JP2005269843A - Parallel operation device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a parallel operation device that can achieve maximum power follow-up control that draws maximum power with a comparatively simple structure, that can be extended easily when a generator circuit 101 is added, and that requires neither a voltage detector (PT) nor a current detector (CT). <P>SOLUTION: Power conversion control portion 5 calculates electric power Wp, based on a voltage detection signal 6c of a DC/DC converter portion 4 obtained by a voltage-dividing circuit 16 and a current detection signal 44a obtained by a current detecting resistor 44, and changes the output power of a generator 2, by increasing or decreasing a target voltage Vs. This target voltage Vs is maintained by the control portion 5 so that it becomes the electric power at the inflection point, where the polarity of an electric power difference ΔW between the previous power Wt calculated, before increasing or decreasing the target voltage and current power Wp, calculated after the increase or decrease the changes to positive or negative. The control portion 5 performs on-off control of a switching element 42 by means of a pulse-width-modulated signal 5a (PWM signal) and the maximum power follow-up control, based on this value of the target voltage Vs. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a grid interconnection device that grid-connects the power generated by a solar power generator, a wind power generator, or a power generation circuit that combines them with another power system such as a commercial power source.

2. Description of the Related Art Conventionally, as a grid interconnection device that grids power generated by a generator with a commercial power supply system, there is a power conversion device for photovoltaic power generation disclosed in JP-A-11-318042.
This is a DC / DC converter (such as a step-up chopper unit or a waveform shaping unit) that performs maximum power tracking of each solar cell module for each solar cell module in order to efficiently extract the power generated by a plurality of solar power generators. DC / DC converter) is provided to derive maximum power from each solar cell module, and the derived power is collectively converted into AC output by a DC / AC inverter (DC / AC inverter) or the like.

The power conversion device disclosed in Japanese Patent Application Laid-Open No. 2003-9537 has a plurality of power generation units in order to solve the problem that each solar cell cannot be optimally operated because the generated power of each cell differs depending on the installation location. The machine was connected by a direct current via a booster circuit and a backflow prevention diode so that power could be supplied by one DC / AC inverter.
Furthermore, DC voltage constant control is performed by the DC / AC inverter, and the duty of the booster circuit connected to each of the plurality of power generation facilities is changed in order so that the AC power output from the DC / AC inverter is maximized. Maximum power follow-up control is performed, DC voltage constant control is performed with a DC / AC inverter, each power generation facility detects the power of each power generation facility from the current / voltage output by the generator, and each power generation facility outputs The maximum power follow-up control is performed by changing the duty of the booster circuit so that the AC power or the input power of each booster circuit is maximized.

  Moreover, the grid connection maintenance apparatus and grid connection maintenance method of Unexamined-Japanese-Patent No. 2003-324848 connect to the rectifier which converts the output of a wind power generator into direct current, and the output of a rectifier connects to a brake circuit and a disconnection circuit. The grid connection inverter and the grid connection maintenance device are connected in parallel to the output of the brake circuit / separation circuit, and the grid connection maintenance device converts the AC power of the transmission line to the rectification / smoothing circuit of the grid connection maintenance device, The AC power is converted into DC power by an AC / DC converter comprising an insulated DC / DC converter and supplied to the grid-connected inverter to maintain the grid-connection.

The grid connection maintaining device starts the operation of the insulated DC / DC converter when the wind speed of the anemometer is larger than a predetermined value, and stops the operation when the wind speed is smaller. The brake circuit / separation circuit short-circuits the output of the rectifier while the insulated DC / DC converter is stopped, and shuts off the grid interconnection inverter and the grid interconnection maintenance device.
Similarly, when the wind speed becomes abnormally high and the generated voltage of the wind power generator becomes higher than the output voltage of the DC / DC converter, the brake circuit / disconnect circuit also shorts the output of the rectifier and It is cut off from the system inverter and the grid connection maintenance device.

The wind power generator disclosed in Japanese Patent Application Laid-Open No. 2002-136192 is a conventional problem, in which a generator is electrically braked by short-circuiting between output terminals of a pair of generators during a strong wind with a short-circuit, and destruction caused by high-speed rotation In order to prevent extreme charging and discharging of the storage battery by stopping power generation to prevent noise and noise, a power conversion circuit that performs PWM (pulse width modulation) control is provided between the generator and the storage battery, and the power conversion circuit The ratio between the input voltage Vin and the output voltage Vout is increased during a strong wind.
With this control, when the input voltage Vin decreases, the rotational speed of the windmill is suppressed, and the rotational speed is suppressed without stopping power generation.
JP 11-318042 A JP 2003-9537 A JP 2003-324848 A JP 2002-136192 A

  Japanese Patent Application Laid-Open No. 11-318042 discloses a power conversion device for photovoltaic power generation in which a plurality of solar cell input units and respective solar cells connected to the plurality of solar cell input units are provided in order to realize a maximum power follow-up function. A maximum power tracking control unit that performs maximum power tracking for the array, a coupling unit that couples input voltages input from the plurality of solar cell input units in a main circuit of the power converter for photovoltaic power generation, and the coupling The present invention is characterized in that an inverter for converting the sum of the input voltages coupled by the means into AC power is provided.

