KR20100092261A - Apparatus for control discharging and charging of solar energy - Google Patents

Abstract

PURPOSE: An apparatus for control discharging and charging of solar energy is provided to maximize the lifespan of a secondary cell by stably controlling the charge and discharge of the secondary cell. CONSTITUTION: A solar cell(210) converts solar energy into electrical energy. An energy storing unit(240) stores the electrical energy of the solar cell. The energy storage unit is composed of a plurality of batteries which is serially connected. An energy charge control circuit(220) measures the voltage of the cell. The energy charge control circuit charges the electrical energy of the solar cell to each cell. An energy discharge control circuit(230) measure the voltage of the each cell. The energy discharge control circuit induce or blocks the discharge of each cell.

Description

Apparatus for control discharging and charging of solar energy}

The present invention relates to a solar energy charging and discharging control device, and more specifically, to control the charging and discharging of the secondary battery stably to maximize the life of the secondary battery solar energy that can extend the replacement cycle of the secondary battery It relates to a charge and discharge control device.

Solar cell light emitting system converts light energy into electrical energy through solar cells during the day to supply power to the output load, and stores the converted energy in energy storage to emit light at night when the surrounding environment falls below a certain level of illumination. It is a system for supplying power to the member to emit light.

In general, as illustrated in FIG. 1, the solar cell light emitting system includes a solar cell 10 for converting light energy into electrical energy and an energy store 20 for storing electrical energy converted by the solar cell 10. ), A control circuit 30 for controlling the charging and discharging of the energy reservoir 20, a driving signal when the light emitting member 40 and the surrounding environment emitted by the discharge of the energy reservoir 20 are less than a predetermined illuminance. It is composed of the sensor circuit 50 by generating a.

In such a solar cell light emitting system, a rechargeable battery is usually used as the energy reservoir. The secondary battery has an advantage of having an energy density of 20 to 120 Wh / kg, but has a disadvantage in that the number of charge and discharge cycles is limited to about 1000 times. In addition, the secondary battery has a problem in that its service life is shortened more quickly when overcharged or discharged below a predetermined voltage.

The present invention has been made to solve the above problems, the stable charging and discharging of the secondary battery to maximize the life of the secondary battery by maximizing the life cycle of the secondary battery charging and discharging Its purpose is to provide a control device.

Solar energy charge-discharge control device according to the present invention for achieving the above object is a solar cell for converting solar energy into electrical energy, and stores the electrical energy of the solar cell, the energy consisting of a plurality of cells connected in series A voltage of each battery constituting the storage means and the energy storage means is measured, and when the measured voltage is lower than the first reference voltage, the electric energy of the solar cell is induced to be charged in the respective cells, and each battery The voltage of each battery constituting the energy storage means and the energy charging control circuit for disconnecting the electrical connection with the solar cell when the voltage of the second voltage corresponds to the first reference voltage, and the measured voltage is the second reference voltage. If higher, the discharge of each of the cells is induced, and if the voltage of each of the cells corresponds to the second reference voltage Energy discharge control circuit for blocking the discharge of the ground and the voltage of each battery measured from the energy charge control circuit and the energy discharge control circuit is input to compare the voltage with the first reference voltage or the second reference voltage to the energy charge And a main controller for selectively controlling the operation of the entire control circuit and the energy discharge control circuit.

A sensor circuit for measuring ambient illuminance is further provided, and the main controller stops the operation of the energy discharge control circuit when the illuminance signal input from the sensor circuit is equal to or higher than a predetermined illuminance, and when the illuminance signal is lower than the predetermined illuminance, the energy. The discharge control circuit can be operated.

The first reference voltage may be a maximum discharge voltage, and the second reference voltage may be a minimum charging voltage. The energy charge control circuit and the energy discharge control circuit may include a charge control circuit and a discharge control circuit corresponding to the number of batteries, and each charge control circuit and the discharge control circuit may be electrically connected to each battery. . In addition, the energy storage means is composed of first to fourth batteries, the energy charge control circuit is composed of first to fourth charge control circuit, the energy discharge control circuit to the first to fourth discharge control circuit Can be configured.

A light emitting member which emits light by the discharge of the energy storage means may be further provided, and each of the batteries may be a LiFePO ₄ battery.

Solar energy charge and discharge control device according to the present invention has the following effects.

In the process of charging or discharging each battery constituting the energy storage means, when the voltage of the battery corresponds to the maximum discharge voltage at the time of charging, the charge is cut off and when the voltage of the battery corresponds to the minimum charge voltage during the discharge By discharging the discharge it is possible to improve the life of the battery.

