KR100960937B1 - Roadlamp apparatus - Google Patents

Abstract

PURPOSE: A roadlamp control device is provided to reduce the power consumption of a roadlamp by driving the roadlamp using a second voltage which is lower than a first voltage. CONSTITUTION: A battery module(100) accumulates sunlight. A storage battery(200) stores the voltage which is generated by the battery module. A first voltage generating part(610) generates a first voltage for driving a roadlamp by using the charging voltage of the storage battery. If the first voltage is lower than a low voltage level which is predetermined by a low voltage setting part, a controller(300) outputs a control signal for generating a second voltage which is lower than the first voltage. A switching part(500) switches the charging voltage to a second voltage generating part(620) according to a control signal of the controller. The second voltage generating part generates the second voltage for driving a roadlamp.

Description

Low voltage control device for street lamps driven by different voltages {ROADLAMP APPARATUS}

The present invention is to control the driving of the street lamp by charging the voltage generated by the battery module (Module) that integrates solar light, more specifically from the battery charged with the voltage generated by the battery module When the charging voltage supplied to the street lamp is lower than or equal to a predetermined low voltage level, the heterogeneous voltage generation unit generates a second voltage, which is a low voltage at a level lower than the first voltage that normally drives the street lamp. The present invention relates to a control device for driving a street lamp so that the power consumption of the street lamp is drastically down, thereby further extending the driving time of the street lamp in preparation for over-discharge of the battery.

In recent years, the world's oil price has been soaring due to the limited dependence on electricity, gas and oil resources. On the other hand, most of mankind has raised environmental pollution problems due to the increase of greenhouse gases caused by the use of petroleum energy. have.

Accordingly, attention is focused on the development of alternative energy using nature such as solar power, wind power and tidal power, which can be used indefinitely in an eco-friendly environment without generating environmental pollution. The development of devices for producing electrical energy required for homes and industries is actively progressing.

On the other hand, as a means for integrating conventional solar energy to control the street light, a solar cell (Module) equipped with a solar cell (Solar cell) using the photoelectric effect (generate effect) that generates a current when receiving sunlight. It is a situation in which a way of receiving a lot of sunlight (for example, south direction) is installed inclined to the struts in which the street lamps are installed, and a method of integrating solar energy accordingly.

However, such a conventional technology is that when the battery module that integrates solar light is cloudy or when the sunlight is short in winter, the amount of solar energy is drastically dropped and the production of electrical energy is reduced.

As a result, the charging capacity charged to the storage battery during the day is reduced through the battery module, and eventually causes a number of problems that must be controlled to drive the streetlight by using a commercial AC power (for example; AV 220V) at night. there was.

The present invention for solving the conventional problems as described above is a heterogeneous voltage when the charging voltage supplied to the street lamp from the battery charged using the voltage generated through the battery module is below the set low voltage level (Level) The generation unit generates a second voltage, which is a low voltage lower than the first voltage that normally drives the street light, to drastically drive down the power consumption of the street light, thereby preparing for overdischarge of the battery. The purpose is to further extend the driving time of the street light.

Means for solving the problems of the present invention as described above is characterized in that a battery module (Module) for integrating sunlight is provided, the storage battery is charged with the voltage generated in the battery module is configured.

In addition, the first voltage generation unit for generating a first voltage (V1) for driving the street light by receiving the charging voltage (Vo) output from the battery is characterized in that it is configured.

In addition, when the first voltage V1 output from the first voltage generation unit is detected and the first voltage V1 is determined to be equal to or lower than the low voltage level VL set by the low voltage setting unit (V1 <VL), The controller may be configured to output a control signal for generating the second voltage V2 having a level lower than the first voltage V1.

The control unit outputs the control signal output from the controller to switch the charging voltage Vo supplied to the first voltage generator to the second voltage generator, thereby generating the second voltage generator. Characterized in that it comprises a switching unit for driving the street light at the second voltage (V2).