Therefore, maximum power follow-up control can be performed for each solar cell array. At this time, the output terminal voltage of the DC / DC converter after the power coupling is not controlled by the DC / DC converter and changes depending on the state of maximum power tracking.
Further, the combined power is converted into alternating current through the inverter device and output, but the inverter device located at the subsequent stage from the position where the power is combined can further perform maximum power tracking control on the combined power, The maximum power follow-up control as a total is possible.

  However, since a specific means for realizing the maximum power tracking control is not disclosed, it is necessary to consider a means for specifically realizing the maximum power tracking control circuit.

  In order to perform maximum power follow-up control, the power conversion device disclosed in Japanese Patent Laid-Open No. 2003-9537 inputs a three-phase AC voltage and a three-phase AC current at a connection point to a chopper control device, and is provided in the chopper control device. The active power is obtained by the power detector, the maximum power tracking operation is performed while switching the plurality of maximum power tracking controllers provided in the chopper control device, and the duty command value is output to the booster circuit. The semiconductor switching elements constituting the booster circuit are controlled to be turned on / off with a duty.

  In this device, a voltage detector (PT) and a current detector (CT) are required to detect the three-phase AC voltage and the three-phase AC current at the connection point, and the power at the system point is maximized. Therefore, it is unclear whether or not the maximum power can be derived from the generator, and the chopper control device is shared by the booster devices, so that there is a problem that the generator cannot be easily added.

  In the present invention, maximum power follow-up control for extracting maximum power can be realized with a relatively simple configuration for each generator, and when a generator circuit is added, the extension can be easily performed, and a voltage detector (PT ) And a current detector (CT).

When the wind speed of the anemometer is smaller than a predetermined value, the grid connection maintaining device and the grid connection maintaining method disclosed in Japanese Patent Laid-Open No. 2003-324848 stop the operation of the insulated DC / DC converter, and the brake circuit / disconnect circuit is Short-circuit the output of the rectifier and shut off from the grid interconnection inverter and grid interconnection maintenance device.
Similarly, when the wind speed becomes abnormally high and the power generation voltage of the wind power generator becomes higher than the output voltage of the DC / DC converter, the brake circuit and disconnection circuit short-circuit the output of the rectifier in the same way. Disconnect from the inverter and grid connection maintenance device.

For this reason, there has been a problem that the power supply to the control circuit such as the grid connection maintenance device is lost, the function is stopped, and the restart is impossible.
In order to solve this problem, it is necessary to separately input a commercial power source as an auxiliary power source to a control circuit such as a grid connection maintaining device.

  The wind power generator disclosed in Japanese Patent Application Laid-Open No. 2002-136192 requires a detector that detects the rotational speed of the windmill, and if the rotational speed of the windmill increases during strong winds, the output voltage Vout is suppressed in order to suppress the input voltage Vin. For this reason, an excessive voltage may be supplied to the load.

  The present invention suppresses the overvoltage of the output of the generator when the load is light or when the wind speed increases, protects the device, and can generate power even when the load is light or the wind speed increases. It is an object of the present invention to provide a grid interconnection device that can be operated without stopping the function as a generator by supplying power to the generator.

The grid interconnection device according to the present invention is, for example,
A DC / DC converter unit 4;
A current detection resistor 44 provided at the input of the DC / DC converter unit 4;
A voltage dividing circuit 16 composed of voltage detection resistors 6a and 6b;
The power value is calculated from the voltage detection signal 6c obtained from the voltage dividing circuit 16 and the current detection signal 44a obtained from the current detection resistor 44, and the target voltage Vs is increased or increased so that the maximum power can be obtained. The polarity of the difference power ΔW between the previous power Wt calculated before the increase or decrease and the current power Wp calculated after the increase or decrease is changed to positive or negative. The power conversion control unit 5 that maintains the target voltage Vs so as to obtain the power at the inflection point, performs on / off control of the switching element 42 based on the target voltage Vs, and performs maximum power tracking control.

Further, the grid interconnection device according to the present invention is, for example,
A rotational speed detection unit 10 that detects the rotational speed of the windmill 1 and outputs a rotational speed detection signal 10a;
A DC / DC converter unit 4;
A voltage dividing circuit 16 composed of voltage detection resistors 6 a and 6 b provided at the input of the DC / DC converter unit 4;
The voltage detection signal 6c obtained from the voltage dividing circuit 16 and the rotational speed detection signal 10a are input, and the rotational speed Np of the windmill 1 is measured from the rotational speed detection signal 10a. When the rotational speed is Np, the maximum power is obtained from the windmill 1. A power conversion control unit 20 that calculates a target voltage that can be obtained, performs on / off control of the switching element 42 based on this value and the voltage Vp obtained from the voltage detection signal 6c, and performs maximum power tracking control. I have.

Further, as the overvoltage suppression circuit unit 3, for example,
A voltage setting unit 32 for setting a target voltage for overvoltage control;
The output voltage of the generator 2 is measured, compared with the set value of the voltage setting unit 32, and when the measured value exceeds the set value of the voltage setting unit 32, control signals 31a and 31b are output. A voltage detector 31;
Switches 33a and 33b which are turned on / off by control signals 31a and 31b;
Resistors 34a connected between the output terminals of the generator 2 when the switches 33a and 33b are turned on by the control signals 31a and 31b, and opened between the output terminals of the generator 2 when the switches 33a and 33b are turned off. 34b.

