KR101142171B1 - Power distribution cable line structure - Google Patents

Abstract

PURPOSE: A distribution line structure is provided to prevent the damage of a solar battery due to strong wind by controlling installation height of the solar battery and to prevent an error of a vibration generating device. CONSTITUTION: A support stand(2) comprises a lower(2a) and an upper support stand(2b) installed at the ground or rooftop. A supporting plate(3) is horizontally fixed to the upper end of the upper support stand. A fixture(4) is installed in four corners of the supporting plate. A solar battery(1) is fixed to the upper end of the fixture in order to put opposite in the supporting plate. A current collecting part(8) collects electricity crated from the solar battery. A transferring part selectively interlinks distribution lines having an allowable current corresponding to amount of the electricity transferred from the current collecting part.

Description

Distribution line structure that can adjust wiring position according to the concentration of solar cell {Power distribution cable line structure}

The present invention is capable of adjusting the wiring position of the distribution line according to the degree of concentration of the solar cell, can prevent birds from nesting on the support plate of the solar cell, and prevent the damage of the solar cell by the wind of the solar cell It relates to a distribution line structure capable of adjusting the wiring position according to the degree of condensing.

1 is a side view illustrating a structure of a distribution line used for power generation using a conventional solar cell. In the case of a distribution line structure used for power generation using a conventional solar cell, a support (2) fixed to the ground, a support plate (3) fixed to the upper end of the support (2), and fixed to an upper surface of the support plate (3) A mounting stand 4 for fixing the solar cell 1 to be fixed, a solar cell 1 fixed to the upper end of the fixing stand 4, and a distribution line for transmitting electricity generated from the solar cell 1. (5) and a cap (6) for protecting the power distribution line (5).

The solar cell 1 is generally installed spaced apart from the ground as shown in FIG. This is because the high position can receive sunlight without disturbing the surrounding obstacles, and can protect the solar cell from various pollutions and animals. By installing solar cells away from the ground, the solar cells can be efficiently protected from terrestrial animals. However, the protection from free-flying birds was inadequate. In particular, the space between the solar cell (1) and the support plate (3) can avoid rain, sunlight, etc., because the ground animals are inaccessible to protect the eggs, birds often nested.

As described above, when the birds build a nest, the solar cell 1 may be contaminated due to bird droppings, and the damage of the solar cell may be caused by the metal wire used to build the nest.

In addition, in the case of solar cells, because of being installed at a relatively high position there was also a problem that strong wind is vulnerable to wealth.

In addition, since the solar cell 1 produces electricity by using sunlight as an energy source, the amount of power generated by the weather is large.

The present invention is to solve the above problems, it is possible to selectively connect the distribution lines having different allowable current capacity according to the degree of condensation of the solar cell, to prevent birds from nesting in the space between the solar cell and the support plate. The purpose of the present invention is to provide a distribution line structure capable of adjusting the wiring position according to the condensing degree of the solar cell of the new structure that can adjust the installation height of the solar cell to prevent damage caused by strong wind.

The present invention for achieving the above object,

A support (2) having a lower support (2a) placed on the ground or a roof, and an upper support (2b) movably inserted and fixed in the longitudinal direction of the lower support (2a);

A support plate 3 fixed horizontally to an upper end of the upper support 2b;

Fixtures (4) are installed on the four corners of the support plate;

A solar cell (1) fixed to an upper end of the holder (4) to face the support plate (3);

A current collector 8 having a plurality of adapters 8a for collecting current produced from a plurality of solar cells;

A plurality of distribution lines 5 having different allowable currents, a current collector 5b for electrically conducting a selected one of the distribution lines 5 and the adapter 8a, and the distribution lines 5 in a semi-cylindrical shape. A transmission unit 7 having a cap 6 installed to enclose a);

A transformer (9) for transforming the electricity received from the power distribution line energized with the current collector (5b); And

