KR102406749B1 - Supporting Bar System of Distribution Line Connected to Transformer - Google Patents

Abstract

The complete system of overhead distribution lines connected to the transformer is equipped with a protective device in the form of a cover on the upper part of the line post insulator, and external shock, rain, snow, etc. It is possible to protect external environmental factors, such as insulators and steel arms, and thus has the effect of providing power stability of the distribution line.

Description

Full iron system of overhead distribution line connected to transformer {Supporting Bar System of Distribution Line Connected to Transformer}

The present invention relates to a complete iron system of an overhead distribution line connected to a transformer in the field of power distribution technology. More particularly, a protection device in the form of a cover is provided on the upper part of the line post insulator to prevent the protection device from rotating or vertical movement of the line post insulator. Through this, it is possible to protect external environmental factors such as external shock, rain, snow, etc. applied to the line post insulator, thereby increasing the lifespan of the insulator and the arm iron of the overhead distribution line connected to the transformer, which can provide power stability of the distribution line. It's about the system.

In general, electricity transmitted from a substation is distributed to each customer through an overhead distribution line installed through electric poles and poles.

At this time, a transformer is installed on the electric pole, and electricity is distributed to each consumer through the outgoing distribution line drawn out from the transformer.

In other words, the large power generated in the power plant is transmitted to each substation as high-voltage power through a transmission line such as a power transmission tower, and then the substation transforms the transmitted power and is supplied to each region by a wire cable so that each customer can use it. .

Electricity supply to general consumers is supplied through electric poles. At this time, there are single-phase, two-wire, and three-wire types of wire cables in each electric pole depending on the distribution line, and these wires and cables are connected using jumper wires. .

Conventional wire cable connection construction is to connect and combine wire cables through suspension insulators from both sides of the wangeum, which is gibbed to both sides of the upper end of a utility pole in a direction orthogonal to the line direction of the wire cables, and connect between the two side suspension insulators with a jumper wire, The construction of supporting the jumper wire in the upward or horizontal direction has been mainly carried out through line post insulators fixedly installed on the upper surfaces of both sides of the wangeum.

Insulators, overhead distribution lines, and steel rods are fixed to the existing electric poles, so if environmental factors such as rain, wind, snow, etc. occur, the product may corrode or add moisture, and there is a risk of blackout accidents such as short circuits.

In particular, there is a limit because of the inefficiency of putting a huge amount of manpower and equipment in sparsely populated areas such as mountainous areas.

Bird nests built on telegraph poles connect high-voltage cables on both sides of Wangeum, causing power outages due to short circuits and ground faults during the rainy season. There is this.

Republic of Korea Patent Registration No. 10-1199518 (Registration Date: November 02, 2012), Title of Invention: "Insulator installation-type full iron on poles for fixing overhead distribution lines

In order to solve the problems and necessity of the prior art, the present invention provides a protective device in the form of a cover on the upper part of the line post insulator so that the protective device rotates or externally applied to the line post insulator through vertical movement of the line post insulator. The purpose is to provide a full iron system of an overhead distribution line connected to a transformer that can protect external environmental factors such as shock, rain, snow, etc., thereby increasing the lifespan of the insulator and the steel wire to provide power stability of the distribution line. .