Moreover, as the overvoltage suppression circuit unit 3,
A voltage setting unit 32 for setting a target voltage for overvoltage control;
The output voltage of the generator 2 is measured and compared with the set value of the voltage setting unit 32. When the measured value exceeds the set value of the voltage setting unit 32, the voltage detection unit 31 that outputs the control signal 31c. When,
A switching element control unit 35 that generates a PWM signal 35a that has a long ON time when the output voltage of the generator 2 is high by the control signal 31c and a short ON time when the output voltage is low;
A switching element 36 controlled by the switching element control unit 35 and a resistor 34 that regulates a current flowing between the output terminals of the generator 2 when the switching element 36 is on are provided.

  According to the present invention, when the load is light or when the wind speed increases, the output voltage of the generator is suppressed and the device is protected, and the power can be generated even when the load is light or the wind speed increases. It is possible to provide a grid interconnection device that can operate without supplying power to the control circuit and stopping the function as a generator.

Embodiment 1 FIG.
Embodiments of the present invention will be described below.
FIG. 1 is a diagram showing an embodiment of a grid interconnection apparatus according to the present invention.
Here, the grid connection refers to, for example, connecting the output of a generator such as a wind power generator or a solar power generator to a commercial power system provided by a power company or the like to perform a grid operation. The grid interconnection device is a device for performing interconnection between the output of the generator and the power grid.

  Reference numeral 1 denotes a windmill. A generator 2 is connected to the windmill 1, and the generator 2 generates power by the rotation of the windmill 1. Reference numeral 3 denotes an overvoltage suppression circuit unit that suppresses overvoltage so that the wind turbine rotates at a high speed during a strong wind and the generated voltage rises so that various devices connected to the generator 2 are not destroyed by the overvoltage.

Reference numeral 4 denotes a DC / DC converter (direct current / direct current converter), which boosts the generated voltage of the generator 2 as an input and outputs it as a current source.
The DC / DC converter unit 4 includes an inductance 41, a switching element 42, and a diode 43. The DC / DC converter unit 4 may include a current detection resistor 44.

  Reference numeral 5 denotes a power conversion control unit, which is a voltage detection signal 6c obtained from a voltage dividing circuit 16 composed of voltage detection resistors 6a and 6b provided at the input of the DC / DC converter unit 4, and the current detection resistor. A current detection signal 44a proportional to the input current of the DC / DC converter unit 4 detected by the device 44 is input, and the power value is calculated from these inputs.

  The power conversion control unit 5 increases or decreases the target voltage Vs to change the output power of the generator 2 so that the maximum power can be obtained from the generator 2, and calculates the previous power Wt calculated before the increase or decrease. The target voltage Vs is maintained so that the polarity of the difference power ΔW with respect to the current power Wp calculated after increasing or decreasing becomes the power at the inflection point where the polarity changes to positive or negative, and based on the target voltage Vs value In addition, a PWM signal (pulse width modulation signal) 5a for controlling the duty of the switching element 42 is generated, and the switching element 42 is turned on / off by the duty signal to perform maximum power tracking control.

Reference numeral 7 denotes a power conversion capacitor, which charges the output current generated by the DC / DC converter unit 4 and converts it into a voltage.
Reference numeral 8 denotes a DC / AC inverter unit (DC / AC inverter unit), which inputs a voltage charged by the power conversion capacitor 7 and converts it into AC power. The converted AC power is connected to another power supply system 9 and supplied to the other power supply system 9.

FIG. 2 is a diagram illustrating an embodiment of the power conversion control unit 5.
A voltage / current measuring unit 51 measures the current Ip from the current detection signal 44a and measures the voltage Vp from the voltage detection signal 6c.
52 is an electric power calculation part, and calculates electric power Wp from the said voltage Vp and the electric current Ip.
53 is a target voltage calculation unit that increases or decreases the target voltage Vs to change the output power of the generator 2 so that the maximum power can be obtained, and calculates the previous power Wt calculated before the increase or decrease. The target voltage Vs for controlling the output voltage of the generator 2 is set so that the polarity of the difference power ΔW from the current power Wp calculated after increasing or decreasing becomes the power at the inflection point where the polarity changes positively or negatively. Calculate.

A difference calculation unit 54 obtains a difference between the target voltage Vs of the target voltage calculation unit 53 and the voltage Vp, and the value of the voltage Vp matches the target voltage Vs calculated by the target voltage calculation unit 53. The correction signal 54a is output.
Reference numeral 55 denotes a PWM signal generator, which outputs a PWM signal 5a for controlling on / off of the switching element 42 by the correction signal 54a of the difference calculator 54.
Reference numeral 56 denotes a non-volatile memory that stores the following information.
1. The target voltage calculation unit 53 stores the power Wp calculated this time as the power Wt calculated last time.
2. The target voltage calculation unit 53 stores whether the target voltage Vs has been increased or decreased.

FIG. 3 is a flowchart showing details of the control operation of the power conversion control unit 5.
FIG. 4 is a characteristic diagram showing the relationship between the voltage and power of the wind power generator.
As shown in FIG. 4, even if the voltage is low or too high, the wind power generator cannot extract the maximum power, and there is an optimum voltage value 130 for extracting the maximum power. The electric power obtained when the voltage value is 130 is called an inflection point. An inflection point is a boundary where the direction of the curve changes. In FIG. 4, the inflection point is a point where the power curve shows a maximum value.
The inflection point is obtained by the following four operations.
Operation 1. When the voltage is increased to increase the power, the voltage is further increased to approach the inflection point.
Operation 2. When the power is increased by lowering the voltage, the voltage is further lowered to approach the inflection point.
Operation 3. If the power is decreased by increasing the voltage, the voltage has been decreased because the inflection point has already been passed.
Operation 4. If the power is reduced by lowering the voltage, the voltage has been raised because the inflection point has already been passed.

