KR101740246B1 - Street light having a high efficiency charging device for renewable energy and Control method thereof - Google Patents

Abstract

A streetlight having a regenerative energy high efficiency charging device and a control method thereof are disclosed. The streetlight is a power generating part that generates solar heat; A battery module for storing charged power; A light for illuminating a predetermined place; A driving unit for driving the back light; And a control unit for charging the battery module using the power generated by the power generation unit and controlling the illuminance of the LED or the like in accordance with the state of the power generation unit, the current time, and the battery remaining amount. In the embodiment of the present invention, The remaining amount of the battery is less than a predetermined reference value, the amount of power generated by the wind power generator is small, and the illuminance is lowered when the sunrise time is long, and the illuminance can be maintained as it is.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a street light having a high-efficiency regenerative energy charging device and a control method thereof,

The present invention relates to a streetlight installed on a street or an alley, and more particularly, to a streetlight which is installed on a street or an alley, and in particular, when a capacitor is used as an auxiliary storage device, To a streetlight having a high efficiency charging device and a control method thereof.

Street light is a lighting facility installed along the street for safety and security of street traffic. Street lights are used according to the installation location, such as highways, main roads in city areas, commercial district roads, and residential district roads.

There are various types of street lamps, such as a highway type bent at the end of a pole and a back at its end, a bracket type that extends horizontally to the end of the pole and has a back to the top of the pole, There are two main types. As a light source, a high-pressure mercury lamp, a fluorescent lamp, a sodium lamp, an ordinary light bulb, and an LED (Light Emitting Diode) are used. Particularly, LED light sources are used in street light more and more because of low power consumption, strong vibration, and long life span.

In the conventional street light, an external power source is indispensably required to illuminate at night, efforts and cost for maintaining and repairing the power source means are consumed, and continuous cost is consumed for supplying the power source. It has been the main cause of electric shock accidents.

Renewable energy, on the other hand, refers to the energy generated by natural ecology, especially solar energy, wind power, hydropower, and tidal power.

In recent years, much attention has been focused on the generation of electricity using renewable energy in place of fossil fuel and nuclear fuel, and research and development for solar power generation and wind power generation are actively being carried out.

In the renewable energy generation technology, it is important to develop how to convert solar energy and wind power into electric energy efficiently and how to efficiently store the generated electric energy.

In the conventional charging apparatus which is responsible for the charging portion among these portions, mainly a large capacity battery is used, and in some cases, charging is performed using a capacitor having excellent charging efficiency.

Such prior arts include Korean Patent Laid-Open Nos. 10-2010-0109104, 10-2012-0110700, 10-2015-0026335, Korean Registered Nos. 10-1295094 and 10-1273976, Various techniques for charging electric power produced by using solar energy and wind power have been disclosed in the related art.

By the way, in the power generation using solar light, wind power, tidal power, etc., the power generation amount changes every moment, and the variation of power generation amount is large depending on natural conditions.

As a result, the charging is not constantly performed according to the amount of generated power which is conventionally changed.

In the prior art, when a small amount of energy that does not satisfy a predetermined condition for minimum charging is applied, charging is not performed.

In the case of the conventional charging apparatus, a capacitor may be used to charge the generated power without discarding the generated power even when the power generation amount is small.

However, since the capacity of the capacitor is limited, there is a limitation in using the capacitor in the case of large-capacity power generation.

When a capacitor is used together with a battery, there is a problem that charging is not performed while the capacitor is charged with the battery.

Korea Patent Registration No. 2015-0026335 (Registration date: 2015.03.11 Title: Solar Inverter

SUMMARY OF THE INVENTION The present invention has been made in an effort to solve the conventional problems, and it is an object of the present invention to provide a power supply device capable of detecting a surrounding human body as a power source by means of electric power generated by sunlight and / or wind power, And to provide a control method thereof.

The present invention also provides a street lamp having a regenerative energy high efficiency charging device for controlling illumination intensity of a wind power generator by checking a power generation state, a remaining battery level or a current time, and a control method thereof.

In addition, the technical problem to be solved by the present invention is to provide a regenerative energy-efficient high-efficiency power generation system in which the remaining battery level is less than a predetermined reference value, the amount of power generated by the wind turbine generator is small, A streetlight having a charging device and a control method thereof.

