JP5939568B2 - System for proper use of generated power by natural energy - Google Patents

Description

The present invention is based on natural energy, for example, to use power generated by natural energy without waste when used by combining power generated from power generation facilities using natural energy such as sunlight and power transmitted by commercial power. The present invention relates to an appropriate use system of the generated power from the power generation facility.

  The present inventor has already converted power from AC to DC of a plurality of direct-current power transmission lines and commercial power supply of power generated by power generation facilities using natural energy represented by sunlight, wind power, and hydropower. A reverse current prevention diode is attached to each of the transmission lines so that power does not flow back to each of the transmission sources, so that direct current power transmission from the plurality of power transmission lines is unified, and normally the natural energy is used. A control method for generating power transmission configured to give priority to power transmission from the generated power generation equipment has already been invented (Japanese Patent Application Laid-Open No. 2011-181055).

  According to the present invention, for example, the amount of power generated by a power generation facility using natural energy represented by sunlight, wind power, and hydropower whose power generation is influenced by natural conditions can be used to the maximum, and power supply from a commercial power source can be performed. Can be controlled appropriately, and as a result, it has the effect that power saving of commercial power can be greatly expected.

  However, the above-mentioned invention converts AC power from a commercial power source into DC power, combines it with DC power from the power generation facility using the natural energy, and uses the DC power in a DC loader. The loader could not be used.

  Therefore, the present inventor also converts AC power generated from power generation facilities using natural energy such as sunlight into AC power, and uses it by combining it with power transmitted by a commercial power source that was originally sent by AC. In addition, the power generated by natural energy can be used without waste, and an appropriate control method that prevents the power generated by natural energy from flowing backward to the commercial power source in an unforeseen situation is invented. It came to do.

  Here, in the case of a commercial power supply of 100V, the average voltage for 30 minutes is determined to be in the range of 95V to 107V, but depending on the situation, it may exceed the range of 95V to 107V.

  Under such circumstances, a DC-AC converter, for example, a power conditioner, that converts generated power from a power generation facility using natural energy such as sunlight into AC power has a voltage of 107 V or more in a connected system. In this case, the product is designed so that the suppression function automatically operates. For example, if the voltage of the commercial power supply exceeds 107 V for some reason, it will generate enough power with natural energy such as sunlight. It is said that it is impossible to use electricity.

  In addition to not being able to sell electricity, the power that flows through the load (for personal consumption) will be given priority to the power on the commercial power supply side, and power generation using natural energy such as sunlight will be wasted. Therefore, the power on the commercial power source side had to be consumed, and extra costs were forced.

  In particular, when there are a plurality of power generation facilities using natural energy such as sunlight in a neighboring area, when the amount of sunlight during the day is large and the amount of power consumption is small, the voltage in the linked system is 107 V or more. As a result, many of the absurdities described above were inviting.

  By the way, the above-described DC-AC converter, for example, a power conditioner, that converts generated power from a power generation facility using natural energy such as sunlight into AC power is designed so that it does not operate unless the amount of generated power is a predetermined amount. ing. Accordingly, there is a problem that the generated power is wasted when the power generated by the power generation facility using natural energy such as sunlight is less than the so-called prescribed amount.

JP 2011-181055 A

Thus, the present invention is a further improvement on the invention already invented by the inventor. AC power is also converted into AC power from power generated by natural energy such as sunlight. In this case, the power generated by the natural power can be used without waste, and the power generated by the natural energy can be used without any waste. Power generation system using natural energy, such as preventing the power from flowing backward to the commercial power supply side. Proper use of generated power from natural energy, such as not wasting power It is an object to provide a system.

