KR100978139B1 - Power cable tension maintenance apparatus for transmission tower - Google Patents

Abstract

PURPOSE: A device is provided to uniformly maintain the tension of a line by automatically compensating the deflection of a line due to the weather or external factors. CONSTITUTION: A drive unit(110) comprises a body(111), a drive motor, a screw(114), two spreading bars(115), a moving body, a connecting member, and a connecting wire. The body is fixed to the arm of a pylon. The screw is driven with the drive motor. Two spreading bars are rotatably fixed to the body. The connecting member interlinks the moving body and the spreading bars. The connecting wire interlinks the bars and an insulator. A tension detection unit(130) measures the tension of a transmission line. A controller drives the driving unit according to the detecting information of the tension detection unit.

Description

Power cable tension maintenance apparatus for transmission tower

The present invention relates to a line tension maintaining device for transmission and distribution pylon, and more particularly, to automatically correct the tension of the transmission and distribution tower for the transmission and distribution tower to maintain a constant tension in response to the sagging phenomenon caused by the tension change automatically. It relates to a line tension maintaining device for transmission and distribution steel tower.

In general, the shape of the steel tower used as a support for transmission and distribution lines depends on the transmission power, voltage, and terrain of the line, and may be as high as 60 m.

The main material is steel with a cross section of L-shape, and the horizontal cross section is often square, so the foundation is also made by concrete solidifying at the square apex.

The towers of transmission and distribution lines usually support three-phase, two-wire or six wires with insulators. The distance between the towers is 20 to 30 m, and the minimum height from the surface of the wires installed on the tower is the electrical equipment. It is decided by technique and, for example, it is 6m in the case of 150,000V track.

In general, when crossing a wide river or deep valley, the span is long, and thus the tension of the wire is increased, so a particularly strong structure is required.

Even for transmission and distribution lines, there are iron poles that are built on a single foundation as a support for small scales or telephone lines.

These transmission and distribution line pylons connect a plurality of transmission and distribution lines to each other, and these transmission and distribution lines are installed under conditions where vibrations or amplitudes are likely to occur due to climatic effects such as wind or snow rain due to the characteristics of being installed at high altitudes. .

Therefore, after a certain period of time, the transmission line is sag, and when strong winds blow, the transmission lines are shaken up and down severely, causing friction with each other. This phenomenon causes large safety accidents such as short circuits or short circuits. It caused the occurrence.

Therefore, conventionally, in order to solve such a problem, the maintenance work that periodically adjusts the tension of the transmission line was taken to cope with the problem of the above-mentioned safety accident due to the sagging of the transmission line.

However, the above-mentioned method has to be accompanied by power cuts, but as a result of the inconvenience, power generation generations have caused great inconveniences and inconveniences.

The present invention was created to solve the above problems, and when the deflection occurs on the tracks extending between the transmission and distribution towers due to seasons or other external factors, the small distribution to automatically detect this and maintain the appropriate tension It is an object of the present invention to provide a line tension maintaining device for a steel tower.

The line tension maintaining device for transmission and distribution pylon according to the present invention for achieving the above object is provided with a body installed on a support plate fixed to the steel tower, one end is spaced apart from each other at a predetermined interval and vertically installed on the body Two openings that are rotatably mounted about the rotation pin and the other end of which extends a predetermined length in a direction away from the body, a screw extending from the body to pass between the openings, and having a screw thread formed on an outer circumferential surface thereof; The drive motor is installed in the inside of the drive motor for forward and reverse rotation, and a bolt hole penetrating the front and rear surfaces so that the screw can be screwed in the center is formed, the rotating groove drawn in from the end at both ends The movable body and a sliding hole through which the opening is formed are formed to slide along the opening. Two bodies coupled to each opening to allow yiding, and each of the movable body extending from the respective body to both rotating grooves of the movable body, rotatable about a second rotary pin penetrating the upper and lower surfaces of the movable body A drive unit including two connection members including a hinge plate coupled to the connection plate, two connection wires extending from the insulator connected to the transmission line and connected to ends of the openings, and between the steel towers. And a tension sensing unit for sensing a deflection state and a control unit for driving the driving motor according to the tension state of the transmission and distribution line measured by the tension sensing unit, wherein the tension sensing unit is installed on the body and irradiates light having straightness. A light irradiator and a first light receiver capable of receiving light, the control unit and the signal An optical signal main module connected to the moon, a second receiver configured to be installed in an adjacent pylon connected to the steel tower on which the body is installed, and the measurement target power distribution line, and receiving light emitted from the light irradiator; 2 in the center of a transmission and distribution line connected between an optical signal auxiliary module including a wireless transmitter for wirelessly transmitting sensing information of the light receiver to the controller through an RF signal, and a steel tower in which the body is installed and a steel tower in which the auxiliary module is installed; It is fixedly positioned so that the light irradiated from the light irradiator can be reflected upwards so that the light irradiated from the light irradiator is not received by the first and second light receivers while the transmission line is maintained at an appropriate tension. The reflection surface is formed to be inclined and the lower portion of the first reflection portion is formed so that the transmission line is too tight The light irradiated from the light irradiator is incident, and includes a light reflecting module including a second reflector having a reflective surface is formed so that the incident light is reflected by the first light receiver.

