KR102291356B1 - Spacer damper for transmission line - Google Patents

Abstract

The present invention relates to a spacer damper for a power transmission line and, more specifically, to a spacer damper for a power transmission line, capable of being quickly and conveniently mounted on and detached from a power transmission line. In accordance with the present invention, the spacer damper for a power transmission line includes: a body; a plurality of arms provided in a radial form from the body; a semicircular clamp having one end hinged with an end of the arms and having the other end opened and closed by a locking device to clamp a power transmission line; a pressure rod embedded in the arms to be slid in a longitudinal direction to press and tighten the clamped power transmission line; and a cam axially combined with the center of the body to eject the pressure rod in accordance with a rotation angle. In accordance with the present invention, the spacer damper for a power transmission line can be easily mounted on a power transmission line through one-touch-type clamps and a locking device, and all the clamps are tightened at the same time through the rotation of a cam in the center, and, as a result, the spacer damper can be quickly fixed and unfixed.

Description

Spacer damper for transmission line

The present invention relates to a spacer damper for a transmission line, and more particularly, to a spacer damper for a transmission line that can be quickly and easily mounted and detached from a transmission line.

In general, transmission lines are installed between transmission towers installed at regular intervals. Transmission lines are installed in several rows, and spacer dampers are installed for transmission lines to keep the transmission lines parallel and prevent them from collide with each other.

A conventional spacer damper for a power transmission line includes a spacer including a spacer body and four spacer arms having inner ends coupled to the spacer body as in Patent No. 10-2001462; a damper coupled to an outer end of the spacer arm; a small conductor fixture coupled to the damper to fix the small conductor; It includes; an aviation obstacle signal means installed in the spacer for emitting an aviation obstacle signal.

The spacer damper for a power transmission line of this structure has a spacer function to maintain a gap between a plurality of small conductors, a damping function to elastically support small conductors, and an aviation obstacle marking function, and the main body pipe and connecting pipe constituting the spacer and The arm pipe is formed in a square cross section having a first pair of vertices positioned in the front-back direction and a second pair of vertices positioned in the up-down direction to minimize the influence of wind, and to the damper installed between the spacer arm and the small conductor fixture. This has the effect of reducing the vibration and shock applied to the insulator by increasing the stress generated in the connection part between the pylon and the insulator, and the insulator and the insulator and preventing the connection failure or dropout of the connection part.

In addition, Patent No. 10-2181668 relates to a spacer damper capable of absorbing vibration, comprising: a body in which a plurality of fixed ends protrude from an outer circumferential surface and a central hole is formed in the center; a fixing part having a fixing body and a clamp body formed at each fixing end of the body part so as to hold an electric wire by a hinge; a central weight which is fixed by a plurality of anti-vibration springs inside the central hole of the body; The fixed end is formed with a long hole on the surface to be connected to the fixed body through a separate first fastening hole, and an elastic spring is provided on the outer circumferential surface of the fixed body so that the elastic spring is positioned between the fixed end and the clamp part. By doing so, it has a structure such that the fixture is always pushed outwardly from the body in the long hole.

In the spacer damper of this structure, a plurality of wires spaced apart by the spacer damper are subjected to stress by continuously shaking or vibrating due to wind, earthquake, or ambient noise. In addition to extending the life of the spacer damper by absorbing vibrations or vibrations by the elasticity of the elastic spring, the spacer damper's inner hole is fixed by a plurality of anti-vibration springs containing a viscous liquid. Even if the spacer is shaken, it has the effect of minimizing the vibration or vibration of the surroundings due to the elasticity of the vibration-proof spring and the viscous liquid such as gel or oil.

However, all conventional spacers have a very complicated structure and are in a state of being suspended from the power line, so the movement of the body is unnatural, making it difficult to clamp the power line. In addition, when there are several transmission lines, since it is necessary to clamp each transmission line, there is a problem that it takes a long time for mounting and dismounting.

KR Registered Patent Publication No. 10-2001462 (2019.07.12) KR Registered Patent Publication No. 10-2181668 (2020.11.17)

The present invention was devised to solve the problems as in the prior art, and the purpose of the present invention is to provide a spacer damper for a transmission line that is easily coupled to each transmission line, is easily clamped, and allows all transmission lines to be tightened at once. have.

