KR101355102B1 - Insulator of electric power line for preventing electric shock - Google Patents

Abstract

The present invention relates to a processing distribution line insulator for preventing an electric shock accident. The present invention is provided to guarantee installation availability by enabling a drawn distribution line for a house wiring which is drawn from the processing distribution line to connect to a telephone pole by using a socket method. The present invention is provided to wire the drawn distribution line inside the telephone pole, thereby not generating the electric shock accident in flooding. The present invention is provided to exclude the electric shock accident by inducing a ground when a short circuit is generated through a ground wire. The processing distribution line insulator for preventing the electric shock accident according to the present invention is provided to enable a drawn distribution line for lead-in which is jumped from the processing distribution line to be safely distributed through the telephone pole, thereby protecting the electric shock accident in the flooding.

Description

Processed distribution line insulator for prevention of electric shock {INSULATOR OF ELECTRIC POWER LINE FOR PREVENTING ELECTRIC SHOCK}

The present invention relates to a processed distribution line insulator for preventing an electric shock, and more particularly, to freely adjust the length of the processing distribution line in accordance with the temperature change and to facilitate the installation of a protective member on the pole, the electric shock accident during flooding and rainy weather The invention relates to an overhead distribution line insulator for protecting against accidental electric shock.

In general, the power supply is connected by installing the overhead distribution line on the insulator fixed to the complete iron poles installed at regular intervals.

Since the connection method as described above usually provides a connection means to the insulator, the connection part is separated or broken due to sagging or expansion of the transmission line due to temperature change, such as in summer or winter, and when disconnected, the electricity is cut off. As a worker has to go up and work in a state, there is a problem that it is sometimes difficult to protect the worker from electric shock due to the residual current and the crash caused by the aerial work, and a problem that causes great inconvenience and originality of generations that need to use electric power during power cut. there was.

On the other hand, in order to easily supply power to downtown areas where homes and buildings are concentrated, the overhead line is drawn out from the overhead wire installed in the insulator of wrought iron, and the fixed overhead cable is simply fixed to the outer surface of the pole and then buried in the ground. If a third party comes into contact with the overhead distribution line, it may lead to an electrical safety accident such as an electric shock, which may cause a life risk.If the external impact is applied to the overhead distribution line, it will be disconnected from the pole and disconnected. As a result of the problem, research was actively conducted to solve the problem.

As a prior art to improve this, Korean Patent Registration No. 10-0987424 (2010.10.06.) "Processing cable support pole for preventing electric shock accident" has been disclosed.

However, the pre-registered patent according to the prior art has a disadvantage in that the installation of the protection member fixed to the pole is difficult and takes a lot of time, and thus the work efficiency decreases.

Republic of Korea Patent Registration No. 10-0987424 (2010.10.06.) "Support pole for overhead distribution line to prevent electric shock accident"

The present invention was created in view of the above-mentioned problems in the prior art, and was created to solve this problem. The process distribution wire insulator ensured the ease of installation of the protection member installed on the processing wire and thus the work efficiency and the reduction of working time can be expected. The main purpose is to provide.