The light reflection module surrounds a transmission and distribution line, a cylindrical body having a plurality of protrusions and protrusions formed on the inner circumferential surface to prevent sliding along the transmission distribution line, and extends radially on the outer circumferential surface of the cylindrical body along a longitudinal direction. A base part including two stoppers spaced apart from each other by a predetermined distance, and rotatable along the circumferential direction of the cylindrical body between the stopper so as to be prevented from being separated by the stopper, and in contact with the outer peripheral surface of the cylindrical body. A plurality of rollers to facilitate rotation on the inner circumferential surface are provided with a plurality of rotary ring members spaced apart from each other along the circumferential direction, and a light reflection provided on the rotary ring member and including the first and second reflecting portions. And a weight member provided below the rotary ring to maintain the light reflection portion standing upright. It is desirable to.

The line tension maintaining device for transmission and distribution steel tower of the present invention can automatically prevent the occurrence of line sag and pull the line so that the line can be maintained at an appropriate tension, thereby effectively preventing short circuit or short circuit caused by sagging line. .

In addition, when pulling one end of the line to maintain the tension of the line, there is an advantage that the line can be safely maintained by preventing the line from being pulled too much.

1 is a perspective view showing an embodiment of a line tension maintaining device for transmission and distribution steel tower according to the present invention,
2 is an exploded perspective view of FIG. 1;
3 is a plan view showing a tension control process of the line through the line tension maintaining device for transmission and distribution steel tower,
4 is an exploded perspective view showing the light reflection module of FIG. 1;
5 is a conceptual diagram showing a tension sensing support through the tension sensing unit of FIG.
6 is a block diagram showing the driving relationship of the line tension maintaining device for transmission and distribution steel tower of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail the line tension maintaining device (hereinafter referred to as "tension holding device") for transmission and distribution steel tower according to the present invention.

1 to 5, the tension maintaining apparatus 100 according to the present invention is to maintain the transmission line 10 extending between the steel towers at an appropriate tension, the one side of the pylon is connected to the transmission line 10 The control unit 170 for driving the drive unit 110 is installed in accordance with the sensing unit 130, the tension sensing unit 130 for measuring the tension of the transmission and distribution line 10, the tension sensing unit 130 is installed. ).

The drive unit 110 is connected to the insulator 20 installed at one end of the transmission and distribution line 10 to adjust the tension of the transmission and distribution line 10 by advancing the insulator 20, the arm 30 of the steel tower A body 111 fixed to the body, a drive motor 113 installed on the body 111, a screw 114 driven by the drive motor 113, and two openings rotatably installed on the body 111. The base 115, the movable body 118 screwed to the screw 114, the connecting member 122 for connecting the movable body 118 and the opener 115, the opener 115 and the insulator 20 It includes a connection wire 117 for connecting.

As described above, the body 111 is fixed to the arm 30 of the steel tower, and a mounting space in which the driving motor 113 is mounted is formed. And for convenience, if the end toward the transmission line 10, which is the tension adjustment target, the front, two mounting grooves 112 are formed in the front to rotatably couple the opening (115) to be described later.

The drive motor 113 is installed inside the body 111 and is driven by the controller 170 to be described later, it is preferable that a DC motor capable of both forward and reverse rotation is applied.

The screw 114 is connected to the drive shaft of the drive motor 113 to be rotated by the drive motor 113, and extends a predetermined length forward through the front surface of the body 111. The screw 114 is formed with a screw thread so that the forward or reverse rotation is performed by the driving motor 113.

Two openings 115 are installed at the front of the body 111 to be spaced apart from each other by a predetermined distance, one end is coupled to the mounting groove 112 provided in the body 111. And it is possible to rotate around the vertical first rotating pin 116 penetrating one end of the body 111 and the opening (115).

Opening band 115 extends toward the front of the body 111, the other end of the opening 115 is connected to the connection wire 117 is connected to the insulator 20.