Another object of the present invention is to provide a street lamp having a regenerative energy high efficiency charging device that saves energy by illuminating a street lamp only when a body such as a person or a differential car is sensed, and a control method thereof.

According to another aspect of the present invention, there is provided a street lamp having a regenerative energy high-efficiency charging device for charging a battery while charging a capacitor with a battery, will be.

It is another object of the present invention to provide a street lamp having a regenerative energy high efficiency charging device capable of constantly charging using a plurality of capacitors as an auxiliary storage device even if a low generation amount is generated under poor charging conditions, Method.

In order to solve such a problem, a streetlight having a regenerative energy high efficiency charging apparatus according to the present invention is characterized in that,

A power generating unit for generating wind or solar heat;

A moving body sensing unit for sensing movement of the moving body;

A timer for checking time;

A battery module for storing charged power;

An LED or the like for illuminating light at a predetermined place;

A driving unit for driving the LED or the like;

A remaining amount sensing unit for sensing a remaining amount of the battery module;

And a controller for charging the battery module using electric power generated by the electric power generator and controlling the illuminance of the LED or the like corresponding to the state of the electric generator, the current time, and the remaining battery power.

The controller reduces the illuminance when the generated current of the power generation unit is less than a predetermined value and the current time differs from the sunrise time by at least a predetermined time and the remaining amount of the battery module is less than a predetermined value.

The control unit controls the control module to charge the battery module with the output voltage of the power generation unit when the output voltage of the power generation unit is higher than the voltage of the battery module,

The first capacitor module is charged with the output voltage of the power generation unit and the battery module is charged with the voltage charged in the second capacitor module if the output voltage of the power generation unit is not higher than the voltage of the battery module.

In order to solve such a problem, a streetlight having a regenerative energy high efficiency charging device according to another aspect of the present invention includes:

A power generating unit for generating wind or solar heat;

A battery module for storing charged power;

A light for illuminating a predetermined place;

A driving unit for driving the back light;

A remaining amount sensing unit for sensing a remaining amount of the battery module;

And a controller for charging the battery module using electric power generated by the electric power generator and controlling the illuminance of the LED or the like corresponding to the state of the electric power generator,

The control unit controls the control module to charge the battery module with the output voltage of the power generation unit when the output voltage of the power generation unit is higher than the voltage of the battery module,

The first capacitor module is charged with the output voltage of the power generation unit and the battery module is charged with the voltage charged in the second capacitor module if the output voltage of the power generation unit is not higher than the voltage of the battery module.

Wherein,

A primary power conversion module (10) and a secondary power conversion module (12) connected in series between the power generation unit and the battery module;

A plurality of capacitor modules (31, 32) installed in parallel between the primary power conversion module (10) and the secondary power conversion module (12);

And a control module (40) for selectively controlling charging and discharging of the plurality of capacitor modules (31, 32).

Switches S1 and S2 are provided on a line connecting the primary power conversion module 10 and the plurality of capacitor modules 31 and 32 and the secondary power conversion module 12 and the plurality of capacitor modules 31 and 32 are provided with switches S3 and S4, respectively,

The switches S1, S2, S3 and S4 are selectively turned on / off under the control of the control module 40.

A main switch 20 is provided in a line directly connecting the primary power conversion module 10 and the secondary power conversion module 12 and the main switch 20 is controlled according to a control signal of the control module 40 And selectively turned on / off.

A method for controlling a streetlight having a high-efficiency charging device according to an aspect of the present invention,

A method for controlling a streetlight having a high-efficiency charging device for controlling a predetermined place to illuminate with a power source of a battery module,

Charging the battery module using power generated by the power generation unit;

The control unit receiving the remaining battery level;

Checking the current time;

Sensing generation power of the power generation unit;

And controlling the illuminance of the LED or the like corresponding to the state of the power generation unit, the current time, and the battery remaining amount.

The step of controlling the illuminance of the LED or the like corresponding to the state of the power generation unit, the current time,

The control unit reduces the illumination when the generated current of the power generation unit is less than a predetermined value and the current time differs from the sunrise time by at least a predetermined time and the remaining amount of the battery module is less than a predetermined value.

Wherein the controller charges the battery module using power generated by the power generator,

The control module of the control unit detecting an output voltage of the power generation unit;

The control module comparing an output voltage of the power generation unit with a voltage of the battery module;

Controlling the control module to charge the battery module with the output voltage of the power generation unit if the output voltage of the power generation unit is higher than the voltage of the battery module;

And charging the first capacitor module with the output voltage of the power generation unit and charging the battery module with the voltage charged in the second capacitor module if the output voltage of the power generation unit is not higher than the voltage of the battery module.

