KR20140083110A - High Rate Solar Cell Charger System - Google Patents

Abstract

The present invention is a system allowing a power storage device to use excess electricity when supplying voltage except input voltage allowed in PCS. The system increases the efficiency of the solar cell by causing actively bringing about voltage variation between the cells which are configured to be mounted in the power storage device, and using the same; adjusts the charge and discharge amount thereof in an ACTIVE BALANCE CIRCUIT provided in each cell by calculating the estimated capacity of each battery of the power storage device to increase the lifetime of the battery; and enables the preventive maintenance of the power storage device which calculates the estimated life of each battery.

Description

TECHNICAL FIELD [0001] The present invention relates to a high-efficiency solar cell charging system,

The present invention relates to a device for controlling a super capacitor, a secondary battery, etc. connected to a solar cell and used as a power storage device. In the conventional method of charging and discharging by receiving a fixed voltage (power) from a PCS (Power Conditioning System) To a solar power charge control apparatus that directly connects a power storage system to a solar power storage system and controls charging of a power storage device by controlling a low voltage or a high voltage in a range not used in PCS from sunrise to sunset

Photovoltaic cells are developing more efficient products through new technology development and improvement, and various technologies have been developed to transmit and store the power generated from these cells

There is a method of using such a photovoltaic cell as a grid-connected type or a stand-alone type, and the grid-connected type uses a power system as a storage battery and does not use the power storage device separately from the transmission and discharge systems. Is directly used or stored in a power storage device

The power generated by the solar power is constantly producing power from the sun to the sunset, but the PCS uses only the power within the maximum efficiency range of the input of the solar cell with the input voltage range. There is a problem in not using all the power from the launch to the sunset

SUMMARY OF THE INVENTION It is an object of the present invention to provide a high-efficiency solar cell charging device for storing solar cell power generation power within a range not used in PCS, among power generated by a solar cell, in a power storage device

In general, when different voltages are generated in a series-connected battery, the average voltage between the cells is adjusted by Active Balance, Passive Balance, etc. However, the different capacities of the batteries are determined only by adjusting the voltages at the time of over- It is difficult to predict the lifetime of each battery connected in series and it is difficult to replace the battery according to the lifetime of each battery

In addition, the surplus production power of the photovoltaic cell can not be utilized properly, resulting in a reduction in efficiency of the entire system

Therefore, in the present invention, a voltage outside the PCS input voltage range not used in the PCS among the power generated in the solar cell is directly connected to the power storage device, and the surplus power generated in the solar cell is stored in the power storage device It is possible to predict the remaining capacity of the battery for power storage (super capacitor, secondary battery) and the life of the battery, and to supply a voltage of 400 volts or less in a low voltage range, for example, in a PCS having an input voltage range of 800 to 400 volts If the PCS is supplied with a voltage outside the input range when the voltage drops below 400 volts (at sunset) or when the voltage continues to rise at 0 volts (at sunrise) or when a voltage of 800 volts or more is supplied In case of stopping the operation, the supplied voltage is measured and the battery of the corresponding voltage among the series-connected batteries corresponding to the measured voltage is supplied with power The battery unit that is supplied and connected in series calculates the capacity that can be charged and discharged by itself, and by charging and discharging the optimum capacity by itself, it can charge and discharge while preventing deterioration of each battery. When different voltage is generated between each battery, It is possible to grasp the chargeable capacity (lifetime) of each battery by determining the amount of charge discharge by itself, and transmit the result to the central device so as to grasp the estimated date and time of battery replacement. As a result, Of surplus generated power

Accordingly, it is an object of the present invention to provide a power storage device that maximizes power generated from a solar cell, prolongs the life of each series-connected battery,

There is also provided a method of increasing the power storage efficiency of a conventional power storage device using the method of the present invention even in a large capacity power storage device

     When the high-efficiency solar charging apparatus of the present invention is used, there is an advantage that it can fully utilize the surplus production power of the photovoltaic cell even in a region where the sunshine amount is insufficient and the sunshine amount is sufficient, When the power demand is lowered, it can offset much of the power received from the grid or generator (diesel generator, etc.) separately, and the size of the solar photovoltaic cell itself can be reduced, and the life of each battery in the power storage device can be predicted It is possible to cope with the system failure before

  It can also contribute to the reduction of carbon emissions due to the efficient use of photovoltaic systems and the efficient use of energy.

