JP2017143470A - Control device, control system, control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control device, a control system, a control method, and a program that do not require installation of a sensor.SOLUTION: A control device 1 includes a power generation information acquisition unit 31, a determination unit 13 and a control signal transmission unit 32. The power generation information acquisition unit 31 acquires information indicating a power generation amount from a photovoltaic power generation system. The determination unit 13 determines whether a condition for performing device control is satisfied on the basis of the information indicating the power generation amount acquired by the power generation information acquisition unit 31. When the determination unit 13 determines that the condition for performing device control is satisfied, the control signal transmission unit 32 transmits a control signal.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a control device, a control system, a control method, and a program.

  The spread of products that can electrically control shading housing equipment such as curtains, window shutters, and blinds has begun. In addition, a mechanism for automatically controlling such a light-shielding housing facility using a HEMS (Home Energy Management System) is generally spreading.

  As a method for automatically controlling the shading housing equipment, a method using a preset timer is generally used. In addition, a method has been proposed in which a brightness sensor is provided in a control system and control is performed based on an input from the brightness sensor, such as the switchgear described in Patent Document 1.

JP2015-158092A

  The control method proposed in Patent Document 1 needs to include a brightness sensor in the control system. Therefore, there is a problem that it takes time and cost to separately install a brightness sensor and to set the brightness sensor when constructing the system. Moreover, when performing control by a general timer, there is a problem that it takes time and effort to periodically change the timer setting in order to cope with the sunrise and sunset times that change daily.

  SUMMARY An advantage of some aspects of the invention is that it provides a control device, a control system, a control method, and a program that do not require installation of a sensor.

  In order to achieve the above object, a control device according to the present invention includes a power generation information acquisition unit, a determination unit, and a control signal transmission unit. The power generation information acquisition unit acquires information indicating the power generation amount from the solar power generation system. The determination unit determines whether or not a condition for performing device control is satisfied based on the information indicating the power generation amount acquired by the power generation information acquisition unit. When the determination unit determines that the condition for device control is satisfied, the control signal is transmitted from the control signal transmission unit.

  According to the present invention, by acquiring information indicating the amount of power generation from the solar power generation system, automatic control of the electric light-shielding device can be realized without requiring installation of a sensor.

It is a figure which shows the system configuration example of the control system which concerns on Embodiment 1 of this invention. 3 is a functional block diagram of a control device according to Embodiment 1. FIG. It is a figure which shows an example of the past power generation information of the solar power generation system which the power generation information storage part which concerns on Embodiment 1 memorize | stores. It is a figure which shows an example of the electric power generation pattern at the time of summer fine weather which the electric power generation pattern memory | storage part which concerns on Embodiment 1 memorize | stores. It is a figure which shows an example of the control information which the control information storage part which concerns on Embodiment 1 memorize | stores. 3 is a flowchart of a control process according to the first embodiment. It is a figure which shows an example of the control information which the control information storage part which concerns on the modification of Embodiment 1 memorize | stores. 6 is a flowchart of control signal transmission processing to each device according to a modification of the first embodiment. It is a figure which shows the system configuration example of the control system which concerns on Embodiment 2 of this invention. 6 is a functional block diagram of a control device according to Embodiment 2. FIG. 6 is a flowchart of date and time correction processing of the control device according to the second embodiment. It is a figure which shows the system configuration example of the control system which concerns on Embodiment 3 of this invention. FIG. 6 is a functional block diagram of a control device according to Embodiment 3. 10 is a flowchart of control processing of the control device according to the third embodiment. It is a figure which shows an example of the control information which the control information storage part which concerns on Embodiment 3 memorize | stores. It is a functional block diagram of the control apparatus which concerns on Embodiment 4 of this invention. 10 is a flowchart of control processing of the control device according to the fourth embodiment. It is a figure which shows the system configuration example of the control system which concerns on Embodiment 5 of this invention. FIG. 10 is a functional block diagram of a control device according to a fifth embodiment. 10 is a flowchart of power generation pattern update processing according to the fifth embodiment. It is a figure which shows the hardware structural example of the control apparatus which concerns on this invention.

  Hereinafter, a control device, a control system, a control method, and a program according to embodiments of the present invention will be described in detail with reference to the drawings. In addition, the same code | symbol is attached | subjected to the part which is the same or it corresponds in a figure.

(Embodiment 1)
As shown in FIG. 1, the control system 1000 according to Embodiment 1 of the present invention includes a control device 1, a photovoltaic power generation system 2, and one or more electric light shielding devices 3.

  The control device 1 receives the power generation information from the solar power generation system 2, determines whether to control the electric light shielding device 3 based on the power generation information, and if it determines to control, the control device 1 sends a control signal to the electric light shielding device 3. Send to.

  The photovoltaic power generation system 2 includes a photovoltaic power generation module that outputs DC power, and a power conditioner that converts the DC power output by the photovoltaic power generation module into AC power.

  The electric shading device 3 is a facility that is installed indoors or outdoors in a building and is electrically openable and closable to block the passage of light indoors and outdoors. For example, an electric curtain, an electric blind, an electric screen, an electric shade, an electric shutter, Such as shutters. These have a function of receiving a control signal from the outside and opening and closing based on the received control signal. However, it may be one that can be manually opened and closed. In addition, the electric shading device 3 can have not only two states, that is, an open state that is a completely open state and a closed state that is a completely closed state, and a plurality of states between the open state and the closed state. There may be a staged state, that is, a state where it is partially opened. Then, there may be a function that can control which state of the plurality of stages is set by a control signal.

  As illustrated in FIG. 2, the control device 1 includes a control unit 10, a storage unit 20, a power generation information acquisition unit 31, and a control signal transmission unit 32 as functional configurations.

  The control unit 10 includes a CPU (Central Processing Unit), and functions of each unit (the control information acquisition unit 11, the estimation unit 12, and the determination unit 13) of the control device 1 by executing a program stored in the storage unit 20. Is realized. The control unit 10 also includes a timer 14 that continues to count the elapsed time since the power of the control device 1 is turned on.

  The control information acquisition unit 11 acquires control information stored in the storage unit 20. The control information includes control conditions and control contents.

  The estimation unit 12 estimates the current external environment based on the power generation information acquired from the power generation information acquisition unit 31.

  The determination unit 13 determines whether the current external environment estimated by the estimation unit 12 satisfies the control condition acquired by the control information acquisition unit 11. When it is determined that the determination unit 13 satisfies, the control unit 10 notifies the control signal transmission unit 32 of the control content acquired by the control information acquisition unit 11.

  The storage unit 20 includes a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The ROM stores programs executed by the CPU of the control unit 10 and data necessary for executing the programs in advance. The RAM stores data that is created or changed during program execution. The storage unit 20 includes a power generation information storage unit 21, a power generation pattern storage unit 22, a control information storage unit 23, and an automatic control switching information storage unit 24.

  The power generation information storage unit 21 stores power generation information indicating the power generation amount acquired by the power generation information acquisition unit 31. As shown in FIG. 3, the latest power generation amount is set as the power generation amount at time 0:00, and the power generation amount is stored together with the time information for the past 24 hours. Information before the past 24 hours is sequentially deleted. The power generation information storage unit 21 stores the value of the timer 14 included in the control unit 10 as this time information as it is, so that when generating the power generation amount from the power generation information storage unit 21, the power generation information storage unit 21. By subtracting the value of the current timer 14 from the value of the time information stored in, it is possible to know how much previous power generation amount from now.