And controlling the control module to charge the battery module with the output voltage of the power generation unit when the output voltage of the power generation unit is higher than the voltage of the battery module,

The control module 40 turns on the main switch so that the direct connection from the primary power conversion module 10 to the secondary power conversion module 12 is performed and the battery module is charged with the power generated by the power generation portion .

The method comprises:

Determining whether the voltage of the first capacitor module is higher than a set voltage set for charging the battery module;

Charging the second capacitor module and charging the battery module with a voltage charged in the first capacitor module when the voltage of the first capacitor module is higher than the set voltage.

Wherein the step of the control module detecting an output voltage of the electricity-

The control module further detects a voltage of the battery, a voltage of the first capacitor module and a voltage of the second capacitor module.

A method for controlling a streetlight having a high-efficiency charging device according to an aspect of the present invention,

A street lamp having a high-efficiency charging device for charging the battery module using the power generation voltage of the power generation section, alternately charging the first capacitor module or the second capacitor module, and controlling the predetermined location to be lit by using the power source of the battery module As control method,

Charging the battery module using power generated by the power generator;

Determining by the control unit whether a moving body is detected by the moving body detecting unit;

And controlling the driving unit so that the backlight shines light for a predetermined time when the moving body is detected by the moving body sensing unit,

Wherein the controller charges the battery module using power generated by the power generator,

The control module of the control unit detecting an output voltage of the power generation unit;

The control module comparing an output voltage of the power generation unit with a voltage of the battery module;

If the output voltage of the power generation unit is higher than the voltage of the battery module, the control module turns on the main switch to make a direct connection from the primary power conversion module 10 to the secondary power conversion module 12, Charging the battery module with electric power developed in the battery module;

If the output voltage of the power generation unit is not higher than the voltage of the battery module,

The control module turns off the main switch, turns on the first switch 21 and the fourth switch 24, turns off the second switch 22 and the third switch 23, The voltage charged in the second capacitor module 32 is discharged and charged to the battery module 4 through the secondary power conversion module 12, To be performed.

The method comprises:

Determining whether the voltage of the first capacitor module (31) reaches a predetermined voltage which is a level at which the control module can charge the battery module (4);

When the voltage of the first capacitor module 31 reaches a set voltage which is a level at which the battery module 4 can be charged, the control module turns off the first switch 21 and the fourth switch 24 And the second switch 22 and the third switch 23 are turned on so that charging is performed from the primary power conversion module 10 to the second capacitor module 32. The first capacitor module 31) is discharged and charged to the battery module 4 via the secondary power conversion module 12. The step of charging the battery module 4 includes charging the battery module 4 through the secondary power conversion module 12,

Wherein the step of the control module detecting an output voltage of the electricity-

The control module further detects a voltage of the battery, a voltage of the first capacitor module and a voltage of the second capacitor module.

The method comprises:

Determining whether the voltage of the second capacitor module (32) reaches a predetermined voltage which is a level at which the control module can charge the battery module (4);

The control module turns on the first switch 21 and the fourth switch 24 when the voltage of the second capacitor module 32 reaches a set voltage which is a level at which the battery module 4 can be charged The second switch 22 and the third switch 23 are turned off to charge the first capacitor module 31 from the first power conversion module 10 and the second capacitor module 32 To the battery module 4 through the secondary power conversion module 12, so that the battery module 4 is charged.

In the embodiment of the present invention, a streetlight having a regenerative energy high efficiency charging device that detects a surrounding human body as a power source by power generated by sunlight and / or wind power and illuminates a streetlight for a predetermined time to eliminate a risk factor such as an electric shock, A control method can be provided.

In addition, the embodiment of the present invention can provide a streetlight having a regenerative energy high efficiency charging device for controlling illumination intensity of a wind power generator by checking a state of power generation, remaining battery power or current time, and a control method thereof.

In addition, in the embodiment of the present invention, a regenerative energy high-efficiency charging device which lowers the illuminance when the remaining amount of the battery is less than a predetermined reference value, the amount of power generated by the wind power generator is small, And a control method thereof.