On the other hand, as another means for solving the problems of the present invention as described above is provided with a battery module (Module) for integrating the solar light, characterized in that the battery is configured to charge the voltage generated in the battery module do.

In addition, the first voltage generation unit and the first voltage generating unit for generating a first voltage (V1) of different voltage levels (Level) different from each other in order to drive the street light by receiving the charging voltage (Vo) output from the battery A second voltage generation unit configured to generate a second voltage V2 having a level lower than the voltage V1 may be configured.

Also, when the charging voltage Vo output from the battery is monitored through a charging state monitoring unit, when the charging voltage Vo is determined to be lower than or equal to the low voltage level VL set by the low voltage setting unit (Vo <VL). The controller may be configured to output a control signal for generating the second voltage V2 in the second voltage generator.

The control unit outputs the control signal output from the controller to switch the charging voltage Vo supplied to the first voltage generator to the second voltage generator, thereby generating the second voltage generator. Characterized in that it comprises a switching unit for driving the street light at the second voltage (V2).

Hereinafter, the objects and solutions to the present invention will become more apparent from the detailed description of the various embodiments shown in the accompanying drawings.

As described above, the present invention generates a low voltage, which is a second voltage having a lower level than the first voltage at which the street lamp is normally driven, as heterogeneous, and significantly lowers the power consumption of the street lamp by the low voltage. In this case, the driving time of the street lamp is further extended in preparation for over-discharge of the storage battery, and the electric energy is further reduced.

In describing a specific embodiment of the present invention, it is illustrated by the drawings of the present invention, the configuration and operation thereof will be described as at least one embodiment, whereby the technical spirit of the present invention and its core Configurations and operations should not be limited.

For reference, in designating reference numerals in the drawings described in the present invention, it should be noted that the same components are given the same reference numerals as much as possible, even if shown in different drawings.

Hereinafter, a control apparatus for a street lamp driven by receiving electric energy (or “voltage”) generated using the solar cell module according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a first embodiment showing a circuit configuration in which a street lamp is controlled to a low voltage by receiving electric energy generated by using a solar cell module according to the present invention, and FIG. 2 is a solar cell module according to the present invention. 2 is a block diagram illustrating a circuit configuration in which a street light is controlled to a low voltage by receiving electrical energy generated using

In the present invention, the street lamp installed on the side of the road is driven by an AC or DC voltage (or referred to as a "light"). It may include various lights such as, but will not be limited to the examples listed above.

As a means for solving the problem of the present invention, it is generally installed in a pillar (not shown) made of metal or concrete, and the like, and the voltage (or A battery module (Module) 100 for generating " electrical energy "

In addition, a storage battery 200 that is charged using a voltage generated by the battery module 100 (for example, 14.4 (V) constant voltage) is configured.

In addition, a first voltage for driving (or also referred to as "lighting") the street light 800 by receiving a charging voltage Vo (for example, 12 (V)) charged and output from the battery 200. A first voltage generator 610 for generating V1 is configured.

In addition, the first voltage V1 output from the first voltage generator 610 is detected, and the first voltage V1 is set to the low voltage level VL set by the low voltage setting unit 400 (eg, For example, when it is determined that 10.5 (V) or less (V1 <VL), a control signal for generating a low voltage that is a second voltage V2 at a level lower than the first voltage V1 is output. The control unit 300 is configured.

In addition, the first voltage V1 output from the first voltage generator 610 and detected through the controller 300 is set to the low voltage level VL (eg, 10.5 (V) set by the low voltage setting unit 400. ) Or higher than the level of the second voltage V2 (for example, 10.4 (V) or less) generated by the second voltage generator 620.

In addition, by receiving the control signal output from the controller 300 by switching the charging voltage (Vo) supplied to the first voltage generator 610 to the second voltage generator 620, the switching (Switching) control, It characterized in that it comprises a switching unit 500 for driving the street lamp 800 at a low voltage which is the second voltage (V2) generated by the second voltage generation unit 620.

