JP2014206852A - Crime prevention system and device controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a crime prevention system that does not make an intruder perceive unnaturalness even for a long-term absence of a resident in a house by automatically turning on and off electric appliances installed in the house depending on a time period, season, weather and a location of the house.SOLUTION: A crime prevention system comprises a solar battery 20, and a device controller 10 controlling the operation of an electric appliance 30. The device controller 10 comprises: a detection unit 11 detecting output voltage data of the solar battery 20; a receiving unit 12 receiving data from a telecommunication network 40; an input unit 13 accepting an input of a user 50; a storage unit 14 storing time data received by the receiving unit 12 and time data accepted by the input unit 13; a calculation unit 17 determining the timing of operation start or operation stop of the electric appliance 30, on the basis of the output voltage data and the time data. When the user 50 sets a crime prevention mode for the purpose of crime prevention, the device controller 10 automatically controls the operation of the electric appliance 30, on the basis of a determination result of the calculation unit 17.

Description

  The present invention relates to a crime prevention system for controlling an indoor electric device based on an output voltage of a solar cell.

  In recent years, systems (for example, HEMS: Home Energy Management System) that collectively control a plurality of electric devices such as home appliances and house equipment have become widespread. The main purpose of these systems is to control the operation of each electrical device in accordance with the power supplied from a power generation device such as a solar cell to save energy. As these systems become widespread in the future, it is required to utilize these systems as security systems.

  Conventionally, as a crime prevention system to prevent the intrusion of suspicious people indoors, audio data such as living sounds recorded in advance is played on an AV device in the absence of a resident, and pretends to be resident indoors Has been proposed. (For example, refer to Patent Document 1). In addition, a crime prevention device has been proposed that uses an electric power supplied from a power generation device such as a solar battery to shake an indoor curtain so that a resident is present indoors (see, for example, Patent Document 2). ).

JP 2007-265021 A JP 2006-65553 A

  In the crime prevention system using the AV device disclosed in Patent Document 1, early morning, morning, afternoon, evening, night, midnight and one day are divided into a plurality of time zones, and audio is played back randomly within each time zone. Yes. However, since the sunrise and sunset times differ depending on the season, it is not possible to sufficiently cope with seasonal changes simply by dividing a day into a plurality of time zones. Moreover, since the outdoor brightness changes depending on the daily weather, it is not possible to sufficiently cope with the weather change by simply dividing the day into a plurality of time zones. Furthermore, these vary depending on the area where the house is located and the location.

  Therefore, in the system that divides the day into fixed time zones and performs the security operation according to each time zone, as in the security system of Patent Document 1, the crime prevention system is in the absence of a long time when the time zone divided by the season and weather changes every day. It was difficult to make full use of the function. For example, there is a possibility that the sound is reproduced after sunset to be reproduced in the evening due to a change in the sunshine time, and in such a case, there is a possibility that the suspicious person who is aiming to intrude may feel unnaturalness.

  In the crime prevention device of Patent Document 2, the curtain is shaken by changing the time and the number of times. However, because it is controlled only by the timer, there is a possibility that the movement of the curtain may be patterned in the absence of long-term, and in such a case, the suspicious person who is aiming to enter feels unnatural. There is a fear.

  The present invention has been made to solve the above-described problems, and automatically operates or stops an electric device provided in a house according to a time zone, a season, weather, and a location of the house. Therefore, it is an object to provide a crime prevention system and a device control device that do not cause unnatural feeling even in the absence of a long term.

  A crime prevention system according to the present invention includes a solar cell that is a power generation device, an electrical device provided in a house, and a device control device that is connected to the solar cell, the electrical device, and a communication network and controls the operation of the electrical device. The device control device includes a detection unit that detects output voltage data of the solar cell, a reception unit that receives data from the communication network, an input unit that receives user input, and time data and an input unit that are received by the reception unit. Calculation for determining the timing of starting or stopping the operation of the electric device based on the storage unit that stores the received time data, the output voltage data detected by the detection unit, and the time data stored in the storage unit When the crime prevention mode for the purpose of crime prevention is set by the user, the operation of the electric device is automatically controlled based on the determination result of the calculation unit.

  According to the present invention, when the crime prevention mode is set, the electric device is automatically operated based on the output voltage data of the solar cell, thereby changing according to the time zone, season, weather, location of the house, or the like. Since the operation timing of electrical equipment changes according to the solar radiation situation to the house, it is possible to make residents feel indoors even when they are absent for a long time, and it is possible to demonstrate a high crime prevention effect .

