JP6546501B2 - Power storage device - Google Patents

Description

  The present invention relates to a power storage device that suppresses fluctuations in power output from a solar power generation device.

  For example, a power leveling device described in Patent Document 1 is known as a device that suppresses fluctuations in power. The power leveling apparatus is configured such that a power conditioner (PCS) as a DC conversion unit is connected to the natural energy power generation apparatus, and a power storage device is connected to the DC link unit of the PCS. BACKGROUND In recent years, power output from a solar power generation apparatus (PV) has been used. However, in the above-described power leveling device, it is difficult to connect the dedicated PCS to the existing PV because the dedicated PCS is required.

  Further, as shown in FIG. 6, the conventional power fluctuation suppressing apparatus is configured to have PV 300, PCS 200 connected to PV 300, and PCS 200 connected to power storage device 400 connected to system 100. A power storage device 400 having a power converter 401 and a power storage device 402 is connected between the grid 100 and the PCS 200.

  According to the power fluctuation suppressing apparatus, the power storage device 402 can perform charging and discharging to level the power.

JP 2002-78205 A

  However, in the conventional power fluctuation suppressing apparatus shown in FIG. 6, when the generated power of the PV 300 is reduced due to a sudden change in the amount of solar radiation, etc., it takes time until the PCS 200 is stopped and the PCS 200 is restarted. For this reason, there was a problem that selling power decreased.

  An object of the present invention is to provide a power storage device capable of suppressing abrupt power fluctuation of generated power of PV and reducing the number of times of stopping the PCS due to the decrease of the output of PV.

The power storage device according to the present invention is a power storage device that outputs generated power input from a solar power generation device to a power conditioner, and converts the power storage device and the power generated by the solar power generation device to convert the power storage device Power converter that outputs the converted power to the power conditioner by discharging the power storage device, and a controller that controls the power converter, the controller including the solar light the electric storage device based on the electric power output generated power of the generator and the power conditioner calculates the charge and discharge command for charging and discharging, and outputs the charging and discharging command to the power converter, wherein the solar light When it is determined that at least one of the output voltage and the output current of the generator is out of the operating range of the power conditioner, the power conditioning A voltage sensor for outputting to the power conversion device a discharge command for discharging the power storage device so as to fall within the operation range of the voltage sensor, and detecting a voltage output to the power conditioner at predetermined time intervals; And a current sensor for detecting the current output to the power conditioner at each of the predetermined time intervals, the power conditioner changing the voltage value from the voltage sensor or the current value from the current sensor. Maximum power point tracking control is performed within the above operating range so as to reach the maximum power point by calculating the power value which is the multiplication of the value and the current value, and comparing the power value calculated this time with the previously calculated power value. The operating range of the power conditioner is determined by the temperature of the solar power generation system and the fluctuation range when searching for the maximum power point by the maximum power point tracking control A range of voltages, characterized in that it is determined from the current range determined by the amount of solar radiation that is irradiated to the photovoltaic device.

  According to the present invention, the control unit calculates a charge / discharge command for charging / discharging the storage device based on the generated power of the solar power generation device and the power output to the power conditioner, and converts the charge / discharge command into the power converter Therefore, the power conversion device outputs the converted power to the power conditioner by charging the storage device with the generated power of the solar power generation device or discharging the storage device according to the charge and discharge command.

  Therefore, while being able to suppress the steep power fluctuation of the generated power of the solar power generation device, it is possible to reduce the number of times the power conditioner stops due to the output decrease of the solar power generation device.

It is a figure which shows the structure of the electric power fluctuation control apparatus containing an electrical storage apparatus and the electrical storage apparatus which concern on Example 1 of this invention. It is a figure which shows the temperature dependence characteristic of the output voltage of PV3 and output current in the electric power fluctuation control apparatus containing the electrical storage apparatus which concerns on Example 1 of this invention. It is a figure which shows the illumination intensity dependence characteristic of the output voltage of PV3 and output current in the electric power fluctuation control apparatus containing the electrical storage apparatus which concerns on Example 1 of this invention. It is a figure which shows the relationship of the voltage at the time of MPPT control of PCS, and electric power in the electric power fluctuation control apparatus containing the electrical storage apparatus which concerns on Example 1 of this invention. It is a figure which shows electric power generation output fluctuation | variation suppression control in the curve of an electric current and a voltage in the electric power fluctuation | variation suppression apparatus containing the electrical storage apparatus which concerns on Example 1 of this invention. It is a figure which shows the conventional electric power fluctuation control apparatus.

