JP6649861B2 - Power generation amount prediction device and power generation amount prediction method - Google Patents

Description

  An embodiment of the present invention relates to a power generation amount prediction device and a power generation amount prediction method.

  2. Description of the Related Art A power supply system that connects a photovoltaic power generation facility to a load facility together with a generator and a storage battery is known (for example, see Patent Literature 1). In such a power supply system, when the generator is started, the generator supplies power to the load equipment and charges the storage battery. When the generator is stopped, the storage battery and the photovoltaic power generation equipment supply power to the load equipment.

In the operation of the power supply system, if the amount of power generated by the photovoltaic power generation facilities for a given day is known in advance, the load generated by the photovoltaic power generation facilities will be reduced during the time when the generator is operated to supply power to the load facilities and charge the storage battery. It becomes possible to supply power to equipment and charge storage batteries. As a result, it is expected that the power generated by the photovoltaic power generation equipment will be effectively used by reducing the operation time of the generator or controlling the timing of charging and discharging the storage battery.
Technology for predicting the amount of power generated by solar power generation equipment from external information such as weather information, and technology for predicting the amount of power generated by solar power generation equipment based on information measured by sensors such as barometric pressure sensors instead of external information There is. The weather information includes information obtained from a weather forecast, cloud cover, and the like.

JP-A-2005-70637

  In order to obtain information from the outside via the Internet, a TV, a radio, and the like, and to estimate the power generation amount from the information from the outside, a communication line may be required or an information provision fee may be required. Also, when predicting from information measured using a barometric pressure sensor or the like, it is possible to predict whether the weather tends to recover or collapse due to atmospheric pressure fluctuations, but it is difficult to predict the amount of power generation. .

  The present invention has been made to solve the above problem, and has as its object to predict the amount of power generated by sunlight without obtaining information from the outside.

(1) One embodiment of the present invention is a calculation unit that calculates a first power generation amount in a first direction and a second power generation amount in a second direction between sunrise time and a first time. And, based on the first power generation amount calculated by the calculation unit, predicts a first total power generation amount that is a total power generation amount per day from the sunrise time , and based on the second power generation amount, A prediction unit that predicts a second total power generation that is a total power generation per day from the time of the sunrise, the first total power generation predicted by the prediction unit, and the second total power generation, An output unit that determines whether the day is sunny or not, and outputs a control signal for controlling the controlled device in accordance with the determination result of whether the day is sunny or not. is there.

( 2 ) In one aspect of the present invention, in the power generation amount prediction device according to (1 ), the prediction unit predicts whether the first total power generation amount exceeds a total power generation amount threshold. It is a quantity prediction device.

( 3 ) In one embodiment of the present invention, in the power generation amount prediction device according to the above (1) or ( 2), the calculation unit performs the calculation for a second time after the elapse of the first time. A third power generation amount, and the prediction unit predicts a power generation amount after the first power generation amount is calculated based on the third power generation amount calculated by the calculation unit. Device.

( 4 ) In one aspect of the present invention, in the power generation amount prediction device according to any one of (1) to ( 3 ), a first sensor and information indicating information detected by the first sensor. An information storage unit that stores the first detection information, wherein the calculation unit calculates the first power generation amount from the first detection information stored by the information storage unit. .

( 5 ) In one embodiment of the present invention, in the power generation amount prediction device according to ( 4 ), the first sensor is installed facing east, and detects the amount of solar radiation or the amount of power generation from the time of the sunrise. , A power generation amount prediction device.

( 6 ) One embodiment of the present invention is the power generation amount prediction device according to ( 4 ) or ( 5 ), further including a second sensor, wherein the information storage unit stores information detected by the second sensor. Is a power generation amount prediction device that accumulates second detection information indicating the second power generation amount from the sunrise time to the first time.

( 7 ) In one embodiment of the present invention, in the power generation amount prediction device according to the above ( 7 ), the second sensor is installed facing south, and detects the amount of solar radiation or the amount of power generation from the time of the sunrise. , A power generation amount prediction device.

(8) One aspect of the present invention is a power generation amount prediction method executed by the power generation amount prediction device , wherein the first power generation amount between the time of sunrise and the first time and the second direction Calculating a second power generation amount, and predicting a first total power generation amount, which is a total power generation amount per day, from the sunrise time based on the first power generation amount calculated in the calculating step. And a step of predicting a second total power generation amount, which is a total power generation amount per day, from the time of the sunrise based on the second power generation amount, and the first total power generation amount predicted in the predicting step. Determining whether or not the day is sunny in accordance with the second total power generation amount, and outputting a control signal for controlling the control target device in accordance with the determination result as to whether or not the day is sunny. And a power generation amount prediction method .

  According to the embodiment of the present invention, it is possible to predict the amount of power generated by sunlight without obtaining information from outside.

It is a figure which shows the relationship between time and the amount of solar radiation in the day when it is fine during the day. It is a figure which shows the relationship between time and the amount of solar radiation in the day when it becomes cloudy during the day. It is a figure showing an example of a power generation amount prediction device concerning an embodiment. It is a figure showing the example of use of the power generation amount prediction device concerning an embodiment. It is a figure showing an example of operation of a power generation amount prediction device concerning an embodiment. It is a figure showing an example of a power generation amount prediction device concerning an embodiment. It is a figure showing the example of use of the power generation amount prediction device concerning an embodiment. It is a figure showing an example of operation of a power generation amount prediction device concerning an embodiment. It is a figure showing the example of application of the power generation amount prediction device concerning an embodiment. It is a figure showing operation of an example of application of a power generation amount prediction device concerning an embodiment.