A spacer damper for a power transmission line according to the present invention for achieving the above object,

body;

a plurality of arms provided radially from the body;

A semi-circular clamp clamping the power line as one end is hinged to the end of the arm and the other end is opened and closed by a locking device;

a pressure rod embedded in the arm and configured to press and tighten the clamped power transmission line as it slides in the longitudinal direction;

The cam is coupled to the axis in the center of the body to protrude and retract the pressure rod according to the rotation angle; It is characterized in that it includes.

In addition, the locking device,

a bearing hinged to the distal end of the arm;

a pressing piece formed at one end of the bearing so that it can be pressed by hand;

a hook formed at the other end of the bearing and caught in the clamp;

A torsion spring that is fitted in the hinge, one end is caught on the pressing piece and the other end is caught on the arm so that the hook maintains the hooked state in the clamp; It is characterized in that it includes.

In addition, the hook is characterized in that the hook automatically retracts and then returns by the clamp, which is closed when the clamp is closed by forming an inclined surface at the tip thereof.

In addition, the hook and the clamp are characterized in that the locking state is not released unless the pressing piece is pressed by forming a separation protrusion on the surface in contact with each other.

In addition, the cam is characterized in that the bolt head or pin hole exposed to the outside is integrally formed so that the cam can be rotated using a tool.

The spacer damper for transmission line according to the present invention is easily mounted on the transmission line by a one-touch clamp and locking device, and all clamps are tightened at once by rotating the central cam, so it can be quickly fixed and released. can have an effect.

1 is a front view showing a state in which a spacer damper for a power transmission line according to the present invention is installed.
2 is a front view showing a spacer damper for a power transmission line according to the present invention.
3 is a cross-sectional view showing the structure of a spacer damper for a power transmission line according to the present invention.
Figure 4 is an enlarged cross-sectional view showing the clamp and the locking device according to the present invention.
5 is a cross-sectional view illustrating a state in which a spacer damper for a transmission line according to the present invention is fixed to a transmission line.
6A to 6E are exemplary views illustrating a clamping process of a clamp according to the present invention.

Hereinafter, a preferred embodiment of a spacer damper for a power transmission line according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view showing a state in which a spacer damper for a transmission line according to the present invention is installed, FIG. 2 is a front view showing a spacer damper for a transmission line according to the present invention, and FIG. 3 is a spacer for a transmission line according to the present invention It is a cross-sectional view showing the structure of the damper, FIG. 4 is an enlarged cross-sectional view showing a clamp and a locking device according to the present invention, and FIG. am.

As shown in these drawings, the spacer damper 100 for a power transmission line according to the present invention includes a body 10; a plurality of arms 20 provided radially from the body 10; A semicircular clamp 30 for clamping the power transmission line 1 as one end is hinged H1 to the distal end of the arm 20 and the other end is opened and closed by the locking device 40; a pressure rod 50 embedded in the arm 20 and tightened by pressing the clamped power transmission line 1 as it slides in the longitudinal direction; A cam (60) for retracting and retracting the pressure rod (50) according to the rotation angle that is shaft-coupled to the center of the body (10); includes

The body 10 has a space therein and a shaft hole is formed in the center so that a cam 60 to be described later can be shaft-coupled. The body 10 is formed in a plate shape and can be coupled by fastening bolts and nuts while maintaining a predetermined distance by forming a plurality of reinforcing flesh on the opposite surface.

The arms 20 are provided in a plurality of radially around the body 10, and may be formed integrally with the body 10 or may be separately manufactured and combined. This arm 20 is provided long to face the center of the body 10, the guide hole 21 is formed in the longitudinal direction therein, both ends are made in an open form. Two or more arms 20 are provided according to the number of power transmission lines 1 .

The clamp 30 is installed at the distal end of the arm 20 and has a semicircular shape, one end of which is hinged H1 to the distal end of the arm 20 , and the other end is opened and closed by a locking device 40 . have

The locking device 40 includes a bearing 41 , a pressing piece 42 , a hook 43 , and a torsion spring 44 .