Hereinafter, a solar energy charge and discharge control apparatus according to an embodiment of the present invention with reference to the drawings will be described in detail. 2 is a block diagram of a solar energy charge and discharge control apparatus according to an embodiment of the present invention, Figure 3 is a detailed configuration of the energy charge and discharge control circuit and the energy storage means.

First, as shown in FIG. 2, a solar energy charge / discharge control device according to an embodiment of the present invention includes a solar cell 210, an energy charge / discharge control circuit, an energy storage unit 240, a sensor circuit 250, and the like. It is made of a combination of the main control unit 280.

The solar cell 210 serves to generate an electromotive force by converting solar energy into electrical energy, and the energy charge / discharge control circuits 220 and 230 have an electromotive force generated from the solar cell 210. It controls the charging of the storage means 240 and controls the discharge of the electromotive force stored in the energy storage means 240.

In addition, the energy storage unit 240 performs charging or discharging of electromotive force under the control of the energy charge / discharge control circuits 220 and 230, and the sensor circuit 250 detects illuminance of the surroundings. do.

The energy charge / discharge control circuit and the energy storage means 240 are configured in detail, as shown in FIG. 3, wherein the energy charge / discharge control circuit includes an energy charge control circuit 230 and an energy discharge control circuit 220. The energy charge control circuit 230 and the energy discharge control circuit 220 may be divided into first to fourth charge control circuits 231, 232, 233 and 234, and first to fourth discharge control circuits, respectively. 221, 222, 223, and 224. In addition, the energy storage means 240 is composed of first to fourth batteries 241, 242, 243, 244.

In this case, the first battery 241 is controlled by the first charge control circuit 231 and the first discharge control circuit 221, and the second battery 242 is the second charge control circuit 232. ) And the second discharge control circuit 222, and the third battery 243 is controlled by the third charge control circuit 233 and the third discharge control circuit 223, and the fourth battery. 244 is controlled by the fourth charge control circuit 234 and the fourth discharge control circuit 224. In addition, the first to fourth batteries 241, 242, 243, and 244 are connected in series, and each battery is configured as a secondary battery, and in one embodiment, may be configured as a LiFePO ₄ battery.

On the other hand, while the energy storage means 240 is timed to be composed of four batteries, it may be composed of a plurality of four or less than four, at this time, the energy charge control circuit 230 and the energy discharge control circuit The number of circuits constituting 220 corresponds to the number of cells.

Finally, the main controller 280 serves to collectively control the operations of the energy charge control circuit 230 and the energy discharge control circuit 220. Specifically, the energy charge control circuit 230 or the energy discharge. First to fourth charge control circuits 231, 232, 233, 234 constituting the energy charge control circuit 230 based on the voltage signals of the first to fourth batteries measured by the control circuit 220. ) Or selectively operate the first to fourth discharge control circuits 221, 222, 223, and 224 constituting the energy discharge control circuit 220. Operations of the energy charge control circuit 230 and the energy discharge control circuit 220 will be described in detail later.

In addition, the main controller 280 stops the operation of the energy discharge control circuit 220 when the illuminance signal input from the sensor circuit 250 is greater than or equal to a predetermined illuminance, and the ambient illuminance is less than or equal to a certain illuminance. In this case, the energy discharge control circuit 220 operates.

Under such a configuration, the charge / discharge of the energy storage means 240 is controlled by the energy charge / discharge control circuits 220 and 230. Hereinafter, the first to fourth cells 241, 242, 243, 244 have been described with reference to the example consisting of each of LiFePO ₄ cell, refer to the minimum charging voltage (Min of the LiFePO ₄ cell. The discharge voltage is about 2.8V, the maximum charge voltage is about 3.6V, and the working voltage is about 3.0-3.3V.

<Charge Control>

First, the charging control process will be described.

In the state where electrical energy is stored in the solar cell 210, the first to fourth charge control circuits 231, 232, 233, and 234 are respectively the first to fourth cells 241, 242, and 243. Measures the voltage of 244) and transmits the measured voltage signal to the main controller 280. The main controller 280 charges the battery measured at the corresponding voltage signal when the voltage signal of each battery is lower than the first reference voltage, for example, when compared with the first reference voltage, for example, the maximum discharge voltage (3.6V). Proceed.

For example, when the voltage signals of the first battery 241 and the third battery 243 among the first to fourth batteries 241, 242, 243, and 244 are lower than the first reference voltage, the first battery ( The charging process is performed only for the 241 and the third battery 243.