It is composed of a long bar shape to the left and right, both sides are provided with a lifting guide 11 in the vertical direction and is fixed to the upper surface of the support plate 3 and the support bar 10, and in the form of a long metal pipe left and right inside It is configured to be installed in the elevating guide (11) in the up and down direction so as to be located above the support bar 10, the elevating block 20 is formed with a projection 23 on the lower side, and both ends of the elevating block ( The spring 30 is connected to the support bar 10 and the lifting block 20 is lowered, and the elastic bar 41 and the elastic bar 41 fixed to the inside of the lifting block 20. Hammer 40 having a head portion 42 of the metal material provided at the front end to hit the inner surface of the elevating block 20 during the elevating of the elevating block 20, and the support bar 10 and Slidably installed in the left and right directions on the upper surface of the support bar 10 to be located between the lifting block 20 And the upper surface is formed with a projection 51 corresponding to the projection 23 of the lifting block 20 and slides to the left and right, the slide block 50 to lift the lifting block 20 and the slide block 50 It is connected to the) includes a slide drive mechanism 60 to slide the slide block 50 in the left and right directions,

The slide drive mechanism 60 is configured to wind the windmill 61 rotated by the wind, the rotary shaft 62 connected to the windmill 61, and a elastic metal plate spirally having an inner end and an outer end. A spring 63 fixed to the circumferential surface of the rotary shaft 62, a ratchet mechanism 64 coupled to the rotary shaft 62 so that the rotary shaft 62 is rotated only on the winding side of the spring 63; Rotating cylinder 65 is coupled to surround the outer side of the mainspring 63 and the outer end of the mainspring 63 is fixed and a through hole 65a through which the rotating shaft 62 passes, and the rotation. The drive shaft 66 is connected to the other side of the cylinder 65 to be coaxial with the rotation shaft 62, and is installed at the end of the drive shaft 66 and connected to the slide block 50, the rotational movement of the drive shaft 66 The crank mechanism 67 for changing the reciprocating motion so that the slide block 50 is moved forward and backward, It is coupled to the intermediate portion of the drive shaft 66 and the braking mechanism 68 for braking the drive shaft 66 and the support bar 10 so as to be located above the lifting block 20 is rotatably installed in the vertical direction The control bar 69 and the plurality of solenoids 70c are connected to the brake mechanism 68 to release the braking action of the brake mechanism 68 when rotated downward, and the plurality of solenoids 70c are driven. A fixing device 70 radially disposed at the center and the grab 70c2 formed at the end of the plunger 70c1 in contact with the outer surface of the drive shaft 66 when the solenoid 70c is energized to prevent rotation of the drive shaft 66. Equipped vibration generating device (B);

Characterized in that it comprises a.

In the distribution line structure capable of adjusting the wiring position according to the concentration of the solar cell according to the present invention, when the birds are placed on the upper surface of the support plate to build a nest, etc., the control bar rotates to the lower side by the weight of the braking mechanism. By the force of the mainspring, the crank mechanism moves forward and backward the slide block, causing the lifting block to swing up and down, and generating noise, thereby preventing birds from nesting on the upper surface of the support plate. If the wind is strong, the height of the support can be adjusted to lower the position of the solar cell, thereby preventing the damage of the solar cell due to the strong wind. There is an effect that can prevent the malfunction of the vibration generating device due to the impact of the city.

1 is a side configuration diagram showing a distribution line structure used for power generation using a conventional solar cell;
2 is a side configuration view showing a distribution structure according to the present invention;
3 is a configuration diagram showing a part of a distribution structure according to the present invention,
Figure 4 is a side configuration view showing a vibration generating device of the distribution line structure according to the present invention,
5 is an exploded view showing a vibration generating device of the distribution line structure according to the present invention,
Figure 6 is a block diagram showing a slide drive mechanism of the distribution line structure according to the present invention,
7 is a plan view showing a windmill of a distribution line structure according to the present invention;
8 is a side sectional view showing a main body and a rotating cylinder of a distribution line structure according to the present invention;
9 is a side view showing a ratchet mechanism of a distribution line structure according to the present invention;
10 is a side view showing a crank mechanism of a distribution line structure according to the present invention;
11 is a side view showing a braking mechanism of a distribution line structure according to the present invention;
12 is a side view illustrating a fixing mechanism of a distribution line structure according to the present invention.

