JP3966998B2 - Device for supplying and connecting power generated by wind power generators - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a connection device and a connection method for cooperatively supplying power generated by two types of generators such as a wind power generator and a solar power generator to an existing power system.
[0002]
[Prior art]
In recent years, in order to protect the global environment from environmental destruction such as global warming and air pollution, wind power generators and solar power generators that generate power using natural power without using fossil energy have been used around the world. Has been reviewed.
[0003]
The electric power obtained by the solar generator is output as a relatively high voltage and is often sold by being connected to an existing commercial power system (or general power system). In such a sale of photovoltaic power, a dedicated connection control device (power conditioner) for controlling the supply of the generated voltage to the commercial power system is usually used to obtain the connection control device and the amount of power sold. Electricity is sold through the electricity sales meter.
[0004]
On the other hand, since the voltage obtained by wind power generators is generally low, it is usually used as direct lighting power or motor electromotive force, or as various power after being temporarily stored in a battery. Often used.
[0005]
[Problems to be solved by the invention]
In recent years, the power generation efficiency of wind power generators has improved with technological development, so that the power generated by wind power generators can be considered as a target for power sales. In addition, if a power generation form using a plurality of wind power generators is taken, the total generated power is sufficient as a power source for selling power. However, the power generated by wind power generation is generally not yet considered as a target for power sale, and the connection form and connection method for selling the power generated by the wind power generator to the commercial power system is not currently available. It has not been established yet.
[0006]
The inventor of the present application has been studying the development of wind power generators and their practical application for many years, but based on their own experience and future prospects of wind power generation, the power generation of wind power is sold to the commercial power system. The conclusion that the connection form to do it should be materialized at the present time was obtained. And for practical use, we think that the connection device between the wind power generator and the commercial power system should be produced as cheaply as possible, and that the generated power should be used without waste. In order to make it happen, it was developed independently.
[0007]
As described above, a connection control device (power conditioner) is used for selling solar power, but this power conditioner has a high standard voltage according to solar power generation and is suitable for wind power generation with a relatively low power generation voltage. On the other hand, it was impossible to use it as it was. In addition, since the power conditioner is expensive, there is a problem that it is too expensive to produce a dedicated power conditioner for wind power generation. The inventor of the present application has developed the connection device independently while solving such problems, and has reached the device of the present invention.
[0008]
Therefore, the subject of this invention is implement | achieving the connection apparatus for supplying wind power generation electric power to a commercial power grid at low cost. Another object of the present invention is to provide a connection device that does not waste generated power and enables stable power supply over a long period of time.
[0009]
[Means for Solving the Problems]
In order to solve the above-described problems, the power supply connecting device of the present invention is a commercial power source (or general system power source, general power) generated by a wind power generator via a connection control device (power conditioner) for solar power generation. A power supply connection device for supplying power to a power system), an input unit (for example, an input control device) for inputting a voltage generated by a wind power generator, and a voltage input from the input unit of the connection control device A boosting unit that boosts the input standard voltage or near a normal power generation voltage by the solar power generator, and an output terminal that outputs the voltage boosted by the boosting unit to the connection control device. The function of this boosting unit raises the relatively low power generation voltage of the wind power generator to the output voltage range of the solar power generation, thereby using the connection control device (power conditioner) for selling the photovoltaic power generation to generate wind power. You can sell the generated power. As described above, the power supply connecting device of the present invention increases the wind power generation voltage to a voltage at which power can be sold. Therefore, for example, using an existing power conditioner or solar power without adding an expensive power conditioner. Using the power conditioner already installed together with the generator, it is possible to sell wind-generated power with an inexpensive device.
[0010]
When the boosting unit receives a power supply stop signal (corresponding to the power sale stop signal in the embodiment) indicating that the connection control device does not output the generated power directly received from the solar power generator to the commercial power source In addition, a switch for switching the circuit may be provided so that the electric power generated by the wind power generator is output to the connection control device. In solar power generation, it is difficult to supply power when the weather is bad, such as rain or cloudy, or at night, but this switch causes wind power when the connection control device is not selling solar power. Since the generated power can be sold, it is possible to stably sell power for a long time. Further, the existing connection control device is defined to stop the output of the photovoltaic power for a certain period of time (for example, 30 minutes) once the photovoltaic power becomes weaker than a predetermined value due to a change in weather or the like. However, according to the present invention, wind power generation power can be output instead of solar power generation power at such time, so that more stable power supply is possible. In addition, instead of the above-described power supply stop signal, a signal indicating that the photovoltaic power is directly output is generated, and when the signal is stopped, it may be regarded as a power supply stop signal. Such cases are also included in the present invention.