1 shows a typical configuration for powering a PCS from a solar cell and powering a power storage system in a PCS as an example of a general stand-alone solar photovoltaic system
FIG. 2 shows a configuration in which power can be supplied directly from the solar cell to the power storage device in the general system configuration of FIG. 1
FIG. 3 shows a block diagram of the configuration of FIG. 2 actually
4 shows the configuration of the ACTIVE BALANCE CIRCUIT used in the present invention
FIG. 5 shows a configuration of a part for transmitting and receiving ACTIVE BALANCE CIRCUIT by measuring the current and voltage of the system in the central control device
6 shows a configuration in which the input voltage and the output of the DC-DC converter are supplied to each individual battery
Figure 7 is a schematic diagram of the entire system

      In order to accomplish the objects of the present invention as described above, the present invention will be described in detail with reference to the accompanying drawings.

      In the conventional solar photovoltaic system, as shown in FIG. 1, a PCS is connected to a solar cell to charge the power storage device in the PCS, and when power is not outputted from the solar cell, the power stored in the power storage device is received from the PCS, The system consists mainly of supplying.

      In the case of FIG. 2, the PCS is directly connected to the solar cell and also directly connected to the power storage device

      When the PCS is normally operated, the power storage device and the solar cell are insulated by the switch of FIG. 3, and the switch of FIG. 3 is the portion of supplying power to the PCS or connecting the supplied portion. Depending on the output command, the power storage unit can be warmed up or off

      The power control unit power supply unit of FIG. 3 represents a portion where the DC power is supplied to or supplied from the PCS to the power storage device.

      In other words, the power generated by the solar cell 1 shown in FIG. 3 is normally used to supply power to the PCS. However, when the voltage of the solar cell exceeds the voltage input range of the PCS or the output does not reach the power supply, Or the module for monitoring the solar voltage in the power storage device senses this, and turns on the third switch in FIG. 3 to supply a voltage of 800 volts or more or 400 volts or less to the power storage device

At this time, it is assumed that the allowable voltage input range of the PCS is between 800 volts and 400 volts

     The 4 switches in FIG. 3 are turned on or off in the power storage device by receiving an on or off command according to the PCS status

     When the power storage device receives a communication that the solar voltage is more than 800 volts and the power conversion operation of the PCS is off, the plus power supply switch among the three switches of Fig. 3 is on and the switch connected to the ground is also turned on simultaneously 3 switch 18 maintains the off state so that power is supplied to the rechargeable battery of 800 volts or more of FIG. 3, so that the voltage of the PCS exceeds the voltage input range of the PCS so that the PCS can use the power even when the PCS is off

     In this case, the 800-volt battery between the 3-switch of FIG. 3 and the 4-switch of FIG. 3 may be composed of a battery of several tens of volts or more according to the design purpose. If the maximum output of the solar battery is 0 to 880 volts, .

     Figure 6 shows a cell between about 800 volts and 400 volts in a PCS operating range

The batteries in this portion are mainly supplied with power by the ACTIVE BALANCE CIRCUIT of FIG. 3, and are supplied with surplus electric power charged in a battery of less than 400 volts or more than 800 volts in FIG. 3

    4 is a detailed description of an ACTIVE BALANCE CIRCUIT (hereinafter abbreviated as ABC) when power is supplied from a solar cell when the switch 18 of FIG. 3 is turned on, that is, when the solar cell power is 400 volts or less

    At this time, the 3-plus supply switch of FIG. 3 is off and the ground switch remains on

    The R2 current limiting resistor in FIG. 4 can confirm the current supplied to the battery when the FET1 is turned on by the MICOM device configured in the ABC, and is utilized as the accumulated amount of the battery capacity calculation