The operation will be described below with reference to FIGS.
The initial value as the previous up / down data of the nonvolatile memory 56 is, for example, up.
The initial value of the power Wt calculated last time in the nonvolatile memory 56 is set to 0, for example.

In FIG. 3, in step 101, the voltage / current measurement unit 51 measures the voltage Vp.
In step 102, the target voltage calculation unit 53 sets the measured voltage Vp as the target voltage Vs.
In step 103, the difference calculation unit 54 outputs a correction signal 54a.
In step 104, the PWM signal generator 55 generates the PWM signal 5a.
In step 105, the voltage / current measurement unit 51 measures the voltage Vp.
In step 106, the difference calculation unit 54 determines whether or not the voltage Vp matches the target voltage Vs within a substantially allowable range.
If they do not match, the process returns to step 103, and the difference calculator 54 obtains the difference between the voltage Vp and the target voltage Vs until they match. The difference calculation unit 54 outputs a correction signal 54a according to the obtained difference.
Then, the loop of Step 103 to Step 106 is repeated until the voltage Vp substantially matches the target voltage Vs within an allowable range.

If they match, the voltage / current measurement unit 51 measures the current Ip in step 107, and the power calculation unit 52 calculates the power Wp from the voltage Vp measured in step 105 and the current Ip in step 108. .
In step 109, the target voltage calculation unit 53 obtains a difference between the power Wp calculated this time and the power Wt calculated last time stored in the nonvolatile memory 56.
The target voltage calculation unit 53 sets this difference as the power difference ΔW.
In step 110, the target voltage calculation unit 53 determines whether the power difference ΔW is positive or zero.

If the result is positive or zero, in step 111, the target voltage calculation unit 53 determines whether or not the previous target voltage Vs has been increased. Since the previous increase corresponds to the case of the voltage value 131 → the voltage value 132 in FIG. 4, the target voltage calculation unit 53 increases the target voltage Vs in step 112. Here, it is determined that “when the voltage is increased and the power is increased, operation 1 for further increasing the voltage to approach the inflection point” is executed.
The value to be increased may be arbitrarily selected depending on the accuracy to be controlled and the voltage to be used. Here, for example, it is assumed that the voltage is increased by 1V.

  When the target voltage calculation unit 53 determines in step 111 that the target voltage Vs has been lowered last time, it corresponds to the voltage value 134 → the voltage value 133 in FIG. 4. Therefore, in step 114, the target voltage calculation unit 53 The target voltage Vs is lowered. Here, it is determined that “when the voltage is lowered and the power is increased, operation 2 for further lowering the voltage to approach the inflection point” is executed.

Next, when the target voltage calculation unit 53 determines in step 110 that the power difference ΔW is negative, in step 113, the target voltage calculation unit 53 determines whether or not the previous target voltage Vs has been increased.
If it was previously increased, it corresponds to the voltage value 133 → the voltage value 134 in FIG. 4. Therefore, in step 114, the target voltage calculation unit 53 decreases the target voltage Vs. Here, it is determined that “when the voltage is increased and the power is decreased, the operation 3 for decreasing the voltage has already been performed because the inflection point has already been passed”.

If the target voltage calculation unit 53 determines in step 113 that the target voltage Vs has been lowered last time, it corresponds to the voltage value 132 → the voltage value 131 in FIG. Increase Vs. Here, it is determined that “when the voltage is lowered and the power is reduced, the operation 4 for raising the voltage has already been performed because the inflection point has already been passed”.
Next, at step 115, the target voltage calculation unit 53 sets the power Wp calculated this time as the power Wt calculated last time, swaps the values of the previous power and the current power, and stores them in the nonvolatile memory 56.
In step 116, the target voltage calculation unit 53 stores the up or down process as previous up / down data in the nonvolatile memory 56, and proceeds to the process of step 103.
Thereafter, the same operation is repeated, and the maximum power follow-up control is performed so that the optimum voltage value 130 from which the maximum power in FIG.

The above is the operation of the power conversion control unit 5.

As shown in FIG. 1, when there are a plurality of wind turbines 1, a generator circuit 101 including the generator 2 to the voltage detection resistors 6a and 6b is provided for each wind turbine 1, and the DC / DC converter unit 4 are connected in parallel with the same polarity, and a power conversion capacitor 7 is connected between the positive and negative electrodes of the junction point. The output current is converted into voltage, and the voltage charged by the power conversion capacitor 7 is input to one DC / AC inverter unit 8.
By configuring in this way, the DC / AC inverter unit 8 takes out the maximum power from each generator circuit 101 and outputs AC power, and this AC power is connected to another power supply system 9. It can be supplied to another power supply system 9.

  The generator circuit 101 may be configured by a solar power generator, or may be configured by combining a wind power generator and a solar power generator (hybrid power generation). In this case, the operation is the same as that described above.