The overhead distribution line system 100 connected to the transformer of the present invention for achieving the above object is a pole 102 and a circular coupling band (not shown) on both upper ends of the pole 102 in the horizontal direction. It includes a longitudinal arm bar 104 to be coupled, and the arm bar 104 is equipped with a horizontal position moving part 110 in the inner space, and a longitudinal slide groove 103 is dug along one outer circumferential surface, and , a plate-shaped connection member 117 protrudes to the outside through the slide groove 103, and the connection member 117 combines the vertical movement part 120 standing vertically at the end of one side, and the top and bottom To the position moving part 120, the arm steel 40 supporting the overhead distribution line 10 in an insulated state, the suspension insulator 20 and the overhead distribution line 10 are connected, and a line post insulator 30 is installed on the upper surface. Installed vertically, the line post insulator 30 is coupled to the protection device 200 on the clamp 31 connecting the jumper wire 11 at the uppermost end, and the protection device 200 is the line post insulator 30 ), a first wing part having a constant length and width in the horizontal direction on both sides of the line post insulator 30 from the upper part of the line post insulator 30 to protect the outside from various causes of wind, rain, and snow 226 and the second wing portion 227 are formed, and the horizontal position movement unit 110 moves the arm iron 40, the suspension insulator 20, and the overhead distribution line 10 in a horizontal direction The tangled or pressed overhead distribution line 10 is arranged, the longitudinal first screw 111 is formed in the horizontal direction, and the first bevel gear 113 is coupled to one end of the first screw 111 and , the second bevel gear 114 is gear-engaged in the vertical direction to the first bevel gear 113 , and the second bevel gear 114 is connected to the first rotation shaft 115 of the first drive motor 116 . coupled to, and the first screw 111 is formed to be long in the longitudinal direction and penetrates the first moving block 112 of a predetermined shape. to be coupled, and the first moving block unit 112 may reciprocate in a horizontal direction along the first screw 111 according to the driving of the first driving motor 116 .

The present invention of the above configuration forms a cover to protect the outer circumferential surface of the line post insulator, and can protect external environmental factors such as external impact, rain, and snow applied to the line post insulator, thereby increasing the life of the distribution line It has the effect of providing power stability of

1 and 2 are diagrams showing the configuration of a complete iron system of an overhead distribution line connected to a transformer according to an embodiment of the present invention;
3 is a perspective view showing the configuration of a horizontal position moving unit and a vertical position moving unit according to an embodiment of the present invention;
4 is a view showing a cross-sectional configuration of a protection device according to an embodiment of the present invention,
5 is a view showing the vertical movement of the transformer by the vertical movement device according to the embodiment of the present invention,
6 is a view showing a forward and backward movement of the transformer by the forward and backward movement device according to an embodiment of the present invention;
7 is a view showing a state of rotation in the circumferential direction of the electric pole according to an embodiment of the present invention,
and
8 is a view for explaining the internal device of the iron system of the overhead distribution line connected to the transformer according to the embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain element, it means that other elements may be further included, rather than excluding other elements, unless otherwise stated.

In rainy, windy areas, a little moisture can be added and the insulators failing. It is also recognized as the main culprit in causing power outages by building bird nests in Jeonju.

The present invention can protect the external environmental factors such as external shock, rain, snow, etc. applied to the line post insulator by providing a protection device for protecting the outside of the line post insulator, thereby increasing the lifespan of the insulator and improving the power stability of the distribution line It provides a complete iron system of overhead distribution lines connected to transformers that can provide.

1 and 2 are diagrams showing the configuration of an overhead distribution line connected to a transformer according to an embodiment of the present invention, FIG. 3 is a horizontal position moving part and a vertical position moving part according to an embodiment of the present invention. 4 is a view showing a cross-sectional configuration of a protection device according to an embodiment of the present invention, and FIG. 5 is a view showing a state of vertical movement of a transformer by a vertical movement device according to an embodiment of the present invention, FIG. 6 is a view showing the forward and backward movement of the transformer by the forward and backward movement device according to an embodiment of the present invention.

An overhead distribution line system 100 connected to a transformer according to an embodiment of the present invention includes a pedestal 101 fixed to the ground, and an electric pole 102 that is fixed to the pedestal 101 and formed of a reinforced concrete structure; , includes a longitudinal bar 104 coupled in the horizontal direction by a circular coupling band (not shown) on the upper end of the electric pole 102 .

The arm bar 104 is equipped with a horizontal position moving part 110 in the inner space, and a slide groove 103 is dug long in the longitudinal direction along one outer circumferential surface.

The steel bar 104 has a plate-shaped connecting member 117 protruding to the outside through the slide groove 103 .

The connecting member 117 combines the vertical position moving part 120 standing vertically at one end. The upper and lower position moving part 120 is coupled to the front end iron 40 supporting the overhead distribution line 10 in an insulated state, and the arm iron 40 is connected to the suspension insulator 20 and the overhead distribution line 10. .

The horizontal position moving unit 110 may position the suspension insulator 20 and the overhead distribution line 10 in a horizontal direction.

The armrest 40 is vertically installed with a line post insulator 30 on its upper surface.