[0011]
The power supply connection device of the present invention may further include a power storage device such as a battery for storing the power generated by the wind power generator. In this case, the boosting unit boosts the power stored in the power storage device. And output to the connection control device. By having such a power storage device, it is possible to temporarily store wind-generated power while selling solar power, and to provide the stored power when solar power cannot be sold. Therefore, stable power supply without waste is possible.
[0012]
Also, in this case, the boosting unit detects a power storage amount of the power storage device, and directs the power stored in the power storage device to the connection control device when the power storage amount detected by the detector satisfies a predetermined condition. And a switch for switching the circuit so that the signal is output. This switch makes it possible to sell the stored power only when the amount of power stored in the power storage device is greater than or equal to a predetermined value, for example, so that the supply of power is not interrupted in a short time and more stable power Supply becomes possible.
[0013]
The power supply connection device of the present invention may further include a step-down unit that steps down the voltage generated by the solar power generator and outputs the stepped-down voltage toward the power storage device. By providing such a step-down unit, when the power generated by the solar generator is not sufficient with respect to the specified voltage of the connection control device, or even if it is sufficient, the output immediately after the power sale is temporarily stopped Since it is possible to store the electric power even when it is impossible to sell the solar power, such as when it is in a stop period, it is possible to supply power more efficiently.
[0014]
In addition, although the above-mentioned electric power supply connection apparatus was demonstrated as what is used when carrying out a cooperative operation of a solar power generator and a wind power generator, for example, when connecting a low power output solar power generator instead of a wind power generator It can also be applied to high-power wind generators and low-power wind power generators that operate in a coordinated manner, and also to other types of generators that are used in combination. However, it shall be included in the scope of the present invention.
[0015]
The generated power supply method of the present invention includes a second generator (for example, wind power generation) via a connection control device for supplying generated power from a first generator (for example, a solar power generator) to a commercial power source. A power generation power supply method for supplying power generated by the second power generator toward the commercial power source, the step of directly or once storing and inputting the power generation voltage generated by the second power generator in the power storage device, and the input voltage Are boosted to a specified input voltage of the connection control device, and the boosted voltage is output to the connection control device. In this way, the voltage generated by the second generator is increased to a voltage that can be sold via the connection control device, so that an expensive connection control device is added separately for the second generator. In addition, the power from the second generator can be sold with an inexpensive device using the connection control device already provided with the first generator. In addition, when storing power, when the first generated power is sold, the generated power of the second generator is stored, and when the stored power cannot be sold. Since it can be provided, stable power supply without waste is possible.
[0016]
The generated power supply method of the present invention further includes a step of generating a power supply stop signal indicating that the connection control device does not output the power generated by the first generator to the commercial power source, and the power supply stop And switching the connection so as to output the electric power generated by the second generator toward the connection control device according to the signal. Thereby, when the connection control device cannot sell the power from the first generator, the power from the second generator can be sold instead. It is possible to sell electricity.
[0017]
Furthermore, the generated power supply method of the present invention may include the step of reducing the voltage generated by the first generator and storing the voltage in the power storage device. As a result, the first generator generates power when the power generated by the first generator is not sufficient with respect to the specified voltage of the connection control device, or even when it is sufficient, for example, when the output is in a specified output stop period. Even when it is impossible to sell power from the machine, it is possible to store the power, so that it is possible to supply power more efficiently.
[0018]
The connection control device of the present invention is a connection control device for supplying electric power generated by a first generator and a second generator toward a commercial power source, and a voltage generated by the first generator is predetermined. When the above condition is not satisfied, an output stop unit that stops the output of the generated power by the first generator, and the output stop unit stops the output of the generated power by the first generator, An output stop signal generator for generating an output stop signal used to switch the connection so that the power generated by the second generator is output instead of the power generated by the first generator. Since the connection control device of the present invention includes such an output stop signal generation unit, when the generated power of the first generator (for example, a solar power generator) is not sold, the second is replaced instead. The circuit can be switched to sell the power generated by the generator (eg, wind power generator). As a result, it is possible to supply power stably by efficiently using the generated power from the two systems.
