KR20000033385A - Armor rod for preventing tracking of all dielectric self supporting cable - Google Patents

Abstract

PURPOSE: An armor rod for armoring an all dielectric self supporting (ADSS) cable is provided to prevent tracking from occurring at the high electric field. CONSTITUTION: An armor rod is an insulating body of high resistance which covers a dead end of the ADSS cable by bending in order to prevent tracking of the ADSS cable at the high electric field. A cover of the ADSS cable is prevented from being damaged due to inflow of free electrons, by using the high resistance armor rod at the dead end of the ADSS cable.

Description

ADDS cable tracking prevention flax rod

The present invention relates to a flax rod for supporting an ADSS cable in order to install the ADSS cable in an ultra high voltage pylon for power transmission, and more particularly, to an flax rod covering an ADSS cable in order to prevent ADSS cable tracking under high pressure.

Overhead cable is a cable used to construct structures such as electric poles and buildings and to cross them into the air. Since the hypothesis weight concentrates on the fixed point of the structure, a cable is applied to many supporting wires. In this case, most of the hypothesis tension is shared by the support line, but the cable body, like an optical fiber composite processing line, There is also a structure that can withstand. The type of cable hanging on the support line includes a hanger using the already installed support line, and a self-supporting cable in which the cable and the support line are integrated in advance.

Among the self-supporting cables are ADSS (All Dielectric Self Supporting) cables, which are non-conducting cables installed in extra-high voltage transmission lines.

Figure 1 shows a state in which the ADSS cable is installed in the ultra high voltage pylon for power transmission.

The processing branch line 120 is installed at the top of the ultra-high voltage pylon 110 for power transmission, and the power line 130 is installed below the processing line line 120, and the ADSS cable 140 is installed below the power line 130. The ADSS cable 140 is fixed to the ultra-high voltage pylon 110 for power transmission by the flax rod 150.

As shown in FIG. 1, the ADSS cable 140 installed in the ultra-high voltage pylon 110 for power transmission has an electric field near a dead end of the cable installed at the end of the steel tower 110 and the earth and the ADSS cable 140. By bending in the horizontal direction under the influence of 150, the electric field strength between the droplets and the droplets charged with the tip of the amarrod 150 due to rain or dew containing ions from salt or pollution causes insulation breakdown of air. There is a problem that the coating damage caused by the free electrons.

The technical problem to be achieved by the present invention is that the electric field near the dead end of the ADSS cable installed in the high-voltage pylon for transmission is bent in the horizontal direction under the influence of the steel tower and the earth and the end of the ADSS cable (including rod) Flax rod made of high-resistance insulator to prevent cladding damage caused by free electrons of flax rod when the end of flax rod and the drop electric field strength exceed the insulation breakdown value of air due to rain or dew containing ions caused by pollution or pollution. In providing.

1 shows a state where the ADSS cable is installed in the pylon.

Figure 2 shows the position of the image charge by the steel tower and the ground and origin according to the installation position of the ADSS cable.

Figure 3 shows the size of the electric field according to the installation position of the ADSS cable.

Fig. 4 shows the tracking of the ADSS cable sheath by the horizontal electric field of the flax rod portion of the ADSS cable.

Figure 5 shows that the electric field is formed by the charging of the water containing the brine or ions on the ADSS cable surface.

Figure 6 shows the flax rod of insulating material to prevent tracking of the ADSS cable according to the present invention.

The flax rod for supporting the ADSS cable according to the present invention for solving the above technical problem is in the flax rod for supporting the ADSS cable to install the ADSS cable in a high-voltage pylon for transmission, the flax rod for supporting the ADSS cable In order to bend the end of the ADSS cable is characterized by being a high resistance insulator wrapping.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First, the electric field according to the installation position of the ADSS cable when the ADSS cable is installed in the transmission high voltage pylon will be described.

Figure 2 shows the electric field according to the installation position of the ADSS cable.

The electric field of P1 is expressed as the sum of the electric field of + Q charge by the power line and the image charge by the pylon (-Q1) and the earth (-Q2) and the origin (+ Q). The electric field at the end of the ADSS cable is bent in the horizontal direction by the metal of the pylon, the ground and the device of the dead end of the ADSS cable. The magnitude and direction of the electric field at the ADSS cable installation location is expressed as the sum of the integrals of the line lengths of the power lines.