The line post insulator 30 is used to support the jumper wire 11, is installed vertically on the upper surface of the armrest 40 to support the jumper wire 11, and is used for the purpose of insulating wires and fittings. .

The line post insulator 30 forms a clamp 31 at the uppermost end, and the protection device 220 is coupled on the clamp 31 .

The clamp 31 is a metal fitting used to connect the jumper wire 11 to the suspension insulator 20 .

The protection device 200 is uniform in the horizontal direction on both sides of the line post insulator 30 at the top of the line post insulator 30 to protect the outside of the line post insulator 30 from various causes of wind, rain, and snow. A first wing portion 226 and a second wing portion 227 having a length and a width are formed.

The protection device 220 includes a protection device case 221 forming an inner space, a gear motor 222 providing a rotational force to the first gear member 223 in the inside of the protection device case 221 , and a first gear A second gear member 224 engaged with one end of the member 223 and a third gear member 225 engaged with the other end of the first gear member 223 are formed.

The second gear member 224 extends in the horizontal direction to combine the first wing portion 226 of a certain length to protect the line post insulator 30 from various impact factors such as wind, sand, rain, snow, and birds, The third gear member 225 extends in the horizontal direction to couple the second wing portion 227 of a certain length to protect the line post insulator 30 from various impact factors such as wind, sand, rain, snow, and birds.

The first wing portion 226 and the second wing portion 227 form bent portions 226a and 227a in which one end is bent at a predetermined angle. These bent portions 226a and 227a have a function of generating a stronger wind during rotation to create a surrounding air flow, and strengthening the strength of the first wing portion 226 and the second wing portion 227 to increase durability. do.

When the gear motor 222 transmits a driving force to the first gear member 223 , a rotational force is applied to the second gear member 224 and the third gear member 225 which are collectively engaged with the first gear member 223 . transmission, and accordingly, the first wing portion 226 and the second wing portion 227 are rotated.

In the armrest 40, a rack gear 228 of a certain length is vertically erected in the inner space, and a pinion gear 229 that is meshed with each other to gear mesh with the rack gear 228 is coupled to the inner sidewall, and the pinion gear 229 A motor (229a) is coupled to the rotation shaft of the

Although the pinion gear 229 of the present invention is configured to directly couple the motor 229a to the rotating shaft, it is not limited thereto, and a gearbox (not shown) is coupled to the rotating shaft, and the motor 229a is coupled to one side of the gearbox. A configuration can also be formed.

The horizontal position moving unit 110 moves the suspended insulator 20 and the overhead distribution line 10 in the horizontal direction to arrange the tangled or pressed suspension insulator 20 and the overhead distribution line 10 to improve the aesthetics of the city. make it

The horizontal position moving unit 110 is formed in the inner space of the steel bar 104 so that the first screw 111 is formed in the horizontal direction, and the first bevel gear 113 is coupled to one end of the first screw 111 . and the second bevel gear 114 is gear-engaged in the vertical direction to the first bevel gear 113 , and the second bevel gear 114 is connected to the first rotation shaft 115 of the first drive motor 116 . combine

The first screw 111 is formed in a straight shape with a constant length, and is elongated in the longitudinal direction so as to penetrate the first moving block unit 112 .

The first screw 111 is formed to be long in the longitudinal direction and penetrates through the first moving block 112 having a predetermined shape and is coupled thereto.

The first screw 111 has a screw groove formed in a rolling or grinding manner along the circumferential direction.

The first moving block part 112 forms a nut part (not shown) therein, and the first screw 111 penetrates the central part of the nut part and is coupled therein.

The nut portion of the first moving block part 112 forms a through hole passing through the front and rear surfaces so that the first screw 111 is coupled to the central portion, and the screw formed on the outer peripheral surface of the first screw 111 on the inner peripheral surface of the through hole. A thread corresponding to the groove is formed.

The first screw 111 is inserted into the through hole of the nut portion of the first moving block portion 112, so that the screw groove and the screw thread are screwed together.

A connection member 117 in the form of a flat plate is connected to one surface of the first moving block unit 112 and protrudes to the outside through the slide groove 103 of each of the steel bars 104a and 104b. The first moving block unit 112 reciprocates in the horizontal direction along the first screw 111 according to the driving of the first driving motor 116 .

