KR101885535B1 - Power supply for high-voltage distribution lines - Google Patents

Abstract

The present invention relates to a power supply apparatus for high-voltage distribution lines, capable of preventing noise and surge from flowing into a high-voltage distribution line automation facility; enabling stable power supply by independently supplying power through private power generation using solar light; enabling the efficiency of solar power generation to be always maintained properly while increasing the efficiency of solar power generation by protecting a solar panel from pollutants such as yellow dust and fine dust; and raising cost effectiveness for installation and operation by having a CPTED function. According to the present invention, the power supply apparatus comprises: a terminal installed in a control box, and receiving a control signal from an external central control room and checking an error in the control signal and then outputting the signal; a load break switch installed outside the control box, and opening or closing a load current or separating a section of a distribution line in response to the control signal inputted from the terminal; a transceiving communication part installed in the control box, and enabling data communication with the central control room; and a solar power generation part. The solar power generation part comprises a support bracket, a housing, a housing unfolding part, a solar panel, a solar panel unfolding part, a transparent cover, a cover opening and closing part, a first sealing member, a second sealing member, a camera module, a lighting module, an emergency bell, a wireless communication module, an illuminance sensor, a GPS module, a control part, a wiper part, and a washer solution spray part.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a power supply for high-

[0001] The present invention relates to a power supply apparatus for a power distribution automation apparatus for automatically controlling a high-voltage power distribution line in the field of power distribution technology, and more particularly, to a power supply apparatus for a power distribution apparatus that prevents noise and surges from entering into an automation facility through a high voltage distribution line, It is possible to provide stable power supply by independent power supply through self-power generation using power generation, and the solar panel for solar power generation is well protected from pollution such as dust and fine dust, The present invention relates to a power supply apparatus for a high-voltage distribution line capable of maintaining the state of a solar cell and improving the efficiency of solar power generation and also improving the cost efficiency due to the installation and operation, .

In general, the distribution automation equipment monitors and controls the condition of the load switch on the distribution line scattered over a long distance using a computer installed in the central control room, measures the voltage and current, and automatically checks the fault section FIG. 1 is a schematic structural view of a distribution automation apparatus 100 according to the prior art. As shown in FIG. In the distribution of electricity, the high pressure includes more than 22.9 KV.

1, the power distribution automation apparatus 100 receives a control signal from a central control room (not shown) via the transmission / reception communication means 130 (see FIG. 2) and checks the error of the received control signal A terminal 110 for outputting a control signal when there is no error, and a load switch 120 for opening / closing a load current by a control signal inputted from the terminal 110 or for separating a section to a power distribution line.

Terminal 110 is typically installed within a control box 111 is provided at the lower part of the load break switch 120, a load break switch (120) for high voltage underground wiring line is for example an SF ₆ gas as insulating medium An insulated gas insulated load switch is used, and the transmission / reception communication means 130 is generally provided in the control box 111. [

In order to operate the power distribution automation equipment 100, a power supply unit 200 of the power distribution automation equipment is included in the control box 111, so that the power supply unit 200 ) Is schematically shown in Fig.

1 and 2, a power supply 200 of a power distribution automation apparatus according to the related art includes a commercial power supply 210, a transformer 220 for dropping the commercial power supply 210 to an appropriate voltage, A rectifier 230 for rectifying a current flowing from the transformer 210 through a bridge rectifying circuit, a voltage stabilizing circuit 220 for smoothing the power rectified by the rectifier 230 through a capacitor (not shown) An output terminal 250 for providing a stabilized voltage to the load switch 120 by the voltage stabilizer 240 and an output terminal 250 for amplifying the voltage dropped by the transformer 220, And a control unit 270 for controlling the output voltage of the output terminal unit 250 and compensating for an output voltage at the time of a power failure and outputting the compensated output voltage.

However, in the case of the power supply apparatus 200 of the conventional power distribution automation apparatus according to the prior art in which power is supplied from the outside, since noises are introduced through the transformer 220, a line for removing noise between the transformer 220 and the rectifier 230 There is a problem that the filter 280 is installed, and the line filter 280 may adversely affect the reliability of the terminal 110.

In addition, since the line filter 280 can not prevent surge of large energy such as a lightning stroke or a discharge of static electricity, a separate surge protection circuit unit 290 must be provided in front of the line filter 280.

In addition, when a power outage occurs, a circuit that can be evacuated to a specific memory such as ROM before the power stored in the capacitor is consumed so that important information such as the amount of active power stored in the memory, Need to be implemented in the control unit 270.

However, when power is supplied again before the power stored in the capacitor is completely consumed due to the instantaneous power failure, malfunction may occur in the controller 270.

In recent years, research and development of solar power generation has been actively carried out as an alternative energy source. In accordance with this tendency, the use of photovoltaic power generation is increasing in real life and various industries.

However, the use of photovoltaic power generation is increasing, but the efficiency of photovoltaic power generation is decreasing due to dust and fine dust on the basis of domestic standards. That is, in recent years, the amount of dust and fine dust inflow from China has greatly increased, and the frequency of inflow has also become frequent. As a result, the solar panel is covered with dust and fine dust, It has been reported through a Korean broadcaster (KBS NEWS.