As described above, the grid interconnection apparatus of this embodiment includes the generator 2.
In addition, the grid interconnection device of this embodiment converts at least one output voltage of the generator 2 into a high voltage, and includes at least one DC / DC converter unit 4 (an example of a boosting unit) that operates as a current source. The generator circuit 101 is provided more than the system.
Further, the grid interconnection device of this embodiment is configured such that the same polarity of the positive and negative output terminals of the DC / DC converter unit 4 (step-up means) is connected in common, and the positive and negative terminals connected in common. A power conversion capacitor 7 for converting a current source output of the DC / DC converter unit 4 (step-up means) into a voltage is provided in between.
The grid interconnection apparatus according to this embodiment connects the input of a DC / AC inverter unit 8 (an example of a DC-AC converter) that converts the output voltage of the power conversion capacitor 7 into an alternating current. The output of the inverter unit 8 (DC-AC conversion means) is connected to a commercial power supply system.
Further, the grid interconnection apparatus of this embodiment includes a generator output current detection means and a generator output voltage detection means.
Further, the grid interconnection device of this embodiment calculates the power from the signals of the current detection means and the current detection means, and in order to obtain the maximum power, the generator load is increased or decreased to set the inflection point of the maximum power. A power conversion control unit 5 (an example of a control unit) that controls the DC / DC converter unit 4 (step-up unit) is provided.

  In the grid interconnection method of the grid interconnection apparatus of this embodiment, the power conversion control unit 5 calculates the power Wp from the voltage detection signal 6c input to the DC / DC converter unit 4 and the current detection signal 44a, and the maximum power To increase or decrease the target voltage Vs to change the output power of the generator 2, the previous power Wt calculated before increasing or decreasing, and the current power Wp calculated after increasing or decreasing The target voltage Vs is maintained so that the polarity of the difference power ΔW becomes the power of the inflection point where the difference power ΔW changes to positive or negative, and the switching element 42 is turned on / off based on the target voltage Vs value, It is configured to perform maximum power tracking control.

Since the grid interconnection apparatus of this embodiment is configured as described above, it has a relatively simple configuration and can realize maximum power tracking control that draws the maximum power for each generator 2.
Further, in the grid interconnection device of this embodiment, when the generator circuit 101 is added, the generator circuit 101 may be connected to the input of the DC / AC inverter unit 8 as it is, and the extension can be easily performed. The voltage detector (PT) and the current detector (CT) are also unnecessary.

Embodiment 2. FIG.
FIG. 5 is a diagram showing an embodiment of a grid interconnection apparatus according to the present invention.
In FIG. 5, the functions of the constituent elements having the same numbers as those in FIG. 1 are the same as the constituent elements in FIG.
Reference numeral 10 denotes a rotation speed detection unit that detects the rotation speed of the windmill 1 and outputs a rotation speed detection signal 10a.

  Reference numeral 20 denotes a power conversion control unit, which is a voltage detection signal 6c obtained from a voltage dividing circuit 16 composed of voltage detection resistors 6a and 6b provided at the input of the DC / DC converter unit 4, and the rotational speed detection. The rotational speed detection signal 10a proportional to the rotational speed of the windmill 1 detected by the unit 10 is input, and the rotational speed Np of the windmill 1 is measured from the rotational speed detection signal 10a. A target voltage Vs from which electric power can be obtained is calculated, and based on this value and the voltage Vp obtained from the voltage detection signal 6c, a PWM signal 5a for controlling the duty of the switching element 42 is generated. The switching element 42 is on / off controlled to perform maximum power tracking control.

FIG. 6 is a diagram illustrating an embodiment of the power conversion control unit 20.
Reference numeral 21 denotes a rotational speed measurement unit that measures the rotational speed Np of the windmill 1 from the rotational speed detection signal 10a.
Reference numeral 22 denotes a voltage measuring unit that measures the voltage Vp from the voltage detection signal 6c.
Reference numeral 23 denotes a target voltage calculation unit that calculates a target voltage at which the maximum power can be obtained from the wind turbine 1 at the rotation speed Np, and calculates a target voltage Vs for controlling the output voltage of the generator 2.

FIG. 7 is a characteristic diagram showing the relationship between the voltage and power of a wind power generator similar to FIG.
As shown in FIG. 4, the wind power generator cannot take out the maximum power even if the voltage is low or too high, and there is an optimum voltage value for taking out the maximum power.
Accordingly, when the wind speed, that is, the rotational speed of the windmill 1 changes as the rotational speeds Npa to Npd, the characteristics of the generated voltage and the generated power also change accordingly.
That is, the optimum voltage value at which the maximum powers 130a to 130d can be taken out corresponding to the rotation speeds Npa to Npd also changes as Vsa to Vsd.

  From the characteristics shown in FIG. 7 for each wind power generator, the voltage at which the maximum power 130a to 130d can be extracted is determined by the rotation speed Npa to Npd of the windmill 1. Therefore, if the rotation speed Npa to Npd is known, the maximum power 130a to 130d is In order to take it out, a target voltage Vs to be controlled by the generator 2 is determined.

  The target voltage calculation unit 23 stores, for example, data on the correlation between the rotational speeds Npa to Npd of the wind turbine 1 and the target voltage Vs to be controlled by the generator 2 in order to take out the maximum powers 130a to 130d in the nonvolatile memory 26. The target voltage Vs corresponding to this value is read from the nonvolatile memory 26 from the value of the rotational speed Np of the windmill 1 measured by the rotational speed measuring unit 21 and the read target voltage Vs is output.

