KR102027910B1 - Distribution Line Apparatus for Strong Wind Damage Prevention - Google Patents

Abstract

The present invention relates to an overhead distribution line device for reducing strong wind damage and, more specifically, to an overhead distribution line device for reducing strong wind damage which blocks access of birds to distribution lines so as to prevent electric accidents, corrosion due to excretion of the birds and the like, and reduces damage due to strong wind such as a typhoon and the like.

Description

Distribution Line Apparatus for Strong Wind Damage Prevention

The present invention relates to a processed distribution line device that reduces the strong wind damage in the field of distribution technology, more specifically to prevent the electrical accident and corrosion due to the excretion of algae by blocking the access of algae to the distribution line, while typhoons The present invention relates to an overhead distribution line device that reduces the damage caused by strong winds.

In general, the distribution line is connected to the distribution tower and distributes the high-voltage current transmitted from the substation to customers, such as homes and businesses.

At this time, if a bird leaves the nest in a distribution tower or the like, a branch, a crest, as well as a conductor such as a wire and a high voltage short-circuit may cause an electric accident.

In addition, when the bird droppings on the distribution line, potassium (K) component of the bird droppings can be dissolved in rain or water vapor to accelerate the corrosion of the distribution line.

Such an electric accident and corrosion cause electric power to be cut through the distribution line, and the electric power cut off causes damage to electric power cut off to customers in companies or residential areas in production.

As a prior art which partially solves this problem, Korean Patent Registration No. 10-1897693 (2018.09.12.) Discloses a 'distribution line with a current elimination function'.

However, such a conventional distribution line does not easily cope with strong winds such as a typhoon, there is a problem that a safety accident may occur while the main body or the like is damaged or separated from the distribution line.

Republic of Korea Patent Registration No. 10-1897693 (2018.09.12.) 'Distribution line with bird control function'

The present invention has been made to solve the above problems, the object of the present invention is to block the access of algae to the distribution line to prevent electrical accidents and corrosion due to the excretion of the algae, while the strong winds such as typhoons It is to provide an overhead distribution line device with reduced wind damage to reduce the damage caused.

The problem to be solved of the present invention is not limited to those mentioned above, other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention includes a frame 110 including a receiving space therein and an opening 150 on the outer surface, and the wing of the circular structure is fixed to the outer surface of the frame 110 A main body 100 including an insulator wing 130 stacked spaced from each other; A direction module 300 including a bird repellent agent 310 subliming into the air to block the access of the bird and a case 330 for accommodating the bird repellent agent 310, and accommodated in the accommodation space; The penetrating core member 230 protruding from one side of the frame 110 and extending in the distribution line L direction, and a fixing base 250 and the penetrating core member for fixing the penetrating core member 230 to one surface of the frame 110. Connection portion 200 including a fastening table 210 for fastening the 230 and the distribution line (L); And a piezoelectric material 410 inserted between the fixing base 250 and one surface of the frame 110 and a heating electrode 470 connected to the piezoelectric material 410 and in contact with an upper portion of the case 330. In the power distribution line device to reduce the strong wind damage consisting of; 400, further comprising a support unit 500 to ensure the support for the direction module 300, the support unit 500 is A support plate 510 disposed below the main body 100; A holding ring 521 formed at an upper portion thereof, coupled to the distribution line L so as to be positioned at both sides of the main body 100, and a fixing bar 520 having a lower portion passing through the support plate 510; Binding means (530) for binding the locking ring (521) to the distribution line (L); A fixing member 540 which is screwed to the lower portion of the fixing bar 520 to bind the support plate 510 to the fixing bar 520; And support means 550 for supporting the case 330 from the support plate 510, wherein the binding means 530 is located between the power distribution line L and the hook 521. A close contact member 531 coupled to the outside of the furnace L; A pressing plate 532 coupled to the locking ring 521; And a binding member 533 which is screwed to the fixing bar 520 and binds the pressing plate 532 to the power distribution line (L). .

According to the present invention, as well as an electric accident due to the approach of the algae, there is an effect that can prevent corrosion of the distribution line due to the excretion of the algae.

In addition, there is an effect that can reduce the damage caused by strong winds, such as typhoons.