Further, in the embodiment of the present invention, it is possible to provide a streetlight having a regenerative energy high efficiency charging device that saves energy by illuminating a streetlight only when a body such as a person or a differential car is sensed, and a control method thereof.

In addition, in the embodiment of the present invention, the capacitor module is charged when the amount of power generation is low, such as when the weather is cloudy or when the wind is weak, and in the capacitor module that has been charged, a discharge is made toward the battery module, And it is possible to provide a street lamp having a regenerative energy high efficiency charging device capable of significantly improving power generation efficiency and a control method thereof.

In addition, in the embodiment of the present invention, since the charging is performed in the other capacitor module while discharging from one capacitor module to the battery module, continuous street lamp charging with a renewable energy high efficiency charging device for maximizing power generation efficiency A control method can be provided.

In addition, in the embodiment of the present invention, it is possible to provide a street lamp having a regenerative energy high efficiency charging device capable of directly charging the battery without passing through a capacitor when the generated amount is large, and a control method thereof.

Further, in the embodiment of the present invention, it is possible to configure the primary conversion module and the secondary power conversion module to track the optimum point of the generated voltage, and to adjust the generated voltage and the voltage of the battery module to realize the maximum charging characteristic It is possible to provide a streetlight having a regenerative energy high efficiency charging device and a control method thereof.

1 is a configuration diagram of a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.
2 is a detailed view of the control unit of FIG.
3 is a flowchart of a charge control method in a method of controlling a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.
4 is a flowchart of a control method of illuminating a streetlight among a method of controlling a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.
5 is a flowchart of a method of controlling the illuminance of a streetlight in a method of controlling a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

1 is a configuration diagram of a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention includes a power generation unit 2, a moving body sensing unit 110, a timer 120, a battery module 4, an LED 140, a driving unit 130, a remaining amount sensing unit 150, and a control unit 100.

The power generation section 2 includes a wind power generator or a solar power generator, and may include a generator using other natural forces as necessary. For example, in addition to a generator generating wind or solar energy, a generator using hydraulic or tidal power may be applied.

The moving body detecting unit 110 may be a sensor for detecting movement of a person or an automobile.

The timer 120 checks the time.

The battery module 4 stores the charged electric power and supplies power to the driving unit 130 driving the LED lamp 140 and the LED lamp 140 according to the control of the controller 100. [

The LED lamp 140 is installed to illuminate various places such as a street, a road, an alley, etc., and may be used as a high-pressure mercury lamp, fluorescent lamp, sodium lamp,

The driving unit 130 drives the LED 140 and the like, and may include a driving circuit and the like.

The remaining amount sensing unit 150 senses the remaining amount of the battery module 4,

The control unit 100 charges the battery module using electric power generated in the electric power generating unit 2 and charges the battery module 4 using electric power generated in the electric power generating unit 2, And controls the illuminance of the LED 140 or the like corresponding to the state of the LED 2, the current time, and the remaining battery level.

When the generated current of the power generation unit 2 is less than a predetermined value and the current time differs from the sunrise time by a predetermined time or more and the remaining amount of the battery module 4 is less than a predetermined value, .

The control unit 100 controls the driving unit 130 to illuminate the light for a predetermined time when the moving body is detected by the moving body sensing unit 110.

If the output voltage of the power generation unit 2 is higher than the voltage of the battery module, the control unit 100 controls the control module to charge the battery module with the output voltage of the power generation unit 2,

If the output voltage of the power generation unit 2 is not higher than the voltage of the battery module 4, the first capacitor module 31 is charged with the output voltage of the power generation unit 2, And controls the charging of the battery module 4 with the charged voltage.

If necessary, the control module 40 of the control unit 100 can perform charge control and streetlight control of the above process.

A detailed configuration of such a control unit is shown in Fig.

2 is a detailed view of the control unit.

2, the controller 100 includes a primary power conversion module 10, a secondary power conversion module 12, a plurality of capacitor modules 31 and 32, and a control module 40.

 The primary power conversion module 10 and the secondary power conversion module 12 are connected in series between the power generation unit 2 for generating electricity and the battery module 4 for charging the produced power.

A plurality of capacitor modules (31, 32) are installed in parallel between the primary power conversion module (10) and the secondary power conversion module (12).

The control module 40 controls the charging and discharging of the plurality of capacitor modules 31 and 32 selectively.