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

2 to 12 illustrate a distribution line structure capable of adjusting a wiring position according to the degree of condensing of a solar cell according to the present invention. It is fixedly installed on the back, the support plate 3 is fixed to the upper end of the support (2) in the form of bolted or welded, and the support (4) fixedly installed in the form of bolted or welded on the upper surface of the support plate (3) and The solar cell 1 is fixedly installed at the upper end of the stator 4 in the form of bolted or welded joints, and a current collector 8 for collecting electricity generated from a plurality of solar cells, and from the current collector 8. Transmitter 7 for transmitting the current transmitted by selectively combining the distribution line having the allowable current corresponding to the amount of power transmitted, transformer 7 and the saddle for transforming the electricity received from the transmitter 7 Image of support plate (3) To include a vibration generator (B) to prevent the build nests.

The support 2 and the fixing stand 4 are in the form of a hollow metal square frame, and the support plate 3 is in the shape of a hollow metal flat plate.

The support 2 is composed of a lower support 2a and an upper support 2b, and the upper support 2b is inserted into the lower support 2a so as to be movable. The upper support 2b is fixed by bolting the through grooves formed in the upper support 2b and the lower support 2a to each other, and the plurality of through grooves are formed in the upper support 2b for fixing after movement. Therefore, in the case of moving the upper support (2b) can be fixed by releasing the bolt coupling and moving again after the bolt coupling.

The electricity produced by the solar cell 1 is transmitted to the distribution line 5 through a wire (not shown) connected to the solar cell 1, and the distribution line 5 transmits and distributes the received electricity to the customer. The electric wires are built in the inside of the holder 4 and the support plate 3 and the support 2 to protect the wires from the external environment. The distribution line 5 installed on the ground or the roof extends long for transmission and distribution, and a cap 6 is installed on the distribution line to protect the distribution line 5 exposed to the ground or the roof of a building. The cap 6 may be made of metal, reinforced plastic, or the like having a strength such that the distribution line 5 is not damaged by the force applied to the upper portion of the cap 6 in a semi-circular long tubular shape.

One surface of the lower support (2a) is fixed to the current collector (8). The current collector 8 collects electricity generated from a plurality of solar cells and transfers the electricity to the distribution line 5. The current collector 6 has a rectangular frame shape, and a plurality of adapters 8a are formed on one surface thereof, and the adapter 8a is connected to the current collector 5b of the transmission unit 7 by a conductor (not shown). Is energized. The electricity produced from the solar cell is connected to the solar cell and the other end is inserted into the adapter (8a) is transmitted to the current collector (8) through the electric wire (L) that is energized with the adapter (8a).

The transmission unit 7 is composed of a current collector 5b, a plurality of distribution lines 5 and a cap 6.

The current collector 5b transmits electricity transmitted from the current collector 8 to the distribution line 5, and is electrically coupled with one of the plurality of distribution lines.

A plurality of distribution lines 5 are provided, and each of the distribution lines 5 has a different allowable current specification. In other words, a distribution line having a specification of an allowable current corresponding to the amount of power generated by a solar cell may be used in combination with a current collector. One end of the distribution line 5 is electrically coupled to the current collector 5b, and the other end is electrically coupled to the transformer 9.

The transformer 9 transforms the electricity received from the power distribution line 5 into a voltage suitable for use by the customer or power transmission.

Vibration generating device (B) is fixedly installed on the upper surface of the support plate 3, to prevent the bird nesting on the support plate (3).