<First embodiment>
<Power generation amount prediction device>
The power generation amount prediction device according to the embodiment predicts the amount of solar power generation using characteristics of the amount of solar radiation obtained from a sensor such as a pyranometer installed facing east.
FIG. 1 shows the relationship between time and the amount of solar radiation on a day when the weather is fine during the day. The upper diagram in FIG. 1 shows the characteristics of the solar radiation in the south direction, and the lower diagram shows the characteristics of the solar radiation in the east direction. According to FIG. 1, the amount of eastward solar radiation before and after about one hour from sunrise on a sunny day becomes twice or more the numerical value of the southward solar radiation.

FIG. 2 shows the relationship between time and the amount of solar radiation on a cloudy day during the day. The upper diagram in FIG. 2 shows the characteristics of the solar radiation in the south direction, and the lower diagram shows the characteristics of the solar radiation in the east direction. According to FIG. 2, on a cloudy day during the day, the eastward solar radiation before and after about one hour from sunrise has a similar or reduced numerical value compared to the southern solar radiation. Become.
The power generation amount prediction device according to the embodiment uses the fact that the amount of eastward solar radiation and the amount of southward solar radiation for about several hours from sunrise in fine weather or cloudy weather are different, and the power generation amount throughout the day is a certain amount. Predict whether to exceed.

FIG. 3 is a diagram illustrating a power generation amount prediction device according to the embodiment. The power generation amount prediction device 100 is installed near a solar power generation facility, and includes a sensor 102, a data storage device 104, and a control unit 106. The control unit 106 is connected to the control target device 108.
The sensor 102 is configured by a pyranometer or the like, and detects the amount of solar radiation. Specifically, the sensor 102 is installed such that the sensing part of the sensor 102 faces east. Further, the sensor 102 is installed such that a surface serving as a sensitive part of the sensor 102 is perpendicular to the ground surface. The sensor 102 outputs information indicating the detected amount of solar radiation to the data storage device 104.
The data storage device 104 is connected to the sensor 102 and stores information indicating the amount of solar radiation output by the sensor 102. Thus, the data storage device 104 accumulates the time transition of the information indicating the amount of solar radiation.

The control unit 106 is realized by an arithmetic processing device such as a CPU (Central Processing Unit) executing a power generation prediction algorithm. When information indicating the amount of solar radiation is stored in the data storage device 104, the control unit 106 converts the stored amount of solar radiation into the amount of power generation. Specifically, the control unit 106 calculates the product of the system capacity, the amount of solar radiation, and the loss coefficient to obtain the amount of power generation. Here, the loss coefficient is obtained in advance by the product of the temperature-dependent loss coefficient, the power conditioner conversion efficiency, and other correction coefficients.
The control unit 106 sets the time when the amount of generated power rapidly increases as the time of sunrise. Specifically, the control unit 106 sets the time when the rate of increase in the amount of generated power is equal to or greater than a predetermined value of the rate of increase in the amount of generated power as the time of sunrise. Here, the power generation amount increase rate threshold is an increase rate of the power generation amount when it can be regarded as sunrise in the relationship between time and the power generation amount.

  The control unit 106 calculates a first power generation amount Ep1 from the time of the sunrise to the first time. Here, the first time is a time for obtaining a power generation amount for determining whether a day from sunrise is sunny or not, and is a time period in which the power generation amount can be predicted most effectively. Is done. Specifically, the first time may be about one hour to two hours near sunrise. The first power generation amount Ep1 indicates the power generation amount during the first time. The control unit 106 predicts that the first power generation amount Ep1 is fine when the first power generation amount Ep1 is equal to or more than the first fine weather identification threshold value Cf1, and that the first power generation amount Ep1 is less than the first fine weather identification threshold value Cf1. Predicts that the weather is not sunny. Here, the first fine weather identification threshold value Cf1 indicates a power generation amount from sunrise time to a first time when the weather is fine, and is set in advance. In the present embodiment, as an example other than the fine weather, the case where the cloudy weather is predicted will be described. When the weather is predicted to be fine, the total power generation on that day can be predicted to be equal to or greater than the total power generation threshold, and when it is predicted to be cloudy, the total power generation on that day can be predicted to be less than the total power generation threshold. Here, the total power generation threshold is the total power generation when the weather is fine, and is obtained in advance in accordance with the power generation by a solar power generation facility such as a solar panel. The control unit 106 performs control for fine weather when it is predicted to be sunny, and performs control for cloudy weather when it is predicted to be cloudy. Here, the control for fine weather and the control for cloudy weather are set in advance.