The system for properly using generated power by natural energy according to the present invention is:
With regard to the power generation equipment that requires AC conversion for the power generated by the power generation equipment using natural energy represented by sunlight, it is based on the transmission power that is converted from DC to AC by the DC-AC converter and sent by the commercial power supply. A power generation system configured so that the power from the power generation facility using the natural energy can be used by combining the transmission power of the alternating current,
When a plurality of the natural energy power generation facilities are installed, and each DC generated power generated from the power generation facilities installed in the plurality of facilities does not become a power generation amount that can be converted from DC to AC by the DC-AC converter. , Each power generation amount is integrated in advance by an integration device, and the power generation amount of DC generated power is converted into a power generation amount that can be converted from DC to AC by the DC-AC converter,
The direct-current generated power converted into the amount of power that can be converted from direct current to alternating current is converted from direct current to alternating current by the direct current to alternating current converter,
When the voltage sent from the commercial power supply is compared with the premises voltage sent from the power generation facility using the natural energy to alternating current and sent to the premises, and the voltage on the commercial power supply side is higher than the premises voltage In addition, the voltage converter converts the commercial power supply side voltage into a pseudo-commercial power supply voltage equivalent to the premises voltage,
When the local voltage is higher than the converted pseudo commercial power supply voltage, a surplus load is increased by the control device, and when the local voltage is equal or lower than the converted pseudo commercial power supply voltage, the control device Reduce the load of surplus load,
It is characterized by
Or
With regard to the power generation equipment that requires AC conversion for the power generated by the power generation equipment using natural energy represented by sunlight, it is based on the transmission power that is converted from DC to AC by the DC-AC converter and sent by the commercial power supply. A power generation system configured so that the power from the power generation facility using the natural energy can be used by combining the transmission power of the alternating current,
When a plurality of the natural energy power generation facilities are installed, and each DC generated power generated from the power generation facilities installed in the plurality of facilities does not become a power generation amount that can be converted from DC to AC by the DC-AC converter. , Each power generation amount is integrated in advance by an integration device, and the power generation amount of DC generated power is converted into a power generation amount that can be converted from DC to AC by the DC-AC converter,
The direct-current generated power converted into the amount of power that can be converted from direct current to alternating current is converted from direct current to alternating current by the direct current to alternating current converter,
When the voltage sent from the commercial power supply is compared with the premises voltage sent from the power generation facility using the natural energy converted into alternating current, the voltage on the commercial power supply side is higher than the premises voltage The voltage converter converts the commercial power supply side voltage into a pseudo-commercial power supply voltage equivalent to the premises voltage.
When the local voltage is higher than the converted pseudo commercial power supply voltage, the control device sends a control signal for increasing the set value of the surplus load to the load control circuit of the surplus load,
If the premises voltage from the conversion by said pseudo commercial power source voltage is equal to or lower pressure value, sends a control signal to decrease the set value of the excess load to the load control circuit for controlling the higher load excess load to the control device,
It is characterized by
Or
Before joining the power from the commercial power source and the generated power from the power generation facility using the natural energy, a backflow prevention breaker was attached to the power transmission line side from the commercial power source,
It is characterized by this.

If the system for properly using generated power by natural energy according to the present invention,
AC power can also be used by converting the power generated from power generation facilities using natural energy such as sunlight into AC power and combining it with the power transmitted by commercial power that was originally sent by AC. Can be used without waste. In other words, there is no need for a DC-AC converter such as a power conditioner for direct-current generated power using natural energy such as sunlight and wind power having different so-called power generation characteristics. In addition to being able to use the generated power without waste, in the event of an unforeseen situation, the generated power generated by natural energy will not flow backward to the commercial power source. Even when the electric power is less than a so-called predetermined amount to be taken in, there is an excellent effect that the generated electric power by natural energy can be properly used, such as the generated electric power is not wasted.

FIG. 3 is an explanatory diagram illustrating a configuration of the first embodiment. It is explanatory drawing (1) explaining the structure of Example 2. FIG. It is explanatory drawing (2) explaining the structure of Example 2. FIG. It is explanatory drawing (3) explaining the structure of Example 2. FIG. FIG. 10 is an explanatory diagram illustrating a configuration of a third embodiment. 10 is a flowchart for explaining the operation of the third embodiment. It is explanatory drawing (1) explaining the structure of Example 4. FIG. It is explanatory drawing (2) explaining the structure of Example 4. FIG. It is explanatory drawing (3) explaining the structure of Example 4. FIG. It is explanatory drawing explaining the structure of a prior art example.

  Hereinafter, the present invention will be described based on embodiments shown in the drawings.

FIG. 1 is an explanatory diagram illustrating a schematic configuration of the first embodiment.
First, the basic configuration of the present invention is as follows. For the power generation equipment 1... That uses natural energy represented by sunlight, the power generation equipment 1. From the power generation equipment 1... Using the natural energy by combining the transmission power 3 that is converted from direct current to alternating current by the direct current-alternating current conversion device 2 and the alternating current transmission power 5 by the commercial power source 4. It is a power generation system configured to use electric power.