The vibration generating device (B), as shown in Figures 2, 4 and 5, the support bar 10, the elevating block 20 is located on the upper portion of the support bar 10, and both ends A spring 30 connected to the support bar 10 and the elevating block 20, a hammer 40 installed in the elevating block 20, and the support bar 10 and the elevating block 20. The slide block 50 is provided between the slide drive mechanism 60 is connected to the slide block (50).

To explain this in detail, the support bar 10 is configured in a long bar shape to the left and right, and the lifting guide 11 in which the lifting block 20 is installed on both sides extends in the vertical direction, and of the supporting plate 3 It is fixed to the top by bolts. The elevating guide 11 is formed in a rod shape vertically long extending from the four corners of the support bar 10 to the upper side.

As shown in FIG. 4, the elevating block 20 is formed in a pipe shape of a metal material that is long in the left and right and has an empty inside, and is vertically disposed in the elevating guide 11 so as to be positioned above the support bar 10. It is installed to be elevated. At this time, the lifting block 20 is formed with a through hole 21 in the vertical direction in which the lifting guide 11 is fitted, and is configured to be elevated in the vertical direction along the lifting guide 11. In addition, the lower side of the lifting block 20 is provided with a plurality of protrusions 23 are spaced apart at regular intervals in the left and right directions. The protrusion 23 is composed of a triangle in which both sides are inclined.

Both ends of the spring 30 are connected to the left and right ends of the support bar 10 and the lifting block 20, respectively, so that the lifting block 20 is lowered to be in close contact with the upper surface of the slide block 50.

As shown in FIG. 5, the hammer 40 has an elastic bar 41 fixed to the inside of the elevating block 20, and a metal head 42 provided at the front end of the elastic bar 41. The elastic bar 41 is installed so that the front end portion can flow in the vertical direction, and the head portion 42 is fixed from the inner upper and lower sides of the elevating block 20 at the front end of the elastic bar 41. It is installed to be spaced apart. Therefore, when the lifting block 20 is vibrated in the up and down direction, the head portion 42 of the hammer 40 is vibrated in the up and down direction to collide with the inner surface of the lifting block 20 to generate noise and vibration. do. At this time, openings 22 are formed at both sides of the lifting block 20 so that the noise generated by the hammer 40 is amplified inside the lifting block 20 and then discharged to the outside through the opening 22. It is configured to be.

The slide block 50 is configured in a long block shape to the left and right, and is slidably installed in the left and right directions on the upper surface of the support bar 10 to be located between the support bar 10 and the lifting block 20. The upper surface is formed with a protrusion 51 corresponding to the protrusion 23 of the lifting block 20. The protrusions 51 are formed of triangles, both sides of which are inclined, such as the protrusions 23 of the elevating block 20. When the slide block 50 is slid left and right, the elevating blocks are formed by the protrusions 23 and 51. As the 20 is elevated in the vertical direction, the lifting block 20 is configured to generate noise and vibration by hitting the upper surface of the slide block 50.

6 to 12, the slide drive mechanism 60 is rotated by the wind, the windmill 61, the rotary shaft 62 connected to the windmill 61, and the rotary shaft 62 is connected A spring 63 and a ratchet mechanism 64 coupled to the rotational shaft 62 so as to rotate only the side in which the rotational shaft 62 is wound, and coupled to surround the outside of the mainspring 63. The outer end of the mainspring 63 is fixed and the rotating cylinder 65 is formed on one side of the through-hole 65a through which the rotating shaft 62 penetrates, and the drive shaft 66 connected to the other side of the rotating cylinder 65. And a crank mechanism 67 installed at an end of the drive shaft 66 and connected to the slide block 50 to change the rotational movement of the drive shaft 66 into a reciprocating motion so that the slide block 50 moves forward and backward. A braking mechanism 68 coupled to an intermediate portion of the drive shaft 66 to brake the drive shaft 66; and the lifting block 20; Is installed in the support bar 10 to be rotatable in the up and down direction so as to be positioned at an upper portion thereof, and is connected to the braking mechanism 68 to be rotated downward to release the braking action of the braking mechanism 68 so that the driving shaft 66 is When the solar cell 1 is lowered close to the ground by adjusting the length of the control bar 69 and the supporter 2 to be rotated, the engagement between the brake member 68b and the disk 68a is released by an impact or the like, and the driving shaft 66 Rotation) is composed of a fixing device 70 for fixing the drive shaft 66 to prevent the vibration generating device (B) from operating.