It is a figure which shows the structure of the crime prevention system which concerns on Embodiment 1 of this invention. It is a flowchart which shows a part of operation | movement of the crime prevention system which concerns on Embodiment 1, 2 of this invention. It is a flowchart which shows a part of operation | movement of the crime prevention system which concerns on Embodiment 1 of this invention. It is a flowchart which shows a part of operation | movement of the crime prevention system which concerns on Embodiment 1 of this invention. It is a flowchart which shows a part of operation | movement of the crime prevention system which concerns on Embodiment 2 of this invention. It is a flowchart which shows a part of operation | movement of the crime prevention system which concerns on Embodiment 2 of this invention. It is a flowchart which shows operation | movement of the crime prevention system which concerns on Embodiment 3 of this invention.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating a configuration of a crime prevention system according to the first embodiment. As shown in FIG. 1, the security system 100 according to the first embodiment includes a device control device 10, a solar cell 20 connected to the device control device 10, a plurality of electrical devices 30 and a communication network 40, and a device control device 10. It is comprised with the user 50 who operates.

  The device control apparatus 10 receives the detection unit 11 that detects the output voltage of the solar battery 20, the reception unit 12 that receives various data from the communication network 40, the input unit 13 that receives input from the user 50, and the reception unit 12. The storage unit 14 that stores the received data and the data received by the input unit 13, the clock unit 15 that has the current time data, and a signal that includes an instruction to drive or stop the one or more electrical devices 30 And the start of operation of one or a plurality of electrical devices 30 based on the output voltage data detected by the detection unit 11, the data stored in the storage unit 14, and the time data of the clock unit 15. And a calculation unit 17 that determines the operation stop timing and controls the operation of the electric device 30 via the communication unit 16. In addition, the device control apparatus 10 can receive device information such as the operating state of the electrical device 30 via the communication unit 16.

  The solar cell 20 is installed outside the house. When sunlight hits the solar cell 20, power generation is performed, and a voltage corresponding to the amount of power generation is output. Then, output voltage data based on the output voltage of the solar battery 20 is input to the calculation unit 17 via the detection unit 11 of the device control apparatus 10. Note that the solar cell 20 may be a solar cell having a function of outputting a voltage corresponding to the amount of power generation to the device control apparatus 10 and a function of supplying power to the indoor electrical device 30.

  Examples of the plurality of electric devices 30 include an electric shutter 31, an air conditioner 32, a ventilation fan 33, a television 34, and an illumination 35. Each of the electrical devices 31 to 35 includes a communication unit that can communicate with the communication unit 16 of the device control device 10. The communication unit 16 of the device control device 10 and the communication unit of each of the electrical devices 31 to 35 are wireless or wired. Are connected to each other. And each electric equipment 31-35 operate | moves by receiving the signal containing the operation instruction | indication transmitted from the communication part 16 of the apparatus control apparatus 10. FIG.

  Specifically, the shutter 31 has two operation modes of an opening operation and a closing operation, and these two operations are controlled by a signal from the device control device 10. In the air conditioner 32, the drive and stop of the compressor and the fan are controlled by a signal from the device control device 10. The ventilation fan 33 is controlled to be driven and stopped by a signal from the device control device 10. The television 34 is controlled to start and stop output of sound and the like by a signal from the device control apparatus 10. The lighting 35 is controlled to be turned on / off by a signal from the device control apparatus 10. In FIG. 1, five electrical devices 31 to 35 are shown as the plurality of electrical devices 30 connected to the device control apparatus 10. However, the present invention is not limited to these, and other electrical devices are used as the device control apparatus 10. You may connect and control operation.

  The communication network 40 is a network such as the Internet. The receiving unit 12 of the device control apparatus 10 receives time data such as sunrise time and sunset time in a region where houses are present, weather data such as temperature, and the like from the communication network 40. These data received by the receiving unit 12 of the device control apparatus 10 are stored in the storage unit 14 of the device control apparatus 10.

  The user 50 is a resident of a house where the device control apparatus 10 is installed. The user 50 can input various information to the device control apparatus 10 via the input unit 13. Information input by the user 50 includes setting / canceling of a crime prevention mode for crime prevention, setting / canceling of the electric device 30 operated in the crime prevention mode, operation start time and operation stop time of the electric device 30 in the crime prevention mode, etc. is there. These pieces of information input to the input unit 13 are stored in the storage unit 14 as data.

  Next, the operation of the security system 100 will be described. 2 to 4 are flowcharts showing a part of the operation of the security system according to the first embodiment. In the first embodiment, the operation of the crime prevention system that opens and closes the shutter 31 in the crime prevention mode will be described. However, instead of the shutter 31, an electric curtain or an electric blind may be opened and closed.

  As shown in FIG. 2, when the security mode is set by the user 50, the operation of the security system 100 is started (S001). First, the calculation unit 17 acquires time data from the clock unit 15, and determines whether the current time corresponds to 0-12 o'clock (S002). Next, the calculating part 17 acquires the information on whether the shutter 31 is closed or open via the communication part 16 (S003, S004). The subsequent operations differ depending on these processing results, and will be described in order with reference to FIGS.

