JP3359252B2 - Overhead transmission line - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overhead transmission line in which a flash accident caused by mutual approach between lines is prevented.

[0002]

2. Description of the Related Art As shown in FIG. 4, an overhead power transmission line generally comprises a tower 20 having a tower arm 10 and electric wires 30 installed on the tower arm 10 of the tower 20. One line of electric wire 30A is installed on one side of the tower arm 10 of the tower 20, and another line of electric wire 30B is installed on the other side of the tower arm 10. The electric wire 30A of one circuit is composed of electric wires 31, 32, and 33 of different phases, and the electric wire 30B of the other circuit is also an electric wire 3 of a different phase.
5, 36, and 37. In FIG. 4, reference numeral 40 denotes a series of insulators, and reference numeral 45 denotes a jumper wire.

In the above overhead transmission line, 1
Wires 31 and 3 of different phases constituting the wire 30A of the circuit
There is a problem that an inter-phase short-circuit accident easily occurs between the wires 2 and 33 or between the wires 35, 36 and 37 of different phases constituting the wire 30B of the other line.

Conventionally, therefore, an inter-phase spacer 50 is provided between wires 31, 32, 33 of different phases constituting one wire 30 A, and wires 35, 36, 37 of different phases constituting another wire 30 B are conventionally provided. Also interphase spacer 50
Is installed to prevent a short circuit accident between each phase.

[0005]

However, as described above, the inter-phase spacer 50 is attached between the wires 31, 32, and 33 of different phases constituting one wire 30A, and the different wires 30B constituting the other wire are formed. Phase electric wire 35,
In the overhead power transmission line where the interphase spacer 50 is also mounted between 36 and 37, when a strong crosswind blows, the electric wire 30A of one circuit and the electric wire 30B of the other circuit respectively oscillate. There was a problem that a flashover accident was likely to occur between the lines when approaching each other. In particular, as the interphase spacer 50, a polymer insulator having a structure in which an FRP rod is used as a core material, silicon rubber, ethylene propylene rubber, or the like is molded around the outer periphery of the FRP rod to form an insulating fold and both ends of the FRP rod are provided with electric wire grippers. When the polymer insulator is used, since the polymer insulator is lightweight, the electric wire 30A of one line and the electric wire 30B of the other line are liable to sway, respectively. Therefore, the electric wires between the lines are close to each other and flash between the lines. This causes a problem that a collision accident is likely to occur.

[0006]

SUMMARY OF THE INVENTION The present invention provides an overhead transmission line which solves the above-mentioned problems, and has an overhead transmission line in which interphase spacers are attached to wires of different phases constituting one circuit. In the transmission line, a counterweight for preventing lateral runout is loosely attached to one or more of the electric wires of the different phases.

As described above, when a counterweight for preventing horizontal runout is attached to one or more phases of wires of different phases, the wires of each line are less likely to generate horizontal runout even when a strong crosswind is blown, and the lines between the lines are hardly affected. Can be prevented.

Further, when a plurality of counterweights are dispersedly attached to the electric wire constituting one circuit, one counterweight is reduced in weight, so that the counterweight is less likely to act as a concentrated load on the electric wire, Further, the total weight Wx of the plurality of counterweights attached to the electric wire forming one circuit is substantially equal to or greater than a value obtained by subtracting the weight Wc of the one-phase electric wire from the wind pressure Pw acting on the one-phase electric wire. When the weight is set, the lateral deflection of the electric wire can be effectively prevented.

[0009]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram of the present invention. This overhead power transmission line is composed of a tower 20 having a tower arm 10 and an electric wire 30 installed on the tower arm 10 of the tower 20. One line is provided on one side of the tower arm 10 of the tower 20. An electric wire 30A is installed, and another wire 30B is installed on the other side of the tower arm 10. One electric wire 30A is a different-phase electric wire 3B.
1, 32, and 33, and other electric wire 3
0B is composed of electric wires 35, 36, and 37 of different phases, and an inter-phase spacer 50 is attached between electric wires 31, 32, and 33 of different phases that constitute the electric wire 30A of one circuit, and an electric wire of another line is used. The inter-phase spacer 50 is also attached between the electric wires 35, 36, and 37 of different phases constituting the electric wire 30B to prevent a short circuit accident between the respective phases, which is the same as the conventional configuration.

In the present invention, of the wires 31, 32, 33 of different phases constituting one wire 30A, the wire 3
1 and counterweight 60 for electric wire 33
It is characterized in that, among the electric wires 35, 36, and 37 of different phases constituting the electric wire 30B of the other line, a counterweight 60 for preventing horizontal runout is also attached to the electric wire 35 and the electric wire 37.