  The power generation pattern storage unit 22 stores the power generation amount by time zone for each season and weather condition. The power generation amount by time zone is, for example, the power generation amount for each time zone at one hour intervals. If this hourly power generation amount is represented by a graph, as shown in FIG. 4, a pattern for each season and weather condition is shown. Therefore, data for 24 hours of hourly power generation amount is also referred to as a power generation pattern. FIG. 4 shows an example of the power generation pattern during clear weather in summer, but the power generation pattern during clear weather in other seasons is also stored. In addition, you may memorize | store the power generation pattern at the time of fine weather every month instead of every season.

  If the weather estimation described below is not required, the power generation pattern does not need to be accurate, just the length of the night time period of each season (monthly) (the length of time from sunset to sunrise the next day). You may just remember. Moreover, not only the power generation pattern in fine weather but also the power generation pattern in each season (each month) such as cloudy weather and rainy weather may be stored. If the power generation pattern in each weather is also stored, the accuracy of weather estimation can be improved.

  When the control device 1 is shipped from a factory or sold at a store, a typical power generation pattern corresponding to the use location of the user of the control device 1 is stored in the power generation pattern storage unit 22 in advance. When it is complicated to customize for each user, a typical power generation pattern in each country may be stored in the power generation pattern storage unit 22 for each shipping country.

  As shown in FIG. 5, the control information storage unit 23 stores conditions (control conditions) for controlling the electric light-shielding device 3 and control contents when the conditions are satisfied. The first example from the top in FIG. 5 is set to control to open the electric light-shielding device 3 30 minutes after sunrise. The second example from the top is set so that the electric light-shielding device 3 is closed 30 minutes before sunset.

  The control conditions are not limited to the time conditions, and conditions such as the estimated external environment such as season, weather, and brightness can be used, and these conditions can be set in combination. For example, the third example from the top in FIG. 5 is a setting for controlling to open the electric light-shielding device 3 if the estimated weather is clear and the estimated time is 3 hours after sunrise. Further, the fourth example from the top in FIG. 5 is a setting for performing control to close the electric light-shielding device 3 if the estimated brightness is less than 0.2.

  In addition, although not shown in the figure, for example, if the control information “summer and sunrise time” and control information “closed” are set, control to close the electric light-shielding device 3 at the sunrise time in summer is performed. Thus, strong sunlight in the summer can enter the room and prevent the room temperature from rising. For example, if the control information “winter and sunrise time” and control information “open” are set, the electric shading device 3 is controlled to open at the sunrise time in winter, and sunlight is emitted indoors in the winter morning. Can be put in.

  Similar to the power generation pattern storage unit 22, the control information storage unit 23 stores control information according to the desire of the user of the control device 1 when shipping from a factory or selling at a store. Alternatively, the user may be able to set after purchase. When enabling the user to set, the control device 1 includes an input unit configured by an input device such as a button or a touch panel, and the control unit 10 stores the content input from the input unit in the control information storage unit 23. Let

  Since there are usually a plurality of control conditions stored in the control information storage unit 23, the determination unit 13 determines the control conditions of the control information in order from the top, and there are control contents corresponding to those satisfying the control conditions. The control contents corresponding to the control condition that is finally satisfied are executed. Moreover, you may make it set a priority to each control condition. In this case, the control conditions are examined in descending order of priority, and the control content corresponding to the control condition that is initially satisfied is controlled. If it is desired to determine a plurality of control conditions at the same time, the same priority is set for them.

  The automatic control switching information storage unit 24 stores automatic control switching information indicating whether or not the electric light-shielding device 3 is automatically controlled. This is information about ON / OFF of the automatic control function, and can be switched ON / OFF by a user operation. When switching from OFF to ON occurs, a control process to be described later starts again from the beginning.

  The power generation information acquisition unit 31 acquires power generation information from the solar power generation system 2. The power generation information is information indicating the amount of power generation, and is the output voltage of the solar cell module or the output power of the power conditioner. When the output voltage of the solar cell module is used as the power generation information, the power generation information acquisition unit 31 may acquire the output voltage data of the solar cell module detected by the power conditioner. Moreover, when using the output power of the power conditioner as power generation information, a current sensor is attached to the power line extending from the power conditioner to the distribution board, and the measurement value of the current sensor is acquired by the power generation information acquisition unit 31. good. In addition, since a general photovoltaic power generation system is provided with a power generation amount monitor and the power generation amount is acquired by the latter method described above, it is not necessary to newly add sensors to construct this control system. .

  This power generation information is not an instantaneous value, but is preferably an integral value of the amount of power generated in a certain time such as a few seconds or a few minutes. Therefore, if necessary, the power generation information acquisition unit 31 is a solar cell module. And a circuit for integrating the output voltage of the power conditioner.

  The control signal transmission unit 32 transmits a control signal for performing the control indicated by the control content notified from the control unit 10 to the electric light shielding device 3. For example, if the control content is “open”, a command for opening the electric light-shielding device 3 is transmitted. There is no limitation on the communication interface between the control device 1 and the electric light-shielding device 3. Physically, it may be a wired communication interface such as Ethernet (registered trademark) or an HA terminal, or a wireless communication interface such as a wireless LAN (Local Area Network), Bluetooth (registered trademark), or infrared rays. As the communication protocol, a combination of TCP / IP and ECHONET Lite may be used, an infrared remote control signal protocol may be used, or another unique protocol may be used.

  In the first embodiment, even when there are a plurality of electric light-shielding devices 3, the individual devices cannot be controlled separately. Therefore, the control signal transmission unit 32 is the same for all the electric light-shielding devices 3. Send a control signal.

  Next, control processing performed by the control device 1 according to Embodiment 1 will be described with reference to FIG. The control process is started when the control program of the control device 1 is activated. First, the control unit 10 acquires automatic control switching information from the automatic control switching information storage unit 24, and determines whether or not the automatic control function of the electric light-shielding device 3 is ON (step S101). If the automatic control function is not ON (step S101; No), the process is terminated.

  When the automatic control function is ON (step S101; Yes), the control unit 10 acquires the current value of the power generation information from the power generation information acquisition unit 31 (step S102). Next, the control unit 10 stores the acquired power generation information in the power generation information storage unit 21 together with time information (step S103). This time information is the value of the timer 14 provided in the control unit 10.

  The storage in the power generation information storage unit 21 in step S103 may not be performed every time. For example, when a value such as 10 minutes, 30 minutes, 1 hour, etc. is set as the power generation information storage interval, and the value of the timer 14 has elapsed from this time stored in the power generation information storage unit 21 more than this power generation information storage interval By storing in the power generation information storage unit 21, the storage capacity of the power generation information storage unit 21 can be saved. In this case, if the value of the timer 14 is before the generation information storage interval elapses in step S103, the process proceeds to step S104 without doing anything.

  However, in order to improve the measurement accuracy of the length of the night time zone, when the power generation amount goes from 0 to 0, and conversely, from 0 to a positive value, the value of the timer 14 is Even if the power generation information storage interval has not elapsed, the time information and power generation information at that time are stored in the power generation information storage unit 21.