Hereinafter, when the voltage signals of each of the first to fourth batteries 241, 242, 243, and 244 are all lower than the first reference voltage, the first to fourth batteries 241, 242, and 243 are used. The charging process for 244 will be described. Here, although the charging order of the first to fourth batteries 241, 242, 243 and 244 may vary according to the voltage signals of the respective batteries, the first to fourth batteries 241 ( Based on proceeding in the order of 242) (243) (244).

First, the first charge control circuit 231 measures the voltage of the first battery 241 and transmits the measured voltage to the main controller 280, and the measured voltage is the first reference voltage, for example, the maximum discharge voltage ( Less than 3.6 V), the electric energy of the solar cell 210 is induced to be charged in the first cell 241 under the control of the main controller 280. At this time, if the measured voltage is greater than or equal to the maximum discharge voltage, the first charge control circuit 231 disconnects between the solar cell 210 and the first cell 241 under the control of the main controller 280. (open) Here, the solar cell 210 is an example in which the maximum electromotive force is 16V.

By charging, when the voltage of the first battery 241 reaches the maximum discharge voltage, the first charge control circuit 231 opens between the solar cell 210 and the first battery 241. At the same time, the second charge control circuit 232 measures the voltage of the second battery 242. When the measured voltage of the second battery 242 is lower than the maximum discharge voltage, the electric energy of the solar cell 210 is induced to be charged in the second battery 242 under the control of the main controller 280, and charging When the voltage corresponds to the maximum discharge voltage, the solar cell 210 and the second cell 242 are disconnected under the control of the second charge control circuit 232. Of course, if the measured voltage is greater than or equal to the maximum discharge voltage, the charging process does not proceed and the solar cell 210 and the second battery 242 are disconnected.

When the charging of the second battery 242 is completed, the third charge control circuit 233 measures the voltage of the third battery 243 and accordingly, the solar cell 210 from the solar cell 210 to the third battery 243. The charging is selectively performed, and the fourth charge control circuit 234 also selectively performs the voltage measurement and the charging process of the fourth battery 244 while the third battery 243 is charged. When the charging is completed up to the fourth battery 244, the first to fourth batteries 241, 242, 243, and 244 are all disconnected from the solar cell 210.

Looking at the above charge control process, the first to fourth charge control circuits 231, 232, 233 in a state where the first to fourth batteries 241, 242, 243, and 244 are connected in series. It can be seen that the first to fourth batteries 241, 242, 243, and 244 are sequentially charged by 234, and at this time, the charged specific cells are disconnected from the solar cell 210. do. Therefore, as the number of cells disconnected from the solar cell 210 increases, the charging speed of the energy storage means 240 becomes faster.

For example, when the electromotive force of the solar cell 210 is 16V and the voltage of each of the first to fourth cells 241, 242, 243, and 244 is 3V, the first battery 241 While the voltage difference between the solar cell 210 and the energy storage means 240 during charging is 4V (16V-12V), when the second battery 242 is charged, the first cell 241 is disconnected and thus the solar cell ( The voltage difference between 210 and the energy storage means 240 is increased to 7V (16V-9V). As such, the voltage difference between the solar cell 210 and the energy storage unit 240 increases as the first battery 241 is charged from the fourth battery 244 to increase the charging speed.

<Discharge Control Process>

Next, the discharge control process will be described.

The first to fourth discharge control circuits 221, 222, 223, and 224 respectively measure voltages of the first to fourth batteries 241, 242, 243, and 244 and measure the measured voltage signals. Transfer to the main control unit 280. The main controller 280 compares the voltage signal of each battery with a second reference voltage, for example, a minimum charging voltage (2.8V), and discharges the battery measured at the corresponding voltage signal when the voltage is lower than the second reference voltage. Proceed.

For example, when the voltage signals of the first battery 241 and the third battery 243 among the first to fourth batteries 241, 242, 243, and 244 are lower than the second reference voltage, the first battery ( The discharge process is performed only on the 241 and the third battery 243.

Hereinafter, when all voltage signals of each of the first to fourth batteries 241, 242, 243, and 244 are higher than the second reference voltage, the first to fourth batteries 241, 242, and 243 may be used. The discharge process for 244 will be described. Here, the discharge order of the first to fourth batteries 241, 242, 243, and 244 may vary according to voltage signals of the respective batteries, but in the present embodiment, the first to fourth batteries 241 ( Based on proceeding in the order of 242) (243) (244).

First, in a state where the first to fourth batteries 241, 242, 243, and 244 are charged at a first reference voltage, for example, a maximum discharge voltage, the first discharge control circuit 221 may be configured to be first. When the voltage of the first battery 241 is continuously measured along with the discharge of the battery 241, and the measured voltage corresponds to the second reference voltage, for example, the minimum charging voltage (2.8 V), the main controller ( Under the control of 280, the discharge of the first battery 241 is blocked.