The effects of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a view showing the overhead distribution line apparatus to reduce the strong wind damage according to the present invention.
Figure 2 is a view for explaining the overhead distribution line apparatus reduced wind damage according to the present invention.
Figure 3 is a cross-sectional view for explaining the overhead distribution line apparatus to reduce the strong wind damage according to the present invention.
Figure 4 is a perspective view showing a direction module in the overhead distribution line device reduced wind damage according to the present invention.
Figure 5 is a cross-sectional view for explaining the release of algae avoidance in the overhead distribution line apparatus reduced wind damage according to the present invention.
6 is a cross-sectional view for explaining the release of the algae repellent when the heat deformation occurs in the overhead distribution line device to reduce the strong wind damage according to the present invention.
Figure 7 is a state diagram showing the use of the overhead distribution line apparatus reduced wind damage according to the present invention.
FIG. 8 is a partially enlarged view illustrating a state in which a bird approaches a power distribution line in FIG. 7.
FIG. 9 is a state diagram illustrating a state in which a power supply unit generates power due to a tidal flow in FIG. 7.
10 is a front view showing a state in which a support unit is provided in the overhead distribution line device to reduce the strong wind damage according to the present invention.
FIG. 11 is a side view illustrating the supporting part of FIG. 10. FIG.
And
12 is a perspective view of the buffer member of FIG. 10.

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

Referring to Figures 1 to 4, the overhead distribution line device 1000 according to the present invention reduced the wind damage damage the main body 100, the connection part 200, the direction module 300 to prevent the access of birds and power supply 400 ) To prevent electrical accidents caused by bird access.

The direction module 300 is housed in the bird repellent 310 to block the access of birds therein, the bird repellent 310 is distributed in the case 330 through the discharge hole (H), bird repellent 310 ) Is discharged out of the frame 100 through the vent 150.

Through this, the distribution line (1000) with a bird elimination function to prevent the access of birds around the distribution tower (P) to prevent electrical accidents, such as short circuits, short circuits that may occur due to birds and bird droppings Of course, it is possible to prevent corrosion of the distribution tower, the insulator structure, etc., due to the excrement discharged by algae.

The direction module 300 may control the amount of the bird repellent 310 is released to the outside of the frame 110 by adjusting the size of the emission hole (H).

The direction module 300 includes a case 330 for storing the algae repellent 310 and the algae repellent 310, the case 330 is the first metal layer 331a and the second thermal expansion coefficient is different The metal layer 331b may be bonded to each other, and may include an upper cap 331 including a discharge hole H passing through the first metal layer 331a and the second metal layer 331b.

At this time, when the temperature of the upper cap 331 increases, due to the difference in the coefficient of thermal expansion of the first metal layer 331a and the second metal layer 331b, the size of the discharge hole (H) increases in the direction Thermal deformation may occur.

Through this, the distribution line 1000 with the bird fighting function can adjust the amount of the bird repellent 310 is discharged according to the day and night.

That is, during the day when the approach of algae can be relatively frequent, the size of the discharge hole (H) can be increased to control the relatively large amount of algae repellent 310 is discharged. On the other hand, at night when the access of birds is relatively rare, the algae repellent 310 can be stored efficiently by reducing the amount of unnecessary discharge.

The distribution line 1000 with the bird elimination function may add the power supply unit 400 to generate electrical energy by the movement of the distribution line L, and convert it into thermal energy to supply the upper cap 331.

When the algae approaches the distribution line (L), the upper cap 331 is heated to release the algae repellent 310 additionally to effectively block the algae.

The main body 100 may function as a frame of the power distribution line 1000 having the bird elimination function, and may provide a predetermined space for storing the direction module 300 therein. To this end, the main body 100 may include a frame 110 and an aza wing 130.

The frame 110 may function as a frame of the distribution line 1000 having the bird fighting function. For example, the frame 110 may have a plate shape. In addition, the inside of the frame 110 may provide an accommodation space having a predetermined size, and may store the direction module 300 in the accommodation space.

The frame 110 may include a vent 150 for providing a flow path on one surface of the bird repellent 310 to be described later to be discharged to the outside of the frame 110.

The vent 150 may be located at one or more of the upper, lower, and side surfaces of the frame 110 to provide a passage through the frame 110.

The vents 150 may be spaced apart at predetermined intervals, and may be arranged in a circular shape surrounding the upper or side portions of the frame 110.

The frame 110 may fix the insulator wing 130 on the top or the side, and a predetermined surface for fixing the penetrating core material 230 to be described later on the surface perpendicular to the surface on which the insulator wing 130 is fixed. Through holes may be provided.

The insulator wing 130 may play a role of increasing the surface area of the insulator to improve insulation function.

The aza wing 130 may be manufactured using a material having excellent insulation, and may be manufactured by mixing any one or more materials of magnetic, glass, polymer, and CFRP.