[0019]
In the above description, the apparatus and method of the present invention have been described so as to be used mainly for the purpose of selling power. However, the apparatus and method of the present invention simply supplies power to other power systems without actually selling the power. It can be used for the purpose, and an apparatus and a method used for such purpose using the concept of the present invention are also included in the scope of the present invention.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of a power supply connecting device according to the present invention will be described with reference to the drawings.
[0021]
FIG. 1 shows a configuration of an embodiment of a power supply connecting apparatus according to the present invention.
[0022]
As shown in the figure, this power supply connection device includes an input control device 11 that receives and controls a generated voltage from one or a plurality of wind power generators, and a booster circuit that boosts the generated voltage received from the input control device 11 ( A booster 12 having a DC booster circuit, and a power conditioner which is a connection device for selling the voltage output from the output terminal of the booster 12 to a commercial power source (or a general power source or a general power system) 13 is provided. The power conditioner 13 is for selling generated power from one or a plurality of solar cell modules that perform solar power generation, and an existing power conditioner can be used, which will be described later with reference to FIG. As described above, a device in which a new function is added to an existing power conditioner may be used. The output voltage from the power conditioner 13 is supplied to a commercial power supply via a power sale meter 14 that measures the amount of power sold.
[0023]
The power supply connecting device of this embodiment further includes a battery 15, and temporarily stores the voltage output from the input control device 11 in the battery 15, and the booster 12 boosts the stored voltage of the battery 15 and sells it. You can also. The power supply connection device further includes a step-down device 16 having a step-down circuit (DC step-down circuit) that steps down the output from the solar cell module and outputs the step-down output to the input control device 11. The voltage input from the step-down device 16 by the input control device 11 is stored in the battery 15 having a standard storage voltage of 12 volts, for example. Note that the output voltage of the step-down device 16 may be stored directly in the battery 15.
[0024]
The power conditioner 13 has an input voltage standard of 200 volts, and converts a DC power generation voltage of about 200 volts by the solar cell module into an AC voltage of about 202 volts synchronized with the commercial power supply and outputs the converted voltage. This output voltage is given as an example. Since the commercial power supply voltage is generally 200 volts, a voltage slightly higher than that is set. The power generation by the solar cell module strongly depends on the time and weather conditions. Power generation stops at night from sunset to sunrise, and the power generation decreases when it is cloudy or rainy. The voltage drops below the input standard voltage, and the power sale is stopped. The power conditioner 13 according to the present invention generates a power sale stop signal notifying that the power sale is stopped at this time, and the signal is output to the booster 12. When the booster 12 receives this power sale stop signal, that is, when the power generated by the solar cell module is not sold, the switch is switched by a switch circuit, and the wind power generator input from the input controller 11 or the battery 15 is used. The generated voltage is boosted to the input standard voltage of the power conditioner 13 and sent to the power conditioner 13, and the power conditioner 13 sells power with the voltage.
[0025]
The power conditioner 13 is a standard in which, when the input voltage from the solar cell module once falls below the input standard voltage, power is not sold for a certain period of time (for example, 30 minutes). If only solar power generation is used, power sales will be stopped during this period, but in this case, the power conditioner 13 continues to output the power received from the booster 12 even in such a case. Electricity sales rarely stop. In addition, when the weather recovers even during such a power sale suspension period, the output voltage of the solar cell module may reach a sufficient value. However, in the conventional power sale method, such power is not sold. It was not wasted. However, in the device of this embodiment, when the step-down device 16 receives a power sale stop signal from the power conditioner 13, the switch circuit switches the circuit and introduces the output voltage of the solar cell module into the step-down circuit. The electric power that has been generated but not sold at that time is stepped down to about 12 volts, then sent to the input control device 11 and stored in the battery 15.
[0026]
In this way, according to the present invention, the electric power generated by solar power generation is also used for power sales with little waste. The above-mentioned power sale stop signal is a signal indicating that the generated power of the solar cell module input directly to the power conditioner 13 (without going through the battery 15) is not sold (power generation by the wind power generator). The power generation voltage of the solar cell module input directly to the power conditioner 13 (without going through the battery 15) may be measured with a voltage measuring device, and the measurement may be performed. Generated by the signal generator when the voltage falls below the specified value. The voltage measuring device and the signal generator may be inside the power conditioner 13 or may be separately provided outside the power conditioner 13. Further, the voltage measuring device may measure the output voltage (power selling voltage) of the power conditioner 13, and based on the measurement result, it is determined whether or not power selling is being performed, and a power selling stop signal is output. You may speak. Instead of the power sale stop signal, a signal indicating that the generated power of the solar cell module directly input to the power conditioner 13 is sold is generated, and the time when the signal is stopped is described above. It may be regarded as the generation time of the power sale stop signal.