Korean Registered Patent No. 10-0840382 (Jun. 23, 2008), "Self-rechargeable power supply device of distribution automation equipment" Korean Registered Patent No. 10-1409355 (issued on July 28, 2014), "Power Supply for High Voltage Distribution Line"

The embodiment of the present invention can prevent the inflow of noise and surge from the outside to the automation equipment by the high-voltage power distribution line, enable the independent power supply through the self-power generation function using the photovoltaic power generation even during the power failure, The solar panel for solar power generation is well protected from dust and fine dust, so that the efficiency of the photovoltaic power generation can always be maintained at a favorable condition, and at the same time, the structure for increasing the efficiency of the photovoltaic power generation is formed. It also provides a high-voltage distribution line power supply that can be used to increase the cost and efficiency of installation and operation.

The power supply apparatus for a high voltage distribution line according to the embodiment of the present invention includes a terminal 3b installed in a control box 3a and receiving a control signal from the outside to output a control signal, And a load switch (3c) installed and opened or closed by a control signal inputted from the terminal (3b) or for separating a section to a power distribution line, the power supply apparatus comprising: A solar power generator 10 installed outside the control box 3a; A battery (20) installed in the control box (3a) to charge the electricity generated by the solar power generator (10) and supply power to the control box (3a); And a charge and discharge control unit 30 installed in the control box 3a and interposed between the solar power generating unit 10 and the battery 20 to supply stable power to the control box 3a, The charge and discharge control unit 30 includes a first voltage sensor 31 for sensing a voltage of the solar power generation unit 10, a second voltage sensor 32 for sensing a voltage of the battery 20, A logic circuit 34 for generating a control signal by performing an operation in accordance with the signals of the first and second voltage sensors 31 and 32 and the light amount sensor 33, And a current modulation circuit (35) for adjusting an output current according to a control signal of the logic circuit (34); The current modulation circuit 35 is implemented with a known pulse width modulation (PWM) circuit; The charge / discharge control unit (30) further includes a backflow prevention diode (36) connected to an output terminal of the solar power generation unit (10) to prevent a reverse current from flowing to the solar power generation unit (10) The photovoltaic unit 50 includes a support bar 51a fixed horizontally in a pole 1000 on which the control box 3a is installed and a support bar 51b fixed in the same direction A support bracket 51 including a pair of hinge arms 51b bent in the horizontal direction and a base plate 51c formed in a horizontal direction from a lower portion of any one of the hinge arms 51b, Shaped structure in which a first installation space 52a is formed on one side of the electric pole 1000 and a second installation space 52b is formed on the other side of the horizontal direction and is installed vertically in the electric pole 1000, As a result, A housing 52 in which a pair of hinge blocks 52c are rotatably coupled to the hinge arms 51b of the bracket 51 and a pair of hinge blocks 52c are formed on the base plate 51c of the support bracket 51 And the rotational force of the first normal / reverse rotation motor 53a and the first normal / reverse rotation motor 53a is transmitted to the rotation shaft 52d between the hinge arm 51b and the hinge block 52c, (52a) of the housing (52) and an outer side of the first installation space (52a) in a state accommodated in the first installation space (52a) of the housing (52) A solar panel 54 rotatably coupled to the first installation space 52a so as to be converted into a deployed state at a predetermined angle with the housing 52 and converting sunlight into electric energy, (52) for generating a rotational power of the solar panel (54) A speed reducer 55b for transmitting the rotational power of the second normal rotation motor 55a to the rotation coupling shaft 54a of the solar panel 54 with respect to the inner surface of the motor 55a and the first installation space 52a, A transparent cover 56 rotatably coupled to the housing 52 to open and close the first installation space 52a of the housing 52, A third normal / reverse rotation motor (57a) provided in the housing (52) for generating a rotational power of the transparent cover (56) A cover opening / closing drive unit 57 including a speed reducer 57b for transmitting the rotational power of the rotary motor 57a; and a case in which the transparent cover 56 is in a state in which the first installation space 52a of the housing 52 is closed When one surface of the transparent cover (56) facing the solar panel (54) is defined as the inner surface, the four sides of the inner surface A first airtight member 58 protrudingly formed on an inner circumferential surface of the first airtight member 58 and having an insertion protrusion 58a protruding along the center of the width direction when the direction is extended and extended in the longitudinal direction; A second airtight member 58 extending from the outer circumferential edge of the first installation space 52a in the housing 52 and having an insertion groove 59a into which the insertion protrusion 58a of the first airtight member 58 is inserted, A camera module 60 installed inside the second installation space 52b of the housing 52 and operating in accordance with an external control signal to photograph the periphery of the camera module 60; An illumination module 61 installed in the second installation space 52b of the electric motor 100 and operating in accordance with an external control signal to illuminate the surroundings, an emergency bell 62 installed in the electric pole 1000, A wireless communication module 63 for receiving information on atmospheric concentrations of ultrafine dust and sandstorms from the weather station, An illuminance sensor 64 installed in the housing 52 for sensing the brightness of the surroundings, a GPS module 65 for receiving GPS time information from the outside, and a dust sensor installed in the housing 52 for detecting minute dust, A critical illuminance for determining whether or not the solar panel 54 is drawn out to the outside of the housing 52 is set and the critical illuminance is set for the wireless communication module 63 The transparent cover 56 is attached to the first installation space 52a of the housing 52 when at least one of information on the concentrations of fine dust, ultrafine dust, When the illuminance information sensed and input through the illuminance sensor 64 is less than the critical illuminance, the solar panel 54 is moved to the first position of the housing 52 Inside the installation space 52a, The cover opening and closing drive unit 57 is operated in a state in which the transparent cover 56 closes the first installation space 52a of the housing 52 after operating the solar panel expansion unit 55 in a state that the cover opening / The illuminance information, which is received through the wireless communication module 63 and sensed by the illuminance sensor 42 at a time when all of the information on the concentration of fine dust, ultrafine dust, and dust in the air is less than the critical concentration, The solar panel 54 is operated in a state in which the transparent cover 56 opens the first installation space 52a of the housing 52 when the critical illuminance is exceeded, The solar panel unfolding unit 55 is operated so as to be drawn out of the first installation space 52a of the housing 52 and the GPS time information is received by the GPS module 65 based on the GPS time information received from the GPS module 65, In the morning time zone When the solar panel 54 is in an unfolded state of 115 ° to 125 ° with respect to the vertical axis and the GPS time information is in the predetermined early afternoon time zone, the solar panel 54 is rotated 85 ° to 95 ° And when the GPS time information is in a predetermined late afternoon time zone, the solar panel expansion unit 55 is operated so that the solar panel 54 is in an unfolded state of 40 ° to 50 ° with respect to the vertical axis, At least one of the information of the concentration of fine dust, ultrafine dust, and dust in the air received and input through the communication module 63 exceeds the threshold concentration, and at the same time, the illuminance information The solar panel expansion unit 55 is operated in a state in which the solar panel 54 is accommodated in the first installation space 52a of the housing 52 when the temperature of the solar panel 54 exceeds the critical illuminance, The cover opening and closing drive unit 57 is operated in a state in which the first installation space 52a of the housing 52 is closed and the GPS time information received from the GPS module 65 is input When the GPS time information is in the predetermined morning time zone, the housing 52 is in an unfolded state of 115 ° to 125 ° with respect to the vertical axis, and when the GPS time information is in the predetermined early afternoon time zone, The housing 52 is extended from 40 to 50 degrees with respect to the vertical axis when the GPS time information is in the predetermined late afternoon time zone, 53 while the housing extension part 53 is operated so that the housing 52 is in an unfolded state of 115 ° to 125 ° with respect to the vertical axis when an emergency signal is input from the emergency bell 62, mother The illumination module 61 is also operated when the illuminance information sensed and inputted through the illuminance sensor 64 is less than the critical illuminance, A control unit 67 for outputting control signals for removing fine dust and dirt, and a control unit 67 for controlling fine dust and yellow dust on the outer surface of the transparent cover 56 while reciprocating linearly along the outer surface of the transparent cover 56 A fourth normal and reverse rotation motor 68a and a pinion 68b and a wiper main body 68c engaged with the pinion 68b and a rack 56b extended from the transparent cover 56 in a state of engagement with the pinion 68b And a wiper part 68 for removing fine dust and yellow dust on the outer surface of the transparent cover 56 through normal and rotational driving of the fourth normal rotation motor 68a according to a control signal of the control part 67. [ And an outer surface of the transparent cover (56) The washer fluid is sprayed onto the outer surface of the transparent cover 56 in conjunction with the control signal for the wiper part 68 of the control part 67 And a washer fluid dispensing part (69).