As shown in FIGS. 2 and 3, the aza wing 130 may protrude from a surface perpendicular to a direction in which the frame 110 is connected to the power distribution line L among the upper or side surfaces of the frame 110. have.

For example, as shown in FIGS. 2 to 3, when the power distribution line L is spaced apart in the Z-axis direction with respect to the frame 110, an XY plane from the side of the frame 110 and from another viewpoint. It may protrude in the direction, but not shown in the drawings, but when the distribution line (L) is spaced in the X or Y direction with respect to the frame 110, the upper surface of the frame 110, YZ or XZ plane from another perspective Can protrude in a direction.

This is so that the agi wing 130, to prevent the interference with the power distribution line (L) should protrude in a direction perpendicular to the direction in which the distribution line (L) and the main body 100 is connected, the agi wing (130) This is because the protruding area can be widened.

The connection part 200 may serve to connect the main body 100 and the distribution line L, and may include a fastening table 210, a penetrating core material 230, and a fixing table 250. .

The fastening table 210 surrounds the distribution line L, and may be fixed to the distribution line L.

The through core material 230 protrudes from the outside of the frame 110 structure and may extend in a direction in which the distribution line L is located.

One surface of the penetrating core material 230 is fixed to the surface of the frame 110 and the surface 110 and the power distribution line (L) facing each other, the other surface is not fixed to the frame 110 May be fixed to the fastener 210. Through this, the through core material 230 may perform a function of connecting the frame 110 to the power distribution line (L).

The holder 250 may be located on the inner surface of the frame 110 to serve to fasten the penetrating core material 230 to the frame 110.

The holder 250 is located on a surface where the frame 110 and the through-core material 230 is in contact with one of the inner surface of the frame 110, the through-core material 230 to be fixed to one surface of the frame 110. Cohesion force can be provided to Through this, the frame 110 may be connected to the distribution line (L).

The direction module 300 may serve to block a bird approaching the distribution line 1000 having the bird elimination function, and may include a bird repellent 310 and a case 330 for this purpose.

The algae repellent 310 is made of a chemical that can block the access of algae, it may be released into the atmosphere through sublimation.

The algae repellent 310 may provide any one or more of methyl anthranilate cinnamon (cinnamon), aldehyde (aldehyde) and pention (fenthion), it may be made of a compound or natural material.

The case 330 stores the bird repellent 310, it may be stored in the receiving space of the frame (110). Through this, the case 330 may protect the algae repellent 310 from being exposed to the outside.

The case 330 may include an upper cap 331 that adjusts the amount of the algae repellent 310 is discharged thereon, the upper cap 331 is the first metal layer 331a, the second metal layer 331b and a discharge hole (H).

The first metal layer 331a may be manufactured in a plate shape having a predetermined volume. The first metal layer 331a may be arranged in an upper direction of the case 330, for example, in a + Z axis direction to cover the upper part of the case.

The first metal layer 331a may be made of a metal material having the first thermal window coefficient.

The second metal layer 331b may be manufactured in a plate shape having a predetermined volume and disposed on an upper end of the first metal layer 331a.

The second metal layer 331a may be made of a metal material having the second thermal window coefficient.

The second thermal expansion coefficient of the second metal layer 331b may be made of a metal lower than the first thermal expansion coefficient of the first metal layer 331a.

For example, the first metal layer 331a may be an alloy of any one of nickel-manganese-iron, nickel-molybdenum-iron, or nickel-manganese-copper having a relatively high coefficient of thermal expansion, whereas the second metal layer ( 331b) may be an alloy of iron-nickel having a relatively low coefficient of thermal expansion.

The first metal layer 331a and the second metal layer 331b may be sequentially disposed, for example, in the + Z axis direction based on an upper end of the case 330.

The emission hole H may provide a through hole penetrating the first metal layer 331a and the second metal layer 331b. Through this, the algae repellent agent 310 may be discharged from the inside of the case 330 and provided in the accommodation space of the frame 110.

According to an embodiment, the discharge hole H may extend in a direction parallel to the top of the case, for example, in an X or Y axis direction, through which the first metal layer 331a and the second metal layer 331b are formed. It can provide a play when heat deformation occurs in the furnace.

The power supply unit 400 converts the physical energy between the power distribution line 1000 and the power distribution line (L) with the current elimination function into electrical energy, and serves to heat the upper cap 333 by using electrical energy. Can be performed. To this end, the power supply unit 400 may include a piezoelectric material 410 and a heating electrode 470.