The control unit 106 calculates the second power generation amount Ep during the power generation amount measurement time interval at each power generation amount measurement time interval after the first time has elapsed from the time of sunrise. Here, the power generation amount measurement time interval indicates a time for obtaining a power generation amount for determining whether or not fine weather continues, and is a time period in which the power generation amount can be predicted most effectively, and is set in advance. You. Specifically, the power generation amount measurement time interval is about one hour to two hours. The second power generation amount Ep indicates the power generation amount at the power generation amount measurement time interval. When the second power generation amount Ep is equal to or less than the power generation end value Ce, the control unit 106 switches to control for cloudy weather and outputs a control signal for cloudy weather to the control target device 108. Here, the power generation end value Ce indicates a power generation amount at a power generation amount measurement time interval during the day when the weather is fine, and is set in advance. When the second power generation amount Ep is equal to or less than the power generation end value Ce, the control unit 106 switches to control for cloudy weather and outputs a control signal for cloudy weather to the control target device 108.
When the control target device 108 acquires the control signal output by the control unit 106, it operates according to the control signal.

  FIG. 4 is a diagram illustrating an example of use of the power generation amount prediction device according to the embodiment. FIG. 4 shows a mount on which the solar panel is mounted, and the solar panel is mounted on the mount. The power generation amount prediction device 100 is connected to the solar panel, and the sensor 102 of the power generation amount prediction device 100 is installed with the sensing part of the sensor 102 facing east. Further, the sensor 102 is installed such that a surface serving as a sensitive part of the sensor 102 is perpendicular to the ground surface.

<Operation of the power generation prediction device>
FIG. 5 is a flowchart illustrating an example of the power generation amount prediction device 100 according to the embodiment. The sensor 102 outputs information indicating the detected amount of solar radiation to the data storage device 104. The data storage device 104 stores information indicating the amount of solar radiation output by the sensor 102.
In step S502, when information indicating the amount of solar radiation is stored in the data storage device 104, the control unit 106 of the power generation amount prediction device 100 converts the stored amount of solar radiation into the amount of power generation. The control unit 106 determines whether or not it is sunrise by detecting a rapid change in the amount of power generation. If no sunrise is detected, the process returns to step S502.
In step S504, when detecting the sunrise, the control unit 106 of the power generation amount prediction apparatus 100 obtains the first power generation amount Ep1 from the sunrise time to the first time. The control unit 106 determines whether or not the first power generation amount Ep1 is equal to or greater than a first fine weather identification threshold value Cf1.
In step S506, when the first power generation amount Ep1 is equal to or more than the first fine weather identification threshold value Cf1, the control unit 106 predicts that the weather is fine.
In step S508, when predicting that the weather is fine, the control unit 106 performs control for fine weather. The control unit 106 outputs a control signal for fine weather to the control target device 108.

In step S510, after outputting the control signal for fine weather to the control target device 108, the control unit 106 obtains the second power generation amount Ep during the power generation amount measurement time interval at each power generation amount measurement time interval. The control unit 106 determines whether or not the second power generation amount Ep is equal to or less than the power generation end value Ce. If the second power generation amount Ep is not equal to or smaller than the power generation end value Ce, the control unit 106 returns to step S510.
In step S512, when the second power generation amount Ep is equal to or smaller than the power generation end value Ce, the control unit 106 performs control for cloudy weather. The control unit 106 outputs a control signal for cloudy weather to the control target device 108. Thereafter, the process returns to step S502.
In step S514, when the control unit 106 determines in step S504 that the first power generation amount Ep1 is not equal to or greater than the first fine weather identification threshold value Cf1, the control unit 106 predicts that the sky is cloudy.
In step S516, when the control unit 106 predicts that the sky is cloudy, it performs control for cloudy sky. The control unit 106 outputs a control signal for cloudy weather to the control target device 108. Thereafter, the process returns to step S502.
In the flowchart shown in FIG. 5, the process of step S510 is described to be performed only once during the day. However, when the control for fine weather is performed, a plurality of processes are performed at arbitrary time intervals during the day. May be performed multiple times.

  In the above-described embodiment, the first power generation amount Ep1 from the time of the sunrise to the first time is obtained, and it is determined whether the first power generation amount Ep1 is equal to or more than the first fine weather identification threshold value Cf1. However, the present invention is not limited to this example. For example, the first power generation amount Ep1 during a first time after a predetermined time has elapsed from the time of sunrise is determined, and the first power generation amount Ep1 is equal to or more than a first fine weather identification threshold value Cf1. The determination may be made as to whether or not it is not. Here, the predetermined time is a time from sunrise until the amount of solar radiation is stabilized, and is about one hour.

  According to the power generation amount prediction device according to the embodiment, the time when the power generation amount rapidly increases is obtained from the information indicating the solar radiation amount acquired from the sensor 102 installed facing east, and the time from the time to the first time is calculated. The first power generation amount Ep1 is determined, and it is determined whether the first power generation amount Ep1 is equal to or greater than a first fine weather identification threshold value Cf1. As a result, it can be determined whether or not the total power generation on that day is equal to or greater than the total power generation threshold. That is, it is possible to predict the amount of power generated by the photovoltaic power generation facilities during the day without obtaining external information such as weather information via the Internet, a TV, a radio, or the like.