The present invention is a means for achieving the above object, the telephone pole 10 which is placed perpendicular to the ground; With a guide groove 21 provided with a protrusion 21a on the inner circumferential surface penetrated horizontally on one side, a pair of wrought iron (20, 20) installed on the outer surface of the electric pole 10 via the band member (B) ')and; A rack 30 installed to be movable between the pair of wrought irons 20 and 20 'via the guide member G; A first pinion which is disposed between the guide grooves 21 of the wrought iron 20, 20 'and has a left thread tap 40a and a right screw tap 40b opposed to each other on the inner circumferential surface and rotates in engagement with the rack 30. 40; The insulator 51 which can fix the first processing distribution line L, and the coupling groove 52a is formed along the longitudinal direction, and has a screw portion 52 having a left or right spiral on the outer circumferential surface thereof, and a guide groove. A length adjusting member (50, 50 ') inserted into the protrusion (21a) of the (21) and fastened to the first pinion (40) and whose length is adjusted by the forward and reverse rotation of the first pinion (40); A temperature sensor 60 installed on one of the pair of wrought irons 20 and 20 'and outputting a measured temperature value by measuring the ambient temperature; A controller 70 which receives a temperature value from the temperature sensor 60 and outputs a forward and reverse rotation signal to the driving motor 80; The second pinion 81 is engaged with the rack 30, and is installed on any one of the pair of sturdy irons 20 and 20 ', and receives the reverse rotation signal from the control unit 70 and the second pinion 81. Drive motor 80 forcibly rotating); The first elastic pad 91a, which is attached to the outer surface of the electric pole 10 and fixed by the fastening means, protrudes to the outer surface of the first elastic pad 91a by a predetermined length, and is drawn out from the first processed distribution line L. It is fixed to the outer surface of the processing distribution line fixing portion 91 and the first elastic pad (91a) provided with a support protrusion (91b) to fix the second processing distribution line (L ') to be embedded in the ground A second fixed by a fastening means so as to protect the second processing distribution line L 'from external force while the support protrusion 91b of the first elastic pad 91a holding the two processing distribution line L' is depressed; An electric shock prevention protective member 90 having an overhead line protection portion 92 provided with an elastic pad 92a; First and second ends DA and DB, which are both ends of the first and second elastic pads 91a and 92a, overlap each other and overlap each other; A plurality of fastening holes FH are formed at overlapping portions of the first end DA; The outer surface of the second end (DB) is provided with a fixing block (GM) having a fixed rod (GR) that can be inserted into and removed from the fastening hole (FH), the fixed block (GM) is a rectangular box with an empty inside Block-shaped housing (GMH), the truncated cone-shaped operating table (GMT) fixed to a part of the length of the fixed rod (GR) to be mounted on the block housing (GMH), fitted to the fixed rod (GR) One end is caught by the lower end of the operating table (GMT) and the other end is passed through one side of the operating spring (GMS), the block housing (GMH) that is caught on the inner wall surface of the block housing (GMH) the operating table (GMT) The tip end face is disposed in contact with the operating knob (GN) and the operating knob (GN) inclined to fit the inclination of the operating table (GMT), and one end thereof is caught by an outer surface of the block housing (GMH). The other end is configured to include a knob spring (GNS) that is engaged to the knob head (GNH) of the operation board (GN). To provide a process distribution line insulators for electrical shock protection, characterized.

The overhead distribution line insulator for preventing electric shock according to the present invention is configured to be safely distributed through the electrical pole jumper for the indoor drawer jumped from the overhead distribution line provides an effect of preventing an electric shock accident in flood or rainy weather.

In addition, it is also possible to obtain an advantage of improving the work efficiency by configuring so that the installation of the protection member fixed to the pole can be easily and quickly.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded perspective view of a pole including a working distribution line insulator for preventing electric shock according to the present invention; FIG.
FIG. 2 is an exploded perspective view of a pole having a working distribution line insulator for preventing electric shock according to the present invention. FIG.
3 is a plan view of a main part viewed from above in a plane having a working distribution line insulator for preventing electric shock accidents according to the present invention.
4 is a plan sectional view showing a protective member for preventing electric shock in a pole having a working distribution line insulator for preventing electric shock according to the present invention.
5 is a block diagram showing interconnections between respective components in a pole having a working line insulator for preventing electric shock according to the present invention.
6A to 6B are diagrams showing an operating relationship of a pole having a working distribution line insulator for preventing an electric shock accident according to the present invention.
Figure 7 is a cross-sectional view of the main portion of the protective member showing a further embodiment according to the present invention.

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

The present invention uses the previously registered patent No. 0987424 as it is. Therefore, all of the device configuration features described below are those described in the registered patent 0987424.

However, the present invention further includes a content of the indoor drawout distribution lines that are wired through electric poles among the components disclosed in Patent No. 0987424 so that they can safely operate even when flooded or in rainy weather without an electric shock accident. It is a key structural feature.

Therefore, the device configuration, features and operation relations described below will be referred to the contents of the Patent No. 0987424 as it is, and will be described in detail with respect to the configuration associated with the main features of the present invention at the rear end.