The movable body 118 is screwed to the screw 114 is to be advanced along the longitudinal direction of the screw 114 during the rotation of the screw 114, a bolt penetrating the front and rear surfaces so that the screw 114 can pass through A ball 119 is formed, and both side ends are formed with rotation grooves 120 each having a predetermined depth drawn inward from the outer circumferential surface.

The connecting member 122 is to connect the movable body 118 and the open stand 115, the body is inserted into the open stand 115 is formed to be movable along the longitudinal direction of the open stand 115 ( 123 and extending from the body 123 toward the movable body 118, and rotatably connected about a second rotary pin 121 that is vertically installed in the pivoting groove 120 of the movable body 118. Hinge plate 124.

The hinge plate 124 is formed with a through hole 125 into which the second rotary pin 121 is inserted, and the through hole 125 extends the length of the hinge plate 124 extending from the body 123. It is in the form of a long hole extending along a predetermined length.

As described above, the connection wires 117 are connected to the ends of the two openings 115 and are connected to the insulator 20. Therefore, the flank 115 and the connection wire 117 takes a rhombus shape as a whole.

Tension control of the transmission and distribution line 10 by the drive unit 110 is made as follows.

Referring to FIG. 3, when the tension of the transmission and distribution line 10 is insufficient and the transmission and distribution line 10 sags downwards, the driving motor 113 drives the screw 114 to rotate forward, and the screw 114. The rotating body 118 screwed with the screw 114 is reversed toward the body 111 by the rotation of the ().

When the movable body 118 is reversed, the connecting member 122 also proceeds toward the body 111 along the opening base 115, and the opening base 115 eventually moves the moving body 118 and the connecting member 122. As a result, the angle around the body 111 increases.

Therefore, the distance between the ends of the open end 115 connected to the connection wire 117 is far apart from each other, and the connection wire 117 also opens in a direction away from each other. In order to keep the connection wire 117 connected to the opener 115 and the insulator 20, the insulator 20 connected to the transmission and distribution line 10 is pulled toward the body 111. By pulling one end of the generated transmission and distribution line 10 it is possible to adjust the tension.

On the contrary, when the transmission and distribution line 10 is too tight, the driving motor 113 is driven in the reverse rotation direction to rotate the screw 114 to advance the movable body 118 in the direction away from the body 111. By closing the distance between the body 111 and the insulator 20 may be farther away.

The tension detecting unit 130 is for detecting whether the tension of the transmission and distribution line 10 is excessively stretched or the tension is too large and is too tight, and the optical signal main module installed in the body 111. 131, an optical signal auxiliary module 141 installed on the steel tower to which the other end of the transmission and distribution line 10, which is connected to the driving unit 110, and the other end thereof, and the transmission and distribution line 10 to be tension-controlled. It includes a light reflection module 151 installed on.

The optical signal main module 131 includes a module box 132 installed on the upper part of the body 111, a light irradiator 133 and a first light receiver 134 mounted on the module box 132. .

The light irradiator 133 irradiates light having a straightness toward the optical signal auxiliary module 141, and receives the light when the light is reflected from the light reflecting module 151 and returns. The light receiving information is transmitted to the controller 170.

The optical signal auxiliary module 141 is installed on the steel tower on which the driving unit 110 is installed and the other steel tower to which the tension control target power distribution line 10 is connected, and receives a light emitted from the light irradiator 133. 142.

When the light is received by the second receiver 142, a wireless transmitter 143 is provided in the optical signal auxiliary module 141 for transmitting the light reception information to the controller 170.

The light reflection module 151 reflects the light irradiated from the light irradiator 133 so that the light reflection module 151 is installed on the power distribution line 10 so as to detect a tension state of the power distribution line 10.

The light reflection module 151 has a base portion 152 mounted on the transmission and distribution line 10, a rotating ring member 157 rotatably mounted on the base portion 152, and an upper portion of the rotating ring member 157. The light reflecting member 161 is provided, and the weight member 164 provided below the rotating ring member 157.

The base portion 152 material has a cylindrical body 153 surrounding the transmission and distribution line 10, and a stopper 154 protruding in the radial direction to the cylindrical body 153, the cylindrical body 153 is open at one side thereof. In order to surround the transmission and distribution line 10, the inner circumferential surface of the cylindrical body 153 is provided with a plurality of concave-convex protrusions 155 with sharp end portions to be inserted into the cover of the transmission and distribution line 10, thereby providing a cylindrical body 153. Is fixed so as not to move in the transmission and distribution line (10).