  Subsequently, the control unit 10 acquires the power generation information for the past 24 hours from the power generation information storage unit 21, and deletes the power generation information before the past 24 hours (step S104). Note that the generation information before the past 24 hours may be deleted in step S103 instead of step S104, and the remaining capacity that can be stored in the generation information storage unit 21 is normally set without being deleted. You may make it delete collectively when it becomes less than the value.

  Next, the control unit 10 acquires a power generation pattern stored in the power generation pattern storage unit 22 (step S105). Then, the estimation unit 12 estimates the season based on the power generation information for the past 24 hours, specifies the power generation pattern corresponding to the estimated season, and estimates the current external environment from the specified power generation pattern and the latest power generation information. (Step S106). The external environment includes time, weather, brightness, and the like. A method for estimating the external environment will be described later.

  Next, the control information acquisition unit 11 acquires the control condition and the control content stored in the control information storage unit 23 (step S107). Then, the determination unit 13 determines whether or not the current external environment estimated by the estimation unit 12 satisfies any of the control conditions acquired by the control information acquisition unit 11 (step S108). If neither is satisfied (step S108; No), the process returns to step S101.

  If either of them is satisfied (step S108; Yes), the process proceeds to step S109, and the control unit 10 acquires the control content acquired by the control information acquisition unit 11 (control content corresponding to the control condition determined to be satisfied in step S108). The control signal transmission unit 32 is notified. And the control signal transmission part 32 transmits the control signal for performing control shown by the control content notified from the control part 10 to the electrically-driven light-shielding apparatus 3 (step S109). Then, the process returns to step S101.

  Next, the external environment estimation in step S106 will be described. The estimation of the season is performed by measuring the length of the time zone in which the power generation amount is continuously zero. For example, the length of time during which power generation continues to be 0 is approximately 10 hours from 19:00 to 5:00 in the summer, while approximately 14 hours from 17:00 to 7:00 in the winter. is there. Therefore, it is possible to estimate whether the current season is close to summer or close to winter based on the length of the time zone in which the power generation amount in the past 24 hours is zero.

  In order to facilitate this estimation, it is also conceivable to set a period of 1 day, 3 days, 200 days, etc. as the long night storage period. This is because the storage unit 20 is further provided with a night long storage unit (not shown) for the number of days of the night long storage period, and the power generation amount every 24 hours is based on the power generation information stored in the power generation information storage unit 21. The length of the time zone that was 0 is stored every day in the night length storage unit. If you set the number of days longer than half a year as the night long memory period, you can see whether the length of the time zone when the power generation amount was 0 is increasing or decreasing in the period longer than half a year, The season can be estimated fairly accurately.

  For example, if the length of the time period in which the power generation amount was 0 has continued to increase for half a year, it can be estimated that it is now near the winter solstice. Conversely, if it has been decreasing for half a year, it can be estimated that it is near the summer solstice. Then, if there is a peak or bottom in the length of this time zone, it is possible to estimate the vicinity of the day as the winter solstice or the summer solstice, so it is possible to estimate the current month based on the number of days from there.

  Further, the current time can also be estimated based on the time zone in which the power generation amount is continuously zero. Specifically, if the time in the middle of the time period in which the power generation amount is continuously 0 is estimated as midnight, and the elapsed time from there to the present is determined based on the value of the timer 14, it is estimated. The current time (elapsed time from midnight). For example, assuming that the value of the timer 14 when the power generation amount changes from positive to 0 is Ts, the value of the timer 14 when the power generation amount changes from 0 to positive is Te, and the value of the current timer 14 is Tc. The current time (elapsed time from midnight) can be expressed as “Tc− (Ts + Te) ÷ 2” when Ts <Te, and “Tc− (Ts + Te) ÷ 2 + 12 hours” when Ts> Te. it can.

  Here, Ts and Te look at the power generation information stored in the power generation information storage unit 21 in chronological order from the past information, and the time information when the power generation amount is switched from a positive value to 0 is Ts, Time information at the time of switching from 0 to a positive value may be Te.

  In addition, if the power generation amount becomes greater than 0 after the power generation amount 0 continues for several hours or more, it can be estimated that the sunrise time has been reached, and after the power generation amount has once peaked, the power generation amount is at the sunrise time. It can be estimated that it is close to sunset when the value is equivalently low. Since the sunrise time and sunset time do not change significantly from those of the previous day, the values of the timer 14 at the sunrise time and sunset time of the previous day (corresponding to the above Te and Ts). It can also be estimated that the time when T hours have elapsed is “24-T hours before sunrise (sunset)”.

  The above-described seasonal estimation is possible as long as the power generation pattern information is at least the length of the time period in which the power generation amount is continuously zero. Furthermore, if the length of the time zone in which the power generation amount is continuously zero is stored in the night long storage unit for more than half a year, the power generation pattern information is based on the rate of change of the length of this time zone. The season can be estimated without it. Further, the estimation of the time described above can be performed based on the time zone in which the power generation amount is 0, even if there is no information on the power generation pattern. Therefore, when it is not necessary to estimate the weather described later, the information stored in the power generation pattern storage unit 22 may not be the power generation pattern, but simply the length of the night time zone for each season. Furthermore, if neither weather estimation nor seasonal estimation is required (and weather estimation is not required and seasonal estimation is performed based on information stored in the night long storage unit), the power generation pattern is not required. In this case, the power generation pattern storage unit 22 may be omitted.

  When only the power generation pattern at the time of fine weather is stored in the power generation pattern storage unit 22, the estimation of the weather is performed between the most recent actual power generation amount and the power generation amount at the estimated current time in the estimated power generation pattern at the time of fine weather in the season. This can be done based on the value of the ratio (“actual power generation amount” ÷ “power generation amount in the power generation pattern”). For example, if the ratio value is 0.8 or more, it can be estimated as “sunny”, 0.4 to less than 0.8, “cloudy”, and if it is less than 0.4, “rain”. However, this estimation is simply based on brightness and may differ from the actual weather. Therefore, the value of this ratio may be used as the value of “brightness” which is one of the information of the external environment.

  When the power generation pattern storage unit 22 also stores the power generation pattern for each weather, the weather and time are estimated based on the actual power generation amount for the past 24 hours stored in the power generation information storage unit 21 and the estimated season. This can be done by comparing the power generation pattern in each weather. At the time of comparison, the actual power generation amount data for the past 24 hours is compared with the power generation pattern while gradually shifting. The time for shifting is preferably set to a time equal to or shorter than the time corresponding to one time zone of the power generation pattern, such as 30 minutes or 1 hour. For example, when the actual power generation amount data for the past 24 hours is shifted by n hours, the power generation amount from n hours ago to the present time is followed by the power generation amount from 24 hours ago to n hours ago. Is used. When the most similar power generation pattern is found, the weather corresponding to the power generation pattern is estimated as the weather of the day. And the present | current time can be estimated based on the quantity which shifted the time of the actual electric power generation at that time. For example, if it is found that the power generation pattern is most similar to that in fine weather when shifted by n hours, the weather on this day is fine, and the current time can be estimated as n hours.

  However, this estimation is based on the assumption that the weather does not change throughout the day. When the weather changes, the actual power generation amount is compared with the power generation pattern of each weather in each time zone, and the weather corresponding to the closest power generation pattern is estimated as the weather in that time zone. It is possible to estimate the weather and current time in each time zone by using a known inference algorithm to determine how the power generation patterns can be combined to approximate the current actual power generation amount.