On the other hand, as another means for solving the problem of the present invention is installed in a pillar (not shown) made of metal or concrete, etc., to integrate the sunlight emitted from the sun to the voltage ( Or "electrical energy") is configured to generate a battery module (Module) (100).

In addition, a storage battery 200 that is charged using a voltage generated by the battery module 100 (for example, 14.4 (V) constant voltage) is configured.

In addition, a first electric field of a different type having different voltage levels in order to drive the street lamp 800 by receiving the charging voltage Vo (eg, 12 (V)) output from the battery 200. The first voltage generation unit 610 for generating the voltage V1 and the second voltage generation unit 620 for generating the second voltage V2 having a level lower than the first voltage V1 are configured. .

In addition, the charging voltage Vo output from the battery 200 is monitored through the charging state monitoring unit 700 so that the charging voltage Vo is set at the low voltage setting unit 400. (For example, 10.5 (V)) or less (Vo <VL), the second voltage generation unit 620 outputs a control signal for generating a low voltage, which is the second voltage V2, at this time. 300 is configured.

In addition, the charge state monitoring unit 700 may set the low voltage level VL (for example, 10.5 (V)) set by the low voltage setting unit 400 with respect to the charge voltage Vo output from the battery 200. Real-time comparison monitoring based on) and supplying the compared monitoring result to the control unit 300 to determine the charging voltage Vo to be equal to or lower than the low voltage level VL set by the low voltage setting unit 400 (Vo> VL). In this case, the control unit 300 outputs a control signal for generating the first voltage V1 from the first voltage generation unit 610 to the switching unit 500.

In addition, by receiving the control signal output from the controller 300 by switching the charging voltage (Vo) supplied to the first voltage generator 610 to the second voltage generator 620, the switching (Switching) control, It characterized in that it comprises a switching unit 500 for driving the street lamp 800 at a low voltage which is the second voltage (V2) generated by the second voltage generation unit 620.

For reference, the charging voltage Vo output from the storage battery 200 (eg, 12 (V)), including the voltage generated in the aforementioned battery module 100 (for example, 14.4 (V) constant voltage). And the low voltage level VL set in the low voltage setting unit 400 (eg, 10.5 (V)) and the first voltage V1 generated in the first voltage generation unit 610 (eg, 10.5 (V). ) To 12 (V)), and the second voltage V2 (for example; 10.4 (V) or less) generated by the second voltage generation unit 620 may be variously changed by those skilled in the art, and thus limited separately. It would be desirable not to have

Next, various exemplary embodiments included in the above-described present invention will be described in detail.

First, a frame (not shown) in which the solar cell 110 using a photoelectric effect characteristic in which a current is generated in the battery module 100 is made of metal or the like. It is characterized by being installed in).

In addition, a first voltage V1 is provided in the heterogeneous voltage generation unit 600 which generates different voltage levels of heterogeneous to drive the street lamp 800 in at least two to two stages. ) Is a first voltage generation unit 610 for generating a voltage and a second voltage generation unit 620 for generating a low voltage which is a second voltage V2 at a lower voltage level than the first voltage V1. do.

In other words, it receives the charging voltage Vo output from the battery 200 to drive the street light 800 and generates (or converts) a DC voltage necessary for driving the street light 800. To generate a first voltage V1 having a different voltage level through the heterogeneous voltage generation unit 600 provided with a DC-DC converter. A first voltage generator 610 and a second voltage generator 620 for generating a second voltage V2 at a level lower than the first voltage V1 are configured, wherein the second voltage generator Down driving current I2 supplied to the street lamp 800 through the unit 620 is 10% of the normal driving current I1 supplied to the street lamp 800 through the first voltage generation unit 610. In this case, the power consumption of the street lamp 800 is driven down by at least 1/10 times to prepare for over-discharge of the storage battery 200. By the operation to further extend the driving time of the street lamp (800) .