The cylindrical body 153 is fixed to surround the transmission and distribution line 10 by the fixing band 156, the mounting of the cylindrical body 153 may be made in various ways in addition to the fixing band 156.

The stopper 154 is formed to extend in the radial direction on the cylindrical body 153, the two is formed in the longitudinal direction of the cylindrical body 153 to be spaced apart from each other at a predetermined interval by the rotary ring member 157 to be described later The cylindrical body 153 is prevented from being separated.

The rotary ring member 157 is rotatably installed on the cylindrical body 153, and has first and second rings 158 and 159 hinged to one side thereof, and the first and second rings 158 and 159 are cylindrical bodies. One annular ring is formed by being interconnected by bolts to enclose 153.

In addition, the inner circumferential surface of the rotary ring member 157 is formed with a plurality of rollers 160 rotating around a rotation axis extending along the longitudinal direction of the cylindrical body 153 to be spaced apart from each other by a predetermined interval along the circumferential direction. The rotation ring member 157 may be easily rotated along the outer circumferential surface of the cylindrical body 153 by the 160.

The light reflection member 161 is provided on the upper portion of the rotating ring member 157, the second reflecting portion 163 extending upward from the rotating ring member 157, and upward from the upper end of the second reflecting portion 163. It has a first reflecting portion 162 extending to.

The second reflecting unit 163 is formed with a reflecting surface capable of reflecting the light of the light irradiator 133 to the first light receiver 134 on one surface exposed toward the light irradiator 133. In other words, the second reflecting unit 163 has a reflecting surface formed such that the incident angle of the light irradiated from the light irradiator 133 may be substantially perpendicular, and the light irradiator 133 may be in a state where the transmission and distribution line 10 is in an excessively tight state. ) Is irradiated from the second reflector 163 and is incident to the first light receiver 134.

The first reflecting portion 162 formed on the upper portion of the second reflecting portion 163 is also formed with a reflecting surface that reflects the irradiated light when light is irradiated from the light irradiator 133. 162 has a height at which light irradiated from the light irradiator 133 can be incident when the transmission and distribution line 10 is maintained at an appropriate tension. Since the reflecting surface is formed to be inclined at a predetermined angle with respect to the irradiation direction of the light irradiated from the light irradiator 133, the first reflector 162 is not received by the first and second light receivers 134 and 142 when light is irradiated. .

The weight member 164 is formed below the rotary ring member 157 and is formed to have a relatively heavy weight than the light reflection member 161.

By the weight member 164, the rotation ring member 157 is formed at the lower center of gravity, and the rotation ring member 157 is rotatably connected to the cylindrical body 153 without being fixed to the light reflection member (to be described later) ( 161 may be located at the top of the transmission line 10 at all times.

 The control unit 170 is installed inside the module box 132, and includes an optical receiver 171 for receiving an RF signal of the wireless transmitter 143 of the optical signal auxiliary module 141. When the light is received by the second light receiver 142 of the module 141, it may be detected. In addition, the driving motor 113 is electrically connected to transmit a driving signal for enabling forward or reverse rotation so that the controller 170 receives the light irradiated from the light irradiator 133 on the first light receiver 134. ) Or the driving motor 113 depending on whether the light is received by the second light receiver 142.

Hereinafter, the driving process of the tension holding device 100 will be described in general.

First, the tension sensing unit 130 periodically detects a tension state of the transmission and distribution line 10.

That is, periodically, the light irradiator 133 of the optical signal main module 131 irradiates light toward the second optical receiver. At this time, when the tension of the transmission and distribution line 10 is maintained at an appropriate level, the deflection height of the transmission and distribution line 10 is reflected by the light of the light irradiator 133 to the first reflecting portion 162 provided in the light reflection module 151. Since it is within the range to be irradiated, the light irradiated from the light irradiator 133 is upwardly reflected by the first reflecting portion 162 having the inclined reflecting surface, and the first light receiver 134 or the second light receiver Light is not received at 142. Therefore, the controller 170 determines that the transmission and distribution line 10 is maintained at an appropriate tension when the light receiving signal is not transmitted from the first light receiver 134 and the second light receiver 142.

When the tension of the transmission and distribution line 10 is excessively excessive and the deflection of the transmission and distribution line 10 occurs a lot, the light reflection member 161 of the light reflection module 151 reflects the light irradiated from the light irradiator 133. You can't descend downward.