  As described above, according to the control system 1000 according to the first embodiment, an external device such as sunrise, sunset, brightness, and the like based on the power generation information of the solar power generation system without requiring a brightness sensor. The situation can be estimated, and a control signal suitable for the estimated situation can be transmitted to the electric light shielding device 3.

(Modification of Embodiment 1)
In the first embodiment described above, since there is no mechanism for designating a control target, all the electric light-shielding devices 3 included in the control system 1000 are collectively controlled when the control condition is satisfied. However, in an actual environment, there may be a case where it is desired to control a plurality of electric light-shielding devices 3 that may exist for each device. As one method for realizing control for each device, a configuration in which a control target is also stored in the control information storage unit 23 of the storage unit 20 is conceivable. A modification of the first embodiment will be described.

  The configuration of a control system 1000 according to a modification of the first embodiment is the same as that of the first embodiment and is shown in FIG. Further, the functional configuration of the control device 1 according to the modification of the first embodiment is the same as that of the first embodiment and is shown in FIG. However, the information of the control device, which will be described later, is added to the information stored in the control information storage unit 23 in FIG. 2 and the information of the control device is transmitted when a signal is transmitted from the control signal transmission unit 32. It is different in that the electric shading device 3 as a transmission destination can be specified by using.

  FIG. 7 is an example of the control information stored in the control information storage unit 23 according to the modification of the first embodiment. Compared with the control information storage unit 23 according to the first embodiment, the difference is that control device information (device ID) for uniquely identifying the electric light-shielding device 3 is added. In FIG. 7, the control device information (device ID) is shown as 001, 002, 003, etc. When the connection between the control device 1 and the electric light-shielding device 3 is, for example, Ethernet (registered trademark), the device ID is MAC. (Media Access Control) address may be used.

  The control signal transmission unit 32 according to the modification of the first embodiment transmits a control signal only to the electric light shielding device 3 specified by the information on the control device. As in the first embodiment, “all” can be designated as a special device ID (control device information) when all the electric light-shielding devices 3 are to be controlled collectively.

  In the example of FIG. 7, a setting is made to perform control to open the device with the device ID 001 among the electric light shielding devices 3 at the sunrise time. And the setting which controls to close all the electric light-shielding apparatuses 3 30 minutes before sunset is performed. Further, when the estimated weather is clear and 3 hours have passed since the sunrise time, a setting is made to control to open the device with the device ID 002 in the electric light shielding device 3. Then, if the estimated brightness is 0.8 or more, the setting is made so that the device with the device ID 003 among the electric light shielding devices 3 is opened.

  The flowchart of the control process according to the modification of the first embodiment is the same as that of the first embodiment and is shown in FIG. Compared with the first embodiment, the process of step S107 to step S109 is slightly changed with the addition of control device information to the information stored in the control information storage unit 23. explain.

  In step S107, the control information acquisition unit 11 acquires the control conditions, the control contents, and the control device information stored in the control information storage unit 23 (step S107). Then, the determination unit 13 determines whether or not the current external environment estimated by the estimation unit 12 satisfies any of the control conditions acquired by the control information acquisition unit 11 (step S108). If neither is satisfied (step S108; No), the process returns to step S101.

  If either of them is satisfied (step S108; Yes), the process proceeds to step S109, and the control unit 10 performs control corresponding to the control content acquired by the control information acquisition unit 11 and the control device (control condition determined to be satisfied in step S108). The control signal transmission unit 32 is notified of the content and the control device. Then, the control signal transmission unit 32 sends a control signal for performing the control indicated by the control content notified from the control unit 10 to the electric light shielding device 3 specified by the information on the control device notified from the control unit 10. Transmit (step S109). Then, the process returns to step S101.

  Details of the operation in step S109 will be described with reference to FIG. In step S111, the control unit 10 determines whether or not the information of the control device acquired in step S107 is “all” (step S111). If it is "all" (step S111; Yes), the control signal transmission part 32 will transmit a control signal to all the electrically connected light-shielding apparatuses 3 (step S112). If it is not “all” (step S111; No), the control signal transmission unit 32 transmits a control signal to the electric light shielding device 3 indicated by the control device information acquired by the control unit 10 in step S107 (step S113).

  As described above, according to the control system 1000 according to the modification of the first embodiment, the control signal can be transmitted to any electric light shielding device 3, so that separate control is performed for each individual electric light shielding device 3. Can be realized.

(Embodiment 2)
In Embodiment 1 and the modification thereof, the time information is estimated based on the power generation information from the solar power generation system 2, and thus an accurate time cannot be acquired. Further, depending on the contents of the power generation information, there is a possibility that a large error is included in the estimated time, and the electric light shielding device 3 cannot be controlled at an accurate time timing. A second embodiment for solving this problem will be described.

  As shown in FIG. 9, the configuration of the control system 2000 according to the second embodiment of the present invention includes a control device 1, a solar power generation system 2, one or more electric light shielding devices 3, and an NTP (Network Time Protocol). ) A server 4 and a network 9 for connecting the control device 1 and the NTP server 4 are provided. Any method may be used for the network 9. For example, Ethernet (registered trademark), HAN (Home Area Network) using a specific low power radio, or the like can be used. In FIG. 9, the control device 1 and the electric light shielding device 3 are directly connected separately from the network 9, but the control device 1 and the electric light shielding device 3 may be connected via the network 9.

  The control device 1, the photovoltaic power generation system 2, and one or more electric light shielding devices 3 are the same as those in the first embodiment. The NTP server 4 can use any server as long as it is a server that delivers accurate current time data using NTP (Network Time Protocol).

  FIG. 10 shows a functional configuration of the control device 1 according to the second embodiment. Compared with the control device 1 of the first embodiment, the storage unit 20 includes an automatic date / time correction information storage unit 25 and a date / time information acquisition unit 33. The automatic date / time correction information storage unit 25 stores automatic date / time correction information indicating whether or not to automatically correct the current time. This is ON / OFF information of the automatic date and time correction function, and can be switched ON / OFF by a user operation. When the automatic date / time correction function is switched from OFF to ON, the date / time correction process described later starts again from the beginning. The date / time information acquisition unit 33 acquires the correct current time from the NTP server 4 through the network 9.

  The control process performed by the control device 1 according to the second embodiment is the same as the control process according to the first embodiment, and is shown in the flowchart of FIG. Next, date correction processing performed by the control device 1 according to the second embodiment will be described with reference to FIG. Similar to the control process, the date correction process is started when the control program of the control device 1 is activated, but is activated by a thread different from the control process and operates in parallel with the control process.

  First, the control unit 10 acquires automatic date / time correction information from the automatic date / time correction information storage unit 25, and determines whether or not the automatic date / time correction function is ON (step S201). If the automatic date and time correction function is not ON (step S201; No), the process is terminated. If the automatic date and time correction function is ON (step S201; Yes), the control unit 10 determines whether or not the current time estimated from the value of the timer 14 is the time correction timing (step S202).