The vertical position moving unit 120 moves the suspended insulator 20 and the overhead distribution line 10 in the vertical direction to move the tangled or pressed suspension insulator 20, the line post insulator 30 and the overhead distribution line 10. It can be organized to improve the aesthetics of the city.

The vertical position movement unit 120 forms an inner space, the housing 121 having a slide groove 121a drilled in the vertical direction is formed in the inner space of the housing 121, and the second screw 122 moves up and down. Standing vertically in the direction, the third bevel gear 124 is coupled to one end of the second screw 122 , and the fourth bevel gear 125 is gear-engaged in the vertical direction to the third bevel gear 124 , and the fourth bevel gear 125 is coupled to the second rotation shaft 126 of the second driving motor 127 .

The second screw 122 is formed in a straight line with a constant length, and is formed to be elongated in the longitudinal direction so as to penetrate the second moving block unit 123 .

The second screw 122 is formed to be long in the longitudinal direction and penetrates through the second moving block 123 having a predetermined shape and is coupled thereto.

In the second screw 122 , a screw groove is processed by rolling or grinding along the circumferential direction.

The second moving block part 123 forms a nut part (not shown) therein, and the second screw 122 penetrates the central part of the nut part and is coupled therein.

The nut part of the second moving block part 123 forms a through hole passing through the front and rear surfaces so that the second screw 122 is coupled to the central portion, and the screw formed on the outer peripheral surface of the second screw 122 on the inner peripheral surface of the through hole. A thread corresponding to the groove is formed.

The second screw 122 is inserted into the through hole of the nut portion of the second moving block portion 123, so that the screw groove and the screw thread are screwed together.

The second moving block part 123 connects the arm convex 40 and protrudes to the outside through the slide groove 121a of each arm convex bar 104a, 104b. The second moving block unit 123 reciprocates in the vertical direction along the second screw 122 according to the driving of the second driving motor 127 .

The electric pole 102 is coupled to the fixed plate 105 and the fixed plate 105 coupled to the periphery of the electric pole 102 at an intermediate point to extend or shorten the length from the fixed plate 105 includes a slide plate 106 .

The fixing plate 105 is horizontally coupled to the circumference of the electric pole 102 so that one side is asymmetrically longer than the other side.

The fixing plate 105 is coupled to the cylindrical coupling member 107 having a cylindrical shape at the upper portion, and the vertical movement device 130 is coupled to the lower portion.

The cylindrical coupling member 107 is coupled to the circumference of the electric pole 102 at a predetermined height, and the guide member 108 is coupled to the upper portion.

The guide member 108 is fitted and coupled to the circumference of the electric pole 102 to form a cylindrical guide body 108a and a plurality of guide bars 108b protruding vertically from the outer circumferential surface of the guide body 108a at regular intervals. do.

The guide bar 108b of the guide member 108 forms a guide groove 105a in the fixing plate 105 so as to correspond, and performs a function of facilitating the vertical movement of the fixing plate 105 .

The slide plate 106 is a panel for mounting and fixing the transformer 20 on the upper surface, and is coupled to the inside of the fixing plate 105 by a connection member 109 so that the connection member 109 is moved into the interior of the fixing plate 105 . The length may be increased or decreased at the same time as it slides or separates and protrudes to the outside.

The vertical movement device 130 couples a plurality of first hydraulic cylinders 130 in the circumferential direction of the electric pole 102 by an annular attachment mechanism 40 to the lower portion of the fixing plate 105 .

The first hydraulic cylinder 130 includes a first cylinder tube 131 having an internal space, and a first cylinder tube 131 installed inside the first cylinder tube 131 to be moved by a working fluid (eg, compressed oil, etc.) 1 piston 133 and a first piston rod 132 coupled to the first piston 133 to serve as a shaft for driving the first piston 133 .

The upper end of the first piston rod 132 is in contact with the lower surface of the fixing plate 105 . The first hydraulic pump 134 introduces and discharges a working fluid for operating the first piston 133 .