The bearing 41 has a shaft hole and is hinged H2 to the end of the arm 20 . One end of the bearing 41 is formed with a pressing piece 42 that can be pressed by hand, and a hook 43 caught by the clamp 30 is formed at the other end. And while being fitted in the hinge (H2), one end is caught on the pressing piece 42 and the other end is caught on the arm 20 so that the hook 43 is caught in the clamp 30 and the torsion spring 44 is is installed

In addition, the hook 43 forms an inclined surface 43' at its tip so that the hook 43 is automatically retracted and returned by the clamp 30 closed when the clamp 30 is closed, and the hook 43 ) is formed with a stepped 45 and the clamp 30 is formed with a separation protrusion 35 so that the locking state cannot be released unless the pressing piece 42 is pressed. That is, only by the operation of pressing the pressing piece 42 , the hook 43 is retracted and the clamp 30 is opened.

The pressure rod 50 is embedded in the arm 20 and slides in the longitudinal direction along the guide hole 21 to press and tighten the power transmission line 1 inserted into the inserted clamp 30 . The tip of the pressure rod 50 is provided with a head 51 having a semi-circular groove formed therein, so that the clamp 30 and the head 51 are pressed and fixed from both sides of the power transmission line 1 .

The cam 60 is axially coupled to the center of the body 10 and has a plate shape, and its circumference is formed as a curved surface gradually moving away from the center. The end of the pressure rod 50 is in contact with the circumference of the cam 60 so that the pressure rod 50 protrudes and retracts by the rotation of the cam 60 . That is, the pressing rod 60 is protruded by the cam 60 and the power transmission line 1 inserted into the clamp 30 is forcibly pressed and tightened, thereby fixing it. The expanded curved surface is repeatedly formed according to the number of arms 20 .

In addition, a bolt head 61 exposed to the outside is formed on one surface of the cam 60 or a pin hole 62 is formed to easily rotate the cam 60 without effort using a tool such as a spanner, a wrench, or a long rod. make it possible

The installation process of the spacer damper for a power transmission line according to the present invention having such a structure will be described in detail.

First, as shown in FIG. 6a, the pressing piece 42 of the locking device 40 is pressed so that it is spaced apart from the step 45 of the hook 43 and the separation protrusion 35. As shown in FIG. When the clamp 30 is opened by flipping it open in this state, one end of the clamp 30 is opened as shown in FIG. 6b , and the power transmission line 1 is connected between the clamp 30 and the head 51 of the pressure rod 50 . After insertion, the clamp 30 is closed to close it.

In this process, as shown in FIG. 6c, the end of the clamp 30 comes into contact with the inclined surface 43' of the hook 43 and at the same time retracts the hook 43 and passes through the inclined surface 43'. As shown, the hook 43 is returned by the torsion spring 44 while the step 45 of the hook 43 is caught by the departure preventing protrusion 35, so that the clamp 30 maintains a closed state. In this way, each clamp 30 is placed and inserted into all the transmission lines 1 .

When the cam 60 is rotated using a tool in this state, as shown in FIG. 5, the pressing rod 50 in contact with the cam 60 protrudes in the direction of the clamp 30, as shown in FIG. 6e. The fixing is completed when the head 51 of the pressure rod 50 presses and tightens the power transmission line 1 .

In this way, since all the power transmission lines 1 are tightened and fixed by the rotation of the cam 60, it can be installed quickly and simply. This effect is maximized as the number of transmission lines 1 increases.

1: transmission line 10: body
20: arm 21: guide hole
30: clamp 35: escape sill
40: locking device 41: bearing
42: press piece 43: hook
43': inclined surface 44: torsion spring
45: step 50: pressure rod
51: head 60: cam
61: bolt head 62: pin ball
100: spacer H1, H2: hinge

Claims (5)

body 10;
a plurality of arms 20 provided radially from the body 10;
A semicircular clamp 30 for clamping the power transmission line 1 as one end is hinged H1 to the distal end of the arm 20 and the other end is opened and closed by the locking device 40;
a pressure rod 50 embedded in the arm 20 and tightened by pressing the clamped power transmission line 1 as it slides in the longitudinal direction;
A cam (60) for retracting and retracting the pressure rod (50) according to the rotation angle that is shaft-coupled to the center of the body (10); includes,
The cam (60) is a spacer damper for a power transmission line, characterized in that the bolt head (61) or pin hole (62) exposed to the outside is integrally formed so that the cam (60) can be rotated using a tool. delete delete delete delete

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