  Then, a plurality of the natural energy power generation facilities 1... Are installed, DC generated power (sending power 3) from the plurality of facilities is integrated in advance by the integration device 6, and direct current is generated by the DC-AC conversion device 2. The feature of the present embodiment is that the amount of power generation is enough to convert from AC to AC.

  In general, the DC-AC converter 2 is composed of a power conditioner. However, the DC-AC converter 2 does not convert DC power into AC power unless it has a predetermined power generation amount (usually about 70 watts).

  Therefore, for example, when it is raining or cloudy, the power generation amount of the power generation facility 1 by solar energy is particularly small, and it may generate only a few watts or a few tens of watts. In such a case, the DC-AC converter 2 does not function, and conventionally, the amount of power generated by each of the power generation facilities 1.

  Therefore, in this embodiment, a plurality of power generation facilities 1 using natural energy are installed, and the amount of power generated by these power generation facilities 1... Is integrated by the integration device 6, and can be DC-AC converted by the DC-AC conversion device 2. It is the amount of power generation.

Here, as the integrated device 6, a backflow prevention diode can be considered. That is, the backflow prevention diode is attached between the power generation facility 1 and the DC-AC converter 2 using each natural energy to integrate the power generated in each power generation facility 1.

2, 3, and 4 are explanatory diagrams illustrating the configuration of the second embodiment.
As can be understood from FIG. 2, in this embodiment as well, the power generation equipment that needs to be converted from direct current to alternating current with respect to the power generated by the power generation equipment 1 that uses natural energy represented by sunlight. As for 1..., A power generation facility using the natural energy by combining a transmission power 3 that is converted from DC to AC by the DC-AC converter 2 and an AC transmission power 5 by the commercial power source 4. A power generation system configured to use the power from 1.

  In the present embodiment, when the generated power is integrated by the integrated device 6 of the generated power from the plurality of power generation facilities 1... Using the natural energy, a plurality of types of import priorities are assigned to the plurality of power generation facilities 1. And the generated power of DC is sent from the power generation facilities 1... To the integrated device 6 in accordance with the determined priority of taking-in.

  2, the integrated device 6 includes a diode that switches an input from each power generation facility 1, and includes switching elements 7... Provided in each power generation facility 1. And a switch controller 8 for controlling switching of the switch.

  Here, switching based on the priority order will be described with reference to FIGS. 3 and 4. The switch controller 8 stores a priority database 20 as shown in FIG.

  For example, when the cost order is selected, as shown in the priority order database 20, the photovoltaic power generation facility 1 has the highest cost order. Therefore, first, the voltage 25 from the photovoltaic power generation facility 1 is checked. If the voltage 25 is such that the photovoltaic power generation can be supplied, the switching element 7 from the photovoltaic power generation is operated to be turned on. Then, the switching elements 7... From other power generation facilities 1 and the commercial power supply 4 are operated to turn them all off.

  In addition, when the voltage from the power generation facility 1 by solar power generation is not the voltage 25 that can be supplied, the wind power generation facility 1 is the second in the following order, that is, the order shown in the priority order database 20. Since it is ranked, the voltage 25 from the wind power generation facility 1 is checked. If the voltage that can be supplied by wind power generation is 25, the switching element 7 from the wind power generation is operated to be turned on, and the switching element 7 from another power generation facility 1 or the commercial power source 4 is operated. All are turned off.

  In addition to the above-mentioned power cost order, the priority order may be the order of power generation (rated value of power generation equipment) or the order of power generation (evaluation not related to power generation capacity, such as the degree of burden on the environment). No), time zone (power generation with the lowest cost in the operating time zone) can be set.

  Therefore, the setting of the priority order is not limited to the contents of the above priority order, and various settings can be made according to the actual situation and changes in the times.

  In this way, by setting various priorities, it is possible to select any of the above-described priorities and supply the generated power with priority in the contents.

  In addition, in order to reflect the electricity rate that fluctuates in the time zone in the ranking, it is sufficient to add a time counter 21 having a table of electricity rates and a clock function in each time zone.

FIG. 4 is a flowchart showing the operation of the present embodiment. In this procedure, each priority order is determined and power is supplied.

FIG. 5 is an explanatory diagram for explaining the configuration of this embodiment.
When the commercial power source 4 is 100V, the average voltage for 30 minutes is determined to be in the range of 95 to 107V, but depending on the situation, the voltage may exceed this range.