According to the embodiment of the present invention, in the process of operating the power supply device using the high-voltage distribution line of the power distribution automation equipment, it is possible to prevent the inflow of noise and surge, and to provide independent power supply through self- The solar panel for photovoltaic power generation can be safely protected from dust and fine dust, and at the same time, it has a structure and an operation method for enhancing the efficiency of the power generation, so that the power generation efficiency of the photovoltaic power generation is always high And the solar panel also has the function of the concept of the concept so that the cost efficiency of installation and operation can be greatly improved.

1 is a schematic structural view of a distribution automation apparatus according to the prior art;
Figure 2 is a block diagram illustrating the structure of a power supply of a distribution automation facility according to the prior art;
3 is a schematic structural view of a power supply apparatus for a high voltage distribution line according to an embodiment of the present invention
4 is a schematic structural view of a power supply apparatus for a high voltage distribution line according to an embodiment of the present invention
5 is a block diagram illustrating a structure of a high-voltage distribution line power supply apparatus according to an embodiment of the present invention.
6 is a perspective view illustrating a state in which a solar power generating unit is disassembled in a power supply apparatus for a high voltage distribution line according to an embodiment of the present invention;
Fig. 7 is a perspective view illustrating the configuration of the rear side of the housing in the solar power generating unit according to Fig. 6;
FIG. 8 is a perspective view illustrating a solar power generating unit according to FIG. 6,
Fig. 9 is a block diagram illustrating the electrical configuration of the solar power generation unit according to Fig. 6
10 is a perspective view illustrating a wiper structure of the solar power generation unit according to FIG.
Figs. 11 and 12 are views showing an operating state of the solar power generation unit according to Fig. 6

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components in each described embodiment may be varied without departing from the spirit and scope of the present invention.

The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which the claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term, not on the name of a simple term, but on the entire contents of the present invention.

Whenever an element is referred to as " including " an element throughout the description, it is to be understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. In addition, the term " "... Module " or the like means a unit for processing at least one function or operation, which may be implemented in hardware or software, or a combination of hardware and software.

3 to 12, a high-voltage distribution line power supply apparatus according to an embodiment of the present invention will be described.