The charging characteristics of the capacitors constituting the capacitor modules 31 and 32 can be charged with a substantially full charge ratio and the internal equivalent resistance is low and the charging efficiency is excellent.

Therefore, it is possible to charge the capacitor module 4 even in the case of a small amount of power generation that can not be charged in the battery module 4.

Particularly, it is difficult to charge the battery module 4 with the power generation voltage generated by solar power generation on cloudy days and power generation by wind power of 3 to 5 m / s or less. However, in the case of the capacitor module, It is possible to efficiently charge the battery even at a low intensity.

 Switches S1 and S2 are provided on the line connecting the primary power conversion module 10 and the plurality of capacitor modules 31 and 32 and the secondary power conversion module 12 and the plurality of capacitors Switches S3 and S4 are provided on the lines connecting the modules 31 and 32, respectively.

The switches S1, S2, S3 and S4 are selectively turned on / off under the control of the control module 40.

A main switch (20) is installed in a line that directly connects the primary power conversion module (10) and the secondary power conversion module (12).

The main switch 20 is selectively turned on / off according to a control signal of the control module 40.

The plurality of capacitor modules 31 and 32 are composed of two capacitors, but the number thereof can be varied as necessary.

In the case where the plurality of capacitor modules 31 and 32 are constituted by two capacitors

Switches (S1, 21) are provided on a line connecting the primary power conversion module (10) and the first capacitor module (31). Switches S2 and 22 are provided on a line connecting the primary power conversion module 10 and the second capacitor module 32. [

Switches S3 and 23 are provided on the line connecting the secondary power conversion module 12 and the first capacitor module 31. [ Switches S4 and 24 are provided on a line connecting the secondary power conversion module 12 and the second capacitor module 32. [

A control method of a furnace or the like having a high efficiency charging apparatus according to an embodiment of the present invention having such a configuration will be described as follows.

3 is a flowchart of a charge control method in a method of controlling a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.

Referring to FIG. 3, first, power is generated in the power generation section 2 by using solar heat, wind power, hydroelectric power, or tidal force.

The control module 40 of the control unit 100 controls the output voltage VIN of the power generation unit 2, the voltage of the battery module 4 and the voltage of the first capacitor module 31 and the voltage of the second capacitor module 32, (S210).

Then, the control module 40 determines whether the output voltage VIN of the power generation unit 2 is higher than the voltage of the battery module 4 (S220).

Next, the control module 40 controls the main switch to turn on if the voltage input from the power generation unit 2 is higher than the voltage of the battery module 4 (S230).

 As described above, when the main switch 20 is turned on, the control module 40 turns off the first switch 21 to the fourth switch 24.

In this state, the secondary power conversion module 12 is directly connected to the primary power conversion module 10 and the power generated by the power generation unit 2 is sufficient, so that the battery module 4 is charged .

The control module 40 controls the main switch 20 to be turned off when the voltage input from the power generation section 2 is lower than the voltage of the battery module 4. [ In this case, it is the case that the battery module 4 can not be charged with the power generation voltage of the power generation section 2, and when the low generation power is produced.

Then, when the main switch 20 is turned off, the control module 40 turns on the first switch 21 and the fourth switch 24 and turns on the second switch 22 and the third switch 23, .

In this state, the primary power conversion module 10 charges the first capacitor module 31, the voltage charged in the second capacitor module 32 is discharged, and the secondary power conversion module 12 And then the battery module 4 is charged (S240).

At this time, step S260 may be performed if necessary. In this case, the second capacitor module 32 is charged first.

Thereafter, the control module 40 determines whether the voltage of the first capacitor module 31 reaches a set voltage, which is a level at which the battery module 4 can be charged (S250).

 The control module 40 turns off the first switch 21 and the fourth switch 24 when the voltage of the first capacitor module 31 reaches a set voltage which is a level at which the battery module 4 can be charged. And controls the second switch 22 and the third switch 23 to be turned on.

In such a state, the primary power conversion module 10 charges the secondary battery module 32, the voltage charged in the primary capacitor module 31 is discharged, and the secondary power conversion module 12 And then the battery module 4 is charged (S260).

In addition, the control module 40 determines whether the voltage of the second capacitor module 32 has reached a set voltage which is a level at which the battery module 4 can be charged (S270).