<Second embodiment>
<Power generation amount prediction device>
The power generation amount prediction device according to the embodiment predicts the amount of solar power generation using characteristics of the amount of solar radiation obtained from a sensor such as a pyranometer installed eastward and a sensor such as a pyranometer installed southward. I do.
FIG. 6 is a diagram illustrating the power generation amount prediction device according to the embodiment. The power generation amount prediction device 200 includes a sensor 202, a sensor 203, a data storage device 204, and a control unit 206. The control unit 206 is connected to the control target device 208.
The sensor 102 can be applied to the sensor 202 and the sensor 203. However, the sensor 202 is installed such that the sensing part of the sensor 102 faces east, and the sensor 203 is installed such that the sensing part of the sensor 203 faces south. In addition, the sensor 202 is installed such that the surface serving as a sensitive part of the sensor 202 is perpendicular to the ground surface, and the sensor 203 is provided such that the surface serving as the sensitive part of the sensor 203 has the same angle and the same angle as the solar panel. You.
The data storage device 204 can apply the data storage device 104. However, the data storage device 204 stores information indicating the amount of solar radiation output by the sensors 202 and 203. Thus, the data storage device 204 stores the time transition of the information indicating the amount of solar radiation output by the sensors 202 and 203.

The control unit 206 is realized by an arithmetic processing device such as a CPU executing a power generation prediction algorithm. The control unit 206 can apply the control unit 106. When information indicating the amount of solar radiation is stored in the data storage device 204, the control unit 206 converts the stored amount of solar radiation into the amount of power generation. The control unit 206 determines, among the information indicating the amount of solar radiation stored in the data storage device 204, the time when the amount of power generation obtained from the amount of solar radiation output from the sensor 202 installed eastward sharply increases is the time of sunrise. Time. Specifically, the control unit 206 sets the time when the increase rate of the power generation amount obtained from the amount of solar radiation output from the sensor 202 is equal to or more than a predetermined increase rate threshold value as the time of sunrise.
The control unit 206 obtains a first power generation amount Ep11 obtained from the insolation amount output from the sensor 202 installed eastward between the time of the sunrise and the first time. Here, the first power generation amount Ep11 is the power generation amount by the sensor 202 installed eastward during the first time. In addition, the control unit 206 obtains a second power generation amount Sp11 obtained from the amount of solar radiation output from the sensor 203 installed southward between the time of the sunrise and the first time. Here, the second power generation amount Sp11 is the power generation amount by the sensor 203 installed facing south during the first time.

The control unit 206 determines whether or not the first power generation amount Ep11 is equal to or greater than a value “Sp11 × a” obtained by multiplying the first power generation amount Sp11 by the coefficient a. Here, the coefficient “a” is used for comparing the first power generation amount Ep11 with the second power generation amount Sp11, and is changed according to the season. For example, “a” in December is “2.0”, and “a” in April is “1.5”.
When the first power generation amount Ep11 is equal to or more than the value obtained by multiplying the first power generation amount Sp11 by the coefficient a, the control unit 206 predicts that the weather is fine, and the first power generation amount Ep11 becomes the first power generation amount. If it is less than the value obtained by multiplying Sp11 by the coefficient a, it is predicted that the sky is cloudy. The control unit 206 performs control for fine weather when it is predicted to be fine, and performs control for cloudy when it is predicted to be cloudy.
The control target device 208 can apply the control target device 108.

  FIG. 7 is a diagram illustrating a usage example of the power generation amount prediction device according to the embodiment. FIG. 7 shows a gantry on which a solar panel is mounted, on which the solar panel is mounted. The solar panel is connected to the power generation amount prediction device 200, and the sensor 202 of the power generation amount prediction device 200 is installed with the sensing part of the sensor 202 facing east, and the sensor 203 of the power generation amount prediction device 200 is connected to the sensor. The sensing part 202 is installed facing south, in the same direction as the solar panel, and at the same angle.

<Operation of the power generation prediction device>
FIG. 8 is a flowchart illustrating an example of the power generation amount prediction device 200 according to the embodiment.
The sensors 202 and 203 output information indicating the detected amount of solar radiation to the data storage device 204. The data storage device 204 stores information indicating the amount of solar radiation output by the sensors 202 and 203.
In step S802, step S502 in FIG. 5 can be applied.
In step S804, when detecting the sunrise, the control unit 206 of the power generation amount prediction device 200 obtains the value from the amount of solar radiation output from the sensor 202 installed eastward between the time of the sunrise and the first time. The first power generation amount Ep11 is obtained. Further, the control unit 206 obtains a second power generation amount Sp11 obtained from the amount of solar radiation output from the sensor 203 installed southward between the time of sunrise and the first time. The control unit 206 determines whether the first power generation amount Ep11 is equal to or greater than a value obtained by multiplying the first power generation amount Sp11 by the coefficient a.
In step S806, when the first power generation amount Ep11 is equal to or greater than the value obtained by multiplying the first power generation amount Sp11 by the coefficient a, the control unit 206 predicts that the weather is fine.
Steps S808-S812 can apply steps S508-S512 of FIG.
In step S814, when the first power generation amount Ep11 is less than the value obtained by multiplying the first power generation amount Sp11 by the coefficient a, the control unit 206 predicts that the weather is cloudy.
Step S806 can apply step S816 of FIG.

  In the above-described embodiment, the first power generation amount Ep11 obtained from the solar radiation amount output from the sensor 202 installed eastward between the time of sunrise and the first time is obtained, and the first power generation amount Ep11 obtained is installed southward. A second power generation amount Sp11 obtained from the solar radiation amount output from the sensor 203 obtained is determined, and it is determined whether the first power generation amount Ep11 is equal to or greater than a value obtained by multiplying the first power generation amount Sp11 by a coefficient a. Although the case has been described, the present invention is not limited to this example. For example, the first power generation amount Ep11 obtained from the insolation output from the sensor 202 installed eastward during a first time after a predetermined time has elapsed from the time of sunrise is obtained, The second power generation amount Sp11 obtained from the solar radiation amount output from the sensor 203 installed in the south direction is obtained, and the first power generation amount Ep11 is equal to or larger than a value obtained by multiplying the first power generation amount Sp11 by the coefficient a. The determination may be made as to whether or not the answer is NO. Here, the predetermined time is a time from sunrise until the amount of solar radiation is stabilized, and is about one hour.