(A) When the time is in the range of 0-12 o'clock (that is, in the morning) and the shutter 31 is closed As shown in FIG. 3, first, the calculation unit 17 acquires the data in the storage unit 14, and the storage unit 14 determines whether the user 50 has set the shutter opening time (S101). The shutter opening time is time data that the user 50 inputs to the input unit 13 of the device control apparatus 10 in advance, and is the start time of the opening operation of the shutter 31 that the user 50 desires.

  If the shutter opening time is set, the calculation unit 17 processes the time (for example, 7 o'clock) as the set time m (S102). On the other hand, if the shutter opening time is not set, today's sunrise time data of the area where the house exists is acquired from the communication network 40 via the receiving unit 12, and stored in the storage unit 14 (S103). And the calculating part 17 processes the sunrise time (for example, 6 o'clock) as the set time m (S104). Note that a time obtained by shortening or extending a predetermined time (for example, 30 minutes) from the acquired sunrise time may be processed as the set time m.

  Next, the calculating part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P exceeds the predetermined value X (S105, S106). Here, the predetermined value X is a threshold value set in advance in the calculation unit 17, and is set based on, for example, the amount of solar radiation that is considered to open a shutter in daily life, the output voltage of the solar cell 20 in a time zone, or the like. Yes. The output voltage P to be compared with the predetermined value X may be an instantaneous value or an average value for a predetermined time.

  And when the output voltage P exceeds the predetermined value X, the calculating part 17 opens the shutter 31 via the communication part 16 (S107). On the other hand, when the output voltage P does not exceed the predetermined value X, the calculation unit 17 determines whether the current time has passed the set time m (S108). When the set time m has elapsed, the shutter 31 is opened (S107). On the other hand, when the set time m has not elapsed, the output voltage P of the solar cell 20 is detected again and repeated until the condition is satisfied. When it is determined that the output voltage P exceeds the predetermined value X, the output voltage P may be acquired again to determine whether the output voltage P acquired again exceeds the predetermined value X. Since the amount of solar radiation varies in a short period of time depending on the weather, etc., it is possible to judge when the sunshine has come to be stable rather than when the sunshine temporarily strengthened by performing these operations multiple times. it can.

  When the conditions are met and the opening of the shutter 31 is completed, the open state of the shutter 31 is maintained. Then, the shutter 31 is kept open until a predetermined time (for example, 12:00) elapses, and when the predetermined time elapses, the operation shifts to an operation (C) for closing the shutter 31 shown in FIG. 4 (S109). ).

  Thus, the shutter 31 is opened when either the condition of the output voltage P or the condition of the set time m is satisfied. In other words, when the sun hitting the house becomes stronger in the time period before the shutter opening time input by the user 50 or the sunrise time acquired from the communication network 40, the shutter 31 is opened based on the output voltage of the solar cell 20. Is done. Thereby, it is possible to prevent an unnatural state in which the shutter 31 is closed even though the sun is shining and getting brighter.

  Further, when the shutter opening time is input by the user 50, the shutter 31 is opened when the shutter opening time (set time m) elapses even if the output voltage P does not exceed the predetermined value X. The shutter 31 can be surely opened by the time desired by the user 50.

(B) When the time is in the range of 0-12 o'clock (that is, in the morning) and the shutter 31 is open As shown in FIG. 3, in this case, the time has passed a predetermined time (for example, 12:00) The shutter 31 is kept open until the predetermined time elapses, and the operation shifts to the operation (C) for closing the shutter 31 shown in FIG. 4 (S109).

(C) When the time is outside the range of 0-12 o'clock (that is, in the afternoon) and the shutter 31 is open As shown in FIG. 4, first, the calculation unit 17 acquires the data in the storage unit 14, and the storage unit 14 determines whether or not the shutter closing time is set by the user 50 (S111). The shutter closing time is time data that the user 50 inputs to the input unit 13 of the device control device 10 in advance, and is the start time of the shutter 31 closing operation desired by the user 50.

  When the shutter closing time is set, the calculation unit 17 processes the time (for example, 17:00) as the set time n (S112). On the other hand, if the shutter closing time is not set, today's day time entry data of the area where the house exists is acquired from the communication network 40 via the receiving unit 12, and stored in the storage unit 14 (S113). . Then, the calculation unit 17 processes the incoming time of the day (for example, 18:10) as the set time n (S114). In addition, you may process the time shortened or extended time by predetermined time (for example, 30 minutes) from the acquisition time of the acquired date as the setting time n.