As shown in FIG. 7, the windmill 61 is configured by installing a cup 61b at an end of the arm 61a extending radially from the end of the rotation shaft 62. It is rotated only in one direction (in this embodiment, clockwise when viewed from the top). Since the windmill 61 of this type is widely used, detailed description thereof will be omitted.

As shown in FIG. 6, the rotating shaft 62 is connected to the windmill 61 and is rotatably supported by being coupled to a bearing 62a provided on an upper surface of the metal bar 2. At this time, the rotating shaft 62 is composed of a vertical portion 62b and a horizontal portion 62c connected to each other by a bevel gear, so that the windmill 61 may be installed on the upper end of the vertical portion 62b. Therefore, when the windmill 61 is rotated clockwise as shown in FIG. 7, the horizontal portion 62c of the rotating shaft 62 is viewed from the right side of the slide driving mechanism 60 as shown in FIG. 9. When it is rotated counterclockwise.

As illustrated in FIG. 8, the mainspring 63 is formed by winding a resilient metal plate in a spiral shape having an inner end and an outer end, and an inner side thereof is fixed to a circumferential surface of the rotation shaft 62. At this time, the mainspring 63 is configured to be wound when the rotating shaft 62 is rotated counterclockwise by being wound in a right spiral direction at an inner end fixed to the circumference of the rotating shaft 62.

As shown in FIG. 9, the ratchet mechanism 64 is coupled to the rotational shaft 62 and has a disk 64a having teeth inclined to one side thereof on a circumferential surface thereof, and a fixing unit 64b provided at the metal bar 2. And ratchet bolts 64c coupled to the fixing member 64b so as to be able to move forward and backward and pressed to protrude forward by a spring so that the front end portion is engaged with the teeth of the disk 64a so that the disk 64a rotates in only one direction. It is composed of At this time, the disk 64a and the ratchet bolt 64c are rotated only in the direction in which the rotating shaft 62 is wound (counterclockwise), and is supported so that the rotating shaft 62 is not rotated in the unwinding direction. It is configured to. As such, the ratchet mechanism 64 for rotating the rotation shaft 62 only in one direction is generally used, and thus detailed description thereof will be omitted.

6 and 8, the rotating cylinder 65 is formed in a cylindrical shape of the synthetic resin material and is coupled to the outside of the mainspring 63 to protect the mainspring 63 from dust, snow, and rain. And, it functions to connect the drive shaft 66 to the outer end of the mainspring (63).

The drive shaft 66 is made of a high strength metal material is connected to the other side of the rotating cylinder 65 to be coaxial with the rotating shaft 62, the bearing 66a is provided on the upper surface of the metal bar (2) Is rotatably supported.

As shown in FIG. 10, the crank mechanism 67 has a crank arm 67a connected to an end of the drive shaft 66, and both ends thereof are hinged to the crank arm 67a and the slide block 50. As shown in FIG. The rod 67b is configured to slide the slide block 50 in left and right directions when the driving shaft 66 is rotated so that the slide block 50 reciprocates in the left and right directions.