Counterweight 60 for preventing lateral runout
As shown in FIG. 2A and FIG. 2B, the electric wire gripper 61 includes an electric wire gripping portion 61 and a weight portion 65 formed below the electric wire gripping portion 61. The electric wire gripping portion 61 includes a hinge portion 62
Is provided with a movable piece 63 rotatably formed through the. The electric wire gripping portion 61 is fixed by a bolt 64 after the electric wire 30 is gripped by the movable piece 63.
In the embodiment, a split collar 70 is attached to the outer periphery of the electric wire 30, and the electric wire grip 61 is loosely attached to the outer periphery of the collar 70. As described above, when the wire gripping portion 61 is loosely attached to the outer periphery of the collar 70, the wire 30
Is twisted freely, so that there is an advantage that unreasonable stress does not act on the electric wire 30. In addition, the wire gripping portion 61 has a collar 7
Since the wire 30 is in contact with the outer circumference of the wire 30, the wire 30 is not damaged.

As described above, of the electric wires 31, 32, and 33 of different phases constituting one electric wire 30A, the counterweight 60 for preventing the horizontal runout is attached to the electric wires 31 and 33, and the other electric wire 30B. Of the electric wires 35, 36, and 37 constituting the different phases, when the counterweight 60 for preventing the lateral vibration is attached to the electric wire 35 and the electric wire 37, the electric wire of each line vibrates when a strong crosswind blows. It becomes difficult. Therefore, a flash accident between lines can be reliably prevented. In addition, by using a plurality of counterweights 60, one counterweight can be reduced in weight, so that the counterweight does not act as a concentrated load on the electric wire.

The total weight Wx of the counterweight 60 attached to the one-line electric wire should be substantially equal to or greater than the weight obtained by subtracting the weight Wc of the one-phase electric wire from the wind pressure load Pw acting on the one-phase electric wire. Is preferred. That is, when a one-phase electric wire is considered, if the wind pressure load Pw acting on the one-phase electric wire is smaller than the sum of the total weight Wx of the counterweight 60 and the weight Wc of the one-phase electric wire, the electric wire hardly swings. Become. Therefore, when considering a one-phase electric wire, the total weight Wx of the counterweight 60 is substantially equal to or smaller than a value obtained by subtracting the weight Wc of the one-phase electric wire from the wind pressure load Pw acting on the one-phase electric wire. It would be preferable to make it larger.

By the way, since one line usually has three phases,
In order to prevent lateral deflection of the three-phase electric wire, a total weight substantially equal to a value obtained by subtracting the weight Wc of the one-phase electric wire from the wind pressure load Pw acting on the one-phase electric wire is used. It is most preferable to attach the respective counterweights 60 to the electric wires of each phase.

However, as described above, if the counterweight 60 is attached to the electric wires of each phase so that the electric wires of each phase do not sway, the strength of supporting the tower may be affected. Therefore, as a result of various studies, the total weight Wx of the plurality of counterweights attached to the electric wire forming one circuit is substantially equal to the weight obtained by subtracting the weight Wc of the one-phase electric wire from the wind pressure load Pw acting on the one-phase electric wire. It has been found that it is possible to effectively prevent the electric wire from swaying. That is, since the electric wires of each phase constituting one circuit are connected by the inter-phase spacer, if a counterweight having a total weight Wx sufficient to stop the lateral vibration of the one-phase electric wire is attached, one circuit is constituted. It became clear that the electric wires of each phase interfered with each other and the overall run-out could be reduced.

The total weight Wx of a plurality of counterweights attached to an electric wire constituting one line is more effective in preventing lateral deflection as the counterweight is heavier, but the upper limit is restricted in relation to the strength of the tower. . In order to prevent the lateral deflection of the electric wire that constitutes one circuit within a range that does not affect the strength of the tower and with the minimum weight, the total weight Wx of the plurality of counterweights attached to the electric wire that constitutes one line is set to 1 It is preferable to make the weight substantially equal to the weight obtained by subtracting the weight Wc of the one-phase electric wire from the wind pressure load Pw acting on the electric wire of the phase.