  Hereinafter, a power storage device according to an embodiment of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram showing a power storage device and a configuration of a power fluctuation suppressing apparatus including the power storage device according to a first embodiment of the present invention. In FIG. 1, the power fluctuation suppressing apparatus includes the PCS 2, the PV 3, the connection box 4, and the power storage device 5.

  The PCS 2 performs power conversion, is connected to the power system 1, and the connection box 4 is connected to the PV 3. The connection box 4 may not be provided, and the PV 3 may be directly connected to the power storage device 5. The PV 3 generates electric power by sunlight and outputs the amount of electric power generation to the power storage device 5 via the connection box 4.

  The power storage device 5 is connected between the PCS 2 and the PV 3 via the junction box 4 to suppress a steep power fluctuation of the generated power of the PV 3 and reduce the number of times the PCS 2 stops due to the output decrease of the PV 3. The storage device 5 includes a power converter 11, a storage device 12, voltage sensors 14 and 16, current sensors 15 and 17, and a control device 13.

  The storage device 12 is a lead storage battery, a lithium ion battery, or the like. The power converter 11 corresponds to the power conversion device of the present invention, converts the generated power of the PV 3 to charge the power storage device 12, and discharges the power storage device 12 to output the converted power to the PCS 2.

  Voltage sensor 14 detects an output voltage on the power storage device side of PCS 2, and outputs the detected output voltage to control device 13. The current sensor 15 detects an output current on the power storage device side of the PCS 2, and outputs the detected output current to the control device 13.

  The voltage sensor 16 detects the output voltage of the PV 3 and outputs the detected output voltage to the control device 13. The current sensor 17 detects the output current of the PV 3 and outputs the detected output current to the controller 13.

  The control device 13 corresponds to the control unit of the present invention, and controls the power converter 11. The controller 13 multiplies the output voltage from the voltage sensor 14 by the output current from the current sensor 15 to calculate the power output to the PCS 2. The controller 13 multiplies the output voltage from the voltage sensor 16 and the output current from the current sensor 17 to calculate the generated power of the PV 3.

  Control device 13 calculates a charge / discharge command for charging / discharging storage device 12 based on the generated power input from PV 3 and the power output to PCS 2, and outputs the charge / discharge command to power converter 11.

  Further, when the control device 13 determines that the output voltage and the output current of the PV 3 are outside the operating range of the PCS 2, the controller 13 converts the discharge command for discharging the storage device 12 into the operating range of the PCS 2. Output to the output unit 11.

  Next, each configuration of the power fluctuation suppressing apparatus including the power storage device of the first embodiment will be described in detail.

(Power generation characteristics of PV3)
Next, the power generation characteristic of the PV 3 will be described. FIG. 2 is a view showing temperature-dependent characteristics of the output voltage and the output current of the PV 3 in the power fluctuation suppressing device including the power storage device according to the first embodiment of the present invention. FIG. 3 is a view showing illuminance-dependent characteristics of the output voltage and the output current of the PV 3 in the power fluctuation suppressing device including the power storage device according to the first embodiment of the present invention.

  As shown in FIG. 2, the PV 3 has a characteristic that the maximum power generation output Pmax decreases as the temperature rises, and the maximum power generation output Pmax increases as the temperature decreases. In this characteristic, focusing on the relationship between the short circuit current Isc which is the current element, the maximum power generation current Ipmax, the open circuit voltage Voc which is the voltage element, and the maximum power generation voltage Vpmax, the voltage component is compared with the current component. Depends largely on the temperature level.

  Further, the short circuit current Isc, which is a current element, increases in proportion to the illuminance as shown in FIG. The open circuit voltage Voc which is a voltage element does not change greatly at a certain illuminance or more. For this reason, PV3 increases the power generation output proportionally at a certain illuminance or more.

(Maximum power point tracking control of PCS2)
Next, the PCS 2 will be described. In order to make the most of the power generation output of PV3, PCS2 performs maximum power point tracking control (MPPT control). Therefore, when PV3 is generating power, the output voltage and output current of PV3 are in the range of constant voltage value and constant current value, that is, voltage range A due to the temperature dependency shown in FIG. It falls within the current range B due to the illumination dependency shown in 3.

  The voltage range A is determined by the fluctuation range in searching for the maximum power point by the temperature of the PV 3 and the maximum power point tracking control (MPPT control). The current range B is determined by the amount of solar radiation irradiated to PV3.

  The current range B is a value proportional to the illuminance (the amount of solar radiation) irradiated to PV 3, but if the power generation output of PV 3 is larger than the consumed amount by the connected load PCS 2, Corresponding current flows.