  Here, the DC-AC converter 2, that is, for example, the power conditioner is configured so that the suppression function works when the voltage of the system (the voltage of the premises 10) becomes 107V or more, depending on the product. When the voltage of the commercial power supply 4 is higher than the 107V, even if sufficient power generation is performed by the power generation facility 1 using natural energy such as so-called sunlight, power cannot be sold.

  Furthermore, in this situation, not only cannot the power be sold, but also the power of the commercial power supply 4 is given priority for the power flowing to the load 16 side (for personal consumption). Not only was the power generation wasted, but the power from the commercial power source 4 had to be forcibly used in the middle, leading to extra costs.

  When there are a large number of solar power generation facilities 1 in the same area, especially when the amount of sunlight is large and the power consumption is low during the day, the commercial power supply 4 is not used, so the voltage is 107V. In some cases, the power will not be sold. These are as already described.

  In the present embodiment, as described above, even when the voltage of the commercial power supply 4 is high, the voltage at the load 16 portion is lowered by performing voltage conversion, and the utilization efficiency of natural energy by sunlight or the like is improved. .

  In addition, when the amount of power generated by natural energy (for example, sunlight) is larger than that of the load 16, it is also intended to avoid the so-called reverse power flow by increasing the surplus load 17.

  The operation of this embodiment will be described. The voltage on the commercial power source 4 side is measured by the voltmeter 11 (see FIG. 1).

  Next, the voltage on the commercial power supply 4 side is converted by the voltage converter 12 so that the voltage of the premises 10 becomes a voltage (for example, 99V) close to the determined voltage. The configuration of the voltage conversion device 12 is not limited in any way, but as shown in FIG. 5, a plurality of tap switching elements 13... Are provided, and the tap switching elements 13. Thus, voltage conversion can be performed.

  That is, when the switching operation of the tap switching elements 13... Is performed, for example, if the voltage on the commercial power supply 4 side is 107 V, the voltage is close to the voltage determined as the voltage of the premises 10 (for example, 99 V). The voltage is converted to.

  Next, the voltage on the load side (premises 10) is checked with a voltmeter 14 (see FIG. 1), and the voltage switched by the tap switching element 13, that is, a voltage close to the voltage determined as the voltage of the facility 10; For example, when it is higher than 99V (in other words, the pseudo commercial power supply voltage of the commercial power supply 4), it can be considered that the power generation amount is larger than that of the load 16.

  Therefore, the control device 15 performs an operation for increasing the load setting value of the surplus load 17.

  That is, in that case, the control device 15 sends the load control signal 18 to the load control circuit 19, and the load control circuit 19 increases the load set value of the surplus load 17.

  In other cases, that is, a voltage close to the voltage determined as the voltage of the premises 10, for example, 99 V (in other words, the pseudo commercial power supply voltage of the commercial power supply 4), or substantially equal, Since power is consumed in the premises 10, the control device 15 sends a load control signal 18 for reducing the load set value to the load control circuit 19.

  The load set value is determined as described above, and the load control signal 18 is sent to the load control circuit 19. The load control circuit 19 controls the surplus load 17 according to the signal 18.

  If it demonstrates with the flowchart of FIG. 6, the voltage by the side of the commercial power source 4 will be measured with the voltmeter 11 (step 100).

  Next, the voltage on the commercial power supply 4 side is converted by the voltage converter 12 so that the voltage of the premises 10 becomes a voltage (for example, 99V) close to the determined voltage. The configuration of the voltage conversion device 12 is not limited at all. However, as described with reference to FIG. 5, the voltage conversion device 12 is configured by providing a plurality of tap switching elements 13. Perform voltage conversion.

  That is, when the tap switching element 13 is switched, for example, if the voltage on the commercial power supply 4 side is 107V, the voltage is converted to a voltage close to the voltage determined as the voltage of the premises 10 (for example, 99V). (Step 102).

  Next, the voltage on the load side (premises) is checked with the voltmeter 14 (step 104), and the voltage switched by the tap switching element 13, that is, a voltage close to the voltage determined as the voltage of the campus 10, for example, 99V If it is higher than (in other words, pseudo commercial power supply voltage of commercial power supply 4) (YES in step 106), it can be considered that the amount of power generation is larger than that of load 16.

  Therefore, an operation for increasing the load setting value of the surplus load 17 is performed by the control device 15 (step 108).