For example, when a steel core aluminum stranded wire having a nominal cross-sectional area of 810 mm ² is installed in a span of 400 m, the total weight of the counterweight is calculated as follows. Pw = a × C × D × S = 1 × 100 × 0.0384 × 4
00 = 1536 kg Wc = wc × S = 2.7 × 400 = 1080 kg Wx = Pw−Wc = 1536−1080 = 456 kg where Pw = wind pressure load (kg) a = constant 0.9 to 1.0 C = constant 100 (Kg / m ² ) D = wire diameter (m) S = span length (m) Wc = weight of one-phase wire (kg) wc = weight per unit length of one-phase wire (kg / m) S = span length Wx = total weight of counterweight If the weight of one counterweight is reduced to about 15kg which does not act as a concentrated load on the wire, 3
Zero counterweights are required, and the counterweights are distributed and attached to the electric wires constituting one circuit.

In FIG. 1, reference numeral 80 denotes an inter-line spacer attached to an electric wire between lines. The inter-line spacer 80 has a structure in which an FRP rod is used as a core material, an insulating fold is provided by molding silicone rubber, ethylene propylene rubber, or the like on the outer periphery thereof, and an electric wire grip is provided at both ends of the FRP rod. . If the wires between the lines are connected by using such an inter-line spacer 80, a flashover accident between the lines can be more reliably prevented as compared with the case where only the counterweight 60 for preventing the lateral vibration is used. There is an advantage that can be. In particular, when the length of one span is long, the inter-line spacer 8 together with the counterweight 60 for preventing lateral runout is used.
When 0 is used together, a flashover accident between lines can be effectively prevented.

The shape of the counterweight used in the present invention is not particularly limited.
(A) As shown in (b), a counterweight 60 for preventing horizontal run-out, which is composed of a wire gripping portion 61 and weight portions 65 provided on both sides of the wire gripping portion 61, may be used. . Counterweight 6 for preventing this sideways shake
Numeral 0 indicates that the electric wire is gripped by the electric wire gripping portion 61 so that the weight portions 65 provided on both sides are horizontal and used. The counterweight 60 for preventing the lateral runout has the advantage that the center of gravity substantially coincides with the axis of the electric wire, so that the counterweight 60 does not swing like a pendulum, and therefore less induces galloping in the electric wire. There is. The position of the electric wire to which the counterweight is attached is not particularly limited. For example, all the electric wires of different phases constituting one electric wire or only one electric wire may be used. Further, the number of counterweights attached to the one-phase electric wire is not particularly limited. further,
The wire gripping portion of the counterweight may or may not be used with a split collar. Furthermore, the inter-line spacer may be used as needed, and may not be used.

[0020]

As described above, the overhead power transmission line according to the present invention is an overhead transmission line in which interphase spacers are attached to wires of different phases. The counterweights are loosely mounted, so that even if strong crosswind blows, the wires of each line are less likely to sway, and a flashover accident between the lines can be effectively prevented.

Further, when a plurality of counterweights are dispersedly attached to the electric wire constituting one circuit, one counterweight is reduced in weight, so that the counterweight is less likely to act as a concentrated load on the electric wire, Further, the total weight Wx of the plurality of counterweights attached to the electric wire constituting one circuit is substantially equal to or greater than a value obtained by subtracting the weight Wc of the one-phase electric wire from the wind pressure load Pw acting on the one-phase electric wire. The weight can effectively prevent the wire from swaying.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of an overhead power transmission line according to the present invention.

FIGS. 2A and 2B show a counterweight for preventing horizontal runout used in the present invention, wherein FIG. 2A is a front view of a main part, and FIG.

FIGS. 3A and 3B show a counterweight for preventing lateral runout used in the present invention, wherein FIG. 3A is a plan view and FIG. 3B is a side view.

FIG. 4 is a schematic configuration diagram of a conventional overhead transmission line.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 Iron tower arm 20 Iron tower 30 Electric wire 30A One line electric wire 30B Other line electric wire 31, 32, 33 One line different phase electric wire 35, 36, 37 Other line different phase electric wire 50 Interphase spacer 60 Counter weight 70 Color 80 Spacer between lines

Claims (2)

(57) [Claims] 1. A 1 line overhead power transmission line interphase spacer wires different phases composing is attached to, mounted counterweight for lateral oscillation preventing loosely to the different phases of one or more phase wires of the wire An overhead power transmission line. 2. A plurality of counterweights are dispersedly attached to an electric wire constituting one circuit, and a total weight Wx of the plurality of counterweights is calculated from a wind pressure load Pw acting on a one-phase electric wire. The overhead transmission line according to claim 1, wherein the weight is substantially equal to or greater than a weight obtained by subtracting a weight Wc of the one-phase electric wire.