As shown in Figures 1 to 5, the overhead line insulator for electric shock prevention according to the present invention is an electric pole (10) vertically placed on the ground; A pair of wrought irons 20 and 20 'installed on the outer surface of the electric pole 10 through the band member B; A rack 30 installed to be movable between the pair of wrought irons 20 and 20 'via the guide member G; A first pinion 40 disposed between the guide grooves 21 of the wrought iron 20 and 20 'to rotate in engagement with the rack 30; A length adjusting member (50, 50 ') inserted into the protrusion (21a) of the guide groove (21) and fastened with the first pinion (40) and whose length is adjusted by the forward and reverse rotation of the first pinion (40); A temperature sensor 60 installed on one of the pair of wrought irons 20 and 20 'and outputting a measured temperature value by measuring the ambient temperature; A control unit 70 receiving the temperature value from the temperature sensor 60 and outputting a forward and reverse rotation signal to the driving motor 80; The second pinion 81 is engaged with the rack 30, and is installed on any one of the pair of sturdy irons 20 and 20 ', and receives the reverse rotation signal from the control unit 70 and the second pinion 81. Drive motor 80 forcibly rotating); And a protection member 90 for preventing electric shock and protecting the second processing distribution line L 'attached to the outer surface of the electric pole 10 and drawn out from the first processing distribution line L, 1 to 3 as shown in FIG.

The wrought iron (20, 20 ') is a tube having an overall shape of a rectangular shape, one end is formed with a guide groove 21 penetrating horizontally, the inner circumferential surface of the guide groove 21 protruding inwardly (21a) ) Is formed integrally, and the other end is provided with a pair of band member (B) is fixed to the upper outer surface of the electric pole 10 via this.

In the present embodiment, the length adjusting members 50 and 50 ', which will be described later, are inserted into the inner circumferential surface of the guide groove 21, and the protrusions 21a and the length adjusting members 50, of the guide groove 21 are movable. 50 ') of the coupling groove (52a) forms a structure that is mutually coupled.

Therefore, even when the first pinion 40 is rotated by the rack 30, the length adjusting members 50 and 50 'do not rotate together but move along the protrusion 21a of the guide groove 21, so that the insulator 51 is rotated. The first processing distribution line L and the second processing distribution line L 'drawn out from the first processing distribution line L fixed to the source can be prevented from twisting.

Although it is preferable to form a rectangular in the case of the wrought iron (20, 20 '), this is only one embodiment and may be modified in various shapes as necessary.

The rack 30, which is installed to be movable through the guide member G between the wrought irons 20 and 20 ', has an overall shape of a rectangular shape, and teeth are provided on the upper surface thereof, and both ends of the longitudinal direction Since it is inserted into the guide member (G) and the slide must be moved, it is processed in a planar shape.

The guide member (G) is fixed by a method such as welding or bolting in a state in which the overall shape is coupled with the rack 30 between the wrought iron (20, 20 ') in the shape of' ''.

The first pinion 40 disposed between the guide grooves 21 of the wrought iron 20 and 20 'to be engaged with the rack 30 and rotated may be rotated by being engaged with the rack 30 on the outer circumferential surface thereof. The same tooth is formed so that the left side thread tab 40a and the right side thread tab 40b which are mutually opposed are formed in the inner peripheral surface.

In addition, the first pinion 40 has length adjusting members 50 and 50 'penetrating through the guide grooves 21 of the wrought iron 20 and 20', respectively, and has a left hand thread tap 40a and a right hand thread tap 40b. Is fastened to.

In the present embodiment, the first pinion 40 is rotated by the rack 30. For example, when the rack 30 protrudes along the length direction (forwardly), the first pinion 40 is half. In the clockwise direction, the length adjusting members 50 and 50 'which are fastened to the left screw tab 40a and the right screw tab 40b of the first pinion 40 are centered on the first pinion 40. Is moved toward to tension the first processed distribution line L fixed to the insulator 51, and the length adjusting members 50 and 50 'are opposite to the aforementioned contents when the first pinion 40 is rotated in the clockwise direction. Is moved outward to play the role of maintaining the first processing distribution line (L) in a relaxed state.