As shown in FIG. 11, the brake mechanism 68 is rotated toward the disk 68a by the disk 68a coupled to the drive shaft 66 and the bracket 2a provided on the support plate 3. And a spring 68c connected to the braking member 68b and connected to the braking member 68b so that the braking member 68b engages with the disk 68a. Teeth to which the braking member 68b is engaged are formed. Therefore, the braking member 68b is normally engaged with the teeth of the disk 68a by the spring 68c to fix the driving shaft 66 so as not to rotate in the direction in which the spring 63 is released, and the control bar 69 is fixed. When the braking member 86b is pulled by, the coupling of the braking member 86b and the disk 68a is released and the driving shaft 66 is rotated by the spring 63.

As shown in FIG. 3, the control bar 69 has a long and thin rod shape to the left and right. The control bar 69 is disposed to extend in the longitudinal direction of the elevating block 20, and the proximal end thereof is an elevating guide of the support bar 10. 11) the main body 69a hinged to be rotated in the up and down direction, and extends upward from the base end of the main body 69a, and is connected to the braking member 68b of the braking mechanism 68 by a wire 69c. When the bar body 69a is rotated downward, as shown by a dotted line in FIG. 10, the extension bar 69b is connected to the braking member through a wire 69c. Pull 68b to allow braking of the brake mechanism 68 to be released.

As shown in FIG. 12, the fixing device 70 is a metal hexahedron shape, the body 70a having through holes 70b penetrating both sides thereof, and the hollow formed on the outer surface of the through holes 70b. It consists of a solenoid (70c) which is built in, the drive shaft 66 is installed to pass through the through hole (70b). The plunger 70c1 of the solenoid 70c is exposed to the through hole 70b, and one end of the plunger 70c1 is provided with a grab 70c2 to prevent rotation of the drive shaft 66. The grab 70c2 has a shape corresponding to the outer surface of the drive shaft 66 and is formed of a rubber material to increase the friction force between the drive shaft 66 and the grab 70c2 to more effectively prevent rotation of the drive shaft 66. Since the solenoid 70c inserts or inserts the plunger 70c1 in response to an electrical signal, a detailed description thereof will be omitted. Although not shown in the drawing, an electric wire for supplying electricity for operating the solenoid 70c is installed, and the electric wire is connected to a switch (not shown) attached to an outer surface of the support 2.

At this time, the installation position or arrangement of the vibration generating device (B) can be freely adjusted.

Referring to the operation of the distribution line structure capable of adjusting the wiring position according to the degree of condensation of the solar cell configured as described above are as follows.

First, when the distribution line 5 is to be replaced in response to the amount of power generated by the solar cell 1 according to the weather, the coupling between the cap 6 and the current collector 5b for protecting the distribution line 5 is released. The coupling between the current collector 5b and the cap 6 can use various known fastening means such as bolt fastening and pin fastening. After the separation of the cap 6, the operator selects a distribution line having a desired allowable current to connect the current collector 5b and the distribution line. The coupling method uses a method of inserting and coupling the groove (not shown) formed in the current collector 5b and the connection terminal 5a formed at the end of the distribution line. In addition, various coupling methods that can be electrically energized may be used. Can be. After the coupling between the current collector 5b and the distribution line is completed, the operator performs the coupling between the distribution line and the transformer 9 in the above manner. After completion of the joining operation of the distribution line, the operator fixedly couples the cap 6 with the current collector 5b and the transformer 9 to protect the distribution line 5 from contamination and the external environment.

Next, the operation of the vibration preventing mechanism B will be described.

When the wind blows, the windmill 61 is rotated in a predetermined direction, and thus, the rotation shaft 62 connected to the windmill 61 is rotated to wind the mainspring 63. At this time, since the ratchet mechanism 64 is coupled to the rotary shaft 62, the rotary shaft 62 is rotated only in a direction in which the mainspring 63 is wound, and the rotary shaft 62 is stopped even when the wind is stopped due to wind. It is rotated in the reverse direction so that the spring 63 is not released. In addition, the driving shaft 66 is fixed so as not to rotate by the braking mechanism 68.