In the state where the discharge of the first battery 241 is cut off, the second discharge control circuit 222 induces the discharge of the second battery 242, and like the first discharge control circuit 221, the second battery ( The voltage of 242 is continuously measured and when the measured voltage corresponds to the minimum charging voltage, the discharge of the second battery 242 is cut off under the control of the main controller 280.

In the discharge interruption state of the second battery 242, the discharge and the interruption of the third battery 243 by the third discharge control circuit 223 proceed, and thereafter, the fourth battery by the fourth discharge control circuit 224 ( 244 is discharged and interrupted.

Meanwhile, in the discharge of the first to fourth batteries 241, 242, 243, and 244 as described above, the first to fourth discharge control circuits 221, 222, 223, and 224 are discharged. Is selectively operated by the driving signal of the sensor circuit 250. Specifically, when the illuminance of the surrounding environment measured by the sensor circuit 250 is equal to or greater than a predetermined illuminance, the first to fourth discharge control circuits 221, 222, 223, and 224 are stopped from operating. The first to fourth discharge control circuits 221, 222, 223, and 224 operate when the illuminance of the environment is below a predetermined illuminance. That is, even when the discharge of the first battery 241 is interrupted and the discharge of the second battery 242 proceeds, when the illuminance of the surrounding environment is greater than a predetermined illuminance, the second discharge control is performed according to the driving signal of the sensor circuit 250. Discharge of the second battery 242 is stopped by the circuit 222.

The configuration and operation of the solar energy charge / discharge control device according to an embodiment of the present invention have been described above. The solar energy charge / discharge control device according to an embodiment of the present invention includes the components described above, that is, a solar cell. In addition to the 210, the energy charge / discharge control circuit, the energy storage unit 240, and the sensor circuit 250, the DC / DC converter 260 and the light emitting member 270 may be further provided.

The DC / DC converter 260 boosts or depressurizes the voltage discharged from the energy storage means 240 to be suitable for the driving voltage of the light emitting member 270, and the light emitting member 270 is the The light emitted by the power input from the DC / DC converter 260 may be configured as a light emitting diode in one embodiment.

1 is a block diagram of a solar cell light emitting system according to the prior art.

Figure 2 is a block diagram of a solar energy charge and discharge control device according to an embodiment of the present invention.

3 is a detailed configuration diagram of an energy charge / discharge control circuit and energy storage means.

Claims (7)

Solar cells for converting solar energy into electrical energy; Energy storage means for storing the electrical energy of the solar cell, consisting of a plurality of cells connected in series; The voltage of each battery constituting the energy storage means is measured, and when the measured voltage is lower than the first reference voltage, the electrical energy of the solar cell is induced to be charged in the respective cells, and the voltage of each battery is zero. An energy charge control circuit that disconnects the electrical connection with the solar cell when it corresponds to one reference voltage; The voltage of each battery constituting the energy storage means is measured, and when the measured voltage is higher than the second reference voltage, the discharge of each battery is induced, and the voltage of each battery corresponds to the second reference voltage. An energy discharge control circuit for blocking discharge of each battery when the surface thereof is lowered; And Operation of the energy charge control circuit and the energy discharge control circuit by receiving a voltage of each battery measured from the energy charge control circuit and the energy discharge control circuit and comparing the voltage with a first reference voltage or a second reference voltage. Solar energy charge and discharge control device comprising a main control unit for selectively controlling the. The method of claim 1, further comprising a sensor circuit for measuring the ambient illumination, The main controller stops the operation of the energy discharge control circuit when the illuminance signal input from the sensor circuit is equal to or higher than a predetermined illuminance, and operates the energy discharge control circuit when the illuminance signal is lower than the predetermined illuminance. Discharge controller. The apparatus of claim 1, wherein the first reference voltage is a maximum discharge voltage and the second reference voltage is a minimum charge voltage. The method of claim 1, wherein the energy charge control circuit and the energy discharge control circuit is composed of a charge control circuit, a discharge control circuit corresponding to the number of the battery, Each charge control circuit, the discharge control circuit is a solar energy charge and discharge control device, characterized in that electrically connected to each cell. The method of claim 4, wherein The energy storage means is composed of first to fourth batteries, The energy charge control circuit is composed of first to fourth charge control circuit, The energy discharge control circuit is a solar energy charge and discharge control device, characterized in that consisting of the first to fourth discharge control circuit. The apparatus of claim 1, wherein each of the batteries is a LiFePO ₄ battery. The apparatus of claim 1, further comprising a light emitting member that emits light by the discharge of the energy storage means.

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