The length adjusting members 50 and 50 'are inserted into the protrusions 21a of the guide groove 21 and fastened to the first pinion 40, and the length adjusting members 50 and 50' are adjusted by the forward and reverse rotation of the first pinion 40. An insulator 51 capable of fixing the first overhead distribution line L; Coupling groove 52a is formed along the longitudinal direction and consists of a screw portion 52 having a left spiral or a right spiral on an outer circumferential surface thereof, as illustrated in FIGS. 2 to 3.

Although not specifically illustrated in the case of the first overhead distribution line L, the first overhead distribution line L fixed to the insulator 51 of the length adjusting members 50 and 50 'mediates a jumper wire (not shown). Interconnected by

In the case of the present embodiment, the screw portion 52 is a well-known left helix or right helix formed on the outer circumferential surface to be fastened to the left screw tab 40a and the right screw tab 40b formed on the inner circumferential surface of the first pinion 40. It is a bolt, and the threaded portion 52 has a coupling groove 52a corresponding to the protrusion 21a so as to be movably coupled to the protrusion 21a of the guide groove 21 along the longitudinal direction.

The electric shock prevention protection member 90 which is attached to the outer surface of the pole 10 and is able to protect the second overhead line L 'drawn out from the first overhead line L and fixed and external force, is the pole 10 The first elastic pad 91a, which is attached to the outer surface of the c) and fixed by the fastening means, protrudes to the outer surface of the first elastic pad 91a by a predetermined length, and is drawn out of the first processing distribution line L and embedded in the ground. A processing distribution line fixing part (91) having a supporting protrusion (91b) to fix the second processing distribution line (L ') to be installed; The second processing distribution line L 'is fixed from the external force while the support protrusion 91b of the first elastic pad 91a is fixed to the outer surface of the first elastic pad 91a and detains the second processing distribution line L'. It is composed of a process distribution line protection unit 92 is provided with a second elastic pad (92a) is fixed by the fastening means to protect the, as shown in Figures 1 and 2 and 4.

In the present embodiment, the overhead distribution line fixing portion 91 is fixed to the outer surface of the pole 10 through the first hook (91c) and the first locking portion (91d) as a fastening means, the overhead distribution line protection unit 92 The second hook (92c) and the second hooking portion (92d) to protect the outer surface of the processing distribution line fixing portion 91 as a medium.

In addition, although not specifically shown in the drawings, the protrusions such as quadrangular pyramidal, conical, hemispherical, etc. are formed on the outer surface of the second elastic pad 92a in a multi-row type so that it can be easily removed even if the flyers and leaflets are attached to the outer surface. It is desirable to be able to.

As described above, the second processing distribution line L 'drawn out from the first processing distribution line L is fixed and protected by the protection member 90 for preventing electric shock, thereby shorting the second processing distribution line L' due to external shock. It can prevent accidents and prevent electric shocks caused by electrical contact.

On the other hand, any one of the pair of wrought iron (20, 20 ') is provided with a temperature sensor 60, the control unit 70 and the drive motor 80, which will be described in more detail as follows.

The temperature sensor 60 is installed on the upper surfaces of the wrought iron 20, 20 ′, and the temperature sensor 60 measures the external temperature in real time and outputs the measured value to the controller 70. Receives the measured value from the temperature sensor 60 determines the forward or reverse rotation of the drive motor 80 to output the operation signal to the drive motor (80).

In addition, the driving motor 80 forcibly rotates the second pinion 81 fixed to the motor shaft (not shown) by the forward or reverse rotation signal output from the controller 70 along the guide member G. The rack 30 is to be moved back and forth, as shown in FIG.

The temperature sensor 60 is a known constituent means, and thus a method for measuring temperature is already well known, so a detailed description thereof will be omitted.

Referring to the effect of the present invention made of the above configuration as follows.

First, briefly explaining the installation process of the overhead distribution line support pole for preventing an electric shock accident according to the present invention, a pair of wrought iron (20, 20 ') on the upper surface of the pole 10 through the band member (B) Horizontally installed, the length adjusting member through the guide groove 21 of the cast iron (20, 20 ') in a state in which the first pinion (40) is disposed between the pair of installed cast iron (20, 20') ( 50, 50 ') is coupled to the inner circumferential surface of the first pinion (40).

