KR100836641B1 - Supporting bar for electric pole - Google Patents

Abstract

A cross arm for an electric pole is provided to reduce impact on an insulator to support a cable by uniformly maintaining tension of the cable to prevent swing of the cable due to strong wind. A cross arm for an electric pole includes a motor(400), an insulator rotating plate(600), a ring, a control unit(300), a storage battery(700), and a solar panel(800). The motor is installed on the cross arm to rotate a rotation axis. The insulator rotating plate rotates by rotation of the rotation axis and is cut in a U shape. Both ends of the insulator rotating plate face a rotation direction. The ring is movably engaged along an insulator fixing groove to fix an insulator. The control unit has a temperature sensor(100) to measure ambient temperature and controls driving of the motor to rotate the insulator rotating plate according to a tension change of a cable. The storage battery supplies power to the motor and the control unit. The solar panel performs photovoltaic generation to charge the storage battery.

Description

Jeonju distribution bar for electric wire connection supporting wire {Supporting bar for electric pole}

The present invention is a wire rod for supporting the distribution type overhead wire of the pole, more specifically, to support the distribution wire fluidly, and to maintain a constant tension of the wire against expansion and contraction of the distribution wire according to temperature changes The present invention relates to a cast iron for supporting the distribution type overhead wire of Jeonju.

The electric wire installed in the conventional telephone pole repeats expansion and contraction according to the season. As the temperature drops, the wire contracts and hangs tightly on the poles at both ends. On the contrary, when the temperature rises, the electric wire expands and falls on the telephone poles of both ends. If the wire is stretched on the telephone pole, it will not look good and the strong wind will cause the stretched wire to move. If the sagging wire is constantly moved by strong winds, the insulator supporting the wire may be impacted, causing the insulator to break or cause an accident that can lead to the insulator. Breakage of the insulators prevents the smooth supply of electricity, which can lead to an interruption in the area where the accident occurred. In addition, residents living in the area where the accident occurred can not use the electricity until the maintenance work proceeds, it is not possible to use a variety of electronic devices and electrical devices driven by electrical energy.

Therefore, the problem to be solved by the present invention is to support the distribution wires and to support the distribution wires of the distribution type overhead wires for maintaining the tension of the wires in preparation for expansion and contraction of the distribution wires due to temperature changes To provide.

In order to achieve the above object, the present invention, in the wrought iron supporting the wire through the insulator, a motor having a rotating shaft rotatably installed on the wrought iron; An insulator rotating plate engaged with a rotating shaft of the motor and having an insulator fixing groove in which both ends of the citron shape are disposed in a rotational direction; An insulator connected through a hook which is hung and movable along the insulator fixing groove; The control unit measures the temperature of the surrounding environment by the temperature sensor, checks the tension change of the wire corresponding to the temperature measured by the temperature sensor, and controls the rotation of the insulator rotating plate by driving the motor according to the confirmed tension of the wire. Wow; A storage battery for supplying power to the motor and the controller; It provides a cast iron for supporting the distribution-type overhead wire of the pole including a solar panel for photovoltaic power generation to charge the storage battery.

According to the present invention, the tension of the wire is kept constant in preparation for expansion and contraction of the distribution wire, thereby eliminating the sagging of the wire between the wire poles, and preventing the shaking of the wire due to strong wind, which is applied to the insulator supporting the wire. It has the effect of alleviating the impact of losing.

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

However, embodiments of the present invention illustrated below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the invention are provided to more fully illustrate the invention to those skilled in the art.

Figure 1 is an exemplary view showing the configuration of a wrought iron for distribution type overhead wire connection support according to an embodiment of the present invention.

Wrought iron includes the function of maintaining the tension of the wire in accordance with the ambient temperature in supporting the wire through the insulator.

The function of keeping the tension of the wire constant according to the temperature of the surrounding environment is achieved by the operation of the control unit 300, the motor 400, and the insulator rotating plate 600.

The input unit 200 receives the length value of the wire and transfers the length value of the wire to the controller 300.

The controller 300 previously stores the tension change data of the wire that is changed according to the length of the wire, and refers to the tension change data of the wire that is stored in advance corresponding to the length value of the wire input by the input unit 200.

The controller 300 receives a temperature value measuring the temperature of the surrounding environment from the temperature sensor 100, detects a tension change of the wire corresponding to the input temperature, and determines the driving amount of the motor according to the tension change of the wire. do.

The temperature sensor 100 measures the temperature of the surrounding environment and transmits the measured temperature value to the controller 300. The controller 300 detects a change in tension of the wire corresponding to the temperature value measured by the temperature sensor 100. The tension change of the wire depends on the temperature change of the environment where the wire is installed. When the temperature decreases, the wire contracts and the tension of the wire becomes stronger. On the contrary, when the temperature increases, the wire expands and the tension of the wire becomes weak.

The controller 300 detects the tension change of the wire according to the measured temperature change and calculates the rotation amount of the motor 400 according to the tension change of the wire. The controller 300 determines the amount of rotation of the motor 400 by referring to the data written in the lookup table based on the amount of rotation of the motor 400 according to the tension of the wire. The lookup table stores the rotation amount of the motor 400 according to the change in tension of the wire supported by the pole.