When the working fluid discharged from the first hydraulic pump 134 flows into the suction hole of the first cylinder tube 131 through an inlet pipe (not shown), the first hydraulic pump 134 continuously supplies the high-pressure working fluid. discharged, and the working fluid is filled in the inside of the first cylinder tube 131 by the pressure.

The working fluid pushes up the first piston 133 upwards, and pushes up the first piston rod 132 connected to the first piston 133 . Accordingly, the first piston rod 132 moves from the inside of the first cylinder tube 131 to the outside in the upper direction to extend.

When the working fluid is sucked from the first hydraulic pump 134 , it is discharged through the discharge hole of the first cylinder tube 131 through an inlet pipe (not shown), and the first hydraulic pump 134 continuously operates at high pressure. The fluid is sucked, and the working fluid escapes from the inside of the first cylinder tube 131 by the pressure.

The working fluid descends the first piston 133 downwards, and descends the first piston rod 132 connected to the first piston 133 . Accordingly, the first piston rod 132 is shortened by inserting and moving in the lower direction from the inside of the first cylinder tube 131 .

As shown in Figure 3, the first hydraulic cylinder 130, the first piston rod 132 descends to the first cylinder tube 131, the first piston rod 132 is the first cylinder tube (131) It rises from and raises and lowers the fixed plate 105, and the transformer 20 rises and falls accordingly.

The cylindrical coupling member 107 couples the first front and rear movement device 140 and the second front and rear movement device 150 to one side of the side.

The first forward and backward movement device 140 and the second forward and backward movement device 150 are respectively coupled to the upper side and the lower side of the cylindrical coupling member 107 .

The first forward and backward movement device 140 and the second forward and backward movement device 150 respectively located at the upper and lower portions are coupled by a first connecting rod 107a and a second connecting rod 107b of a certain length to improve durability and fastening force. .

The first forward/backward moving device 140 and the second forward/backward moving device 150 are the second hydraulic cylinder 140 and the third hydraulic cylinder 150 , and the cylindrical coupling member 107 and the transformer 20 are connected to each other to connect the transformer (20) can be moved forward and backward.

The second hydraulic cylinder 140 is installed inside the second cylinder tube 141 and the second cylinder tube 141 forming an internal space and is moved by a working fluid (eg, compressed oil, etc.) The second piston 143 includes a second piston rod 142 coupled to the second piston 143 to serve as an axis for driving the second piston 143 .

One end of the second cylinder tube 141 is coupled to the upper side of the cylindrical coupling member 107 , and one end of the second piston rod 142 is a first ring coupling in the form of a ring inserted around the transformer 20 . coupled to the sphere 106a.

The third hydraulic cylinder 150 includes a third cylinder tube 151 having an internal space, and a third cylinder tube 151 installed inside the third cylinder tube 151 to be moved by a working fluid (eg, compressed oil, etc.) It includes a third piston 153 and a third piston rod 152 coupled to the third piston 153 to serve as a shaft for driving the third piston 153 .

One end of the third cylinder tube 151 is coupled to the lower side of the cylindrical coupling member 107 , and one end of the third piston rod 152 is a second ring coupling in the form of a ring inserted around the transformer 20 . coupled to the sphere 106b.

The second and third hydraulic pumps 144 and 154 introduce and discharge the working fluid for operating the second and third pistons 143 and 153 .

When the working fluid discharged from the second and third hydraulic pumps 144 and 154 flows into the suction holes of the second and third cylinder tubes 141 and 151 through an inlet pipe (not shown), the second and third hydraulic pumps ( 144, 154) continuously discharges a high-pressure working fluid, and the working fluid is filled in the inside of the second and third cylinder tubes 141 and 151 with the pressure.

The working fluid horizontally moves the second and third pistons 143 and 153 from one side to the other, and horizontally moves the second and third piston rods 142 and 152 connected to the second and third pistons 143 and 153 in the horizontal direction. move Accordingly, the second and third piston rods 142 and 152 move from the inside of the second and third cylinder tubes 141 and 151 to the outside in the horizontal direction to extend.

When the working fluid is sucked from the second and third hydraulic pumps 144 and 154, it is discharged through the outlet holes of the second and third cylinder tubes 141 and 151 through an inlet pipe (not shown), and the second and third hydraulic pressures The pumps (144, 154) continuously suck the high-pressure working fluid, and the working fluid exits the inside of the second and third cylinder tubes (141, 151) with the pressure.