In addition, the first pinion 40 disposed between the cast irons 20 and 20 'by fixing and installing the rack 30 through the guide member G between the cast irons 20 and 20' in the installed state as described above. ) And the second pinion 81 to interlock with each other, thereby completing the installation.

On the other hand, the lower outer surface of the pole 10 is mounted to the electric shock prevention protection member 90, which will be described in more detail, the first elastic pad (91a) of the processing wire fixing member 91 pole 10 (10) The first hook 91c formed at one end of the outer surface of the first elastic pad 91a is pulled with a finger to the second hooking portion 91d formed at the other end in a state of being attached to the outer peripheral surface of the bottom of the first elastic pad 91a. ) To maintain the desorption state.

As described above, in the state in which the processing wire fixing part 91 is fixed to the electric pole 10, the first processing distribution line L between the support protrusions 91b arranged in multiple rows on the outer surface of the first elastic pad 91a. The second processing distribution line (L ') drawn from the) is fixed by inserting, but the second processing distribution line (L') is selectively mounted to allow the second processing distribution line (L ') to be drawn out and used as needed. It is desirable to be able to.

The second overhead distribution line L 'is mounted between the support protrusions 91b, and then the second elastic pad 92a of the overhead distribution line protection portion 92 is gripped with both hands and pulled inward to pull the second overhead distribution line ( L ') attaches the outer surface of the supporting protrusion 91b, and pulls the second hook 92c formed at one end of the second elastic pad 92a with a finger to the other end of the second elastic pad 92a. The second hanging portion 92d may be hooked to maintain the depressed state of the overhead distribution line protection portion 92. In the case of dismantling, the method may be performed in the reverse order.

Referring to the operation relationship of the overhead line insulator for preventing the electric shock accident, because the change in the length of the first overhead line L is small in the spring and autumn when the temperature change is very small as shown in FIG. The overhead distribution line L is fixed to the insulator 51 in a stable state.

However, when the temperature rises, such as in summer, the temperature sensor 60 installed in the complete iron (20, 20 ') measures the external temperature in real time and outputs the measured value to the control unit 70, the control unit 70 The real-time external temperature state is determined by receiving the measured value in real time from the temperature sensor 60.

In the present embodiment, when the temperature in the summer rises, the first process distribution line L expands and tries to leave the insulator 51 due to the sag phenomenon, so that the first process distribution line L is maintained in a tensioned state. 70 outputs a forward rotation operation signal to the drive motor 80.

Accordingly, the driving motor 80 receiving the forward rotation operation signal from the control unit 70 rotates in the forward direction, and thus the second pinion 81 fixed to the motor shaft (not shown) is forcibly rotated. The rack 30 is pushed in the longitudinal direction (front), and the first pinion 40 engaged with the upper surface of the rack 30 is rotated in the reverse direction by the rack 30 moving forward.

When the first pinion 40 rotates in the counterclockwise direction, the length adjusting members 50 and 50 ′ fastened to the inner circumferential surface of the first pinion 40 move toward the inner center of the first pinion 40. The first processing distribution line L fixed to the insulator 51 is also pulled by the length adjusting members 50 and 50 'which are moved to maintain the tensioned state, thereby sagging the first processing distribution line L. It will be able to prevent, as shown in Figure 6a.

On the other hand, in winter, as the first processing distribution line (L) is contracted, the length is shortened to be in a taut state. In this case, the temperature sensor 60 measures the external temperature in real time to the controller 70. The controller 70 receives the measured value in real time from the temperature sensor 60 to determine the current external temperature state.

In the case of the present embodiment, when the temperature is lowered as in winter, the first processing distribution line (L) is to be separated from the insulator 51 by contraction, so that the first processing distribution line (L) to some extent to relax the control unit 70 ) Outputs a reverse rotation operation signal to the drive motor 80.

Accordingly, the driving motor 80 receiving the reverse rotation operation signal from the control unit 70 rotates in the reverse direction, whereby the second pinion 81 fixed to the motor shaft (not shown) is forcibly rotated. The rack 30 is pushed rearward (electrically circumferentially), and the first pinion 40 engaged with the upper surface of the rack 30 by the rack 30 moving toward the rear is rotated clockwise.