Then, when a bird puts a twig or the like on the top of the support plate 3 to build a nest on the support plate 3, the control bar 69 is shown by the dotted line in FIG. Pressed down and lowered, accordingly, the braking member 68b of the braking mechanism 68 is pulled to release braking of the braking mechanism 68, and the rotary cylinder 65 and the drive shaft 66 are caused by the elasticity of the spring 63. As the crank mechanism 67 rotates, the slide block 50 reciprocates from side to side at a high speed.

When the slide block 50 is reciprocated at a high speed, the lifting block 20 is vibrated up and down at a high speed by the action of the protrusions 23 and 51 to hit the upper surface of the slide block 50. Noise and vibration will be generated, thereby shaking off the tree branches placed on the lifting block 20 and the control bar 69, and at the same time to frighten away birds.

In particular, the hammer 40 installed in the elevating block 20 collides with the inner upper and lower sides of the slide block 50 to cause a greater noise. At this time, since the hammer 40 is installed in the inner space of the lifting block 20, the noise generated by the hammer 40 is amplified in the lifting block 20 to become larger.

In addition, when a strong wind is expected or blown due to a typhoon or the like, the high position of the solar cell 1 may cause the panel to be separated from the holder 4 or the support plate 3 to be separated from the support 2 so that the solar cell 1 may be damaged. There is a danger. Therefore, in the above case, it is necessary to lower the installation position of the solar cell 1 close to the ground in advance. In this case, after releasing the bolt (2c) fixing the lower support (2a) and the upper support (2b) can be fixed by lowering the upper support (2b) by a desired distance and then tighten the bolt (2c) again.

When the position of the solar cell 1 is moved as described above, the engagement between the brake member 68b of the brake mechanism 68 and the disk 68a may be released. In this case, the vibration generating device (B) is operated, which causes the operator to be surprised and miss the support, which may damage the solar cell 1. Therefore, there is a need to prevent the malfunction of the vibration generating device (B).

The operator can prevent the rotation of the drive shaft 66 due to a malfunction by operating a switch (not shown) installed on the outer surface of the support 2 in advance before the moving operation of the support 2. Referring to FIGS. 11A and 11B, when an operator presses a switch, the solenoid 70c is operated to push the plunger 70c1 so that the grab 70c2 comes into close contact with the outer surface of the drive shaft 66. . Therefore, even if the momentary braking member 68b and the disk 68a are released due to the shock when the position of the solar cell 1 is released, the driving shaft 66 is prevented from rotating, thereby preventing the vibration generator B from malfunctioning. You can do it.

The distribution line structure capable of adjusting the wiring position according to the condensing degree of the solar cell configured as described above has an advantage that easy replacement is possible by selecting a distribution line having an allowable current corresponding to the amount of power generated from the solar cell according to the weather.

 In addition, when a bird or the like places a tree branch on the vibration generating device B installed on the upper surface of the support plate 3, the control bar 69 is rotated to the lower side by the weight of the braking mechanism 68. The action is released, and accordingly, the crank mechanism 67 moves forward and backward the slide block 50 by the force of the spring 63, causing the lifting block 20 to swing up and down and generating noise at the same time. At the same time, the tree can shake off the branches and shake off the branches, which can prevent birds from nesting at the top.

In addition, by using the mainspring 63, the force of the windmill 61 rotated by the wind is stored in advance, and when the bird puts a twig on the upper part of the support plate 3 to build a nest, the mainspring 63 is pulled out. While vibrating the lifting block 20 up and down, there is no need for a separate power, there is an advantage that can vibrate the lifting block 20 very strongly.

In addition, by lowering the installation position of the solar cell 1 close to the ground when bad weather such as strong wind is expected, it is possible to prevent damage of the solar cell 1 due to bad weather, solar cell (1) By preventing the malfunction of the vibration generating device (B) according to the adjustment of the position, the operator is surprised to miss the support (2) has the advantage that can prevent the solar cell (1) from being damaged.