The piezoelectric material 410 may be inserted at a position where one surface of the holder 210 and the frame 110 face each other, and one surface of the piezoelectric material 410 is a through material 230 of the frame 110. It may be in contact with the surface fixed to, the other surface of the piezoelectric material 410 is in contact with the holder 210, it may wrap the through material 230.

The heating electrode 470 may be in contact with the upper cap 333, and may surround the outside of the upper cap 333.

The heating electrode 470 may be electrically connected to the piezoelectric material 410 to receive electrical energy from the piezoelectric material 410 to heat the upper cap 333.

When the distribution line (L) is moved, the piezoelectric material 410 may convert the electrical energy of the movement of the distribution line (L), it may supply the converted electrical energy to the heating electrode (470).

The heating electrode 470 may heat the upper cap 333 through the electrical energy supplied from the piezoelectric material 410.

In this case, thermal deformation of the first metal layer 331a and the second metal layer 331b occurs due to heating, and the direction module 300 may switch from the first state to the second state due to heat deformation. Can be.

That is, the power supply unit 400 may generate electrical energy through the movement of the distribution line L, and heat the upper cap 333 with the generated electrical energy to activate that the algae repellent 310 is released. have.

Hereinafter, an operation state of the direction module 300 will be described with reference to FIGS. 5 to 6.

Referring to FIG. 5, when the thermal deformation does not occur because the temperature is low around the direction module 300, the upper cap 331 may have a state of minimizing the width of the discharge hole (H). The state may be defined as a first state.

In the first state, it is possible to minimize the sublimation algae repellent 310v is discharged out of the direction module 300 through the discharge hole (H).

In the first state, the first metal layer 331a and the second metal layer 331b of the upper cap 331 extend in a direction covering the upper portion of the case 330, for example, in an X axis direction. It can have Through this, the first metal layer 331a and the second metal layer 331b extending in the X-axis direction may minimize the width of the emission hole H.

In this case, it is possible to minimize the algae repellent 310 to change to the sublimed algae repellent 310v, it is possible to reduce the amount of the algae repellent 310 is consumed.

 Referring to FIG. 6, when heat deformation occurs due to a high temperature around the direction module 300, the upper cap 331 may have a state of increasing the width of the discharge hole (H). The state may be defined as a second state.

In the second state, it is possible to maximize the sublimation algae repellent 310v is discharged out of the direction module 300 through the discharge hole (H).

In the second state, the first metal layer 331a and the second metal layer 331b of the upper cap 331 are deformed in a direction in which the upper portion of the case 330 is opened, for example, in the + Z axis direction. Can be. Through this, the first metal layer 331a and the second metal layer 331b deformed in the + Z axis direction may increase the width of the emission hole H.

In this case, sublimation of the algae repellent 310 is activated to generate more sublimated algae repellent 310v, thereby increasing the consumption of the algae repellent 310.

Through this, the consumption of the bird repellent 310 can be adjusted by switching between the first state and the second state of the direction module 300.

When the temperature at which the transition occurs to the first state or the second state is defined as the transition temperature, by adjusting to a specific point of the day and night temperature difference of the point where the distribution line 1000 with the current elimination function is installed, During the day when the approach of the bird is active, the direction module 300 is switched to the second state to block the access of the bird. On the contrary, at night when the access of the bird is stagnated, the direction module 300 is switched to the first state. By controlling the consumption of the algae repellent 310.

7 to 8, in the distribution line 1000 having the tidal current suppressing function, when the tidal current does not approach the distribution line L, the first temperature according to the ambient temperature of the direction module 300 is determined. The state and the second state can be switched.

However, when the bird approaches the distribution line (L) to move the distribution line (L), or as shown in Figure 9, when the bird sits on the distribution line (L), due to the weight of the distribution line (L) ) Can be exerted a tensile force (F).

At this time, the distribution line (L) can move the fastening table 210 due to the tensile force (F), the fastening table 210 is the fixing table (250) through the penetrating core material 230 through the tensile force (F) ) Can be delivered. The fixture 250 may receive the tension (F) to compress or stretch the piezoelectric material 410 and deform (T).

Through this, the piezoelectric material 410 may produce electrical energy, and the heating electrode 470 may heat the upper cap 333 to switch the direction module 300 to the second state.