[0027]
The booster 12 is provided with a battery charge amount monitoring circuit, whereby the charge amount of the battery 15 is constantly monitored. Therefore, the voltage booster 12 determines the voltage of the battery 15 when the amount of power stored in the battery 15 exceeds a predetermined value or is within a predetermined range and the power conditioner 13 outputs a power sale stop signal. Is boosted and output to the power conditioner 13.
[0028]
Next, each component of the power supply connecting apparatus shown in FIG. 1 will be specifically described.
[0029]
FIG. 2 is a circuit diagram illustrating a configuration example of the input control device 11.
[0030]
As shown in FIG. 2, the input control device 11 includes a polyacene battery 21, a booster circuit 22, voltage detectors C1 to C4 such as comparators, switches S1 to S5 such as electronic switches, a gate G1, and a Schottky diode. It is a charge pump type charging circuit device including D1 to D3 and protective resistors R1 and R2. In the figure, reference numeral 23 denotes a wind power generator that outputs power to the input control device 11, and the output of the input control device 11 is stored in the battery 15. The output of the input control device 11 may be input to the booster device 12 without being stored in the battery 15.
[0031]
The wind power generator 23 is connected to the input unit 25 of the input control device 11, and a Schottky diode D1 and a switch S1 that is opened and closed by the voltage detector C1 are disposed between the input unit 25 and the polyacene battery 21. . The polyacene battery 1 is a 5V withstand voltage (or rated voltage 5V) capacitor type secondary battery using polyacene organic semiconductor (PAS) as an active material, and gradually accumulates electric charges supplied from the power generation device 3. The voltage detector C1 and the switch S1 are an overcharge protection circuit for the polyacene battery 21. The voltage detector C1 detects that the power generation voltage Vg generated by the wind power generator 23 is 5 V or more, which is the withstand voltage of the polyacene battery 21. At this time, the switch S1 is turned off.
[0032]
A switch S2 that is opened and closed by a voltage detector C2 is disposed between the polyacene battery 21 and the booster circuit 22, and the charge stored in the polyacene battery 21 by the opening and closing of the switch S2 is intermittent with respect to the booster circuit 22. Discharged. The voltage detector C2 has hysteresis, and the switch S2 is turned on when detecting that the voltage Vp of the polyacene battery 1 has reached, for example, 5V, and turned off when the voltage Vp becomes 2V or less.
[0033]
The booster circuit 22 is a circuit that boosts and outputs a voltage (2 to 5 V) charged in the polyacene battery 21 to a chargeable voltage (for example, 6 V or more) of the battery 4. A switch S4 that is opened and closed by a protective resistor R1, a Schottky diode D2, and a voltage detector C4 is connected between the booster circuit 22 and the output terminal 26. The switch S4 is for protecting the battery 15 connected to the output terminal 26 from overcharging. The voltage detector C4 is configured so that the voltage at the output terminal 26 (that is, the charging voltage of the battery 15) is, for example, that of the battery 15. When it is detected that the rated voltage (or a voltage corresponding to full charge) has been reached, the switch S4 is turned off.
[0034]
Between the input terminal 25 and the switch S4, a series circuit of a switch S3 that is opened and closed by a voltage detector C3, a protective resistor R2, and a Schottky diode D3 is connected in parallel to the polyacene battery 21 and the booster circuit 22. Yes. When the voltage detector C3 detects that the power generated by the wind power generator 23 is increased and the generated voltage Vg is, for example, 7 V or more, the switch S3 is turned on. In this case, since the generated voltage Vg is higher than the chargeable voltage (6 V) of the battery 15, the battery 15 is directly charged by the generated voltage Vg without going through the booster circuit 22.