The working fluid horizontally moves the second and third pistons 143 and 153 from the other side to one side, and horizontally moves the second and third piston rods 142 and 152 connected to the second and third pistons 143 and 153 in the horizontal direction. move Accordingly, the second and third piston rods 142 and 152 are inserted and moved in the horizontal direction into the second and third cylinder tubes 141 and 151 to be shortened.

The second and third hydraulic cylinders 140 and 150, the second and third piston rods 142 and 152 move from right to left inside the second and third cylinder tubes 141 and 151, and the second and third pistons The rods 142 and 152 move from left to right inside the second and third cylinder tubes 141 and 151 to move the transformer 20 forward and backward.

As shown in FIG. 4 , when the transformer 20 is moved forward and backward, the slide plate 106 inserts the connecting member 109 into the inside of the fixing plate 105 or protrudes it to the outside of the transformer 20 . help you move

7 is a view showing a state of rotation in the circumferential direction of the electric pole according to an embodiment of the present invention.

The electric pole 102 is provided with a first bearing member 102a at the inner upper end, and a second bearing member 102b at the inner lower end. The second bearing member 102b may be positioned between the outer circumferential surface of the electric pole 102 and the inner circumferential surface of the pedestal 101 .

The first bearing member 102a and the second bearing member 102b perform a function of increasing the rotational force by the fitting bar member 30 .

In another embodiment of the rotation of the electric pole 102, a vertically erected screw 102c is coupled to the electric pole 102, and a first bevel gear (not shown) is coupled to the lower end of the screw 102c, and the first bevel A second bevel gear (not shown) is gear-engaged in a direction perpendicular to the gear, and may include a configuration in which the second bevel gear is coupled to the rotation shaft of the driving motor 102d.

The rotation of the electric pole 102 may be automatically rotated by the rotational force of the driving motor 102d.

8 is a view for explaining the internal device of the iron system of the overhead distribution line connected to the transformer according to the embodiment of the present invention.

The control unit 135 generates a driving signal and transmits it to the first driving motor 116 , and the first moving block unit 112 reciprocates in the horizontal direction along the first screw 111 .

The horizontal position moving unit 110 moves the arm iron 40 , the suspension insulator 20 and the overhead distribution line 10 in the horizontal direction.

The control unit 135 generates a driving signal and transmits it to the second driving motor 127 , and the second moving block unit 123 reciprocates in the horizontal direction along the second screw 122 .

The vertical position movement unit 120 moves the arm iron 40 , the suspension insulator 20 and the overhead distribution line 10 in the vertical direction.

The pressure sensor 128 may be installed on one side of the line post insulator 30 and the arm iron 40 to sense the pressure applied to the line post insulator 30 . Here, the sensing pressure is a pressure value applied to the line post insulator 30 by contact with birds or climatic environments such as rain, snow, and wind.

The control unit 135 is electrically connected to the pressure sensor 128 and when the pressure value received from the pressure sensor 128 is greater than a preset reference pressure value, the control unit 135 determines that it is receiving strong pressure and generates a drive signal to generate a drive signal ( 222) is sent. In accordance with the driving of the gear motor 222, a rotational force is transmitted to the second gear member 224 and the third gear member 225 which are collectively engaged with the first gear member 223, and accordingly, the first wing part ( 226) and the second wing portion 227 is rotated.

Rotation of the first wing part 226 and the second wing part 227 can prevent the approach of birds first, and prevent damage to the line post insulator 30 due to climatic environments such as rain, snow, and wind. .

When the pressure value received from the pressure sensor 128 is greater than a preset reference pressure value, the control unit 135 generates a driving signal and transmits it to the motor 229a. By rotating the pinion gear 229 according to the driving of the motor 229a, the rack gear 228 moves up and down and the line post insulator 30 moves up and down to prevent the access of birds or remove snow or other foreign matter; It can perform various functions such as tension control.

The control unit 135 generates a first control signal and transmits it to the first hydraulic pump 134 , and when the first hydraulic pump 134 is driven, the fixed plate 105 is raised and lowered by the vertical movement device 130 to raise and lower the transformer. (20) raises and lowers the position.