In this case, the street lamp 800 may be driven by a direct current (DC) voltage by connecting a plurality of LED elements in series, parallel, or parallel type in consideration of a driving voltage or a driving current.

In addition, the controller 300 determines that the first voltage V1 output from the first voltage generator 610 is equal to or lower than the low voltage level VL set by the low voltage setting unit 400 (V1> VL). At this time, a control signal for stopping the driving of the second voltage generator 620 is output to the switching unit 500 so that the second voltage V2 generated at a lower voltage than the first voltage V1 is not output. It may be desirable to control the system so that it is controlled.

In addition, when the charging voltage Vo of the battery 200 falls below a normal driving voltage range (for example, 10.5 V) of the street lamp 800, the second voltage generator 620. ) Is output at least 0.99 times based on the first voltage V1 (eg, at least 10.5 (V)) output from the first voltage generation unit 610 (eg, at least 10.5V). By differentially generating at a low voltage level (10.4 (V) or less), it may be desirable to maintain the driving time of the street lamp 800 for a longer time.

In addition, the controller 300 has a voltage lower than 50% of the low voltage level VL (for example, 10.5 (V)) set by the low voltage setting unit 400 that is output from the battery 200. If it is determined that (Vo <VL x 50%), then a control signal for stopping driving of the second voltage generator 620 is output to the switching unit 500, and the heterogeneous voltage generator 600 is output. By controlling such that the second voltage (V2) is not output through, it will be desirable to prevent over-discharge of the storage battery 200.

Here, the switching unit 500 may be made of a contact relay or a contactless logic device.

On the other hand, the controller 300 is a voltage that is less than 50% of the low voltage level (VL) (for example; 10.5 (V)) set by the low voltage setting unit 400, the charging voltage (Vo) output from the battery 200 If it is determined that (Vo <VL x 50%), that is, when the storage battery 200 is in a dangerous state of over discharge, a control signal for supplying external power to the street lamp 800 is output to the switching unit 500. It may be desirable to drive the street lamp 800 through the external power source.

In addition, between the battery module 100 and the storage battery 200, a constant voltage regulator for generating and supplying a constant voltage for charging the storage battery 200 (for example, 14.4 (V)) is omitted. It will be desirable to provide a stable charging voltage to the storage battery 200 through the).

It will be apparent to those skilled in the art that various changes, modifications, and the like can be made without departing from the technical spirit of the present invention through the above description.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments as mentioned, but should be defined by the claims of the present invention.

1 is a block diagram of a first embodiment showing a circuit configuration in which a street light is controlled to a low voltage by receiving electrical energy generated by using a solar cell module according to the present invention.

FIG. 2 is a block diagram of a second embodiment showing a circuit configuration in which a street light is controlled at a low voltage by receiving electrical energy generated by using the solar cell module according to the present invention.

Explanation of symbols on the main parts of the drawings

100: battery module

110: solar cell

200: storage battery

300: control unit

400: low voltage setting part

500: switching unit

600: heterogeneous voltage generation unit

610: the first voltage generation unit

620: second voltage generation unit

700: charging status monitoring unit

800: street light

Claims (8)