[0035]
A switch S5 that is opened and closed by a gate G1 is connected in parallel with the polyacene battery 21 between the input terminal 25 and the booster circuit 22. The gate G1 turns on the switch S5 when the switches S1, S2, and S3 are all OFF. As a result, the power generation voltage Vg of 5 V or more and less than 7 V directly operates the booster circuit 22 without passing through the polyacene battery 1, and the power generation voltage Vg that has been boosted and can be charged is supplied to the battery 15. Schottky diodes D1 to D3 are diodes for preventing backflow, and protection resistors R1 and R2 are connected for protection of the booster circuit 22 and overcharge protection of the battery 15.
[0036]
It is also possible to replace the booster circuit 22 of the input control device 11 with the booster device 12 of FIG. 1. In this case, the booster circuit 22 boosts the input voltage to the standard voltage of the power conditioner 13, and the input control device 11. Is supplied to the power conditioner 13 instead of the battery 15.
[0037]
FIG. 3 is a diagram showing the configuration of the booster 12 in FIG.
[0038]
As shown in this figure, the booster device 12 includes a battery charge amount monitoring circuit 31, a switch 32, a switch control circuit 33, and a booster circuit. The battery storage amount monitoring circuit 31 monitors the storage amount of the battery 15, and when it is determined that the storage amount of the battery 15 is equal to or greater than a predetermined amount, a signal indicating that is sent to the switch control circuit 33. Output. When the switch control circuit 33 receives a signal from the battery charge amount monitoring circuit 31 and further receives a power sale stop signal from the power conditioner 13, the switch control circuit 33 closes the switch 32 and introduces the voltage of the battery 15 into the booster circuit 34. The booster circuit boosts the voltage thus input to the input specified voltage of the power conditioner 13 and outputs the boosted voltage.
[0039]
When the booster 12 receives a voltage directly from the input control device 11, the battery storage amount monitoring circuit 31 is not used, and the switch control circuit 33 turns on the switch 32 when receiving a power sale stop signal.
[0040]
FIG. 4 is a diagram illustrating a configuration example of the power conditioner 13 in the power supply connection device of FIG. 1.
[0041]
As shown in the figure, the power conditioner 13 includes a voltage monitoring device 41, a switch control circuit 42, a switch 43, a signal generation circuit 44, and a voltage connection control device 45. The voltage monitoring device 41 is configured by a voltmeter or the like, measures the voltage output from the solar cell module to the power conditioner 13, and transmits the measurement result to the switch control circuit 42 and the signal generation circuit 44. Upon receiving the voltage measurement result, the switch control circuit 42 opens the switch 43 and cuts off the voltage from the solar cell module when determining that the output voltage of the solar cell module has fallen below a predetermined specified value. Further, when the signal generation circuit 44 determines that the output voltage of the solar cell module has fallen below a predetermined specified value from the voltage measurement result by the voltage monitoring circuit, the signal generation circuit 44 generates the above-mentioned power sale stop signal and sends it to the booster 12. Output.
[0042]
The voltage connection control device 45 is a device having functions similar to those required for power sales such as a voltage conversion function in an existing power conditioner, and uses the electric power received from the solar cell module or the booster device 12 as a commercial power source. Voltage conversion is performed so that power can be sold. As a result, in this embodiment, the output voltage is about 202 volts, and since this exceeds 200 volts, which is the input voltage from the commercial power source, power is sold toward the commercial power source. This amount of electric power sold is measured by the electric power sale meter 14.
[0043]
In the power conditioner 13 described above, the voltage monitoring device 41 may measure the output voltage from the voltage connection control device 45, and the switch control circuit 42 and the signal generation circuit 44 perform the above operation based on the measurement result. Also good. Further, the switch control circuit 42 may be set so that the switch 43 is opened for a certain period of time after the output voltage of the solar cell module falls below a predetermined value (for example, 30 minutes in accordance with the existing power conditioner standard) In this case, the signal generation circuit 44 continues to generate a power sale stop signal for the same time.
[0044]
FIG. 5 shows a configuration example of the step-down device 16 in the power supply connection device of FIG.
[0045]
As shown in the figure, the step-down device 16 includes a switch control circuit 51, a switch 52, and a step-down circuit 53. When the switch control circuit 51 receives a power sale stop signal from the power conditioner 13, the switch control circuit 51 closes the switch 52 and introduces the output voltage of the solar cell module to the step-down circuit 53. The step-down circuit 53 steps down the received voltage to an input possible voltage of the battery 15 and outputs it to the battery output terminal of the input control device 11. Note that the output of the step-down circuit 53 may be directly input to the battery 15.