The control unit 135 generates a second control signal and transmits it to the second hydraulic pump 144 and the third hydraulic pump 154 , and drives the second hydraulic pump 144 and the third hydraulic pump 154 to drive the transformer Adjust the position of the transformer 20 by moving (20) forward and backward. At this time, the slide plate 106 is slid by the connecting member 109 .

The control unit 135 generates a third control signal and transmits it to the driving motor 102d, and drives the driving motor 102d to rotate the first and second bevel gears to rotate the screw 102c, the electric pole 102 to fine-tune the position of the transformer 20 by rotating it in place at a certain angle. As such, the present invention uses the rotation of the electric pole 102, the vertical movement device 130, and the second and third hydraulic cylinders 140 and 150, as needed, to the position desired by the operator to the position of the transformer 20. Can be adjusted.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto. is within the scope of the right.

100: complete iron system of overhead distribution line connected to the transformer
110: horizontal position moving unit 120: vertical position moving unit
130: vertical movement device 140: first forward and backward movement device
150: second forward and backward movement device

Claims (2)

It includes an electric pole 102, and a longitudinal bar 104 coupled in the horizontal direction by a circular coupling band (not shown) on both upper ends of the electric pole 102,
The arm bar 104 is equipped with a horizontal position moving part 110 in the inner space, a slide groove 103 is dug in the longitudinal direction along one outer circumferential surface, and a connection member in the form of a flat plate through the slide groove 103 (117) protrudes to the outside,
The connecting member 117 combines the vertical position moving part 120 standing vertically at the end of one side, and the vertical position moving part 120 supports the overhead distribution line 10 in an insulated state 40, The suspension insulator 20 and the overhead distribution line 10 are connected, and the line post insulator 30 is vertically installed on the upper surface,
The line post insulator 30 combines the protection device 200 on the clamp 31 connecting the jumper wire 11 at the uppermost end,
The protection device 200 is horizontally on both sides of the line post insulator 30 at the top of the line post insulator 30 to protect the outside of the line post insulator 30 from various causes of wind, rain, and snow. To form a first wing portion 226 and a second wing portion 227 having a constant length and width in the direction,
The horizontal position moving unit 110 moves the arm iron 40, the suspension insulator 20 and the overhead distribution line 10 in the horizontal direction to arrange the overhead distribution line 10 that is tangled or pressed, A first screw 111 in the longitudinal direction is formed in a horizontal direction, a first bevel gear 113 is coupled to one end of the first screw 111 , and a second bevel gear 113 is formed in a vertical direction to the first bevel gear 113 . The bevel gear 114 is gear-engaged and meshed, the second bevel gear 114 is coupled to the first rotation shaft 115 of the first driving motor 116, and the first screw 111 is in the longitudinal direction. It is formed to be long and penetrates through the first moving block part 112 of a certain shape and is coupled, and the first moving block part 112 is the first screw 111 according to the driving of the first driving motor 116 . A complete iron system of overhead distribution lines connected to a transformer that reciprocates in the horizontal direction.
The method according to claim 1,
The electric pole 102 is coupled to the periphery of the electric pole 102 at an intermediate point, a cylindrical coupling member 107 of a cylindrical shape is coupled to the upper portion, and a fixed plate of a certain shape in which a vertical movement device 130 is coupled to the lower portion ( 105); and
A guide body (108a) in a cylindrical shape formed on the upper portion of the cylindrical coupling member (107) and fitted to the circumference of the electric pole (102), and a guide bar (108a) protruding in the vertical direction on the outer peripheral surface of the guide body (108a) ( Includes a guide member 108 for forming a plurality of 108b at regular intervals,
The vertical movement device 130 moves the first hydraulic cylinder 130 for elevating the fixing plate 105 by an annular attachment mechanism 40 to the lower portion of the fixing plate 105 in the circumferential direction of the electric pole 102 . A complete system of an overhead distribution line coupled to a plurality of couplings and connected to a transformer that elevates and lowers the fixing plate 105 along the guide bar 108b of the guide member 108 by the first hydraulic cylinder 130.

Images