The controller 300 rotates the motor 400 by the determined amount of rotation of the motor 400 to rotate the insulator rotating plate 600 rotated by the motor 400 counterclockwise. When the insulator rotating plate 600 rotates in a counterclockwise direction, the insulator fixed to the insulator rotating plate 600 through a ring moves toward the rotation axis of the insulator rotating plate 600 to pull the wire connected to the insulator to compensate for the sagging of the wire.

The controller 300 drives the motor 400 while correcting the rotation amount of the motor 400 by referring to the position value measured by the position sensor (not shown) of the rotation amount of the motor 400 to insulate the rotation plate ( 600) to be in the correct position.

The storage battery 700 supplies power to the control unit 300, the motor 400, and various electrical components so that electrical energy is supplied to various electrical components constituted of wrought iron.

The solar panel 800 generates photovoltaic power and generates electrical energy, and supplies the generated electrical energy to the storage battery 700.

2 is a perspective view showing a pole in accordance with an embodiment of the present invention.

The control box 900, the solar panel 800, the motor 400, the insulator rotating plate 600, the ring 620 and the insulator 630 are installed on the wrought iron 20 installed to protrude horizontally from the pole body 10. It is composed.

The control box 900 is equipped with a control unit and a storage battery. The substrate of the control unit includes a temperature sensor and an input unit.

The solar panel 800 is horizontally installed on the wrought iron 20 to supply the various electrical components in the control box 900 to control the electrical energy generated by photovoltaic power generation.

The motor 400 is installed at the end of the wrought iron 20 and is interlocked with the rotating shaft of the insulator rotating plate 600. The motor 400 and the insulator rotating plate 600 are engaged to allow the insulator rotating plate 600 to rotate counterclockwise by the rotational movement of the motor 400. The motor 400 includes a position sensor so as to detect the rotational position of the insulator rotating plate 600.

The insulator rotating plate 600 includes an insulator fixing groove 610 in which both ends of the citron form are disposed in the rotation direction. The insulator 630 is connected to the insulator fixing groove 610 via a ring 620 that is hung and movable along the groove. When the insulator rotating plate 600 rotates, the ring 620 located in the insulator fixing groove 610 moves close to the rotation axis of the insulator rotating plate 600.

3 is an exemplary view showing a moving position of the ring as the insulator rotating plate rotates according to an embodiment of the present invention.

The rotational position of the ring 620 is shown as the insulator rotating plate rotates. In FIG. 3A, the rings 620 are positioned at both ends of the insulator fixing groove 610. When the rings 620 are located at both ends, the temperature of the surrounding environment is the lowest.

3 (b), (c), (d) shows that the position of the ring 620 is changed as the insulator rotating plate rotates. When the insulator rotating plate rotates counterclockwise, the ring 620 moves along the insulator fixing groove 610. As the insulator rotating plate rotates, the ring 620 moves closer to the axis of rotation to pull the insulator connected to the ring 620. Pulling the insulator will pull the wires connected to the insulator.

FIG. 3E illustrates the position of the ring 620 when the insulator rotating plate rotates about half a turn in the counterclockwise direction. If the material of the ring 620 is not bent in the metal ring 620 is in contact with each other is placed in a position that can no longer rotate. In other words, the insulator rotating plate is in a position that should no longer rotate.

In FIG. 3 (f), a case in which the insulator rotating plate rotates more than half a turn will be described. If the material of the ring located in the insulator fixing groove 610 of the insulator rotating plate is a metal, the insulator rotating plate is placed in a position where it can be damaged. In addition, damage to the motor and the rotating plate may occur.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical details of the appended claims.

Figure 1 is an exemplary view showing the configuration of a wrought iron for distribution-type overhead wire connection support according to an embodiment of the present invention.

2 is a perspective view showing a pole in accordance with an embodiment of the present invention.

3 is an exemplary view showing a moving position of the ring as the insulator rotating plate rotates in accordance with an embodiment of the present invention.

Explanation of terms for the main parts of the attached drawings

100: temperature sensor 200: input unit

300: control unit 400: motor

600: insulator rotating plate 700: storage battery

800: solar panel

Claims (1)

In the perfect steel which supports the electric wire through the insulator, A motor installed on the wrought iron and rotating a rotating shaft; An insulator rotating plate rotating in the rotation of the rotating shaft and having an insulator fixing groove formed in an incision in a 'U' shape and disposed at both ends thereof in a rotational direction; A ring configured to movably engage along an insulator fixing groove to fix the insulator; A control unit having a temperature sensor for measuring a temperature of the surrounding environment, checking a tension change of the wire corresponding to the measured temperature, and controlling driving of the motor so that the insulator rotating plate rotates according to the checked tension change of the wire; A storage battery for supplying power to the motor and the controller; And Solar panels for photovoltaic power generation to charge storage batteries; Wrought iron for distribution-type overhead wire connection support including a pole.

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