[0046]
Although the embodiment of the power supply connecting device according to the present invention has been described above, this embodiment describes one configuration example of the power supply connecting device, and the arrangement position of each component, each voltage value, or a default value, etc. Even if they are different, they can be included in the scope of the present invention as long as the same effects as those of the power supply connecting device described above can be obtained.
[0047]
【The invention's effect】
According to the power supply connection device of the present invention, wind power generation power can be supplied to the commercial power system using the existing solar power generation power conditioner, so that the wind power generator connection device can be made inexpensively. Can be realized. In addition, according to the present invention, even when the power generated by the solar power generator is weakened, the power generated by the wind power generator can be supplied instead. Therefore, stable power supply can be provided over a long period of time. It becomes. Furthermore, since the electric power that has not been used in the past and is wasted among the photovoltaic power generation power can be used after it has been stored once, efficient and stable power supply becomes possible.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an embodiment of a power supply connecting apparatus according to the present invention.
2 is a circuit diagram illustrating a configuration example of an input control device 11 in the power supply connection device of FIG. 1;
FIG. 3 is a diagram illustrating a configuration example of a booster device 12 in the power supply connection device of FIG.
4 is a diagram illustrating a configuration example of a power conditioner 13 in the power supply connection device of FIG. 1. FIG.
5 is a diagram illustrating a configuration example of a step-down device 16 in the power supply connection device of FIG. 1;
[Explanation of symbols]
11 Input control device
12 Booster
13 Power conditioner
14 Power meter
15 battery
16 Step-down device
21 Polyacene battery
22 Booster circuit
23 Wind power generator
25 Input terminal
26 Output terminal
C1-C4 voltage detector
S1-S5 switch
G1 gate
D1-D3 Schottky diode
R1, R2 Protection resistance
31 Battery charge amount monitoring circuit
32 switches
33 Switch control circuit
34 Booster circuit
41 Voltage monitoring device
42 Switch control circuit
43 switch
44 Signal generation circuit
45 Voltage connection control image value
51 Switch control circuit
52 switch
53 Step-down circuit

Claims (7)

A power supply connection device for supplying electric power generated by a wind power generator toward a commercial power supply via a connection control device for solar power generation,
An input unit for inputting a voltage generated by the wind power generator;
Boosting means for boosting the voltage input from the input unit to an input specified voltage of the connection control device;
The voltage boosted by said boosting means, and an output terminal for output to the connection control device,
When the connection control device receives a power supply stop signal indicating that the power generated by the solar power generator is not output to the commercial power source, the connection control unit controls the power generated by the wind power generator. A power supply connection device comprising switch means for switching a circuit to output to the device. Furthermore, it has a storage means for storing the power generated by the wind power generator,
The power supply connection device according to claim 1, wherein the boosting unit boosts the power stored in the power storage unit and outputs the boosted power to the connection control device. The boosting unit detects a storage amount of the storage unit, and outputs the stored power of the storage unit to the connection control device when the storage amount detected by the detection unit satisfies a predetermined condition The power supply connection device according to claim 2 , further comprising a switch unit. Furthermore, the electric power supply connection apparatus of Claim 2 or 3 provided with the pressure | voltage reduction means which pressure | voltage-falls the power generation voltage by a solar power generator, and outputs it toward the said electrical storage means. A generated power supply method for supplying generated power from a second generator toward the commercial power source via a connection control device for supplying generated power from the first generator toward the commercial power source,
A step of storing the voltage generated by the second generator directly or once after being stored in the storage means;
Boosting the input voltage to an input regulation voltage of the connection control device;
Outputting the boosted voltage to the connection control device;
Generating a power supply stop signal indicating that the connection control device is not outputting the power generated by the first generator to the commercial power source;
In response to the power supply stop signal, switching the connection to output the power generated by the second generator toward the connection control device;
A method for supplying generated power. Furthermore, the generated electric power supply method of Claim 5 including the step which carries out the pressure | voltage reduction of the electric power generation voltage by a said 1st generator, and stores it in the said electrical storage means. A connection control device for supplying electric power generated by a first generator and a second generator toward a commercial power source,
Output stopping means for stopping output of the generated power by the first generator when the generated voltage by the first generator does not satisfy a predetermined condition;
When the output stop means stops the output of the power generated by the first generator, the connection is switched so that the power generated by the second generator is output instead of the power generated by the first generator. Output stop signal generating means for generating an output stop signal used for
A connection control device.

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