  The time correction timing is, for example, “daily fixed time” (midnight, noon, etc.) and immediately after the control device 1 is activated. The timing immediately after activation of the control device 1 can be determined by the value of the timer 14. The “daily fixed time” and the timing for controlling the electric light-shielding device 3 are preferably timings that are more than the time necessary for controlling the electric light-shielding device 3, for example, 30 minutes or more. The “daily fixed time” may be set, for example, at midnight when shipped from the factory, and may be changed by the user of the control device 1 as necessary. In this case, unless changed by the user, the timing immediately after the activation of the control device 1 and the time when the current time estimated by the timer 14 is midnight are the time correction timing.

  If it is not time correction timing (step S202; No), it will return to step S201. If it is time timing (step S202; Yes), the date information acquisition unit 33 connects to the NTP server (step S203) and acquires the current time (step S204). Then, the control unit 10 corrects the date information by setting the current time acquired by the date information acquisition unit 33 in the timer 14 (step S205), and returns to step S201.

  This date and time correction process is performed in parallel with a thread different from the control process, whereby the time is corrected to the correct time every day. Therefore, in the second embodiment, the accurate current time can be used for the estimation of the external environment in step S106 and the determination of the control condition in step S108 in the control process, so that the electric light shielding device 3 is controlled at a more accurate timing. can do.

(Modification of Embodiment 2)
In the second embodiment described above, the current time information is acquired from the NTP server 4, but the acquisition of the current time information is not limited to the acquisition from the NTP server 4. For example, the user of the control device 1 may be able to manually set the current time information.

  The configuration of the control system according to the modification of the second embodiment is the same as that of the control system 1000 of FIG. 1 except for the NTP server 4 and the network 9 from FIG. The functional configuration of the control device 1 according to the modification of the second embodiment is the same as that of the second embodiment and is shown in FIG. 10, but the date / time information acquisition unit 33 acquires the current time information directly from the user. Input devices such as buttons (date / time setting start button, date / time input button, setting completion button, etc.) and a touch panel for enabling this function are provided.

  Moreover, the date correction process performed by the control device 1 according to the modification of the second embodiment is a process in which a part of the process in FIG. 11 is changed as follows.

  The “time correction timing” in step S202 is the timing when the user issues a time correction instruction to the date / time information acquisition unit 33 (for example, the timing when the date / time setting start button is pressed). There is no processing corresponding to step S203. In step S204, the user inputs the current time using, for example, a date input button and a setting completion button, and the date information acquisition unit 33 acquires the current time input by the user. The processing of other steps is the same as that of the second embodiment.

  In the modification of the second embodiment, even in an environment where the NTP server cannot be used, the electric light-shielding device 3 can be more accurately compared with the first embodiment by having the user input the current time. It can be controlled by timing.

  An embodiment in which the second embodiment and a modification of the second embodiment are combined is also possible. In this case, the date / time correction process according to the second embodiment and the date / time correction process according to the modification of the second embodiment operate in parallel in different threads. Normally, the date and time correction required for the NTP server 4 is performed. However, when the correct time is not provided from the NTP server for some reason, the date and time can be manually corrected.

(Embodiment 3)
In the above-described embodiment, only weather information and brightness information estimated based on power generation information obtained from the power generation information acquisition unit 31 can be used for weather information. Since this estimation is based on brightness regardless of the actual weather, it has been difficult to accurately estimate rain, cloudiness, snow, and the like. Also, the temperature and humidity could not be estimated. A third embodiment that solves these problems will be described.

  As shown in FIG. 12, the configuration of the control system 3000 according to Embodiment 3 of the present invention includes a control device 1, a solar power generation system 2, one or more electric light shielding devices 3, a weather information server 5, and the like. And a network 9 that connects the control device 1 and the weather information server 5. The system of the network 9 may be anything as in the second embodiment of the present invention. In FIG. 12, the control device 1 and the electric light shielding device 3 are directly connected separately from the network 9, but the control device 1 and the electric light shielding device 3 may be connected via the network 9.

  The control device 1, the photovoltaic power generation system 2, and one or more electric light shielding devices 3 are the same as those in the first embodiment. The weather information server 5 is a server that distributes information related to weather such as weather and temperature.

  FIG. 13 shows a functional configuration of the control device 1 according to the third embodiment. Compared to the control device 1 of the first embodiment, the difference is that a weather-related information acquisition unit 34 is provided. The weather related information acquisition unit 34 acquires information related to weather such as weather and temperature from the weather information server 5 through the network 9.

  A control process performed by the control device 1 according to the third embodiment will be described with reference to FIG. The control process is started when the control program of the control device 1 is activated. The processing from step S301 to step S307 is the same as the processing from step S101 to step S107 in FIG. However, as shown in FIG. 15, the control information acquired in step S <b> 307 can include control conditions including weather-related information that can be acquired from the weather information server 5, such as the forecast weather of the day and the predicted temperature.

  In step S308, the weather related information acquisition unit 34 acquires weather related information from the weather information server 5 (step S308). At the time of this acquisition, the weather related information acquisition unit 34 may notify the weather information server 5 of information on the current position (area where the user lives) of the control unit 1. By doing so, the weather information server 5 can transmit the detailed weather information of the notified region to the weather related information acquisition unit 34.

  The weather related information acquired at this time includes the weather related information included in the control condition acquired by the control information acquiring unit 11 in step S307. The weather related information acquired at this time includes the weather related information included in the control condition acquired by the control information acquiring unit 11 in step S307. For example, in FIG. 15, the control conditions are “summer and morning at 8:00 and sunny day”, “sunset and next day's expected minimum temperature ≧ 0 ° C.”, “sunset and next day's expected minimum temperature <0 ° C.”, “typhoon “Approach” and “not typhoon approach” are set. Therefore, when these control conditions are acquired in step S307, when acquiring weather-related information in step S308, “current season”, “current weather”, “predicted lowest temperature of next day”, “sunset time” "," Typhoon information "is acquired.

  Note that the processing order of step S306, step S307, and step S308 is arbitrary. For example, step S306 may be followed by step S308 and then step S307. In that case, in step S308, all the weather information included in the possible control conditions is acquired. Further, processing may be performed in the order of step S307 → step S308 → step S306. In this case, in step S308, only the weather related information included in the control condition acquired by the control information acquisition unit 11 in step S307 may be acquired. If included in the control condition, the season or weather is determined in step S308. Is already acquired, it is not necessary to estimate the season and weather in step S306.

  In step S309, the current external environment estimated by the estimation unit 12 in step S306 and the weather related information acquired by the weather related information acquisition unit 34 in step S308 are the control acquired by the control information acquisition unit 11 in step S307. It is determined whether or not any of the conditions is satisfied (step S309). When neither is satisfied (step S309; No), the process returns to step S301.

  If either of them is satisfied (step S309; Yes), the process proceeds to step S310, and the control unit 10 controls the control content acquired by the control information acquisition unit 11 and the control device (control corresponding to the control condition determined to be satisfied in step S309). The control signal transmission unit 32 is notified of the content and the control device. Then, the control signal transmission unit 32 sends a control signal for performing the control indicated by the control content notified from the control unit 10 to the electric light shielding device 3 specified by the information on the control device notified from the control unit 10. Transmit (step S310). Then, the process returns to step S301.

  In step S310, if the information on the control device notified from the control unit 10 is “all”, the control signal transmission unit 32 transmits a control signal to all connected electric light shielding devices 3. . In FIG. 15, control information including control device information is taken as an example. Therefore, in the above description of the control processing, the control processing in the case where control information includes control device information has been described. As described above, all of the electric light-shielding devices 3 may be controlled together using control information that does not include control device information.