In other words, when the bird sits on the distribution line (L), the tensile force (F) is generated, the piezoelectric material 410 receives the tensile force (F) is deformed by compression or tension (T) to convert the tensile force (T) into electrical energy In addition, the heating electrode 470 may convert the electrical energy into thermal energy to heat the upper cap 333. Through this, the bird repellent 310 may be activated to be released.

Processed distribution line (1000) equipped with a bird elimination function according to the present invention by activating the release of the algae repellent 310 when the algae approached to prevent algae access around the distribution tower (P) to the algae and algae feces It is possible to prevent electrical accidents such as short circuits, short circuits, etc., which may occur, and to prevent corrosion of the distribution tower (P) or insulator structure caused by bird droppings.

In addition, the generation of algae can operate the direction module 300 to save the algae repellent 310 to extend the life of the direction module 300.

The overhead distribution line device 100 having reduced strong wind damage according to the present invention further includes a support part 500 for stably supporting the direction module 300 as shown in FIGS. 10 to 12.

The support part 500 prevents breakage from the distribution line L together with damage that may occur while the main body 100 is shaken by a strong wind such as a typhoon.

The support part 500 is coupled to the distribution line (L) to be located on both sides of the main body 100 is formed with a support plate 510, a hook 521 is formed on the upper side of the main body 100 While the lower portion of the fixing bar 520 passing through the support plate 510, the fastening means 530 for binding the hook 521 to the power distribution line (L), screwed to the lower portion of the fixing bar 520 And a fixing member 540 for binding the support plate 510 to the fixing bar 520 and support means 550 for supporting the case 330 from the support plate 510.

The support plate 510 forms a square plate extending in the longitudinal direction of the distribution line (L).

The fixing bar 520 is bent in the downward direction as the top is formed with a hook 521, such as '∩' on the top.

The hook 521 is coupled to the distribution line (L) so that the fixing bar 520 is located on both sides of the main body 100.

The binding means 530 is a close contact member 531 coupled to the outside of the distribution line (L) to be located between the distribution line (L) and the hook 521, the pressing plate coupled to the locking ring (521) ( 532 and a binding member 533 which is screwed to the fixing bar 520 to bind the pressing plate 532 to the distribution line (L).

The contact member 531 may be made of silicon or rubber material, and preferably formed of a plate shape to surround the outside of the power distribution line (L).

The pressing plate 532 is coupled to both ends of the hook 521 to be positioned below the distribution line (L). Here, the hook 521 may be understood that one end is integral with the fixing bar 520.

Accordingly, the fixing bar 520 may be understood that the pressing plate 532 is coupled upward from the bottom of the fixing bar 520 while both ends are directed downward.

The locking ring 521 is screwed to the outer peripheral surface and the binding member 533 is screwed to the locking ring 521 while the thread is formed on the inner peripheral surface.

The binding member 533 allows the pressing plate 532 to be in close contact with the distribution line (L) in accordance with the tightening rotation so that the fixing bar 520 can be stably fixed to the distribution line (L).

The fixing bar 520 is a screw thread is formed on the lower outer peripheral surface, the fixing member 540 is screwed to the lower outer side of the fixing bar 520 while the thread is formed on the inner peripheral surface.

The fixing member 540 is screwed to the fixing bar 520 so that the support plate 510 is supported by the fixing bar 520.

The fixing member 540 may adjust the separation distance between the support plate 510 and the main body 100 while moving in the longitudinal direction of the fixing bar 520 as it rotates.

In other words, the fixing member 540 may be stably supported by the support means 550 by adjusting the separation distance between the support plate 510 and the main body 100 according to rotation. Position can be adjusted.

The support means 550 is a support plate 551 which is located at the bottom of the main body 100, the support bar 552 is fixed to the mounting plate 551, the lower portion passes through the support plate 510 and The spring 553 is coupled to the outside of the support bar 552 to be located between the mounting plate 551 and the support plate 510.

The mounting plate 551 may be rotatably connected to the lower portion of the support bar 552 through a hinge coupling or the like.

The spring 553 presses the mounting plate 551 upward so that the mounting plate 551 is in contact with the lower portion of the main body 100.

The spring 553 contracts and relaxes the body 100 due to an external force such as a strong wind, and contracts and relaxes according to left and right rotations, while cushioning the shock while restoring the body 100 to its original state smoothly. To be done.

The support bar 552 is guided so that the contraction, relaxation of the spring 553 is made smoothly while moving up and down together in accordance with the vertical movement of the main body 100 by an external force.

The support means 550 may further include a buffer member 554 disposed on both sides of the support plate 510 with respect to the support bar 552 to support both sides of the main body 100.