Reference numeral 24 denotes a difference calculation unit that obtains a difference between the target voltage Vs obtained by the calculation of the target voltage calculation unit 23 and the voltage Vp, and the value of the voltage Vp is calculated by the target voltage calculation unit 23. The correction signal 24a is output so as to match the voltage Vs.
Reference numeral 25 denotes a PWM signal generation unit that outputs a signal for on / off control of the switching element 42 by the correction signal 24 a of the difference calculation unit 24.

Reference numeral 7 denotes a power conversion capacitor, which charges the output current generated by the DC / DC converter unit 4 and converts it into a voltage.
Reference numeral 8 denotes a DC / AC inverter unit, which receives a voltage charged by the power conversion capacitor 7 and converts it into AC power. This AC power is connected to another power supply system 9 to be connected to another power supply system. 9 is supplied.

In this embodiment, even when there are a plurality of generator circuits 101, the operation is the same as in this embodiment.
The voltage detection resistors 6a and 6b and the current detection resistor 44 are configured to detect the output voltage and output current of the generator 2, but when the generator circuit 101 is one circuit (one component), the voltage The detection resistors 6 a and 6 b and the current detection resistor 44 may be provided at the output of the DC / DC converter unit 4. That is, the voltage detection resistors 6 a and 6 b and the current detection resistor 44 may be provided between the DC / DC converter unit 4 and the power conversion capacitor 7.

  Further, the generator circuit 101 can be configured by a solar power generator, or can be configured by combining a wind power generator and a solar power generator (hybrid power generation). In this case, the operation is the same as the above operation.

As described above, the grid interconnection device of this embodiment includes the rotation speed detection unit 10 (means for detecting the rotation speed) that detects the rotation speed of the windmill 1 and the voltage detection means for the output of the wind power generator. ing.
Further, the grid interconnection apparatus of this embodiment measures the rotational speed of the windmill from the output of the rotational speed detection unit 10 (means for detecting the rotational speed), and can obtain the maximum power at the rotational speed. A power conversion control unit 5 (an example of a control unit) that calculates a generator output and controls a DC / DC converter unit 4 (step-up unit) is provided.

  In the grid interconnection method of the grid interconnection apparatus of this embodiment, the voltage detection signal 6c input to the DC / DC converter unit 4 and the rotation speed detection signal 10a proportional to the rotation speed of the windmill 1 are input. Then, the power conversion control unit 5 measures the rotational speed Np of the windmill 1, calculates the target voltage Vs from which the maximum power can be obtained from the windmill 1 at the rotational speed Np, and uses this value and the voltage detection signal 6c. Based on the obtained voltage Vp, the switching element 42 is on / off controlled to perform maximum power tracking control.

Since the grid interconnection apparatus of this embodiment is configured as described above, it is possible to realize maximum power tracking control that draws the maximum power for each generator 2 with a relatively simple configuration.
Further, in the grid interconnection device of this embodiment, when the generator circuit 101 is added, the generator circuit 101 can be directly connected to the DC / AC inverter unit 8 as it is. The detector (PT) and the current detector (CT) are also unnecessary.

Embodiment 3 FIG.
FIG. 8 is a diagram illustrating a first embodiment relating to an overvoltage suppression circuit unit 3 used in the grid interconnection device according to the first and second embodiments.
In FIG. 8, the function of the component having the same number as in FIG. 1 is the same as that of the component in FIG.

Reference numeral 31 denotes a voltage detection unit that measures the output voltage of the generator 2 and compares it with the set value of the voltage setting unit 32. If the measured value exceeds the set value of the voltage setting unit 32, control is performed. Signals 31a and 31b are output.
33a and 33b are switches that are turned on / off by the control signals 31a and 31b.
Reference numerals 34a and 34b denote resistors, which are connected between the output terminals of the generator 2 when the switches 33a and 33b are turned on by the control signals 31a and 31b, and the generators when the switches 33a and 33b are turned off. Opened between the two output terminals.

That is, when the output voltage of the generator 2 exceeds the set value of the voltage setting unit 32, the switches 33a and 33b are turned on by the control signals 31a and 31b, and the resistors 34a and 34b are output from the generator 2. Connected between terminals.
Thereby, since the load of the generator 2 increases, the output voltage of the generator 2 falls, and the overvoltage at the time of light load and when the wind speed increases can be suppressed.

  The control sequence of the switches 33a and 33b is such that when the output voltage of the generator 2 exceeds the set value of the voltage setting unit 32, the switch 33a is first turned on by the control signal 31a, and the resistor 34a is connected to the generator 2 Connect between the two output terminals. Nevertheless, when the output voltage of the generator 2 exceeds the set value of the voltage setting unit 32, the switch 33b is turned on by the control signal 31b, and the resistor 34b is connected between the output terminals of the generator 2.

When the load increases or the wind speed decreases, the output voltage of the generator 2 decreases and falls below the set value of the voltage setting unit 32, the switch 33b is turned off by the control signal 31b, and the resistor 34a is connected to the generator 2 Open from between the output terminals.
Still, when the output voltage of the generator 2 falls below the set value of the voltage setting unit 32, the switch 33a is turned off by the control signal 31a, and the resistor 34a is opened from between the output terminals of the generator 2.