  That is, in that case, the control device 15 sends the load control signal 18 to the load control circuit 19 (step 112), and the load control circuit 19 increases the load setting value of the surplus load 17. Here, specific contents of the surplus load 17 include a storage battery, ice storage, hot water storage, heating assistance, load heating load, and the like.

In other cases, that is, when the voltage is close to the voltage determined as the voltage of the premises 10, for example, 99 V (in other words, the pseudo commercial power supply voltage of the commercial power supply 4), or substantially equal ( Since power is consumed in the premises 10, the control device 15 sends a load control signal 18 for decreasing the load set value to the load control circuit 19 (steps 110 and 112).

  In the present embodiment, before the power from the commercial power source 4 and the power generated from the power generation facility 1 using natural energy such as sunlight are merged, backflow prevention is performed on the power transmission line 5 side from the commercial power source 4. A breaker 22 is attached.

  By adopting such a configuration, even if a power failure or the like occurs and the voltage on the commercial power supply side suddenly decreases, the reverse power flow from the power generation facility 1 side due to natural energy can be completely prevented.

  Referring to FIGS. 5 and 7, the AC backflow prevention breaker 22 can be configured as shown in FIG. In other words, the direction in which the power flows is detected by the voltages V1 and V3, and when the current flows in the opposite direction, the switch is turned off to cut off the circuit. And when it is interrupted, it recovers with a reset switch or when the voltage of V2 becomes zero. Thus, automatic recovery is possible when the commercial power supply 4 is restored.

  The operation of FIG. 7 will be described. When V1 × V3> 0, the switch is turned on (it is understood that power is normally flowing from the AC input to the AC output).

  However, when V1 × V3 <0, the switch is turned OFF (because it is understood that the flow is from the AC output to the AC input, that is, the power is flowing backward).

  Instead of looking at the voltage of V3, the current flow can be measured with a Hall current sensor or the like and the value can be used.

  Next, a modification of the present embodiment will be described with reference to FIG. FIG. 8 shows the configuration of a so-called AC bidirectional (reverse power flow compatible) wattmeter.

  This is an invention of a wattmeter that supports so-called reverse power flow (when the direction in which power is supplied is reversed), and whether the direction in which power is supplied is the so-called reverse power flow or supply in a normal direction It is to judge whether it is done. Moreover, it is a wattmeter which can also measure the electric energy. By combining the wattmeter and a so-called power breaker, the backflow prevention breaker 22 can be obtained.

  Normally, alternating current is switched between positive and negative, so it is not easy to know the direction in which power is supplied. However, theoretically, the direction and magnitude of the current can be known by comparing the voltage waveforms of V1 and V2.

  That is, as shown in FIG. 8, when a current flows, the voltage (amplitude) on the load side decreases by the voltage drop due to the resistance.

  By comparing the magnitude of this amplitude, it is possible to know the direction in which power is supplied, and the current can be found from the voltage across the resistor (difference between V1 and V2) and the resistance value. Power can be obtained from V1 or V2.

  However, the resistance for measurement must be small, and then a high-precision voltmeter is required to determine the minute difference between V1 and V2. For example, when R is 0.1Ω, a voltage of V1 to 100V is supplied, and when a 5 W bulb is lit, the voltage drop is only about 5 mV. Measuring 5mV is not so difficult, but to examine the difference of 5mV (0.005V) at a voltage level of 100V, a voltmeter that can measure 100.005V, that is, a voltmeter with at least 6 significant digits It will be necessary.

  Such a voltmeter is not very realistic. To solve this problem, a voltmeter that can measure a minute voltage is used for V3, and the phase information of the measured values of V1 and V3 is used to easily detect the direction of power supply with high accuracy. A wattmeter that can be configured can be configured.

  FIG. 9 is a similar modification, and shows the configuration of an AC bidirectional (reverse power flow) wattmeter.

  In FIG. 9, V1 is a voltmeter that can measure the range of input voltage, and V3 is a voltmeter that can measure the voltage drop across the resistor that occurs when power in the range to be measured flows. is there.

  A normal wattmeter also measures power using the voltages V1 and V3, but it does not take into account the phase of the waveform, so it cannot know the direction of power.

  If the input is alternating current, the voltage that can be observed at V3 is of course alternating current, so the direction of the current cannot be determined by the positive or negative voltage. However, by using the phase of V1 and V3, the direction of power supply can be determined.

  When electric power is supplied in the direction of arrow 24 in FIG. 9, V1 and V3 have waveforms as shown on the left in FIG. Further, when power is supplied in the reverse direction, the waveform shown on the right in FIG. 9 is obtained.