  In the first example from the top of FIG. 15, when the weather on the day is sunny in the summer due to the control condition “summer and 8 am and clear weather on the day”, control is performed to close all the electric light-shielding devices 3 at 8 am in the morning. By doing so, it is possible to prevent strong sunlight from entering the room and raising the room temperature. Although not shown in the figure, for example, if the control information “winter and 8:00 am and clear weather on the day” and control information “open” are set, if the weather on the day is sunny in winter, the electric light is cut off at 8:00 am Control is performed to open the device 3, and sunlight can enter the room on a sunny day even in cold winter.

  In the second and third examples from the top of FIG. 15, it is assumed that the device with device ID (control device information) 001 is an electric curtain, and the device with device ID 002 is an electric shutter. These control conditions are “Sunset and next day's expected minimum temperature ≧ 0 ° C” and “Sunset and next day's expected minimum temperature <0 ° C”. The shutter is closed, and when the temperature is 0 ° C. or higher, the electric curtain is closed. In other words, when the cold is expected to be severe, close the electric shutter to prevent the room temperature from decreasing as much as possible, and when the cold is not so severe, close the electric curtain that is easier to open and close By doing so, the convenience of the user is improved.

  In the fourth and fifth examples from the top of FIG. 15, the control conditions are “typhoon approach” and “not typhoon approach”. When the electric shutter at 002 is closed and the approach of the typhoon is not expected, the electric curtain with the device ID 001 can be closed.

  As described above, according to the control system 3000 according to the third embodiment, the control can be performed in consideration of the weather related information. Therefore, by acquiring the sunrise time and sunset time as weather-related information, the electric light-shielding device can be controlled with more accurate timing. Further, by acquiring temperature information as weather-related information, more flexible control such as adjusting control conditions according to the temperature can be performed. In addition, by acquiring accurate weather and season as weather-related information, control according to the season and weather can be performed, and the effect of reducing utility costs can be expected.

(Embodiment 4)
In the above-described embodiment, since the current open / closed state of the electric light-shielding device 3 could not be acquired, the open control may be performed even when the electric light-shielding device 3 is already open, or the close control may be performed even when it is already closed. Moreover, since it cannot be confirmed whether the state of the electric light-shielding device 3 is really controlled after the control, for example, an error occurs when the control signal is transmitted, and the electric light-shielding device 3 remains uncontrolled. It was also possible. A fourth embodiment for solving these problems will be described.

  As shown in FIG. 1, the control system according to the fourth embodiment of the present invention is configured by the same control system 1000 as in the first embodiment. FIG. 16 shows a functional configuration of the control device 1 according to the fourth embodiment. Compared with the control device 1 of the first embodiment, the difference is that a device state acquisition unit 35 that acquires the state of the electric light-shielding device 3 is provided.

  A control process performed by the control device 1 according to the fourth embodiment will be described with reference to FIG. The control process is started when the control program of the control device 1 is activated. The processing from step S401 to step S408 is the same as the processing from step S101 to step S108 in FIG.

  In step S409, the device state acquisition unit 35 acquires the states of all the electric light shielding devices 3 (step S409). In step S410, the control unit 10 needs to transmit a control signal by comparing the control content corresponding to the control condition determined to be satisfied in step S408 with the device state acquired by the device state acquisition unit 35. Is determined (step S410). For example, if the device state is closed and the control content is also closed, there is no need to transmit a control signal. Conversely, if the device state is open and the control content is closed, it is necessary to transmit a control signal.

  If the control device information acquired by the control information acquisition unit 11 is the device ID of each control device of the electric light-shielding device 3, the control unit 10 performs device status determination for each device in step S410. Do. When the control device information acquired by the control information acquisition unit 11 is “all”, the control unit 10 determines whether the state of all the electric light-shielding devices 3 is in a state in which control signal transmission is unnecessary. In any case, when there is one electric shading device 3 that needs to transmit a control signal, the determination by the control unit 10 in step S410 is “need to transmit control signal”.

  If it is not necessary to transmit the control signal (step S410; No), the process returns to step S401. If it is necessary to transmit a control signal (step S410; Yes), the process proceeds to step S411, and the control unit 10 sets the control content acquired by the control information acquisition unit 11 and the control device (the control condition determined to be satisfied in step S408). Corresponding control content and control device) are notified to the control signal transmitter 32. Then, the control signal transmission unit 32 sends a control signal for performing the control indicated by the control content notified from the control unit 10 to the electric light shielding device 3 specified by the information on the control device notified from the control unit 10. Transmit (step S411).

  In step S411, if the control device information is “all”, the control signal is transmitted only to the device that needs to transmit the control signal based on the device state of each device acquired in step S409. May be.

  Next, in order to wait for the operation of the electric light-shielding device 3 to be completed, the control unit 10 waits by counting the time required for the operation of the electric light-shielding device 3 to be completed by the timer 14, for example, 5 minutes ( Step S412). And the apparatus information acquisition part 35 acquires the state of the electric light-shielding apparatus 3 again (step S413).

  In step S414, the control unit 10 determines whether the state of the electric light-shielding device 3 to which the control signal is transmitted in step S411 is a state indicated by the control signal (step S414). If the state of the electric light-shielding device 3 is the state indicated by the control signal (step S414; Yes), the process returns to step S401.

  If the state of the electric light-shielding device 3 is not in the instructed state (step S414; No), the process returns to step S411 to retransmit the control signal (step S411). Although not shown in FIG. 17, in consideration of the case where the electric light-shielding device 3 cannot receive the control signal or does not operate normally, a retransmission counter is set when proceeding to Yes in step S410, and step S414. It is desirable to limit the number of times to return from step S411 to step S411.

  If the answer is Yes in step S410, the retransmission counter is set to 10, for example, and in step S414, the determination is made as to “instructed state” only while the retransmission counter is a positive value. Each time becomes No, the retransmission counter is decreased by one. If the retransmission counter is 0 or less in step S414, the process may return to step S401 regardless of the device state.

  As described above, according to the control system 1000 according to the fourth embodiment, the control signal is transmitted only when the control signal needs to be transmitted by acquiring the state of the electric light-shielding device 3 before transmitting the control signal. Therefore, occurrence of unnecessary communication can be suppressed. Further, the control of the electric light-shielding device 3 can be realized by acquiring the state of the electric light-shielding device 3 after transmitting the control signal and retransmitting the control signal if the electric light-shielding device 3 is not in a desired state.

  In addition, when the determination result in step S408 of FIG. 17 is No, the process does not return to step S401 immediately, but the state of the electric light-shielding device 3 should be periodically acquired and the electric light-shielding device 3 at that time should be present. When the state and the actual state of the electric light-shielding device 3 are different, the control signal may be transmitted so that the electric light-shielding device 3 is in a desired state. By performing such processing, the electric light-shielding device 3 can be maintained in a desired state.

(Embodiment 5)
In the embodiment described above, the power generation pattern stored in the power generation pattern storage unit 22 is stored in the power generation pattern storage unit 22 in advance when the control device 1 is shipped from the factory or sold at a store. It is a thing. Since the value of the power generation pattern varies depending on the region, the power generation pattern according to the user's place of use should be stored at the time of purchase, but such individual correspondence is often difficult. In addition, the value acquired from the power generation information acquisition unit 31 also changes depending on the performance of the solar power generation system and changes over time. Is good. Therefore, a fifth embodiment for realizing the power generation pattern update function will be described.