In order to prevent hunting of the switches 33a and 33b, it is desirable to provide setting means. Here, hunting is a kind of oscillation phenomenon. Here, when the control operation of the switches 33a and 33b is performed by the control signals 31a and 31b, the control amount is periodically changed to be in a stable state. This is a phenomenon that does not happen.
For example, in order to prevent the hunting of the switches 33a and 33b, when the voltage detection unit 31 outputs the control signals 31a and 31b, it has a timer function, or a detection level that outputs an on signal and a detection that outputs an off signal. Hysteresis is provided between levels and setting means is provided so that they can be varied.

  Further, on / off control can be made cyclic in order to make the operating rates of the switches 33a, 33b and the resistors 34a, 34b uniform.

  The switches 33a and 33b and the resistors 34a and 34b do not need to be particular about two circuits, but may be one circuit or may be provided with three or more circuits as necessary.

As described above, the overvoltage suppression circuit unit 3 (an example of the overvoltage suppression means) of this embodiment is a series of at least one switch and a resistor connected in parallel with the generator 2 to the output of the generator 2. It has a circuit.
The overvoltage suppression circuit unit 3 of this embodiment includes an overvoltage detection means for the output of the generator 2. The overvoltage detection means includes a voltage detection unit 31 and a voltage setting unit 32.
The overvoltage suppression circuit unit 3 of this embodiment increases the load on the generator and lowers the output voltage by sequentially turning on the switches according to the overvoltage when the overvoltage detection means detects the overvoltage. It is characterized by that.

  The overvoltage suppression method of the overvoltage suppression circuit unit 3 of this embodiment measures the output voltage of the generator 2 with the voltage detection unit 31, compares it with the set value of the voltage setting unit 32, and the measured value is the voltage setting unit. When the set value of 32 is exceeded, the switches 33a and 33b are turned on, and the resistors 34a and 34b are connected between the output terminals of the generator 2, and when below the set value, the switches 33a and 33b are turned off and the generator is turned on. The resistors 34a and 34b are opened from between the two output terminals.

  As a result, the overvoltage suppression circuit unit 3 of this embodiment suppresses the overvoltage of the output of the generator 2 when the load is light or when the wind speed increases, and generates power even when the load is light or the wind speed increases. Since power can be supplied to the circuit of each component, the function as the generator circuit 101 can be operated without stopping.

Embodiment 4 FIG.
FIG. 9 is a diagram illustrating a second embodiment relating to the overvoltage suppression circuit unit 3 used in the grid interconnection device according to the first and second embodiments.
In FIG. 9, the function of the component having the same number as in FIG. 1 is the same as that of the component in FIG.

Reference numeral 31 denotes a voltage detection unit that measures the output voltage of the generator 2 and compares it with the set value of the voltage setting unit 32. If the measured value exceeds the set value of the voltage setting unit 32, control is performed. The signal 31c is output.
A switching element control unit 35 converts the control signal 31c into a signal for turning on / off the switching element 36. When the output voltage of the generator 2 is high, the on-time is long and the output voltage is low. A PWM signal 35a whose on-time is shortened is generated.
Reference numeral 34 denotes a resistor, which causes a current to flow between the output terminals of the generator 2 when the switching element 36 is turned on, and does not flow a current between the output terminals of the generator 2 when the switching element 36 is turned off. .

Therefore, when the output voltage of the generator 2 is high, the on-time of the switching element 36 becomes long, so that the current flowing through the resistor 34 increases.
That is, the load on the generator 2 increases and the output voltage is suppressed. When the output voltage is low, the ON time of the switching element 36 is shortened, so that the current flowing through the resistor 34 is reduced.
That is, the load on the generator 2 decreases and the output voltage increases.

  With the above operation, it is possible to prevent the output voltage of the generator 2 from becoming an overvoltage during a strong wind or a light load.

  The voltage detection unit 31 can also be shared with the voltage dividing circuit 16 constituted by the voltage detection resistors 6a and 6b.

As described above, the overvoltage suppression circuit unit 3 (an example of the overvoltage suppression means) of this embodiment includes a series circuit of a semiconductor switching element and a resistor connected in parallel to the generator 2 at the output of the generator 2. ing.
The overvoltage suppression circuit unit 3 of this embodiment includes an overvoltage detection means for the output of the generator 2. The overvoltage detection means includes a voltage detection unit 31 and a voltage setting unit 32.
The overvoltage suppression circuit unit 3 of this embodiment includes means for controlling the time ratio between on and off of the semiconductor switching element according to the overvoltage detection value of the overvoltage detection means, and the overvoltage value is large. By increasing the on-time of the semiconductor switching element, the current flowing through the resistor connected between the generator outputs is increased, and the output voltage when the generator is overvoltage is controlled so that it does not exceed the specified value. It is characterized by doing.

  The overvoltage suppression method of the overvoltage suppression circuit unit 3 of this embodiment measures the output voltage of the generator 2, compares it with the set value of the voltage setting unit 32, and the measured value sets the set value of the voltage setting unit 32. When it exceeds, the time for turning on the switching element 36 is lengthened, and when it does not exceed, the PWM control is performed so that the on time of the switching element 36 is shortened.

  Thereby, the overvoltage suppression circuit unit 3 of this embodiment suppresses the overvoltage of the output of the generator 2 at the time of light load or when the wind speed increases, and generates power even at the time of light load or when the wind speed increases. In addition, since power can be supplied to the circuit of each component, the function as the generator circuit 101 can be operated without stopping.