    Even when the FET2 is turned on, the R4 current limiting resistor is utilized as the integrated value of the battery capacity flowing out of the battery

    The calculated battery capacity of the MICOM device is

 (A / h) X millisecond X hour (second) X hour (minute)

 (2) Charging capacity change value = (battery voltage V) / (R2 current limiting resistance) X time (millisecond)

 (3) discharge capacity change value = (battery voltage V) / (R4 current limiting resistance) X time (millisecond)

 Equation 4) Charge capacity change value = Power storage device charge current X time (millisecond)

 Equation 5) Discharge capacity change value = Power storage device discharge current X time (millisecond)

 Equation 6) Variable battery capacity value = Equation 1 - (Equation 2 or Equation 3 or Equation 4 or Equation 5)

 Equation 7) Estimated battery capacity value = Equation 6) Value X Temperature constant K

 Expression 8) Total system capacity value = (total value of each ABC estimated capacity value) / (ABC quantity)

 Equation 9 Estimated battery capacity The temperature constant K may vary depending on the characteristics of the battery used in the power storage device, The value can be determined based on the characteristic table according to the temperature of the battery to be released from the manufacturer

    For example, a 3 (A / h)

                  10.8 E6 = 3 X 1000 X 60 X 60

    So that the discharge value and the charge value of several tens of milliseconds can be accumulated to increase the accuracy of the battery capacity value

    The amount of current charged in the battery by R2 when charging from the solar cell can be calculated in Equation 2), and the amount of current discharged by R4 can be calculated in Equation 3

    The central control unit of FIG. 5 communicates the charge / discharge current value and the voltage value of the entire power storage device to each ABC, and each ABC substitutes the result of Equation 4) into Equation 6) Estimate the capacity value and use the final estimate by Eq. (7)

    The central control unit 8 of FIG. 5 transmits the system capacity value calculated according to Equation 8 to each ABC, and each ABC compares its estimated capacity value with the average capacity value to receive the surplus power supplied from the solar cell Or discharging to determine whether or not the voltage should be close to the average value

    9), each ABC can estimate the battery capacity change (life expectancy), which is determined by the life of most battery manufacturers when the charge capacity is 80% of the initial design value

    Therefore, the battery capacity change by Eq. (9) can be estimated as the life expectancy of each battery, and each ABC transmits the data to the 8 central control unit of FIG. 5 to improve the reliability of the entire system Be able to figure out

FIG. 6 is a graph showing the relationship between the battery voltage and the battery voltage at the 15th position charged with the solar surplus power. The DC-DC converter of FIG. 6 is driven to supply power to the ABC of the entire system, ABC installed in the battery may not be charged or charged to each battery by the result of the built-in MICOM equation (9)

1: Solar Cell
2: PCS (voltage input range 400 to 800 volts)
3: Power switch (solar photovoltaic part)
4: PCS and power storage unit power switch
5: More than 800 VOLT rechargeable battery
6: Charging battery between 400 VOLT <-> 800 VOLT
7: ACTIVE BALANCE CIRCUIT (ABC)
8: Central control unit
9: Power storage system voltage measurement module in central control unit
10: Power storage system current measurement module in central control unit
11: Power switch for solar charging
12: Single cell nth cell
13: Single cell n-1th battery
14: Voltage range of PCS charging or solar charging
15: Battery voltage supplied to DC-DC CONVERTER Single cell CELL 3 + x
x is a factor that determines the voltage of the battery voltage supplied to the DC-DC converter

Claims (3)

The voltage of the solar cell, which is out of the PCS (Power Conditioning System) input range, is directly supplied to the power storage device through the PCS, thereby causing a voltage imbalance between the cells in the power storage device. How to supply voltage to low battery  Each of the unequally charged cells in the above 1 is determined by itself to determine a charging capacity and a discharging capacity by referring to the capacity estimation value of the battery, thereby preventing overcharge or overdischarge In the above 2, each battery transmits its estimated capacity value to the central control device, so that the central control device can perform preventive maintenance such as replacement of each battery

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