1. Solar Cell 2. Support
3. Support plate B. Vibration generating device
7. Transmission section 8. Current collector
9. Transformer 10. Support Bar
20. Lifting block 30. Spring
40. Hammer 50. Slide Block
60. Slide driving mechanism

Claims (1)

A support (2) having a lower support (2a) placed on the ground or a roof, and an upper support (2b) movably inserted and fixed in the longitudinal direction of the lower support (2a);
A support plate 3 fixed horizontally to an upper end of the upper support 2b;
Fixtures (4) are installed on the four corners of the support plate;
A solar cell (1) fixed to an upper end of the holder (4) to face the support plate (3);
A current collector 8 having a plurality of adapters 8a for collecting current produced from a plurality of solar cells;
A plurality of distribution lines 5 having different allowable currents, a current collector 5b for electrically conducting a selected one of the distribution lines 5 and the adapter 8a, and the distribution lines 5 in a semi-cylindrical shape. A transmission unit 7 having a cap 6 installed to enclose a);
A transformer (9) for transforming the electricity received from the power distribution line energized with the current collector (5b); And
It is composed of a long bar shape to the left and right, both sides are provided with a lifting guide 11 in the vertical direction and is fixed to the upper surface of the support plate 3 and the support bar 10, and in the form of a long metal pipe left and right inside It is configured to be installed in the elevating guide (11) in the up and down direction so as to be located above the support bar 10, the elevating block 20 is formed with a projection 23 on the lower side, and both ends of the elevating block ( The spring 30 is connected to the support bar 10 and the lifting block 20 is lowered, and the elastic bar 41 and the elastic bar 41 fixed to the inside of the lifting block 20. Hammer 40 having a head portion 42 of the metal material provided at the front end to hit the inner surface of the elevating block 20 during the elevating of the elevating block 20, and the support bar 10 and Slidably installed in the left and right directions on the upper surface of the support bar 10 to be located between the lifting block 20 And the upper surface is formed with a projection 51 corresponding to the projection 23 of the lifting block 20 and slides to the left and right, the slide block 50 to lift the lifting block 20 and the slide block 50 It is connected to the) includes a slide drive mechanism 60 to slide the slide block 50 in the left and right directions,
The slide drive mechanism 60 is configured to wind the windmill 61 rotated by the wind, the rotary shaft 62 connected to the windmill 61, and a elastic metal plate spirally having an inner end and an outer end. A spring 63 fixed to the circumferential surface of the rotary shaft 62, a ratchet mechanism 64 coupled to the rotary shaft 62 so that the rotary shaft 62 is rotated only on the winding side of the spring 63; Rotating cylinder 65 is coupled to surround the outer side of the mainspring 63 and the outer end of the mainspring 63 is fixed and a through hole 65a through which the rotating shaft 62 passes, and the rotation. The drive shaft 66 is connected to the other side of the cylinder 65 to be coaxial with the rotation shaft 62, and is installed at the end of the drive shaft 66 and connected to the slide block 50, the rotational movement of the drive shaft 66 The crank mechanism 67 for changing the reciprocating motion so that the slide block 50 is moved forward and backward, It is coupled to the intermediate portion of the drive shaft 66 and the braking mechanism 68 for braking the drive shaft 66 and the support bar 10 so as to be located above the lifting block 20 is rotatably installed in the vertical direction The control bar 69 and the plurality of solenoids 70c are connected to the brake mechanism 68 to release the braking action of the brake mechanism 68 when rotated downward, and the plurality of solenoids 70c are driven. A fixing device 70 radially disposed at the center and the grab 70c2 formed at the end of the plunger 70c1 in contact with the outer surface of the drive shaft 66 when the solenoid 70c is energized to prevent rotation of the drive shaft 66. Equipped vibration generating device (B);
Distribution line structure capable of adjusting the wiring position according to the degree of condensing of the solar cell comprising a.

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