FIG. 3 is a schematic structural view of a self-rechargeable power supply apparatus according to an embodiment of the present invention, FIG. 4 is a schematic structural view of a self-rechargeable power supply apparatus according to an embodiment of the present invention, and FIG. 1 is a block diagram illustrating the structure of a self-powered power supply according to an example.

As shown in the figure, the power supply apparatus 1 for a high-voltage power distribution line according to an embodiment of the present invention is installed in a control box 3a and receives a control signal from an external central control room (not shown) And a load switch (not shown) for opening / closing the load current or disconnecting a section of the load line by a control signal provided outside the control box 3a and input from the terminal 3b, (3c) provided in the control box (3a), and a transmission / reception communication means (3d) provided in the control box (3a) for enabling data communication with the central control room It plays a stable role.

The power supply apparatus 1 is provided with a control box 3a for preventing the inflow of noise and surge and capable of supplying independent power even during a power failure, A solar battery 10 installed in the control box 3a to charge the electricity generated by the solar power generator 10 and to control the charged power source 3a, And a control box (3a) installed in the control box (3a) and interposed between the solar panel (12) of the solar power generator (10) and the battery (20) (30).

Here, the solar panel 12 of the solar power generating unit 10 converts photons into electric energy using the property of a semiconductor, and a large number of solar cells having a large area similar to a PN junction diode And are assembled in units of one module.

The solar power generation unit 10 converts sunlight, which is a type of natural energy, into electric energy, and thus, the power supply apparatus 1 with the high-voltage distribution line according to the present invention can provide a core component And is installed outside the control box 3a, particularly above the control box 3a.

The control box 3a constituting the power distribution automation apparatus 3 is provided with a storage battery 20 which charges the electricity generated by the solar power generator 10 and supplies it to the distribution automation facility 3 To the control box 3a for operation of the control box 3a. The control box 3a is illustrated as being provided inside the control box 3a, but may be installed outside the control box 3a.

A charge / discharge control unit 30 is installed on one side of the terminal 3b in the control box 3a. The charge / discharge control unit 30 is provided between the solar cell 10 and the battery 20, 5, a first voltage sensor 31 for sensing the voltage of the solar panel 12 of the solar power generating unit 10, and a second voltage sensor 31 for detecting the voltage of the solar panel 12, A second voltage sensor 32 for sensing the voltage of the battery 20, a light amount sensor 33 for sensing the light amount of sunlight, a first and second voltage sensors 31 and 32 and a light amount sensor 33 A logic circuit 34 for performing an operation according to a signal to generate a control signal and a current modulation circuit 35 for adjusting an output current supplied to the control box 3a in accordance with a control signal of the logic circuit 34 .

The logic circuit 34 compares the voltage of the solar battery 12 detected by the first voltage sensor 31 with the voltage of the battery 20 detected by the second voltage sensor 32, 33 to output a control signal for operation of the current modulation circuit 35 by performing an arithmetic operation with the amount of light detected as a parameter.

Therefore, when the amount of light decreases at sunset and the output voltage of the solar panel 12 decreases below a predetermined value, the logic circuit 34 controls the current modulation circuit 35 so that the current is supplied to the control box 3a When the output voltage of the solar panel 12 increases to a predetermined value or more due to an increase in the amount of sunlight due to sunrise, the current modulation circuit 35 is controlled to block the current supply to the control unit 3a .

When the voltage of the battery 20 detected by the second voltage sensor 32 falls within the set range, the current modulation circuit 35 changes the duty ratio of the pulse current according to the voltage of the battery 20 (11a) controls the duty ratio of the pulse current by adjusting the duty ratio of the battery 20 when the voltage of the battery 20 is low and decreasing the duty ratio when the voltage of the battery 20 is high Can be implemented with a known pulse width modulation (PWM) circuit so that the supplied current is always kept constant.

The charging / discharging control unit 30 preferably further includes a backflow prevention diode 36 connected to the output terminal of the solar panel 12. The backflow prevention diode 36 is connected to the solar panel 10, To prevent the water from flowing.

The current modulating circuit 35 preferably further includes a relay switch 34a connected between the backflow preventing diode 36 and the battery 20. The relay switch 34a is connected to the solar panel The voltage of the battery 20 detected by the second voltage sensor 32 is excessively high and there is a danger of overcharging the battery 20 to supply the current to the battery 20, Thereby stopping the charging operation.

The charge / discharge control unit 30 preferably further includes a low voltage differential (LVD) circuit 37. The low voltage differential circuit 37 is a circuit for transferring data of the transmission / .

Hereinafter, the entire operation of the power supply apparatus 1 with the self-charging type high voltage distribution line according to the embodiment of the present invention will be described.

In the case of the power supply apparatus 1 with the self-charging type high voltage distribution line according to the embodiment of the present invention, the power generated from the solar power generation unit 10 is charged in the battery 20 to drive the power distribution automation apparatus 3 The noise from the transformer is prevented from flowing into the power supply apparatus of the power distribution automation apparatus according to the prior art and the surge caused by the power outage can be prevented. It is possible to provide a stable power supply.