When the voltage of the second capacitor module 32 reaches a set voltage which is a level at which the battery module 4 can be charged, the control module 40 again transmits the first switch 21 and the fourth switch 24 And controls the second switch 22 and the third switch 23 to be turned off.

In this state, the primary power conversion module 10 charges the first capacitor module 31, the voltage charged in the second capacitor module 32 is discharged, and the secondary power conversion module 12 And then the battery module 4 is charged (S240).

In this way, by the operation of selectively turning off / off the first switch 21 and the fourth switch 24 or the second switch 22 and the third switch 23 in the control module 40, The first capacitor module 31 and the second capacitor module 32 are alternately charged and discharged.

That is, while the first capacitor module 31 is charged, the second capacitor module 32 is discharged, and while the first capacitor module 31 is discharged, the second capacitor module 32 is charged. Therefore, even if the generated power of the power generation section 2 is weak, the battery module 4 can be continuously charged.

Here, the charging and discharging control of the first capacitor module 31 or the second capacitor module 32 is controlled based on whether the voltage of the first capacitor module 31 or the second capacitor module 32 reaches the set voltage The control module 40 is configured in advance.

Then, the above process is repeatedly performed

The control module 40 detects the voltage VIN input from the power generation unit 2 and compares the detected voltage VIN with the first capacitor module 31 and the second capacitor module 32, 1 capacitor module 31 and the second capacitor module 32 to maximize the efficiency of the electric power charged in the capacitor module 31 and the second capacitor module 32.

The control module 40 controls two voltage differences by a PWM (Pulse Width Modulation) method.

By configuring the primary power conversion module 10 and the secondary power conversion module 12, it is possible to realize the maximum charging characteristic by adjusting the generation voltage and the voltage of the battery module 4.

The primary power conversion module 10 and the secondary power conversion module 12 can convert the input and output voltage ratios to high efficiencies by adjusting the duty ratios of the PWM (Pulse Width Modulation) type control Do.

As described above, when the battery module 4 is charged or the streetlight is turned on during charging, this process will be described as follows.

4 is a flowchart of a control method of illuminating a streetlight among a method of controlling a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.

Referring to FIG. 4, the moving body detection unit 110 detects movement of a person or an automobile and outputs the detected motion to the control unit 100.

Then, the control unit 100 determines whether a moving body is detected by the moving body sensing unit 110 (S410).

The control unit 100 starts the timer 120 in step S420 and controls the driving unit 130 to turn on the LED lamp 140 in step S430. At this time, the brightness can be 100 percent.

Then, the control unit 100 controls the driving unit 130 so that the LED 140 or the like illuminates the light for a predetermined time, which is sufficient time for a person or an automobile to pass through.

Next, the control unit 100 refers to the timer 120 and determines whether a predetermined time has passed (S440).

When the predetermined time has elapsed, the control unit 100 resets the timer 120, lowers or turns off the erection of the LED or the like by 50%, and repeats the above-described process (S410).

If the moving body sensing unit 110 continuously detects the moving body by checking the moving body sensing unit 110 continuously after a predetermined time has elapsed after the moving body is detected and the LED or the like is turned on and the timer is started, The timer 120 is started to determine the timer delay time from the last movement.

Therefore, it is possible to prevent the light from being turned on and off repeatedly when the movement continuously occurs under the LED or the like.

If necessary, the controller 100 may turn on the street lamp only when there is movement of the body without time check.

5 is a flowchart of a method of controlling the illuminance of a streetlight in a method of controlling a streetlight having a regenerative energy high efficiency charging apparatus according to an embodiment of the present invention.

Referring to FIG. 5, the remaining amount sensing unit 150 senses the remaining battery power of the battery module 4 and outputs the remaining battery amount to the control unit 100. Then, the controller 100 receives the battery remaining amount from the remaining amount sensing unit 150 (S510).

Then, the control unit 100 checks the current time with reference to the timer 120 (S520).

Then, the control unit 100 senses the generated power of the power generation unit 2 (S530). Especially, when the street lamp lights up at night, there is no sun, so it senses the generated power of the wind power generator.

Then, the control unit 100 determines whether the generated current of the wind turbine generator is less than a reference value (S540). That is, the reference power value such as whether the power generated from very weak wind power is greater than the power that turns on the light is set as the reference value.