It is a figure which shows a grid connection apparatus. It is a figure which shows the power conversion control part. 5 is a flowchart showing details of a control operation of the power conversion control unit 5. It is a characteristic view which shows the relationship between the voltage and electric power of a wind power generator. It is a figure which shows a grid connection apparatus. It is a figure which shows the power conversion control part. It is a characteristic view which shows the relationship between the voltage and electric power of a wind power generator. 2 is a diagram illustrating a first embodiment relating to an overvoltage suppression circuit unit 3. FIG. FIG. 5 is a diagram showing a second embodiment relating to an overvoltage suppression circuit unit 3.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Windmill, 2 Generator, 3 Overvoltage suppression circuit part, 4 DC / DC converter part, 5 Power conversion control part, 6a, 6b Voltage detection resistor, 7 Power conversion capacitor, 8 DC / AC inverter part, 9 Others Power supply system, 10 rotation speed detection unit, 20 power conversion control unit, 44 current detection resistor.

Claims (7)

In the grid interconnection device that supplies the power generated by the generator to the power system,
A booster circuit for boosting the voltage of the generator output;
A current detection circuit for detecting the current of the generator output and outputting a current detection signal;
A voltage detection circuit that detects the voltage of the generator output and outputs a voltage detection signal;
In order to obtain the maximum power by calculating the power from the current detection signal output from the current detection circuit and the voltage detection signal output from the voltage detection circuit, the inflection point of the maximum power is obtained by increasing or decreasing the generator load. And a power conversion control unit for controlling the booster circuit. The booster circuit includes a switching element that increases or decreases the voltage of the generator output,
The power conversion control unit
A voltage / current measuring unit that measures the current Ip from the current detection signal and measures the voltage Vp from the voltage detection signal;
A power calculator that calculates power Wp from voltage Vp and current Ip;
A non-volatile memory for storing the power Wp calculated by the power calculation unit;
The difference power ΔW between the power Wp calculated by the power calculation unit and the previously calculated power Wt stored in the nonvolatile memory is calculated, and a target voltage Vs for controlling the output voltage of the generator is calculated based on the difference power ΔW. A target voltage calculation unit to calculate,
A difference calculation unit that obtains a difference between the target voltage Vs calculated by the target voltage calculation unit and the voltage Vp, and outputs a correction signal so that the value of the voltage Vp matches the target voltage Vs calculated by the target voltage calculation unit; ,
2. The system interconnection apparatus according to claim 1, further comprising: a PWM signal generation unit that outputs a pulse width modulation signal (PWM signal) for controlling on / off of the switching element by a correction signal of the difference calculation unit. In a grid interconnection device that supplies power generated by a generator that generates electricity by rotating a windmill,
A booster circuit for boosting the voltage of the generator output;
A voltage detection circuit that detects the voltage of the generator output and outputs a voltage detection signal;
A rotational speed detector that detects the rotational speed of the windmill and outputs a rotational speed detection signal;
The rotation speed of the wind turbine is measured from the rotation speed detection signal output from the rotation speed detection unit, the generator output capable of obtaining the maximum power is obtained, the voltage is obtained from the voltage detection signal output from the voltage detection circuit, and this voltage is obtained. And a power conversion control unit for controlling the booster circuit so as to obtain a generator output capable of obtaining the maximum power. The booster circuit includes a switching element that increases or decreases the voltage of the generator output,
The power conversion control unit
A voltage measurement unit for measuring the voltage Vp from the voltage detection signal;
A rotational speed measurement unit that measures the rotational speed Np of the windmill from the output of the rotational speed detection unit;
A non-volatile memory that stores the target voltage of the generator capable of obtaining the maximum power corresponding to the rotation speed;
A target voltage calculator that reads out and outputs the target voltage Vs of the generator that can obtain the maximum power stored in the nonvolatile memory based on the rotational speed Np of the windmill measured by the rotational speed measurement unit;
A difference calculation unit that obtains a difference between the target voltage Vs output by the target voltage calculation unit and the voltage Vp, and outputs a correction signal so that the value of the voltage Vp matches the target voltage Vs;
4. The system interconnection apparatus according to claim 3, further comprising: a PWM signal generation unit that outputs a pulse width modulation signal (PWM signal) that controls on / off of the switching element by a correction signal of the difference calculation unit. The grid interconnection device further includes an overvoltage suppression circuit that increases the load on the generator and lowers the output voltage,
The overvoltage suppression circuit
A series circuit of at least one switch and a resistor connected in parallel to the generator at the output of the generator;
A voltage detection unit that detects an output voltage of the generator and turns on the switch to lower the output voltage when the detected voltage is an overvoltage is provided. The grid interconnection device described. The grid interconnection device further includes an overvoltage suppression circuit that increases the load on the generator and lowers the output voltage,
The overvoltage suppression circuit
A series circuit of a semiconductor switching element and a resistor connected in parallel to the generator at the output of the generator;
A voltage detector for detecting the output voltage of the generator;
The grid interconnection device according to claim 1, further comprising a switching element control unit that controls an on / off ratio of the semiconductor switching element in accordance with a value of the output voltage detected by the voltage detection unit. .   The grid interconnection device according to any one of claims 1 to 4, wherein the power generator is configured by a wind power generator or a combination of a wind power generator and a solar power generator.

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