Particularly, the charge / discharge control section 30 interposed between the solar power generating section 10 and the storage battery 20 controls the voltage of the solar battery 12 of the solar power generator 10, the voltage of the battery 20, The charging and discharging of the battery 20 and the supply of electric current are controlled according to the amount of light according to the sunrise and the sunset and supplied to the control box 11a by the current modulation circuit 35 of the charging and discharging control unit 30 The current can always be kept constant.

The solar power generation unit 10 will now be described with reference to Figs. 6 to 12. Fig.

6 is a perspective view illustrating a solar power generating unit in a disassembled state in a power supply apparatus for a high-voltage power distribution line according to an embodiment of the present invention, and FIG. 7 is a perspective view illustrating a configuration of a solar power generating unit, FIG. 8 is a perspective view illustrating a solar power generating unit according to FIG. 6 in a state where a transparent cover is closed, FIG. 9 is a block diagram illustrating an electrical configuration of the solar power generating unit according to FIG. FIG. 11 is a perspective view illustrating a wiper structure of the solar power generating unit according to FIG. 6, and FIG. 12 is a view illustrating an operation state of the solar power generating unit according to FIG.

As shown in the figure, the solar power generating section 50 includes a support bracket 51, a housing 52, a housing expansion section 53, a solar panel 54, a solar panel expansion section 55, a transparent cover 56, The first airtight member 58, the second airtight member 59, the camera module 60, the illumination module 61, the emergency bell 62, the wireless communication module 63, the illuminance sensor 64, a GPS module 65, a control section 67, a wiper section 68, and a washer liquid spraying section 69.

The support bracket 51 functions to rotatably couple the housing 52, which will be described later, to the electric pole 1000 on which the control box 3a is installed. The support bracket 51 is provided with a support bar 51a fixed to the electric pole 1000 in the horizontal direction and a support bar 51b which is formed by bending the support bar 51a in both the same direction and in the horizontal direction And a base plate 51c formed in a horizontal direction from a lower portion of any one of the pair of hinge arms 51b and the hinge arms 51b.

The housing 52 is rotatably coupled to the support bracket 51 as described above. The housing 52 has a first installation space 52a on one side in the horizontal direction and a second installation space 52a on the other side in the horizontal direction. Is a rectangular box-shaped structure vertically installed in the electric pole (1000) in the form of a space (52b). The housing 52 is formed with a pair of hinge blocks 52c rotatably coupled to the hinge arms 51b of the support bracket 51 at one end with respect to the vertical direction.

The housing expansion portion 53 includes a first normal and reverse rotation motor 53a mounted on the base plate 51c of the support bracket 51 and a hinge arm 51b of the support bracket, And a speed reducer 53b that transmits power to the housing 52 through the rotation shaft 52d between the hinge blocks 52c of the housing to provide forward and reverse rotation power. In other words, the housing expanding section 53 functions to rotate the housing 52 in the vertical direction about the horizontal axis.

The solar panel 54 is switched to a state in which it is stored in the first installation space 52a of the housing 52 and a state in which the solar panel 54 is deployed at a predetermined angle with the housing 52 outside the first installation space 52a And is rotatably coupled to the first installation space 52a. This solar panel 54 converts sunlight into electric energy. In other words, the solar panel 54 functions as a generator through sunlight.

The solar panel expansion unit 55 is installed in the housing 52 to rotate the second normal rotation motor 55a and the second normal rotation motor 55a, which generate rotational power of the solar panel 54, And a speed reducer 55b for transmitting the rotation to the rotation coupling shaft 54a of the solar panel 54 with respect to the inner surface of the solar cell 52a. In other words, the solar panel expansion part 55 functions to rotate the solar panel 54 in the vertical direction about the horizontal axis.

The transparent cover 56 is rotatably coupled to the housing 52 for opening and closing the first installation space 52a of the housing 52. [

The cover opening and closing drive unit 57 includes a third normal and reverse rotation motor 57a provided in the housing 52 for generating a rotational power of the transparent cover 56 and a rotary engaging shaft 56b for the transparent cover 56 for the housing 52. [ And a speed reducer 57b for transmitting the rotational power of the third normal / reverse rotation motor 57a to the first and second normal / reverse rotation motors 57a and 56a. In other words, the cover opening / closing drive unit 57 functions to rotate the transparent cover 56 in the vertical direction about the horizontal axis.

The first airtight member 58 is provided on one side of the transparent cover 56 facing the solar panel 54 on the basis of the state in which the transparent cover 56 closes the first installation space 52a of the housing 52 The insertion protrusions 58a are protruded along the center of the width direction when the longitudinal direction is set to extend along the four sides of the inner surface.

The second airtight member 59 extends along the outer circumference of the first installation space 52a in the housing 52 so as to correspond to the first airtightness member 58, 58a are inserted into the insertion groove 59a.

The camera module 60 is installed inside the second installation space 52b of the housing 52 and operates according to an external control signal to photograph the surroundings.

The illumination module 61 is installed inside the second installation space 52b of the housing 52 and functions to illuminate the periphery by operating according to an external control signal.

The emergency bell 62 is installed in the electric pole 1000 and functions to input an emergency signal to the control unit 67 during its operation.

The wireless communication module 63 receives information on the atmospheric concentration of fine dust, ultrafine dust, and yellow dust from the weather agency. The wireless communication module 63 receives the fine dust, ultra fine dust, The information on the concentration is input to the control unit 67. [

The illuminance sensor 64 is installed in the housing 52 to sense the brightness of the surroundings.