In this case, since the light is not reflected, the irradiated light is received by the second receiver 142, and when the light is received by the half-signal auxiliary module 141, the received signal is controlled by the wireless transmitter 143. To be sent. The controller 170 senses this signal and receives the light from the second receiver 142 to drive the driving unit 110 to increase the tension of the transmission and distribution line 10.

In the case where the transmission and distribution line 10 is too tense, the light reflection module 151 is not lowered to an appropriate level, so the light irradiated from the light irradiator 133 is reflected by the second reflector 163. As described above, since the reflective surface of the second reflector 163 is formed to reflect the light irradiated from the light irradiator 133 toward the first light receiver 134, the second reflector 163 may be used. Light reflected from the first light receiver 134 is received. The controller 170 drives the driving unit 110 so that when the light is received by the first light receiver 134, the transmission and distribution line 10 may be loosened.

Thus, the tension maintaining apparatus 100 according to the present invention periodically checks the tension state of the transmission and distribution line 10, and adjusts the tension of the transmission and distribution line 10 to an appropriate level automatically according to the measurement result. This prevents problems from occurring due to excessive tension or looseness of).

100; Tension holding device
110; Drive unit
111; Body 113; Drive motor 114; screw
115; Open stage 117; Connection wire 118; Moving object
122; Connecting member
130; Tension sensing unit
131; Optical signal main module
132; Module box 133; Light irradiator 134; First receiver
141; Optical signal auxiliary module
142; Second receiver 143; Wireless transmitter
151; Light reflection module
152; Base portion 157; Rotary ring member 161; Light reflecting member
164; Weight member
170; Control
171; Wireless receiver

Claims (2)

A body installed on a support plate fixed to the pylon,
Two openings, one end of which is spaced apart from each other by a predetermined distance and rotatably mounted about a rotation pin installed perpendicular to the body, and the other end extending a predetermined length in a direction away from the body;
A screw extending from the body to pass through the opening and having a thread formed on an outer circumferential surface thereof;
A drive motor installed inside the body to rotate the screw forward and reverse;
A bolt hole penetrating the front and rear surfaces is formed in the center so that the screw can be screwed, the moving body is provided with a rotating groove drawn in from both ends to the inside,
Sliding hole through which the opening is formed is formed and two bodies coupled to each opening so as to be slid along the opening, and extending from each of the body to both side rotation grooves of the movable body, the upper and lower surfaces of the movable body Two connecting members including a hinge plate coupled to the movable body so as to be rotatable about a second rotating pin penetrating the second rotating pin;
A driving unit extending from an insulator connected to a transmission and distribution line and including two connection wires respectively connected to ends of the openings;
A tension sensing unit for sensing a deflection state of the transmission and distribution line disposed between the steel towers;
And a controller for driving the driving motor according to the tension state of the transmission and distribution line measured by the tension sensing unit.
The tension sensing unit is provided with a light irradiator for irradiating light having a straightness and installed in the body, a first light receiver for receiving the light and the optical signal main module connected to the signal transmission and the control unit;
A second receiver for receiving the light irradiated from the light irradiator, and a light receiving information of the second light receiver to the controller through an RF signal; An optical signal auxiliary module including a wireless transmitter for transmitting;
It is fixedly installed to be located in the center of the transmission line connected between the steel tower in which the body is installed and the steel tower in which the auxiliary module is installed, the light irradiated from the light irradiator when the transmission line is maintained at an appropriate tension The first reflector is formed to be inclined to reflect the light irradiated upward from the light irradiator so that the light is not received by the second receiver, and the lower portion of the first reflector is formed so that the transmission line is too tight. When the light irradiated from the light irradiator is incident, characterized in that it comprises a light reflecting module including a second reflector having a reflective surface is formed so that the incident light is reflected by the first light receiver Line tension maintaining device for transmission and distribution steel tower. The method of claim 1,
The light reflection module surrounds a transmission and distribution line, a cylindrical body having a plurality of protrusions and protrusions formed on the inner circumferential surface to prevent sliding along the transmission distribution line, and extends radially on the outer circumferential surface of the cylindrical body along a longitudinal direction. A base part comprising two stoppers spaced apart from each other by a predetermined distance;
A plurality of rollers are rotatable along the circumferential direction of the cylindrical body between the stoppers to prevent the separation by the stopper, and a plurality of rollers to facilitate rotation on the inner circumferential surface in contact with the outer circumferential surface of the cylindrical body along the circumferential direction Rotating ring member and a plurality of spaced apart from each other,
A light reflection member provided on the rotary ring member and including the first and second reflection parts;
And a weight member provided at a lower portion of the rotary ring to maintain a state in which the light reflection part is vertically stood up.

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