  As shown in FIG. 18, the control system 5000 according to Embodiment 5 of the present invention includes a control device 1, a photovoltaic power generation system 2, one or more electric light shielding devices 3, a power generation pattern providing server 6, And a network 9 that connects the control device 1 and the power generation pattern providing server 6. The system of the network 9 may be anything as in the second embodiment of the present invention. In FIG. 18, the control device 1 and the electric light shielding device 3 are directly connected separately from the network 9, but the control device 1 and the electric light shielding device 3 may be connected via the network 9.

  The control device 1, the photovoltaic power generation system 2, and one or more electric light shielding devices 3 are the same as those in the first embodiment. The power generation pattern providing server 6 is a server that distributes information on the power generation pattern to be stored in the power generation pattern storage unit 22 in the storage unit 20 of the control device 1.

  FIG. 19 shows a functional configuration of the control device 1 according to the fifth embodiment. Compared with the control device 1 of the first embodiment, the storage unit 20 includes a power generation pattern automatic update information storage unit 26 and a power generation pattern acquisition unit 36. The power generation pattern automatic update information storage unit 26 stores power generation pattern automatic update information indicating whether or not to automatically update the power generation pattern stored in the power generation pattern storage unit 22. This is ON / OFF information of the automatic power generation pattern update function, and can be switched ON / OFF by a user operation. When the automatic power generation pattern update function is switched from OFF to ON, a power generation pattern update process described later is started again from the beginning. Further, the power generation pattern acquisition unit 36 acquires information on the power generation pattern from the power generation pattern providing server 6 through the network 9.

  The control process performed by the control device 1 according to the fifth embodiment is the same as the control process according to the first embodiment, and is shown in the flowchart of FIG. Next, the power generation pattern update process performed by the control device 1 according to the fifth embodiment will be described with reference to FIG. Like the control process, the power generation pattern update process is started when the control program of the control device 1 is activated, but is activated by a thread different from the control process and operates in parallel with the control process.

  First, the control unit 10 acquires power generation pattern automatic update information from the power generation pattern automatic update information storage unit 26, and determines whether or not the power generation pattern automatic update function is ON (step S501). If the automatic update function is not ON (step S501; No), the process is terminated. If the automatic update function is ON (step S501; Yes), the power generation pattern acquisition unit 36 connects to the power generation pattern providing server 6 (step S502). At the time of connection to the power generation pattern providing server 6, the power generation pattern acquisition unit 36 installs the solar power generation system 2 and information such as the model number, performance, and use start time of the solar power generation system 2 connected to the control device 1. Information such as the address, installation direction, and inclination of installation may be transmitted to the power generation pattern providing server 6. By transmitting these pieces of information, the power generation pattern providing server 6 can provide a power generation pattern more suitable for the use environment of the user.

  Next, the power generation pattern acquisition unit 36 determines whether or not the power generation pattern information provided by the power generation pattern providing server 6 has been updated (step S503). If the power generation pattern information has not been updated (step S503; No), the process returns to step S501. If the power generation pattern information has been updated (step S503; Yes), the power generation pattern acquisition unit 36 acquires the power generation pattern information from the power generation pattern providing server 6 (step S504).

  And the control part 10 updates the information of the power generation pattern memorize | stored in the power generation pattern memory | storage part 22 using the information of the power generation pattern which the power generation pattern acquisition part 36 acquired (step S505), and returns to step S501.

  With the power generation pattern update process described above, the control system 5000 according to the fifth embodiment can always estimate the external environment based on the latest and high-accuracy power generation pattern. Control is possible with high accuracy.

  Here, there are roughly two types of timing for updating the power generation pattern. One is an update timing based on the time, and is updated in order to provide a power generation pattern suitable for the month (week, day) such as monthly, weekly, or daily. In particular, when updating every day, it is possible to provide a highly accurate power generation pattern based on the weather forecast information for that day.

  The other is when a new product of the solar power generation system 2 is released or when it is adapted to the solar power generation system 2 that has not been supported so far. When a pattern can be provided, it is updated to provide information including the power generation pattern.

(Modification of Embodiment 5)
In the fifth embodiment described above, the power generation pattern is obtained from the power generation pattern providing server 6. However, the power generation pattern cannot be updated unless the power generation pattern providing server 6 exists. For example, the user of the control device 1 may be able to update the information on the power generation pattern stored in the power generation pattern storage unit 22 based on the power generation information from the solar power generation system 2 used by the user. .

  The configuration of the control system according to the modification of the fifth embodiment is the same as that of the control system 1000 of FIG. 1 except for the power generation pattern providing server 6 and the network 9 from FIG. And although the function structure of the control apparatus 1 which concerns on the modification of Embodiment 5 is the same as that of Embodiment 5, and it is what was shown in FIG. 19, the electric power generation pattern acquisition part 36 receives an electric power generation pattern update instruction | indication and the day from a user. Input devices such as buttons and a touch panel for inputting weather information and current date and time. Then, the power generation pattern acquisition unit 36 creates a power generation pattern using the power generation information stored in the power generation information storage unit 21 based on the power generation pattern update instruction from the user, and the control unit 10 stores the generated power generation pattern. It is stored in the power generation pattern storage unit 22.

  The power generation pattern update process performed by the control device 1 according to the modification of the fifth embodiment is a process in which a part of FIG. 20 is changed as follows.

  There is no processing corresponding to step S502. In step S503, the power generation pattern acquisition unit 36 determines whether there is a power generation pattern update instruction from the user. In step S <b> 504, the power generation pattern acquisition unit 36 acquires the weather information and the current date and time of the day from the user, and acquires power generation information for the past 24 hours from the power generation information storage unit 21.

  In step S505, based on the power generation information and weather information acquired in step S504, the power generation information is generated using the power generation information, and the power generation pattern information stored in the power generation pattern storage unit 22 is created. Update. The processing of other steps is the same as that of the fifth embodiment.

  In the modification of the fifth embodiment, even in an environment where the power generation pattern providing server 6 cannot be used, the power generation information stored in the power generation information storage unit 21 and the weather information and current date / time information input by the user are displayed. By using the power generation pattern, it is possible to obtain a power generation pattern that matches the actual situation at the point used by the user. Since the external environment can be estimated based on the power generation pattern in accordance with this actual situation, the electric light shielding device 3 can be controlled with higher accuracy.

  An embodiment in which the fifth embodiment and a modification of the fifth embodiment are combined is also possible. In this case, the power generation pattern update process according to the fifth embodiment and the power generation pattern update process according to the modification of the fifth embodiment operate in parallel with different threads. For example, when a high-rise apartment is built on the south side of the place where you live, the power generation pattern provided from the power generation pattern providing server 6 is usually used. However, the existence of a high-rise apartment significantly affects the power generation pattern. When generating the power generation pattern, the power generation pattern update process according to the modification of the fifth embodiment can also generate a power generation pattern that matches the current environment.