The GPS module receives the GPS time information from the outside, and the GPS time information received through the GPS module is input to the control unit 67.

The control unit 67 is installed in the housing 52 and sets a threshold concentration for atmospheric concentrations of fine dust, ultrafine dust, and yellow dust, respectively, and determines whether or not the solar panel 55 is taken out of the housing 52 A critical illuminance for determination is set.

When at least one of information on the concentration of fine dust, ultrafine dust, and dust in the air received and input through the wireless communication module 63 exceeds the critical concentration, the control unit 67 controls the transparent cover 56 to cover the housing The cover opening / closing drive section 57 is operated in a state in which the first installation space 52a of the cover opening / closing section 52 is closed.

When the illuminance information sensed through the illuminance sensor 64 is less than the critical illuminance, the controller 67 controls the state in which the solar panel 55 is accommodated in the first installation space 52a of the housing 52 The operator operates the cover opening and closing drive part 57 in a state in which the transparent cover 56 closes the first installation space 52a of the housing 52 after operating the solar panel expansion part 55. [

In addition, the control unit 67 detects all of the air concentration of fine dust, ultrafine dust, and yellow sand received through the wireless communication module 63 and is less than the critical concentration and is detected through the illuminance sensor 42, The transparent cover 56 operates the cover opening and closing drive unit 57 in a state in which the first installation space 52a of the housing 52 is opened and then the solar panel 54 is opened, The solar panel expansion unit 55 is operated so as to be drawn out of the first installation space 52a of the housing 52 and the GPS time information is set on the basis of the GPS time information received from the GPS module 65 The solar panel 54 is in an unfolded state of 115 ° to 125 ° with respect to the vertical axis, and when the GPS time information is the predetermined early afternoon time zone, 95 deg., And the G When the PS time information is in the predetermined late afternoon time zone, the solar panel expansion unit 55 is operated so that the solar panel 54 is in an unfolded state of 40 ° to 50 ° with respect to the vertical axis.

11A illustrates a state in which the solar panel 54 is developed at an angle of 40 DEG to 50 DEG with respect to the vertical axis. FIG. 11B illustrates a state in which the solar panel 54 is in a vertical (C) illustrates a state in which the solar panel 54 is deployed at an angle of 115 ° to 125 ° with respect to the vertical axis. In other words, the solar panel can move to a position where the solar panel can receive the sunlight according to the position of the sun based on the day, so that the efficiency of the solar power generation can be improved.

At least one of information on the concentrations of fine dust, ultrafine dust, and dust in the air received and input through the wireless communication module 63 exceeds the threshold concentration, and the controller 67 controls the illuminance sensor 42 The solar panel expansion unit 55 is operated in a state in which the solar panel 55 is accommodated in the first installation space 52a of the housing 52 The cover opening and closing drive section 57 is operated in a state in which the first installation space 52a of the housing 52 is closed and the transparent cover 56 covers the first installation space 52a of the housing 52. Based on the GPS time information received and input from the GPS module 65 When the GPS time information is set in the predetermined morning time, the housing 52 is in an unfolded state of 115 ° to 125 ° with respect to the vertical axis. When the GPS time information is the predetermined early afternoon time zone, The expanded state of 85 ° to 95 ° And when the GPS time information is in a predetermined late afternoon time zone, the housing expansion unit 53 is operated so that the housing 52 is in an unfolded state of 40 ° to 50 ° with respect to the vertical axis.

12 (a) illustrates a state in which the housing 52 is developed at an angle of 40 ° to 50 ° with respect to a vertical axis, (b) (C) illustrates a state in which the housing 52 is unfolded at an angle of 115 ° to 125 ° with respect to a vertical axis. That is, according to the position of the sun on the first day, the housing can move to a position where the sunlight can be incident on the inner solar panel, thereby enabling the solar power generation, Can be improved.

The control unit 67 controls the camera module 60 in a state in which the housing expansion unit 53 is operated so that the housing 52 is in an unfolded state of 115 ° to 125 ° with respect to the vertical axis when an emergency signal is input from the emergency bell 62 And operates the illumination module 61 when the illuminance information sensed through the illuminance sensor 64 is less than the critical illuminance. The control unit 67 rotates the housing 52 to the position illustrated in FIG. 12 (c) when an emergency signal is input from the emergency bell 62, and in this state, the camera module 60 and the lighting module 61 so that the camera module 60 can function as a CCTV camera.

Further, the control unit 67 outputs a control signal for removing fine dust and yellow dust on the outer surface of the transparent cover 56 to the wiper unit 68, which will be described later.

The wiper section 68 is rotated in the forward and reverse directions along the outer surface of the transparent cover 56 to rotate the fourth normal and reverse rotation motor 68a and the pinion 68b to clean the fine dust and dirt on the outer surface of the transparent cover 56 And a rack 68d that is long in the transparent cover 56 in a state of being engaged with the pinion 68b and a wiper main body 68c which engages with the pinion 68b. The wiper section 68 removes fine dust and yellow dust on the outer surface of the transparent cover 56 through normal / rotational driving of the fourth normal / reverse rotation motor 68a by the control signal of the control section 67. [

The washer liquid spraying section 69 is provided so as to face the direction in which the wiper section 68 is positioned at the hinge engaging section of the lower end of the transparent cover 56. The washer liquid spraying section 69 is provided at the hinge- (68) to spray the washer liquid onto the outer surface of the transparent cover (56).