A battery module (Module) 100 for integrating sunlight; A storage battery 200 in which the voltage generated by the battery module 100 is charged; A first voltage generator configured to generate a first voltage V1 having a different voltage level in order to drive the street light 800 by receiving the charging voltage Vo output from the battery 200. 610; And a heterogeneous voltage generation unit 600 including a second voltage generation unit 620 for generating a second voltage V2 having a level lower than the first voltage V1. Including, The first voltage V1 output from the first voltage generator 610 is detected to determine that the first voltage V1 is equal to or lower than the low voltage level VL set by the low voltage setting unit 400 (V1 <VL). A control unit 300 outputting a control signal for generating a second voltage V2 having a level lower than the first voltage V1; The control signal output from the controller 300 is supplied to switch the charging voltage Vo supplied to the first voltage generation unit 610 to the second voltage generation unit 620 to control switching. A switching unit 500 for generating a second voltage V2 having a level lower than the first voltage V1 in the voltage generator 620 to drive the street lamp 800; Low voltage control device for a street lamp driven by a heterogeneous voltage, characterized in that configured to include. The low voltage level VL or the second voltage set by the low voltage setting unit 400 according to claim 1, wherein the first voltage V1 output from the first voltage generator 610 and detected by the controller 300 is set. Generated higher than the second voltage V2 generated by the generation unit 620; Low voltage control device for a street lamp driven by a heterogeneous voltage. A battery module (Module) 100 for integrating sunlight; A storage battery 200 in which the voltage generated by the battery module 100 is charged; A first voltage generator configured to generate a first voltage V1 having a different voltage level in order to drive the street light 800 by receiving the charging voltage Vo output from the battery 200. A heterogeneous voltage generation unit 600 including a second voltage generation unit 620 for generating a second voltage V2 having a level 610 and a lower level than the first voltage V1; And a charging state monitoring unit 700 for monitoring the charging voltage Vo output from the storage battery 200. Including, The charging state monitoring unit 700 monitors the charging voltage Vo in real time based on the low voltage level VL set by the low voltage setting unit 400, and sets the charging voltage Vo to low voltage. When it is determined that the low voltage level VL or less (Vo <VL) set by the unit 400 is determined, the second voltage generator 620 generates a second voltage V2 having a level lower than the first voltage V1. A control signal for performing; And when the charging voltage Vo is determined to be equal to or more than the low voltage level VL set by the low voltage setting unit 400 (Vo> VL), the first voltage generation unit 610 generates the first voltage V1. A control unit 300 for outputting a control signal; The control signal output from the controller 300 is supplied to switch the charging voltage Vo supplied to the first voltage generation unit 610 to the second voltage generation unit 620 to control switching. A switching unit 500 for generating a second voltage V2 having a level lower than the first voltage V1 in the voltage generator 620 to drive the street lamp 800; Low voltage control device for a street lamp driven by a heterogeneous voltage, characterized in that configured to include. delete The heterogeneous voltage generation method according to claim 1 or 3, wherein a DC-DC converter is provided to receive the charging voltage Vo output from the battery 200 to drive the street lamp 800. The first voltage generation unit 610 for generating the first voltage V1 having different voltage levels through the unit 600 and the level lower than the first voltage V1. The down driving current I2 supplied to the street lamp 800 through the second voltage generator 620 generating the second voltage V2 is the street lamp 800 through the first voltage generator 610. Generated at 10% or less of the normal driving current I1 supplied to; Low voltage control device for a street lamp driven by a heterogeneous voltage. According to claim 1 or claim 3, wherein the control unit 300 is the first voltage (V1) output from the first voltage generation unit 610 is less than the low voltage level (VL) set by the low voltage setting unit 400 (V1) > Is determined to be greater than or equal to VL, outputting a control signal for stopping driving of the second voltage generator 620 to the switching unit 500 to control the second voltage V2 not to be output; Low voltage control device for a street lamp driven by a heterogeneous voltage. The method of claim 1, wherein the second voltage V2 output from the second voltage generator 620 is at least based on the first voltage V1 output from the first voltage generator 610. Differentially generating voltage levels of less than 0.99 times; Low voltage control device for a street lamp driven by a heterogeneous voltage. According to claim 1 or claim 3, wherein the control unit 300 is a voltage (Vo) that is less than 50% of the low voltage level (VL) of the charge voltage (Vo) output from the battery 200 is set in the low voltage setting unit 400 <VL x 50%), a control signal for stopping the driving of the second voltage generator 620 is outputted to the switching unit 500, and the second voltage generator 620 generates a control signal. Controlling not to output the two voltages V2; Driven by heterogeneous voltage, characterized in that Low voltage control of street light.

Images