(Variation suppression control of power generation output of PV 3 by power storage device 5)
Next, in consideration of the power generation characteristics of PV 3 and the control operation of PCS 2, fluctuation suppression control of the power generation output of PV 3 by power storage device 5 will be described. When the PCS 2 searches for the maximum power point, the voltage value from the voltage sensor 14 or the voltage value from the voltage sensor 14 at certain time intervals as shown by the characteristic (PV curve) of the generated output P of PV 3 and the voltage V shown in FIG. MPPT control to calculate the power value which is the multiplication of the voltage value and the current value while changing the current value from the current sensor 15, and compare the power value calculated this time with the power value calculated previously to reach the maximum power point In the PCS operating range R.

  The storage device 5 suppresses and controls the fluctuation of the power generation output of the PV 3 and suppresses the stop of the PCS 2 due to a sudden decrease in the amount of solar radiation and the like. Therefore, charge control and discharge control of the storage device 12 are performed in consideration of the MPPT control range of the PCS 2.

  Next, fluctuation suppression control of the power generation output of PV 3 by power storage device 5 will be described using characteristics (I-V curve) of output current I and output voltage V of PV 3 shown in FIG. 5 (IV curve is PV curve and characteristics of agreement).

  Basically, the PCS 2 performs MPPT control within a PCS operating range R surrounded by points P1, P2, P3 and P4 shown in FIG. This is because, in the characteristic of MPPT control, the voltage value or the current value is changed at certain time intervals, so that the relationship between the power value (voltage value and current value) indicated by a clean straight line is not obtained.

In addition, since the voltage value also changes somewhat depending on the temperature of PV3, the relationship is a range having a certain width.
Point P1 Voltage element value: Maximum output operating voltage Vpmax value-(open voltage Voc × 120% value-maximum output operating voltage Vpmax value)
Current element value: Short circuit current Isc point P2 Voltage element value: Open voltage Voc × 120% value Current element value: Short circuit current Isc value point P3 Voltage element value: Maximum output operating voltage Vpmax value − (Open voltage Voc × 120% value -Maximum output operating voltage Vpmax value)
Current element value: Maximum output operating current Ipmax × 20% Value point P4 Voltage element value: Open voltage Voc × 120% value Current element value: Maximum output operating current Ipmax × 20% value Here, the voltage provided for PCS2 The sensor 14 and the current sensor 15 constantly measure the output voltage value and the output current value of the DC system, and the voltage sensor 16 and the current sensor 17 provided for the PV 3 calculate the output voltage value and the output current value of the DC system. Always measure.

  The control device 13 performs discharge control of the power storage device 12 so as to be in the PCS operation range so that the PCS 2 does not stop due to a sudden decrease in the amount of solar radiation or the like. The control device 13 also performs charge control on the storage device 12.

  Specifically, voltage sensors 14 and 16 measure the output voltage value of the DC system at a certain time interval (sampling time), and current sensors 15 and 17 measure the output current of the DC system at a certain time interval (sampling time) Measure the value.

  The control device 13 determines whether or not the measured value of the output voltage value of the voltage sensor 16 and the output current value of the current sensor 17 falls within a preset PCS operating range R.

  In addition, the control device 13 compares the current measurement value of the generated power based on the output voltage value of the voltage sensor 16 and the output current value of the current sensor 17 with the previous measurement value of the generated power and falls within a range where the PCS 2 stops. In order to determine whether or not the rate of change of the measurement value of the generated power is calculated from the previous measurement value of the generated power or a plurality of past measurement values of the generated power.

  From these two determination factors, the controller 13 operates when the output voltage value and output current value (rate of change of the measured value of the generated power) of PV3 are out of the PCS operating range R, that is, in the operation stop range or PCS2 operates. When there is a possibility of entering the stop range, a discharge command for performing discharge control of the storage device 12 is output to the power converter 11 so that the voltage value and current value (power value) fall within the PCS operating range R. Do.

  In addition, since the voltage value does not largely change even if the amount of power generation decreases due to the sudden decrease in the amount of solar radiation due to the characteristic of PV 3, the control device 13 controls the discharge of the storage device 12 by giving priority to the current value.

  Control device 13 outputs a charge command to power converter 11 so as to charge storage device 12 with a predetermined charging current when the discharge control is not performed.

  Next, determination of the control constant will be described. In the PCS operating range, the range in which the PCS 2 stops depends on the control of the PCS itself, but when the amount of power generation of the PCS 2 decreases due to the sudden decrease in the amount of solar radiation, the current value reaches 20% or less of Ipmax. When it is out of the PCS operation range R shown in, the PCS stop range is obtained. Therefore, when it is predicted that the stop range is reached, control device 13 performs discharge control of power storage device 12.