As can be seen from the embodiments of FIGS. 3 to 12, the power supply apparatus for a high-voltage power distribution line according to the embodiment of the present invention is a power supply apparatus for high- And surge suppression, and self-power generation function using solar power generation during power outage, independent power supply is possible and stable power supply is possible, and solar panel for solar power generation is protected from dust and fine dust pollution. In addition, it has the structure and operation method to increase the power generation efficiency, so that the power generation efficiency of the solar power generation can be maintained at a high efficiency at all times, and the solar panel can also function as the concept of the concept, The contrast efficiency can be greatly improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all the equivalents or equivalents of the claims, as well as the claims set forth below, fall within the scope of the present invention.

3a: Control box 3b: Terminal
3c: Actuator 20:
30: charge / discharge control unit 31: first voltage sensor
32: second voltage sensor 33: light amount sensor
34: logic circuit 35: current modulation circuit
36: reverse current prevention diode 37: low voltage differential circuit
50: solar power generating part 51: support bracket
51a: Support bar 51b: Hinge arm
51c: base plate 52: housing
52a: first installation space 52b: second installation space
52c: a hinge block 52d:
53: housing expansion part 53a: first and second forward / reverse rotation motors
53b: Reducer 54: Solar panel
54a: rotation coupling shaft 55: solar panel development unit
55a: second normal / reverse rotation motor 55b:
56: transparent cover 56a: rotationally coupled shaft
57: cover opening / closing drive part 57a: third /
57b: Reduction gear 58: First airtight member
58a: insertion protrusion 59: second airtight member
59a: insertion groove 60: camera module
61: Lighting module 62: Emergency bell
63: wireless communication module 64: illuminance sensor
65: GPS module 67:
68: wiper section 68a: fourth and fifth forward / reverse rotation motors
68b: Pinion 68c: Wiper body
68d: rack 69: washer liquid dispensing part
1000: Electric pole

Claims (1)