  According to the power generation amount prediction device according to the embodiment, the time when the power generation amount rapidly increases is obtained from the information indicating the amount of solar radiation acquired from the sensor 202 installed in the east direction, and between the time and the first time. A first power generation Ep11 obtained from the solar radiation output from the sensor 202 installed eastward is obtained, and a second power generation obtained from the solar radiation output from the sensor 203 installed southward Sp11 is determined, and it is determined whether the first power generation amount Ep11 is equal to or greater than a value obtained by multiplying the first power generation amount Sp11 by the coefficient a. Thereby, it is possible to determine whether or not the power generation on that day is equal to or greater than the total power generation threshold. That is, the daytime solar power generation can be predicted without obtaining external information such as weather information through the Internet, a TV, a radio, or the like.

<Application example>
An application example of the power generation amount prediction device according to the above-described embodiment will be described.
FIG. 9 is a diagram illustrating a power supply system to which the power generation amount prediction device according to the embodiment is applied. Specifically, the power supply system is applied to the control target device 108 of the power generation amount prediction device 100 according to the above-described embodiment.
The power supply system supplies power to the communication facility 10 as a load. The power supply system includes a solar cell 11, a DC / DC converter 12, a power failure monitoring unit 13, a generator 14, a rectifier 15, a storage battery 16, an overdischarge prevention unit 17, and a control unit 18. The solar cell 11, the DC / DC converter 12, the power failure monitoring unit 13, the generator 14, the rectifier 15, the storage battery 16, the overdischarge prevention unit 17, and the control unit 18 are arranged adjacent to the communication facility 10.

  The solar cell 11 generates power when receiving power that can be generated regardless of whether or not the commercial power supply that supplies power to the communication facility 10 is out of power. The solar cell 11 supplies the generated power to the communication facility 10. The maximum power generated by the solar cell 11 is the sum of the power required by the communication facility 10 and the power capable of storing the storage battery 16. The power generated by the solar cell 11 is supplied to the communication facility 10 with priority. When the solar cell 11 generates power higher than the power required by the communication facility 10, surplus power higher than the power required by the communication facility 10 is charged into the storage battery 16. Further, when power is supplied from the solar cell 11 to the communication facility 10 during a non-power outage, power is supplied from a commercial power supply if the power from the solar cell 11 is not sufficient for the communication facility 10.

The DC / DC converter 12 is connected downstream of the solar cell 11. The DC / DC converter 12 has an MPPT (Maximum Power Point Tracking) function.
The power failure monitoring unit 13 monitors whether or not the commercial power supply has failed. The power failure monitoring unit 13 supplies the monitoring result to the control unit 18.
The generator 14 operates when a commercial power supply that supplies power to the communication facility 10 is out of power, and can supply power to the communication facility 10. The generator 14 operates based on the control of the control unit 18 when the commercial power supply stops. The rectifier 15 is connected downstream of the generator 14. The rectifier 15 is, for example, an AC / DC converter. The generator 14 generates power so that the power output from the rectifier 15 has the power required by the communication facility 10 and the power capable of storing the storage battery 16.

The storage battery 16 can be stored by the power supplied by the solar cell 11 and the power supplied by the generator 14. The storage battery 16 can supply the stored power to the communication facility 10. The storage battery 16 does not supply the stored power to the communication facility 10 if the communication facility 10 can be operated by the power supplied by the solar cell 11 when the commercial power supply is interrupted. Various types of storage batteries such as a lead storage battery, a lithium ion battery, or a nickel hydride storage battery can be used as the storage battery 16.
The over-discharge prevention unit 17 prevents the storage battery 16 from being over-discharged. The overdischarge prevention unit 17 is realized by, for example, a switch. The overdischarge prevention unit 17 is controlled by the control unit 18 based on the voltage of the storage battery 16.

The control unit 18 operates the generator 14 when the voltage value corresponding to the electric power stored in the storage battery 16 becomes equal to or lower than a predetermined lower limit voltage value when the commercial power supply stops, and the control unit 18 responds to the electric power stored in the storage battery 16. When the voltage value reaches a predetermined upper limit voltage value, the generator 14 is stopped.
The control unit 18 changes both the lower limit voltage value and the upper limit voltage value according to the condition regarding the power generation of the solar cell 11. The condition relating to the power generation of the solar cell 11 is an estimation of the power generation amount of the solar cell 11. The control unit 18 sets the lower limit voltage value and the upper limit voltage value lower when the power generation amount of the solar cell 11 is expected to be equal to or more than the predetermined amount than when the power generation amount of the solar cell 11 is expected to be less than the predetermined amount. I do. For example, when the amount of power generation of the solar cell 11 is expected to be equal to or more than a predetermined amount, the lower limit voltage value and the upper limit voltage value are respectively a third voltage (first lower limit voltage value) V3 and a fourth voltage (first lower limit voltage value). (Upper limit voltage value) V4. When the amount of power generated by the solar cell 11 is expected to be less than the predetermined amount, the lower limit voltage value and the upper limit voltage value are respectively equal to the first voltage (second lower limit voltage value) V1 and the second voltage (second (Upper limit voltage value) V2. Here, V3 <V1 and V4 <V2. The third voltage V3 is higher than the voltage when the storage battery 16 is overdischarged. Here, an example of the predetermined amount is the above-described total power generation amount threshold.