  In addition, the rate of change of the current value is calculated based on the sampling time of the measurement data, and it is determined whether or not it reaches 20% or less of Ipmax at the time of discharge control. However, if the amount of power generation decreases suddenly, the PCS 2 will stop immediately, so if the voltage value changes significantly, the charge control of the storage device 12 will be stopped and only the discharge control will be performed. Suppress the termination of

  In addition, specific numerical values such as the maximum power generation output Pmax are calculated using open circuit voltage, short circuit current, resistance and other specifications (standard test cell conditions (STC) values) of PV3 connected to PCS2. The voltage value may be multiplied by the number of PV3 connected in series, and the current value may be multiplied by the number of strings connected in parallel.

  As described above, according to the power storage device of the first embodiment, the control device 13 calculates the charge / discharge command for charging / discharging the power storage device 12 based on the generated power of PV3 and the output power of PCS2, Since the electric power is output to the converter 11, the electric power converter 11 outputs the converted electric power to the PCS 2 by charging the storage device 12 with the generated power of the PV 3 or discharging the storage device 12 according to the charge / discharge command.

  That is, the storage device combines charge control and discharge control to suppress abrupt power fluctuation of the PV generated power, and can reduce the number of times the PCS is stopped due to the decrease in the PV output.

1 Power system 2 PCS
3 PV
REFERENCE SIGNS LIST 4 connection box 5 power storage device 11 power converter 12 power storage device 13 control device 14, 16 voltage sensor 15, 17 current sensor

Claims (3)

A storage device for outputting generated power input from a solar power generation device to a power conditioner,
A storage device,
A power conversion device that converts the generated power of the solar power generation device to charge the power storage device and discharges the power storage device to output the converted power to the power conditioner;
And a controller configured to control the power converter.
The control unit calculates a charge / discharge command for charging / discharging the power storage device based on the power generated by the solar power generation apparatus and the power output to the power conditioner, and converts the charge / discharge command into the power When it is output to the device and it is determined that at least one of the output voltage and the output current of the solar power generation device is out of the operating range of the power conditioner, the storage battery is within the operating range of the power conditioner. Outputting a discharge command for discharging the device to the power converter;
A voltage sensor that detects a voltage output to the power conditioner at predetermined time intervals;
And a current sensor for detecting the current output to the power conditioner at each of the predetermined time intervals,
The power conditioner calculates a power value which is the product of the voltage value and the current value while changing the voltage value from the voltage sensor or the current value from the current sensor, and calculates the power value calculated this time last time Perform maximum power point tracking control within the operating range to reach the maximum power point by comparing with the value,
The operating range of the power conditioner is a voltage range determined by the temperature of the solar power generation device and the swing width when searching for the maximum power point by the maximum power point tracking control, and the solar power generation device is irradiated And a current range determined by the amount of solar radiation . A storage device for outputting generated power input from a solar power generation device to a power conditioner,
A storage device,
A power conversion device that converts the generated power of the solar power generation device to charge the power storage device and discharges the power storage device to output the converted power to the power conditioner;
And a controller configured to control the power converter.
The control unit calculates a charge / discharge command for charging / discharging the power storage device based on the power generated by the solar power generation apparatus and the power output to the power conditioner, and converts the charge / discharge command into the power The power conditioner is output to the device, the change rate of the generated power of the solar power generation device is calculated, and the power conditioner is determined to be out of the operating range of the power conditioner based on the calculated change rate of the generated power. Outputting a discharge command to the power conversion device to discharge the power storage device so as to fall within the operation range of
A voltage sensor that detects a voltage output to the power conditioner at predetermined time intervals;
And a current sensor for detecting the current output to the power conditioner at each of the predetermined time intervals,
The power conditioner calculates a power value which is the product of the voltage value and the current value while changing the voltage value from the voltage sensor or the current value from the current sensor, and calculates the power value calculated this time last time Perform maximum power point tracking control within the operating range to reach the maximum power point by comparing with the value,
The operating range of the power conditioner is a voltage range determined by the temperature of the solar power generation device and the swing width when searching for the maximum power point by the maximum power point tracking control, and the solar power generation device is irradiated And a current range determined by the amount of solar radiation .   The control unit outputs a charge command for causing a predetermined charging current to flow through the storage device to the power conversion device when the discharge control based on the discharge command is not performed. The power storage device according to claim 2.

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