A terminal 3b installed in the control box 3a and receiving a control signal from the outside and outputting a control signal; and a controller 3b provided outside the control box 3a and controlled by a control signal inputted from the terminal 3b, A power supply apparatus for supplying power to a power distribution automation apparatus including a load switch (3c) for opening / closing a current or separating a section to a power distribution line,
A photovoltaic power generation unit 50 installed outside the control box 3a; A storage battery (20) installed in the control box (3a) for charging electricity generated by the solar power generator (50) and supplying power to the control box (3a); And a charge and discharge control unit 30 installed in the control box 3a and interposed between the solar power generating unit 50 and the battery 20 to supply stable power to the control box 3a,
The charge and discharge control unit 30 includes a first voltage sensor 31 for sensing the voltage of the solar power generation unit 50, a second voltage sensor 32 for sensing the voltage of the battery 20, A logic circuit 34 for generating a control signal by performing an operation in accordance with the signals of the first and second voltage sensors 31 and 32 and the light amount sensor 33, And a current modulation circuit (35) for adjusting an output current according to a control signal of the logic circuit (34); The current modulation circuit 35 is implemented with a known pulse width modulation (PWM) circuit; The charge and discharge control unit 30 further includes a backflow prevention diode 36 connected to an output terminal of the solar power generation unit 50 to prevent a reverse current from flowing to the solar power generation unit 50,
The solar power generation unit 50
A support bar 51a fixed to the electric pole 1000 on which the control box 3a is installed and fixed in the horizontal direction and a support bar 51b formed in the same direction as the support bars 51a, A support bracket 51 including a pair of hinge arms 51b and a base plate 51c formed in a horizontal direction from a lower portion of any one of the hinge arms 51b;
A rectangular box structure in which a first installation space 52a is formed on one side in the horizontal direction and a second installation space 52b is formed on the other side in the horizontal direction and is vertically installed in the electric pole 1000, A housing 52 having a pair of hinge blocks 52c rotatably coupled to the hinge arms 51b of the support bracket 51 at one end thereof,
A first normal and reverse rotation motors 53a and 53b provided on the base plate 51c of the support bracket 51 and a hinge arm 51b and a hinge block 52c, A housing expansion part 53 including a reduction gear 53b that transmits power to the rotation shaft 52d between the housing 52 and the housing 52 to provide forward and reverse rotation power.
The housing 52 is housed in the first installation space 52a and the first installation space 52a is formed at a predetermined angle with respect to the housing 52 so as to be converted into a deployed state, A solar panel 54 rotatably coupled to the first installation space 52a and converting sunlight into electric energy;
A second normal / reverse rotation motor (55a) installed in the housing (52) for generating a rotational power of the solar panel (54) And a speed reducer (55b) for transmitting a rotational power of the second forward / reverse rotation motor (55a) to the shaft (54a);
A transparent cover (56) rotatably coupled to the housing (52) for opening and closing the first installation space (52a) of the housing (52);
A third normal and reverse rotation motor 57a installed in the housing 52 for generating a rotational power of the transparent cover 56 and a second normal and reverse rotation motor 57b for rotating the transparent cover 56 A cover opening / closing drive unit 57 including a speed reducer 57b for transmitting rotational power of the third normal / reverse rotation motor 57a;
When one side of the transparent cover 56 facing the solar panel 54 is defined as an inner surface on the basis of a state in which the transparent cover 56 closes the first installation space 52a of the housing 52, A first hermetic member (58) protrudingly formed on an inner circumferential edge of the inner surface to define an insertion protrusion (58a) along the center of the width direction when the direction is set to be the lengthwise direction;
And the insertion protrusion 58a of the first hermetic member 58 extends along the outer circumference of the first installation space 52a in the housing 52 so as to correspond to the first hermetic member 58, A second airtight member (59) forming an insertion groove (59a) to be inserted;
A camera module (60) installed inside the second installation space (52b) of the housing (52) and operating in accordance with an external control signal to photograph the surroundings;
An illumination module (61) installed inside the second installation space (52b) of the housing (52) and operating according to an external control signal to illuminate the surroundings;
An emergency bell (62) installed in the electric pole (1000);
A wireless communication module (63) for receiving information on atmospheric concentrations of fine dust, ultrafine dust and dust;
An illuminance sensor (64) installed in the housing (52) for sensing the brightness of the surroundings;
A GPS module (65) for receiving GPS time information from the outside;
A threshold concentration for the concentration of fine dust, ultrafine dust, and yellow dust in the air is set, respectively, and a determination is made as to whether or not the solar panel 54 is drawn out to the outside of the housing 52 And when at least one of the information on the concentrations of fine dust, ultrafine dust, and dust in the air received and input through the wireless communication module 63 exceeds the threshold concentration, the transparent cover 56 The cover opening and closing drive unit 57 is operated in a state where the first installation space 52a of the housing 52 is closed and the illumination information input through the illumination sensor 64 is less than the critical illuminance After the solar panel expansion part 55 is operated in a state in which the solar panel 54 is accommodated in the first installation space 52a of the housing 52 and the transparent cover 56 is mounted on the housing 52 The first installation space 52a is closed And the information on the atmospheric concentration of fine dust, ultrafine dust, and yellow dust received and input through the wireless communication module 63 is less than the critical concentration, and at the same time, When the illuminance information sensed and inputted through the sensor 64 exceeds the critical illuminance, the transparent cover 56 is moved to the cover open / close driving portion (state) in a state in which the first installation space 52a of the housing 52 is opened The solar panel expansion unit 55 is operated so that the solar panel 54 is drawn out to the outside of the first installation space 52a of the housing 52 after the operation of the solar panel 54 is started, When the GPS time information is set in the predetermined morning time based on the input GPS time information, the solar panel 54 is in an unfolded state of 115 ° to 125 ° with respect to the vertical axis, The solar panel 54 is in an unfolded state of 85 ° to 95 ° with respect to the vertical axis, and when the GPS time information is in a predetermined late afternoon time zone, the solar panel 54 is rotated 40 °- At least one of information on the concentration of fine dust, ultrafine dust, and dust in the air received through the wireless communication module (63) is inputted to the solar panel expansion unit (55) When the illuminance information exceeding the critical concentration and sensed and inputted through the illuminance sensor 64 exceeds the critical illuminance, the solar panel 54 is placed inside the first installation space 52a of the housing 52 The cover opening and closing drive part 57 is operated in a state in which the transparent cover 56 closes the first installation space 52a of the housing 52 after operating the solar panel expansion part 55 in a state of being housed The GPS When the GPS time information is set in the predetermined time zone based on the GPS time information received from the GPS module 65, the housing 52 is in an expanded state of 115 ° to 125 ° with respect to the vertical axis, The housing 52 is in an unfolded state of 85 ° to 95 ° with respect to the vertical axis, and when the GPS time information is in a predetermined late afternoon time zone, The housing expansion unit 53 is operated so as to be in an unfolded state of 40 to 50 degrees, and when the emergency signal is input from the emergency bell 62, the housing 52 is in a deployed state of 115 to 125 degrees with respect to the vertical axis The camera module 60 is operated to photograph the periphery of the camera module 60 while the housing expansion unit 53 is operated so that the illuminance information sensed through the illuminance sensor 64 is less than the critical illuminance Wu said lighting module (61) and also work with, the control unit 67 outputs a control signal for the fine dust and the dust removal of the transparent cover 56, the outer surface:
A fourth normal / reverse rotation motor 68a, a pinion 68b, and the pinion 68b are provided for wiping fine dust and yellow dust on the outer surface of the transparent cover 56 while reciprocating linearly along the outer surface of the transparent cover 56. [ A wiper body 68c engaged with the pinion 68b and engaged with the pinion 68b on one side of the transparent cover 56 and a direction in which the pinion 68b is continuously engaged with the pinion 68b as the pinion 68b rotates And a rack 68d which is installed in the long side of the transparent cover 56. The controller 67 controls the normal and reverse rotation of the fourth normal rotation motor 68a to remove fine dust and yellow dust on the outer surface of the transparent cover 56 A wiper section (68);
The transparent cover 56 is installed at an outer surface of the transparent cover 56 and at a lower hinge connection portion in a direction in which the wiper portion 68 is positioned and interlocked with a control signal for the wiper portion 68 of the control portion 67, And a washer liquid spraying portion (69) for spraying the washer liquid onto the outer surface of the transparent cover (56)
It is possible to generate solar light while moving to a position where the solar panel 54 can receive sunlight according to the position of the sun on the basis of a day, Is a high voltage distribution line capable of generating solar light while moving to a position where sunlight can be well incident on the solar panel 54 inside the solar panel 54.

Images