  The first voltage V1 is a lower limit voltage of the storage battery 16 at night or when the amount of power generated by the solar cell 11 is expected to be less than a predetermined amount. The second voltage V2 is a recovery voltage of the storage battery 16 at night or when the power generation amount of the solar cell 11 is expected to be less than a predetermined amount. The third voltage V3 is a lower limit voltage of the storage battery 16 when the amount of power generated by the solar cell 11 is expected to be equal to or more than a predetermined amount. The fourth voltage V4 is a recovery voltage of the storage battery 16 when the power generation amount of the solar cell 11 is expected to be equal to or more than a predetermined amount. The selection between the setting of the first voltage V1 and the second voltage V2 or the setting of the third voltage V3 and the fourth voltage V4 is made, for example, for fine weather output by the control unit 106 of the power generation amount prediction device 100. Or the control signal for cloudy weather. This is because the power supply from the storage battery 16 is lengthened by lowering the voltage expected in the power generation of the solar cell 11, thereby delaying the activation of the generator 14 and reducing the number of activations and the activation time. That is, fuel is saved.

When the control unit 18 acquires the control signal output by the control unit 106 of the power generation amount prediction device 100, the control unit 18 acquires a condition regarding power generation of the solar cell 11 based on the control signal.
When the power generation amount of the solar cell 11 is expected to be less than the predetermined amount based on the control signal output by the control unit 106 of the power generation amount prediction device 100, the control unit 18 performs the control at a predetermined first time (morning or noon). Then, the first voltage V1 and the second voltage V2 are set. When the power generation amount of the solar cell 11 is expected to be equal to or more than the predetermined amount based on the control signal output by the control unit 106 of the power generation amount prediction device 100, the control unit 18 performs the control at the predetermined first time (morning or noon) Then, the third voltage V3 and the fourth voltage V4 are set. At a predetermined second time (evening), the controller 18 sets the first voltage V1 and the second voltage V2. That is, when the control unit 106 outputs the control signal for fine weather, the control unit 18 sets the third voltage V3 and the fourth voltage V4. When the control unit 106 outputs a control signal for cloudy weather, the control unit 18 sets the first voltage V1 and the second voltage V2.
When the voltage of the storage battery 16 becomes equal to or lower than the first voltage V1 or the third voltage V3, sufficient power cannot be supplied from the storage battery 16 to the communication facility 10, so that the control unit 18 starts the generator 14. Thereby, the electric power generated by the generator 14 is supplied to the communication facility 10 and used for charging the storage battery 16. Here, when the voltage of the storage battery 16 becomes equal to or lower than the first voltage V1 or the third voltage V3, the generator 14 is started to charge the storage battery 16, so that the storage battery 16 does not overdischarge, and the life of the storage battery 16 is reduced. Can be extended.

When the voltage of the storage battery 16 becomes the second voltage V2 or the fourth voltage V4, it means that the voltage of the storage battery 16 has recovered, and the control unit 18 stops the generator 14. Thereby, power is supplied from the solar battery 11 or the storage battery 16 to the communication facility 10. Thereafter, the above-described processing is repeated until the power failure of the commercial power supply is restored.
When the amount of power generated by the solar cell 11 is expected to be less than the predetermined amount, the reason for setting the first voltage V1 and the second voltage V2 is that it is impossible to operate the communication facility 10 using only the power generated by the solar cell 11. This is because it is possible and there is a high possibility that power is supplied to the communication facility 10 from the generator 14 or the storage battery 16.

<Operation of power supply system>
FIG. 10 is a diagram illustrating an operation of an application example of the power generation amount prediction device according to the embodiment. FIG. 10 is a diagram for explaining the operation of the power supply system that operates using the determination result of whether or not the total power generation of the day predicted by the power generation prediction device according to the embodiment is equal to or more than the total power generation threshold. FIG. In FIG. 10, the horizontal axis indicates time, and the vertical axis indicates the voltage of the power generation amount and the voltage of the storage battery. The line “A” indicates the voltage of the storage battery 16, the line “B” indicates the power generation amount of the solar cell 11, and the line “C” indicates the power generation amount of the generator 14.
The first voltage V1, the second voltage V2, the third voltage V3, and the fourth voltage V4 are set to values at which the fuel efficiency of the generator 14 is most efficient so that the maximum power is at the output side of the rectifier 15. Is done. The first voltage V1 and the third voltage V3 are the discharge lower limit voltage value of the storage battery 16 and the starting voltage value of the generator 14. The second voltage V2 and the fourth voltage V4 are charging upper limit voltage values of the storage battery 16 and stop voltage values of the generator 14. The first voltage V1 to the fourth voltage V4 are set based on a certain experience and knowledge, and may each be three or more.