  The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention. Although it has already been explained that the combination of the second embodiment and the modification of the second embodiment is possible, and the combination of the modification of the fifth embodiment and the fifth embodiment is possible, for example, Embodiments combining the embodiments are also possible. In this case, the main control process is integrated and operates in one thread, and the date correction process and the power generation pattern update process operate in parallel in different threads. In this case, the NTP server 4, the weather information server 5, and the power generation pattern providing server 6 connected to the network 9 may exist separately, or are integrated into a single server having these various functions. May be.

  In addition, the control system according to each of the above-described embodiments includes the electric light-shielding device 3, but any device that has a function of receiving a control signal from the outside and operating based on the received control signal. Various other devices can be connected and automatically controlled. For example, a system that automatically controls a shutter of a garage, a shutter of a store, a sprinkler for watering a plant or a lawn in accordance with the time of sunrise or sunset can be considered. Since the electric power used by the electric light shielding device 3 and other automatically controlled devices does not have to be generated by the solar power generation system 2, power is supplied from the solar power generation system 2 at night or in rainy weather. Even if this is difficult, automatic control can be performed without any problem.

  In each embodiment, it has been described that the various storage units in the storage unit 20 are provided in the control device 1. However, in a control system in which the network 9 is present, a server connected to the network 9 has these various storage units. You may make it provide.

  The hardware of the control device 1 according to the embodiment of the present invention includes a processor 1001, a memory 1002, and an interface 1003 as shown in FIG. Each function of the control device 1 is realized by the processor 1001 executing a program stored in the memory 1002. The interface 1003 is for connecting the control device 1 and components such as the solar power generation system 2 and the electric light-shielding device 3 to establish communication, and may be configured by a plurality of types of interfaces as necessary. . FIG. 21 illustrates an example in which the processor 1001 and the memory 1002 are each configured as one, but a plurality of processors and a plurality of memories may execute the above functions in cooperation.

  In any of the above-described embodiments, each function can be performed by a normal computer. Specifically, in the above-described embodiment, the program executed by the control unit 10 has been described as being stored in advance in the ROM of the storage unit 20. However, the program is stored and distributed on a computer-readable recording medium such as a flexible disk, CD-ROM (Compact Disc Read Only Memory), DVD (Digital Versatile Disc), and MO (Magneto-Optical Disc). A computer capable of realizing each of the functions described above may be configured by reading and installing the program on a computer. When each function is realized by sharing between an OS (Operating System) and an application, or by cooperation between the OS and the application, only a part other than the OS may be stored in the recording medium.

  Furthermore, each program can be superimposed on a carrier wave and distributed via a communication network. For example, the program may be posted on a bulletin board (BBS, Bulletin Board System) on a communication network, and the program may be distributed via the network. Then, the above-described processing may be executed by starting these programs and executing them in the same manner as other application programs under the control of the OS.

  As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to the specific embodiment which concerns, This invention includes the invention described in the claim, and its equivalent range It is.

1000, 2000, 3000, 5000 Control system, 1 control device, 2 solar power generation system, 3 electric shading device, 4 NTP server, 5 weather information server, 6 power generation pattern providing server, 9 network, 10 control unit, 11 control information Acquisition unit, 12 estimation unit, 13 determination unit, 14 timer, 20 storage unit, 21 power generation information storage unit, 22 power generation pattern storage unit, 23 control information storage unit, 24 automatic control switching information storage unit, 25 automatic date and time correction information storage Unit, 26 power generation pattern automatic update information storage unit, 31 power generation information acquisition unit, 32 control signal transmission unit, 33 date and time information acquisition unit, 34 weather related information acquisition unit, 35 device state acquisition unit, 36 power generation pattern acquisition unit, 1001 processor , 1002 memory, 1003 interface.

Claims (13)

A power generation information acquisition unit that acquires information indicating the amount of power generation from the solar power generation system;
A determination unit that determines whether or not a condition for performing device control is satisfied based on information indicating the amount of power generation acquired by the power generation information acquisition unit;
A control signal transmission unit that transmits a control signal when the determination unit determines that a condition for performing the device control is satisfied;
A control device comprising: Furthermore, based on information indicating the power generation amount acquired by the power generation information acquisition unit, comprising an estimation unit for estimating the external environment,
The determination unit determines whether or not a condition for performing device control is satisfied based on the external environment estimated by the estimation unit.
The control device according to claim 1. In addition, a power generation pattern storage unit that stores information on the power generation pattern indicating the amount of power generation by time zone for each period,
The estimation unit estimates an external environment based on information on the power generation pattern stored in the power generation pattern storage unit and information indicating the power generation amount acquired by the power generation information acquisition unit,
The control device according to claim 2. Furthermore, a power generation pattern acquisition unit that acquires information on the power generation pattern is provided.
Based on the information on the power generation pattern acquired by the power generation pattern acquisition unit, the information on the power generation pattern stored in the power generation pattern storage unit is updated.
The control device according to claim 3. And a control information storage unit for storing control condition information indicating a condition for performing the device control, control device information for specifying a transmission destination of the control signal, and control information including control content information indicating the content of the device control. ,
The determination unit determines whether the external environment estimated by the estimation unit satisfies any of the conditions indicated in the control condition information,
When the determination unit determines that any one of the conditions is satisfied, the control signal transmission unit transmits a control signal for performing the control indicated in the control content information to the transmission destination indicated in the control device information. To
The control device according to any one of claims 2 to 4. In addition, a device status acquisition unit that acquires the status of the device to be controlled by the device,
The control signal transmission unit transmits a control signal when the device state acquired by the device state acquisition unit is different from the device state based on the control information.
The control device according to claim 5. Furthermore, a date and time information acquisition unit for acquiring current date and time information is provided,
Conditions for device control include conditions related to date and time,
The determination unit determines whether or not a condition for performing device control is satisfied based on the current date and time acquired by the date and time information acquisition unit and information indicating the power generation amount acquired by the power generation information acquisition unit.
The control device according to any one of claims 1 to 6. In addition, a weather-related information acquisition unit that acquires information on the weather,
Conditions for device control include weather conditions
The determination unit determines whether or not a condition for performing device control is satisfied based on information on the weather acquired by the weather-related information acquisition unit and information indicating the power generation amount acquired by the power generation information acquisition unit. ,
The control device according to any one of claims 1 to 7. The weather-related information acquired by the weather-related information acquisition unit includes weather information on the day of information acquisition,
The control device according to claim 8. The weather-related information acquired by the weather-related information acquisition unit includes information on weather forecasts after the next day of information acquisition,
The control device according to claim 8 or 9. A solar power generation system comprising: a solar cell module that converts sunlight into DC power; and a power conditioner that converts the DC power into AC power;
A control device according to any one of claims 1 to 10,
The power generation information acquisition unit provided in the control device acquires information indicating the amount of power generation from the solar power generation system,
Control system. A power generation information acquisition step for acquiring information indicating the amount of power generation from the solar power generation system;
A determination step for determining whether or not a condition for performing device control is satisfied based on information indicating the power generation amount acquired in the power generation information acquisition step;
A control signal transmission step for transmitting a control signal when it is determined that the condition for performing the device control is satisfied in the determination step;
A control method comprising: On the computer,
A power generation information acquisition step for acquiring information indicating the power generation amount from the solar power generation system,
A determination step for determining whether or not a condition for performing device control is satisfied based on information indicating the power generation amount acquired in the power generation information acquisition step,
A control signal transmission step for transmitting a control signal when it is determined that the condition for performing the device control is satisfied in the determination step;
A program for running

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