  In the left waveform, V1 and V3 are in phase, and when V1 is positive, V3 is also positive. Conversely, the right waveform shows that when V1 is positive, V3 is negative.

  Therefore, by obtaining the product of V1 and V3, the power supply direction can be determined from the sign.

  On the other hand, the power value can be calculated because the voltage is obtained from V1 and the current is obtained from V3 and R, as in a normal wattmeter.

The direction of power can be known from the sign of the product of V1 and V3, but this may be obtained numerically using an AD converter or may be obtained by creating an arithmetic circuit. In addition, V1 and V3 do not require an extremely large number of significant digits.

DESCRIPTION OF SYMBOLS 1 Power generation facility using natural energy 2 DC-AC converter 3 Sending power 4 Commercial power supply 5 Sending power 6 Integration device 7 Switching element 8 Switch controller 10 Premise 11 Voltmeter 12 Voltage converter 13 Tap switching element 14 Voltmeter 15 Control Device 16 Load 17 Surplus load 18 Load control signal 19 Load control circuit 20 Priority database 21 Time counter 22 Backflow prevention breaker 24 Arrow 25 Voltage

Claims (3)

With regard to the power generation equipment that requires AC conversion for the power generated by the power generation equipment using natural energy represented by sunlight, it is based on the transmission power that is converted from DC to AC by the DC-AC converter and sent by the commercial power supply. A power generation system configured so that the power from the power generation facility using the natural energy can be used by combining the transmission power of the alternating current,
When a plurality of the natural energy power generation facilities are installed, and each DC generated power generated from the power generation facilities installed in the plurality of facilities does not become a power generation amount that can be converted from DC to AC by the DC-AC converter. , Each power generation amount is integrated in advance by an integration device, and the power generation amount of DC generated power is converted into a power generation amount that can be converted from DC to AC by the DC-AC converter,
The direct-current generated power converted into the amount of power that can be converted from direct current to alternating current is converted from direct current to alternating current by the direct current to alternating current converter,
When the voltage sent from the commercial power supply is compared with the premises voltage sent from the power generation facility using the natural energy to alternating current and sent to the premises, and the voltage on the commercial power supply side is higher than the premises voltage In addition, the voltage converter converts the commercial power supply side voltage into a pseudo-commercial power supply voltage equivalent to the premises voltage,
When the local voltage is higher than the converted pseudo commercial power supply voltage, a surplus load is increased by the control device, and when the local voltage is equal or lower than the converted pseudo commercial power supply voltage, the control device Reduce the load of surplus load,
A system for the proper use of generated power by natural energy.
With regard to the power generation equipment that requires AC conversion for the power generated by the power generation equipment using natural energy represented by sunlight, it is based on the transmission power that is converted from DC to AC by the DC-AC converter and sent by the commercial power supply. A power generation system configured so that the power from the power generation facility using the natural energy can be used by combining the transmission power of the alternating current,
When a plurality of the natural energy power generation facilities are installed, and each DC generated power generated from the power generation facilities installed in the plurality of facilities does not become a power generation amount that can be converted from DC to AC by the DC-AC converter. , Each power generation amount is integrated in advance by an integration device, and the power generation amount of DC generated power is converted into a power generation amount that can be converted from DC to AC by the DC-AC converter,
The direct-current generated power converted into the amount of power that can be converted from direct current to alternating current is converted from direct current to alternating current by the direct current to alternating current converter,
When the voltage sent from the commercial power supply is compared with the premises voltage sent from the power generation facility using the natural energy converted into alternating current, the voltage on the commercial power supply side is higher than the premises voltage The voltage converter converts the commercial power supply side voltage into a pseudo-commercial power supply voltage equivalent to the premises voltage.
When the local voltage is higher than the converted pseudo commercial power supply voltage, the control device sends a control signal for increasing the set value of the surplus load to the load control circuit of the surplus load,
If the premises voltage from the conversion by said pseudo commercial power source voltage is equal to or lower pressure value, sends a control signal to decrease the set value of the excess load to the load control circuit for controlling the higher load excess load to the control device,
A system for the proper use of generated power by natural energy.
Before joining the power from the commercial power source and the generated power from the power generation facility using the natural energy, a backflow prevention breaker was attached to the power transmission line side from the commercial power source,
The system for properly using generated power by natural energy according to claim 1 or 2.

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