  When a power failure occurs (time T1), power is supplied from the solar battery 11 or the storage battery 16 to the communication facility 10. When the communication facility 10 can be operated only by the power of the solar cell 11, no power is supplied from the storage battery 16 to the communication facility 10. When the communication facility 10 cannot be operated only by the power generated by the solar cell 11, power is also supplied to the communication facility 10 from the storage battery 16. Before the solar cell 11 generates electric power for operating the communication equipment (“B1” shown in FIG. 10), the control unit 106 of the power generation amount prediction device 100 Based on the result of the prediction, one of a combination of the first voltage V1 and the second voltage V2 and a combination of the third voltage V3 and the fourth voltage V4 are selected. Here, the generator 14 is not operated immediately after a power failure, so that the fuel of the generator 14 is saved.

  At time T2, since the voltage A of the storage battery 16 has reached the predetermined lower limit voltage value, the control unit 18 starts the generator 14. Here, since the time T2 is night, the predetermined lower limit voltage value is the first voltage V1. The electric power generated by the generator 14 is used for operating the communication facility 10 and for charging the storage battery 16. As a result, the voltage of the storage battery 16 increases.

At time T3, since the voltage A of the storage battery 16 has reached the predetermined upper limit voltage value, the control unit 18 stops the generator 14. Here, since the time T3 is night, the predetermined upper limit voltage value is the second voltage V2. After time T3, power is supplied from the storage battery 16 to the communication facility 10. As a result, the generator 14 does not consume fuel.
After time T3, when the voltage of the storage battery 16 reaches the predetermined lower limit voltage value, the generator 14 starts (time T4, time T6), and the voltage A of the storage battery 16 becomes the predetermined upper limit voltage value. In this case, the operation of stopping the generator 14 (time T5, time T7) is repeated.

At time T8, when the solar cell 11 starts generating power, the generated power is used for operating the communication facility 10 and for charging the storage battery 16. Note that, before time T8, the control unit 18 determines the combination of the first voltage V1 and the second voltage V2 and the combination of the third voltage V3 and the fourth voltage V4 based on the prediction of the power generation amount of the solar cell 11. And either one is selected. Thereby, the voltage of the storage battery 16 increases. Since the generator 14 is not operated unless the voltage of the storage battery 16 becomes equal to or lower than the first voltage V1 or the third voltage V3, the fuel consumed by the generator 14 is saved.
In the above-described power supply system, a case where the power supply system is applied to the control target device 108 of the power generation amount prediction device 100 has been described as an example, but the invention is not limited to this example. For example, a power supply system may be applied to the control target device 208 of the power generation amount prediction device 200.

  According to the power supply system according to the present embodiment, the solar battery 11 that supplies power to the communication facility 10 and the commercial power supply that supplies power to the communication facility 10 operate when a power failure occurs to supply power to the communication facility 10. It is possible to store the power by the generator 14 that can be supplied, the power supplied by the solar cell 11, and the power supplied by the generator 14, and communicate the stored power in the event of a commercial power failure. And a storage battery 16 that can be supplied to the facility 10. Thereby, the power supply system can supply power to the communication facility 10 even when the commercial power supply is interrupted.

  In addition, when the commercial power supply fails, the power supply system operates the generator 14 when the voltage value corresponding to the power stored in the storage battery 16 becomes equal to or lower than a predetermined lower limit voltage value, and the power stored in the storage battery 16 is reduced. When the corresponding voltage value reaches a predetermined upper limit voltage value, the generator 14 is stopped. Further, the power supply system changes both the lower limit voltage value and the upper limit voltage value in accordance with the condition regarding the power generation of the solar cell 11. Accordingly, the power supply system changes the reference for operating the generator 14 according to the conditions related to the power generation of the solar cell 11, so that the fuel consumption of the generator 14 can be suppressed. Further, since the power supply system 1 can suppress the fuel consumption of the generator 14, the power can be supplied to the communication facility 10 for a long time even when the commercial power supply is interrupted. The lower limit voltage value is set to a voltage value at which storage battery 16 does not overdischarge. Thereby, the power supply system 1 can suppress a decrease in the capacity of the storage battery 16.

In addition, the power supply system sets the lower limit voltage value and the upper limit voltage value when the power generation amount of the solar cell 11 is expected to be equal to or more than the predetermined amount than when the power generation amount of the solar cell 11 is expected to be less than the predetermined amount. Set lower. Specifically, even when the commercial power supply is stopped and the voltage V of the storage battery 16 is lower than the first voltage V1, when the power can be supplied from the solar cell 11 to the communication facility 10, the generator 14 It does not start. That is, when the voltage V of the storage battery 16 becomes equal to or lower than the third voltage V3 (<V1), the generator 14 starts. Further, when power can be supplied from the solar cell 11 to the communication facility 10, a lower voltage (the fourth voltage V <b> 4 (<4th voltage) than when power cannot be supplied from the solar battery 11 to the communication facility 10 can be expected. In V2)), the generator 14 stops. For this reason, the power supply system 1 can suppress the fuel consumption of the generator 14.
In addition, the power supply system acquires the condition regarding the power generation of the solar cell 11 based on the result of the determination as to whether or not the total power generation on the day predicted by the power generation prediction device described above is equal to or greater than the total power generation threshold. Thereby, the power supply system can set the predetermined lower limit voltage value and the predetermined upper limit voltage value according to the total power generation amount of the day.