The buffer member 554 may be formed of a leaf spring 555 having a shape such as '⊂' and a coating layer 556 surrounding the leaf spring 555 while one side is opened.

The coating layer 556 may be made of silicon, rubber, or the like.

The pair of shock absorbing members 554 symmetrically symmetrically around the support bar 552 while cushioning and relaxing the shock according to the left and right shaking of the main body 100 by external force, while cushioning the shock while the main body ( 100) to restore to the original state smoothly.

For this reason, the support part 500 may prevent breakage from the distribution line L together with damage that may occur while the main body 100 is shaken by a strong wind such as a typhoon.

What has been described above is only an embodiment for implementing the overhead distribution line apparatus with reduced strong wind damage according to the present invention, the present invention is not limited to the above embodiment, as claimed in the following claims Without departing from the gist of the invention, anyone of ordinary skill in the art to which the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

100: main body 110: frame
130: aza wing 200: connection portion
300: direction module 310: algae repellent
330: case 400: power supply
410: piezoelectric material 470: heating electrode
500: support portion 510: support plate
520: fixed bar 530: binding means
540: fixing member 550: support means

Claims (1)

A frame 110 including an accommodation space therein and having an opening 150 formed on an outer surface thereof, and an insulated wing 130 fixed to an outer surface of the frame 110 and having wings of a circular structure spaced apart from each other and stacked Body 100 including;
A direction module 300 including a bird repellent agent 310 subliming into the air to block the access of the bird and a case 330 for accommodating the bird repellent agent 310, and accommodated in the accommodation space;
The penetrating core member 230 protruding from one side of the frame 110 and extending in the distribution line L direction, and a fixing base 250 and the penetrating core member for fixing the penetrating core member 230 to one surface of the frame 110. Connection portion 200 including a fastening table 210 for fastening the 230 and the distribution line (L); And
A piezoelectric material 410 inserted between the fixing member 250 and one surface of the frame 110 and a heating electrode 470 connected to the piezoelectric material 410 and in contact with an upper portion of the case 330. In the power distribution line device reduced the strong wind damage consisting of;
The support unit 500 to prevent the departure from the distribution line (L) with the damage that can be generated while the main body 100 is shaken by the strong wind to ensure that the support for the direction module 300 is made more stable. Include,
The support part 500,
A support plate 510 disposed below the main body 100;
A hook 521 having a '∩' shape is formed at an upper portion thereof, coupled to the distribution line L so as to be positioned at both sides of the main body 100, and a fixed bar 520 having a lower portion passing through the support plate 510. ;
Binding means (530) for binding the locking ring (521) to the distribution line (L);
A fixing member 540 which is screwed to the lower portion of the fixing bar 520 to bind the support plate 510 to the fixing bar 520; And
It includes a support means 550 for supporting the case 330 from the support plate 510,
The binding means 530,
A close contact member 531 formed in a plate shape and coupled to surround the outside of the distribution line L so as to be located between the distribution line L and the hook 521;
A pressing plate 532 coupled to both ends of the hook 521 so as to be positioned below the distribution line (L); And
And a binding member 533 which is screwed to both ends of the hook 521 to bind the pressing plate 532 to the distribution line L.
The binding member 533 is,
The pressing plate 532 is in close contact with the distribution line (L) in accordance with the tightening rotation so that the fixing bar 520 is stably fixed to the distribution line (L)
The support means 550,
A mounting plate 551 positioned below the main body 100;
A support bar 552 having an upper portion fixed to the mounting plate 551 and a lower portion passing through the supporting plate 510;
The mounting plate 551 is coupled to the outside of the support bar 552 so as to be positioned between the mounting plate 551 and the support plate 510, and the mounting plate 551 is pressed upwards so that the mounting plate 551 is the main body 100. A spring 553 in contact with the spring; And
It includes a buffer member 554 is disposed on both sides of the support plate 510 around the support bar 552 to support both sides of the main body 100,
The mounting plate 551 is,
It is rotatably connected to the lower portion of the support bar 552 by a hinge coupling,
The buffer member 554 is,
One side is open and the leaf spring 555 forming a shape such as '⊂'; And
It includes a coating layer 556 surrounding the leaf spring 555, while symmetrical about the support bar 552 while contracting, relaxing according to the left and right shake of the main body 100 by the external force to cushion the shock On the other hand, the overhead distribution line apparatus with reduced strong wind damage, characterized in that to restore the original state to the main body 100 smoothly.

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