Referring to Figure 3 to obtain the size and direction of the electric field according to the ADSS cable installation position as shown in Equation 1.

here, r ; Distance between Pylon and P1 Point l ; Distance from point P1 to the end of the power line

h ; Height between power line and ADSS cable ρ _l ; Charge density

R ² = h ² + l ² = h ² (1 + sec ² θ) = h ² tan ² θ

l = hsecθ dl = htan ² θdθ

span : Overall length of power line between pylon and pylon

4 shows the electric field from the power line ( ) Is influenced by pylon / ground / flax rods and varies in direction and size along the ADSS cable surface axis.

The tracking of the ADSS cable sheath proceeds by the horizontal electric field of the armor rod portion.

Figure 5 shows that the electric field is formed by the charging of the water containing the brine or ions on the ADSS cable surface.

Electric field of part A ) Is determined by the concentration of ions (curvature radius) and the curvature and spacing of the ends of the flax rod (510). And amarods 510 formed in a space of several minutes by a power line It is represented by the vector sum of and.

If the electric field exceeds the dielectric breakdown strength of the air, the inflow of free electrons in the metal body damages the ADSS cable 520 sheath.

Electric field of part B ) Size and direction are determined by the shape of the moisture (curvature radius) and the separation distance for several minutes of ion concentration. Formed in a space of several minutes by a power line It is represented by the vector sum of and.

If the electric field exceeds the dielectric breakdown strength of the air, as in the case of the rod 510, there is no inflow of free electrons, but an electrostatic phenomenon occurs.

In order to solve the problem as described above will be described with reference to FIG.

Figure 6 shows the flax rod of insulating material to prevent tracking of the ADSS cable according to the present invention.

The flax rod according to the present invention is a high resistance insulator which wraps around the end of the ADSS cable to prevent tracking of the ADSS cable. As the high resistance insulator, plastic, rubber and metal materials coated with plastic or rubber are used.

The electric field near the dead end of the ADSS cable installed in the transmission high voltage pylon is bent horizontally under the influence of the end of the ADSS cable including the steel tower, the earth, and the flax rod to contain ions from salt or pollution. In order to prevent coating damage caused by free electrons on the flax rod when the flax end of the flax and the drop electric field strength exceed the insulation breakdown value due to rain / dew, etc. Connect the ADSS cable.

The insulator is made of insulator material to fix the ADSS cable, so there is no inflow of free electrons in case of breakdown of air under high electric field such as in case of metal amarrod, preventing damage of ADSS cable sheath.

In other words, the use of an insulating flax rod eliminates the strong field concentration phenomenon at the end of the flax rod as in the case of using a metallic material. In addition, since there are no free electrons as in the case of metal materials, the effect on the coating during insulation breakdown is insignificant.

Therefore, by using the flax rod of the insulating material for preventing the tracking of the ADSS cable according to the present invention shown in Figure 6 using the flax rod 510 shown in Figure 6, the water containing salt or ions on the ADSS cable surface In this case, even if the electric field due to the charging exceeds the dielectric breakdown strength of the air, free electrons are not introduced by the flax rod, so that the ADSS cable sheath can be prevented.

According to the present invention, by using a high-resistance flax rod at the end of the ADSS cable, it is possible to prevent damage to the ADSS cable sheath due to the inflow of free electrons, thereby ensuring long-term reliability.

Claims (5)

In the flax rod housing the ADSS cable to prevent ADSS cable tracking under high pressure, Said flax rod is The ADSS cable tracking prevention flax rod, characterized in that the high-resistance insulator wraps around the end of the ADSS cable in order to prevent the ADSS cable tracking under the high system of the ADSS cable. 2. The ADSS cable tracking preventing flax rod of claim 1, wherein the high resistance insulator is plastic. The ADSS cable tracking flax rod according to claim 1, wherein the high resistance insulator is a rubber material. The ADSS cable tracking flax rod according to claim 1, wherein the high-resistance insulator is formed by coating a metal with plastic. 2. The ADSS cable tracking preventive flax rod according to claim 1, wherein the high resistance insulator is coated with rubber.