In the power generation amount prediction device according to the above-described embodiment, a case where a pyranometer is applied as an example of the sensor 102 has been described, but the invention is not limited to this example. For example, a solar cell may be applied instead of a pyranometer.
In the power generation amount prediction device according to the above-described embodiment, the case where the time when the increase rate of the power generation amount is equal to or more than the predetermined increase rate threshold is the sunrise time is described, but the present invention is not limited to this example. For example, the time when the rate of increase in the amount of solar radiation is equal to or more than a predetermined threshold value of the rate of increase in the amount of solar radiation may be set as the time of sunrise.
In the power generation amount prediction device according to the above-described embodiment, the case where it is determined whether the day is sunny or cloudy has been described, but the present invention is not limited thereto. For example, it may be determined whether it is rainy weather in addition to fine weather and cloudy weather.
In the power generation amount prediction device according to the above-described embodiment, a case has been described in which it is determined whether the total power generation amount of the day is equal to or greater than the total power generation amount threshold value by determining whether the day is sunny or cloudy. However, this is not the case. For example, by determining whether it is rainy in addition to fine weather and cloudy weather, it may be determined which of a plurality of total power generation thresholds the total power generation on that day corresponds to.

  As described above, the embodiments of the present invention and the modifications thereof have been described. However, these embodiments and the modifications thereof have been presented as examples, and are not intended to limit the scope of the invention. These embodiments and their modifications can be implemented in other various forms, and various omissions, replacements, changes, and combinations can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and their equivalents.

Note that the above-described power generation amount prediction device has a computer inside. The process of each process of each device described above is stored in a computer-readable recording medium in the form of a program, and the above process is performed by reading and executing the program by the computer. Here, the computer-readable recording medium refers to a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Alternatively, the computer program may be distributed to a computer via a communication line, and the computer that has received the distribution may execute the program.
Further, the program may be for realizing a part of the functions described above.
Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

  In the above-described embodiment, east is an example of a first azimuth, the control unit is an example of a calculation unit, a prediction unit, and an output unit, and the first power generation amount Ep1 is an example of a first power generation amount. The south direction is an example of the second direction. The second power generation amount Sp11 is an example of a second power generation amount, the power generation amount measurement time interval is an example of a second time, and the second power generation amount Ep is an example of a third power generation amount. . The information indicating the amount of solar radiation is an example of first detection information and second detection information, the solar radiation system is an example of a first sensor and a second sensor, and the data storage unit is an information storage unit. This is an example.

  DESCRIPTION OF SYMBOLS 10 ... Communication equipment, 11 ... Solar battery, 12 ... DC / DC converter, 13 ... Power failure monitoring part, 14 ... Generator, 15 ... Rectifier, 16 ... Storage battery, 17 ... Overdischarge prevention part, 18 ... Control part, 100 200: power generation amount prediction device, 102: sensor, 104: data storage device, 106: control unit, 108: controlled device, 202: sensor, 203: sensor, 204: data storage device, 206: control unit, 208: control Applicable equipment

Claims (8)

A calculation unit that calculates a first power generation amount in a first direction from a sunrise time to a first time, and a second power generation amount in a second direction ;
Based on the first power generation amount calculated by the calculation unit , a first total power generation amount, which is a total power generation amount per day , is predicted from the sunrise time, and the sunrise time is calculated based on the second power generation amount. a prediction unit for predicting a second total generation is the total power generation amount of daily from the time of,
According to the first total power generation amount predicted by the prediction unit and the second total power generation amount, it is determined whether or not the day is sunny, and the determination result of whether or not the day is fine is An output unit for outputting a control signal for controlling the control target device in response to the request . The power generation amount prediction device according to claim 1, wherein the prediction unit predicts whether the first total power generation amount exceeds a total power generation amount threshold. The calculation unit calculates a third power generation amount during a second time after the elapse of the first time,
  3. The power generation amount according to claim 1, wherein the prediction unit predicts a power generation amount after calculating the first power generation amount based on the third power generation amount calculated by the calculation unit. 4. Prediction device. A first sensor;
An information storage unit that stores first detection information indicating information detected by the first sensor;
With
4. The power generation amount prediction device according to claim 1, wherein the calculation unit calculates the first power generation amount from the first detection information accumulated by the information storage unit. 5. The power generation prediction device according to claim 4, wherein the first sensor is installed facing east, and detects the amount of solar radiation or power generation from the time of the sunrise. Second sensor
With
The information storage unit stores second detection information indicating information detected by the second sensor,
The power generation amount prediction device according to claim 4 or 5, wherein the calculation unit calculates a second power generation amount between the time of the sunrise and a time of a first time. The power generation amount prediction device according to claim 6, wherein the second sensor is installed facing south, and detects the amount of solar radiation or the amount of power generation from the time of the sunrise. A power generation prediction method executed by the power generation prediction device,
Calculating a first power generation amount between a time of sunrise and a first time period, and a second power generation amount in a second direction;
Based on the first power generation amount calculated in the calculating step, a first total power generation amount, which is a total power generation amount per day, is predicted from the sunrise time, and based on the second power generation amount, Estimating a second total power generation, which is the total power generation per day, from the time of sunrise;
According to the first total power generation amount predicted in the predicting step and the second total power generation amount, it is determined whether or not the day is sunny, and the determination result as to whether or not the day is fine Outputting a control signal for controlling the controlled device in accordance with
, A power generation amount prediction method.

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