operate in part of the displacement range or in the entire displacement range. The position of the roller 4 is influenced by the direction in which the current conductor 1 passes the column 48 depending on the field conditions. The roller 4 may be tensioned sideways or downward by the current conductor 1.

In the event that the traction element 3 and the roller 4 are not able to slip over, i.e. there is a torque transfer between the traction element 3 and the roller 4, so that the trace movement of the current conductor 1 results in the rotation of the roller 4 under all conditions, then the current conductor 3 limiting the forward movement of the track or generating a return force that increases with the track direction can be accomplished by limiting the rotation of the roller 4 and / or increasing the force of the roller 4 by increasing the force.

By using roller suspensions along the trail, the return force at different locations may have different strengths, so that the trace movement of the conductive wire can be controlled artificially. This can be a major advantage on all terrain where the use of a current conductor (such as wind, rime, level difference) varies from place to place. The roller suspension ensures the direction of the current of the current conducting wire, so within a certain limit, there are no six harmful forces in the direction of the path.

Also shown in FIG. 2, the reverse T-chain current conductor suspension is used to suspend the current conductor strand 1 onto a column stem or column arm 13 or a lever arm. The conductor 1 is connected to the insulation chains 2 from both directions of the track. The ends of the insulating chains 2 opposite the conductive strand are connected by hinge coupling directly or by means of pulling, not necessarily flexible machine elements, and a support structure is connected to the connection point by a hinge. The other end of the support structure 11 is also connected to the clamping point 6 via a hinge. The current conductor 1 is an electric current4

The power supply is generated by 7 power connections. The support structure A is of such a length that, in the event of uneven loading or in the event of a wire breakage, the rotation of the track forces causes a sufficient amount of track-to-wire current movement to limit the line forces.

A particular feature of the solution is that by changing the length of the fixation time required by the change of seasons, by changing the length of the component between the support structure or the support structure and the insulating chain 2 it can be realized even during the operation of the transmission line. Thus, during winter and summer operation, varying degrees of suspension height and direction can be met.

Figures 3 and 4 illustrate a modification of a column known per se which allows for the placement of additional conductive wires 1 by means of a new lever 14, underneath the original column arm 13, with the aid of the current conductor wires 1 raised by one of the above described solutions. This means that through the use of the old trail and the old columns, the transferable power can be increased, or new power lines or power lines can be created. If we place grounded wires in place of the auxiliary wires or conductive wires with a lower voltage than the original wires, then the field strength is significantly reduced below the wires.

Figures 5 and 6 illustrate the suspension of the current conductor in the column body. If the current conductor 1 is suspended on the columns 48 of the electric power line by the above described roller or reversed solution T, the point of attachment of the current conductor 1 will be higher than the length of the insulating chain 2 which is placed vertically on the supporting columns. In addition to the elevation of the current conducting wire above the ground, another advantageous effect is that the insulating chain 2 as a swinging component disappears, so that the point of attachment of the current conductor strand may be closer to the stem 15 of column 48. If the electrical continuity of the current conductor 1 is provided by a current circuit 7 using an otherwise known insulating arm 50, the point of attachment of the current conductor 1 may also be placed within the stem of the column 48 or within the body of the column 48. This means that, on the old columns 48, more conductive wires or additional power conductor wires 12 can be dispensed more favorably, or new columns 48 which have no arms 13 can be formed, only the auxiliaries and / or insulating elements 50 for removing the current connections from the strain 15 are. The electrical continuity circuit 7 can also be passed through a well-known aperture of known size on the body 15 of column 48. The closer the conductive wires 1 are to the vertical axis of the column 48, the narrower the safety zone, and the less the tension on the stem of the column 48. A further advantage of the solution is that the wavelength of the conductive wires 1 is shorter with the length of the insulating chain 2, so the chances of collapse are reduced and smaller phase distances can be formed.

In addition to the high-height power cable suspension and the suspension-mounted power line column solutions, there is a significant environmental and aesthetic surplus beyond the technical-economic benefits.

Claims (8)

PATENT CLAIMS Apparatus for increasing the height above ground of conductive wires suspended on poles of electric power lines by means of an insulating chain and electrical continuity for electric continuity, characterized in that the conducting wires (1) move in a downward direction in the direction of the track to reduce the downstream force on the column (48). (4, 11) are suspended on the column (13, 14, 15, 48) by means of a power chain (7), bridged by a power link (7). Apparatus according to Claim 1, characterized in that the insulating chains (2) connected to the current conducting wire (1) and the anchor point (6) on the column or axes are arranged with a steel structure (5) substantially perpendicular to the longitudinal axis of the wire (1). or have a roller (4) or rollers for tensioning the towing element (3) fixed to the column (13,14,15,48) through a bearing. Apparatus according to Claim 2, characterized in that the spring (1) is deformed by a downward displacement of the conductor wire (1) between the insulating chain (2) or chains and the stationary motion limiter (9) or stationary motion limiter connected to the clamping point (6). 10) or springs are provided. Apparatus according to claim 1, characterized in that the insulating chains (2) connected to the current conducting wire (1) and the holding point (6) on the column (13,14,15,48) are hinged at both ends, has a pivotable support structure (11) as a result of its displacement in the direction of the track. Apparatus according to claim 4, characterized in that the conductor wire (1) has a variable length support structure (11) which varies the height of the suspension. 6. An electric power line post with a wire rope suspension according to any one of claims 1 to 3, characterized in that the conductor wires (1) are raised to varying degrees. 7. An electric power line post with a wire rope suspension according to any one of claims 1 to 4, characterized in that the suspension is secured to the support (15) or the support (15) of the support pillar and the power connection (7) to the mast (13) or auxiliary and / or insulating arm using it, it is formed bypassing the column body (15) or through an opening in the body of the support column. 8. An electric power line column with a wire rope suspension according to any one of claims 1 to 4, characterized in that, in the area released by raising the wire rope, a spare arm (14) is secured to the column body (15) and additional auxiliary wire ropes (12) are attached to the auxiliary arm.