When the first pinion 40 is rotated in the clockwise direction, the length adjusting members 50 and 50 ′ fastened to the inner circumferential surface of the first pinion 40 move outward from the inside of the first pinion 40. In addition, the process distribution line (L) fixed to the insulator 51 is also moved with the length adjusting members (50, 50 ') to be moved to maintain a relaxed state, the process distribution line (L) by excessive contraction It is possible to prevent the departure from the insulator 51, this series of processes are shown as shown in Figure 6b.

As described above, the first pinion 40 and the length adjusting members 50 and 50 'having the first processing distribution line L fixed thereto are installed at the ends of the first pinion 40. By installing the temperature sensor 60, the control unit 70 and the drive motor 80 to control the length so that the length can be adjusted, the first processed distribution line (L) is sag or contracted by the temperature change insulator It is possible to prevent the separation or breaking from the 51 in advance, it is relatively simple configuration, easy to assemble and easy to repair and replacement is quite easy.

In addition, the electric shock prevention protection member 90 is installed on the lower outer circumferential surface of the electric pole 10, and the second processing distribution line L ′ drawn out from the first processing distribution line L is fixed through the protection member 90 for electric shock prevention. And by being protected, it is possible to fundamentally solve the problem that the second processing distribution line (L ') from damage from external forces, as well as to protect the worker from electric shock due to contact.

Further embodiments according to the present invention include the above-described configuration as it is while further improving some of the configuration as shown in Figure 7 when the protective member 90 is installed on the pole 10 to obtain the ease of installation work, installation time shortening effect It can be configured to be.

To this end, as illustrated in FIG. 7A, both ends of the first and second elastic pads 91a and 92a, that is, the first end DA and the second end DB may be stacked on each other. In this case, the sides facing each other when the step is processed to overlap each other when the thickness of the nested portion is configured to remain the same as the remaining unpadded pad portion.

At this time, since the shape of the first end DA and the second end DB is applied to both the first and second elastic pads 91a and 92a, the first end DA and the second end DB are separated into the first and second elastic pads 91a and 92a. Without describing, both will be described through one example.

In addition, a plurality of fastening holes FH are formed in the first end DA at a predetermined interval along the longitudinal direction.

In addition, a fixing block GM is firmly fixed to an outer surface of the second end DB, and the fixing block GM is provided with a fixing rod GR that can be penetrated through the fixing block GM. GR is configured to be inserted into any one of the fastening holes FG.

In addition, an operating knob GN for operating the fixed rod GR is provided on one side of the fixed block GM. When the operating knob GN is pressed, the fixed rod GR is fixed. GM) is drawn into the inside of the block housing (GMH), more precisely shown in Figure 7 (b), and when the actuating knob (GN) is released, it is automatically resilient and withdrawn from the block housing (GMH). It is configured to go in and out.

At this time, a specific configuration for the fixed rod (GR), the operating knobs (GN) including the fixed block (GM) is as shown in FIG.

Referring to FIG. 7B, the fixed block GM includes a block housing GMH.

The block housing (GMH) has a hollow rectangular box shape, and a pair of opposite surfaces facing each other in the six-sided surface is formed with through-holes at the same point so that both ends of the fixed rod GR can be sunk. do.

In addition, a truncated cone-shaped operating table GMT is fixed to a part of the length of the fixing rod GR, and an operating spring GMS is interposed between the lower end of the operating table GMT and the inner wall surface of the block housing GMH. The operating spring GMS is provided in a form fitted to the fixed rod GR.

Therefore, the fixed rod GR always keeps protruding forward because of the operating spring GMS.

In addition, one side of the block housing (GMH) is inserted into the operation knob (GN) penetrating it, the knob engaging jaw (engaged in the inner wall surface of the block housing (GMH) in a portion of the length of the operation knob (GNH) ( GNT) is provided, the cross section of the operating knob (GN) is inclined to correspond to the inclined surface of the operating table (GMT).

In addition, the operating knob (GN) is formed to have a smaller diameter than the knob head (GNH), the knob spring (GNS) is fitted to the knob head (GNH) while the opposite end of the outer wall of the block housing (GMH) It is caught on the surface.