If it is determined that the generated current is less than the reference value, the control unit 100 determines whether the remaining amount of the battery module 4 measured by the remaining amount sensing unit 150 is less than a reference value (S550). In this case, the reference value is a reference value that is enough to be completely discharged after about 1 hour, and the reference value may be set differently according to the capacity or performance of the battery.

As a result of the determination, if the remaining amount of the battery module 4 is less than the reference value, the controller 100 determines whether the current time is within one hour from the sunrise time (S560). That is, if the sunrise time is 7 o'clock, it is determined whether it is after 6 o'clock. At this time, if the sunrise time is not long, it is judged that the song charging is possible. In some cases, the weather conditions can also be determined, and such control can be omitted on the occasion that the solution does not rise.

As a result of the determination, if the battery remaining amount is not enough and the charging power is not sufficient yet and the battery needs to be charged for a long time, the illuminance is reduced by 50% (S580).

If it is determined in step S540, S550, or S560 that the generated current of the power generation unit 2 is equal to or greater than a predetermined value, or if the current time does not differ from the sunrise time by a predetermined time or the remaining amount of the battery module is equal to or greater than a predetermined value The control unit 100 maintains the illuminance at 100% without decreasing the illuminance (S570).

The control in the above process can be applied to a case in which the street lamp is turned on during the night time, and the case in which the light is turned on only when the body is detected.

In the embodiment of the present invention, the illuminance of the lighting can be controlled by checking the power generation state of the wind turbine generator, the remaining amount of the battery, or the current time.

Further, in the embodiment of the present invention, the remaining amount of the battery is less than a predetermined reference value, the amount of power generated by the wind power generator is small, and the illuminance is lowered when the sunrise time is long.

In addition, in the embodiment of the present invention, as a power source by power generated by sunlight and / or wind power, the surrounding human body is sensed and the streetlight is illuminated for a predetermined time, thereby eliminating the risk of electric shock.

In addition, in the embodiment of the present invention, it is possible to save energy by illuminating a streetlight only when a moving body such as a person or a differential car is detected.

In addition, in the embodiment of the present invention, the capacitor module is charged when the amount of power generation is low, such as when the weather is cloudy or when the wind is weak, and in the capacitor module that has been charged, a discharge is made toward the battery module, And the power generation efficiency can be greatly improved.

Also, in the embodiment of the present invention, charging is performed in one capacitor module while discharging from one capacitor module to the battery module, so that continuous charging is continuously performed, thereby maximizing power generation efficiency.

Further, in the embodiment of the present invention, when the generated amount is large, it is possible to charge the battery directly without passing through the capacitor.

In addition, in the embodiment of the present invention, it is possible to track the optimum point of the generated voltage by configuring the primary conversion module and the secondary power conversion module, and to adjust the generated voltage and the voltage of the battery module to realize the maximum charging characteristic have.

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

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 disclosed exemplary embodiments, It belongs to the scope of right.

Claims (10)