Therefore, when the operating knob (GN) is pressed, the tip thereof moves forward, and the operating table (GMT) in contact therewith is inclined contact, so that it is pushed back by the pushing force of the operating knob (GN) and is retracted to move forward. The fixed rod GR is drawn into the block housing GMH.

When the force applied to the operation knob GN is removed, the fixing rod GR is protruded again by the elastic force of the two springs.

By using the above operation, the fixing rod GR is inserted and fixed through the operation knob GN in the state where the first and second ends DA and DB are overlapped with each other, so that the fixing operation can be easily and quickly performed. do.

10: Jeonju 20.20 ': Support 21: Guide groove
21a: protrusion 30: rack 40: first pinion
50.50 ': Length adjusting member 51: Insulator 52: Thread part
52a: coupling groove 60: temperature sensor 70: control unit
80: drive motor 90: electric shock protection member
91: Overhead distribution line 92: Overhead distribution line protection unit

Claims (1)

An electric pole (10) perpendicular to the ground; With a guide groove 21 provided with a protrusion 21a on the inner circumferential surface penetrated horizontally on one side, a pair of wrought iron (20, 20) installed on the outer surface of the electric pole 10 via the band member (B) ')and; A rack 30 installed to be movable between the pair of wrought irons 20 and 20 'via the guide member G; A first pinion which is disposed between the guide grooves 21 of the wrought iron 20, 20 'and has a left thread tap 40a and a right screw tap 40b opposed to each other on the inner circumferential surface and rotates in engagement with the rack 30. 40; The insulator 51 which can fix the first processing distribution line L, and the coupling groove 52a is formed along the longitudinal direction, and has a screw portion 52 having a left or right spiral on the outer circumferential surface thereof, and a guide groove. A length adjusting member (50, 50 ') inserted into the protrusion (21a) of the (21) and fastened to the first pinion (40) and whose length is adjusted by the forward and reverse rotation of the first pinion (40); A temperature sensor 60 installed on one of the pair of wrought irons 20 and 20 'and outputting a measured temperature value by measuring the ambient temperature; A controller 70 which receives a temperature value from the temperature sensor 60 and outputs a forward and reverse rotation signal to the driving motor 80; The second pinion 81 is engaged with the rack 30, and is installed on any one of the pair of sturdy irons 20 and 20 ', and receives the reverse rotation signal from the control unit 70 and the second pinion 81. Drive motor 80 forcibly rotating); The first elastic pad 91a, which is attached to the outer surface of the electric pole 10 and fixed by the fastening means, protrudes to the outer surface of the first elastic pad 91a by a predetermined length, and is drawn out from the first processed distribution line L. It is fixed to the outer surface of the processing distribution line fixing portion 91 and the first elastic pad (91a) provided with a support protrusion (91b) to fix the second processing distribution line (L ') to be embedded in the ground A second fixed by a fastening means so as to protect the second processing distribution line L 'from external force while the support protrusion 91b of the first elastic pad 91a holding the two processing distribution line L' is depressed; An electric shock prevention protective member 90 having an overhead line protection portion 92 provided with an elastic pad 92a;
First and second ends DA and DB, which are both ends of the first and second elastic pads 91a and 92a, overlap each other and overlap each other;
A plurality of fastening holes FH are formed at overlapping portions of the first end DA;
The outer surface of the second end (DB) is provided with a fixing block (GM) having a fixed rod (GR) that can be inserted into and removed from the fastening hole (FH), the fixed block (GM) is a rectangular box with an empty inside Block-shaped housing (GMH), the truncated cone-shaped operating table (GMT) fixed to a part of the length of the fixed rod (GR) to be mounted on the block housing (GMH), fitted to the fixed rod (GR) One end is caught by the lower end of the operating table (GMT) and the other end is passed through one side of the operating spring (GMS), the block housing (GMH) that is caught on the inner wall surface of the block housing (GMH) the operating table (GMT) The tip end face is disposed in contact with the operating knob (GN) and the operating knob (GN) inclined to fit the inclination of the operating table (GMT), and one end thereof is caught by an outer surface of the block housing (GMH). The other end is configured to include a knob spring (GNS) that is engaged to the knob head (GNH) of the operating knob (GN). Processing distribution line insulators for electric shock prevention featuring.

Images