A power generating unit for generating wind or solar heat;
A moving body sensing unit for sensing movement of the moving body;
A timer for checking time;
A battery module for storing charged power;
An LED or the like for illuminating light at a predetermined place;
A driving unit for driving the LED or the like;
A remaining amount sensing unit for sensing a remaining amount of the battery module;
And a controller for charging the battery module using electric power generated by the electric power generator and controlling the illuminance of the LED or the like corresponding to the state of the electric power generator,
Wherein the control unit turns on the main switch when the output voltage of the power generation unit is higher than the voltage of the battery module and direct connection is made from the primary power conversion module to the secondary power conversion module, Lt; / RTI >
When the output voltage of the power generation unit is not higher than the voltage of the battery module, the control unit turns off the main switch, turns on the first switch and the fourth switch, turns off the second switch and the third switch, Charging the battery module from the power conversion module to the first capacitor module, discharging the voltage charged in the second capacitor module, charging the battery module via the secondary power conversion module,
The controller determines whether the voltage of the first capacitor module has reached a set voltage, which is a level at which the battery module can be charged,
The controller turns off the first switch and the fourth switch when the voltage of the first capacitor module reaches a set voltage which is a level at which the battery module can be charged, The charging is performed from the primary power conversion module to the second capacitor module, the voltage charged in the first capacitor module is discharged, and the battery module is charged through the secondary power conversion module Respectively,
Wherein the controller further detects a voltage of the battery module, a voltage of the first capacitor module, and a voltage of the second capacitor module
Street lamp with high efficiency charging device. The method according to claim 1,
Wherein the control unit reduces the illuminance when the generated current of the power generation unit is less than a predetermined value and the current time differs from the sunrise time by a predetermined time or more and the remaining amount of the battery module is less than a predetermined value, ≪ / RTI > delete A power generating unit for generating wind or solar heat;
A battery module for storing charged power;
A light for illuminating a predetermined place;
A driving unit for driving the back light;
A remaining amount sensing unit for sensing a remaining amount of the battery module;
And a controller for charging the battery module using electric power generated by the electric power generator and controlling the illuminance of the LED or the like corresponding to the state of the electric power generator,
Wherein the control unit turns on the main switch when the output voltage of the power generation unit is higher than the voltage of the battery module and direct connection is made from the primary power conversion module to the secondary power conversion module, Lt; / RTI >
When the output voltage of the power generation unit is not higher than the voltage of the battery module, the control unit turns off the main switch, turns on the first switch and the fourth switch, turns off the second switch and the third switch, Charging the battery module from the power conversion module to the first capacitor module, discharging the voltage charged in the second capacitor module, charging the battery module via the secondary power conversion module,
The controller determines whether the voltage of the first capacitor module has reached a set voltage, which is a level at which the battery module can be charged,
The controller turns off the first switch and the fourth switch when the voltage of the first capacitor module reaches a set voltage which is a level at which the battery module can be charged, The charging is performed from the primary power conversion module to the second capacitor module, the voltage charged in the first capacitor module is discharged, and the battery module is charged through the secondary power conversion module Respectively,
Wherein the controller further detects a voltage of the battery module, a voltage of the first capacitor module, and a voltage of the second capacitor module
Street lamp with high efficiency charging device. delete 5. The method of claim 4,
Wherein the control unit reduces the illuminance when the generated current of the power generation unit is less than a predetermined value and the current time differs from the sunrise time by a predetermined time or more and the remaining amount of the battery module is less than a predetermined value, ≪ / RTI > delete A method for controlling a streetlight having a high-efficiency charging device for controlling a predetermined place to illuminate with a power source of a battery module,
Charging the battery module using power generated by the power generation unit;
The control unit receiving the remaining battery level;
Checking the current time;
Sensing generation power of the power generation unit;
Controlling the illuminance of the LED or the like corresponding to the state of the power generation unit, the current time, and the battery remaining amount,
Wherein the controller charges the battery module using power generated by the power generator,
The control module of the control unit detecting an output voltage of the power generation unit;
The control module comparing an output voltage of the power generation unit with a voltage of the battery module;
Wherein when the output voltage of the power generation unit is higher than the voltage of the battery module, the control module turns on the main switch so that a direct connection is made from the primary power conversion module to the secondary power conversion module, Charging the module;
If the output voltage of the power generation unit is not higher than the voltage of the battery module, the control module turns off the main switch, turns on the first switch and the fourth switch, turns off the second switch and the third switch, Charging the first capacitor module from the secondary power conversion module and discharging the voltage charged in the second capacitor module to charge the battery module via the secondary power conversion module,
Determining whether the voltage of the first capacitor module reaches a predetermined voltage which is a level at which the control module can charge the battery module;
The control module turns off the first switch and the fourth switch when the voltage of the first capacitor module reaches a set voltage which is a level at which the battery module can be charged, The charging is performed from the primary power conversion module to the second capacitor module, the voltage charged in the first capacitor module is discharged, and the battery module is charged through the secondary power conversion module The method comprising the steps of:
Wherein the step of the control module detecting the output voltage of the electricity-
Wherein the control module further detects a voltage of the battery module, a voltage of the first capacitor module, and a voltage of the second capacitor module,
Controlling the control module to charge the battery module with the output voltage of the power generation unit if the output voltage of the power generation unit is higher than the voltage of the battery module;
Charging the first capacitor module with the output voltage of the power generation unit and charging the battery module with the voltage charged in the second capacitor module if the output voltage of the power generation unit is not higher than the voltage of the battery module,
The step of controlling the illuminance of the LED or the like corresponding to the state of the power generation unit, the current time,
Wherein the control unit reduces the illuminance when the generated current of the power generation unit is equal to or less than a predetermined value and the current time differs from the sunrise time by at least a predetermined time and the remaining amount of the battery module is less than a predetermined value
Method of controlling street lamp with high efficiency charging device. delete delete

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