  Next, the calculating part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P is less than the predetermined value Y (S115, S116). Here, the predetermined value Y is a threshold value set in advance in the calculation unit 17, and is set based on, for example, the amount of solar radiation considered to close a shutter in daily life, the output voltage of the solar cell 20 in a time zone, and the like. . The predetermined value Y is smaller than the predetermined value X shown in FIG. 3, and different threshold values are set for the opening operation and the closing operation. Since there is a difference in the amount of solar radiation between the morning sun and the sunset, a more natural opening / closing operation can be performed by changing the opening operation threshold and the closing operation threshold. The output voltage P to be compared with the predetermined value Y may be an instantaneous value or an average value for a predetermined time.

  And when the output voltage P is less than the predetermined value Y, the calculating part 17 closes the shutter 31 via the communication part 16 (S117). On the other hand, when the output voltage P is not less than the predetermined value Y, the calculation unit 17 determines whether the current time has passed the set time n (S118). If the set time n has elapsed, the shutter 31 is closed (S117). On the other hand, when the set time n has not elapsed, the output voltage P of the solar cell 20 is acquired again, and the process is repeated until the condition is satisfied. When it is determined that the output voltage P is lower than the predetermined value Y, the output voltage P may be acquired again and it may be determined whether the output voltage P acquired again is lower than the predetermined value Y. Since the amount of solar radiation fluctuates in a short time depending on the weather or the like, by performing these operations a plurality of times, it is possible to determine not only when the sun is temporarily weakened, but when the sun is no longer shining stably.

  When the conditions are met and the closing of the shutter 31 is completed, the closed state of the shutter 31 is maintained. Then, the closed state of the shutter 31 is maintained until a predetermined time (for example, 24:00) elapses, and when the predetermined time elapses, the operation shifts to an operation (A) for opening the shutter 31 shown in FIG. 3 (S119). ).

  In this way, the shutter 31 is closed when either the condition of the output voltage P or the condition of the set time n is satisfied. That is, when the sun hitting the house becomes weaker in the time zone earlier than the shutter closing time input by the user 50 or the sunset time acquired from the communication network 40, the shutter 31 is based on the output voltage of the solar cell 20. Is closed. Thereby, it is possible to eliminate an unnatural state that the shutter 31 is open even though the sunlight hitting the house is weakened and the surroundings are darkened.

  In addition, when the shutter closing time is input by the user 50, the shutter 31 is closed when the shutter closing time (set time n) has elapsed even if the output voltage P is not lower than the predetermined value Y. The shutter 31 can be reliably closed by the time desired by 50.

(D) When the time is outside the range of 0-12 o'clock (that is, in the afternoon) and the shutter 31 is closed, as shown in FIG. 4, in this case, the time has passed a predetermined time (for example, 24:00) The closed state of the shutter 31 is maintained until the predetermined time elapses, and when the predetermined time has elapsed, the operation proceeds to the operation (A) for opening the shutter 31 shown in FIG. 3 (S119).

  As described above, the opening / closing operation of the shutter 31 is repeatedly performed. The operation of the security system 100 continues until the user 50 performs an operation for canceling the security mode using the input unit 13 of the device control apparatus 10. In other words, the daily opening / closing operation of the shutter 31 can be automatically performed even in the absence of a long term. Since the operation timing of the opening / closing operation is changed according to the amount of daily solar radiation that changes depending on the season, weather, etc., the opening / closing operation of the shutter 31 is not patterned, and a resident can stay indoors even when absent for a long time. It is possible to make you feel like you are in the room.

Embodiment 2. FIG.
Since the configuration of the security system according to the second embodiment is the same as that of the first embodiment, the description thereof is omitted. 2, 5 and 6 are flowcharts showing a part of the operation of the crime prevention system according to the second embodiment. In the second embodiment, the operation of the security system that opens and closes the shutter 31 will be described. However, an electric curtain or an electric blind may be opened and closed instead of the shutter 31.

  As shown in FIG. 2, when the security mode is set by the user 50, the operation of the security system 100 is started (S001). First, the calculation unit 17 acquires time data from the clock unit 15 and determines whether the current time corresponds to 0-12 o'clock (S002). Next, the calculating part 17 acquires the information whether the shutter is closed or the shutter 31 is open via the communication part 16 (S003, S004). The subsequent operations differ depending on these processing results, and will be described in order with reference to FIGS.

(A) When the time is in the range of 0-12 o'clock (that is, in the morning) and the shutter 31 is closed As shown in FIG. 5, first, the calculation unit 17 acquires the data in the storage unit 14, and the storage unit 14 determines whether or not the shutter opening time is set by the user 50 (S201). The shutter opening time is time data that the user 50 inputs to the input unit 13 of the device control apparatus 10 in advance, and is the start time of the opening operation of the shutter 31 that the user 50 desires.

  When the shutter opening time is set, the calculation unit 17 processes the time (for example, 7 o'clock) as the set time m (S202). On the other hand, if the shutter opening time is not set, today's sunrise time data of the area where the house exists is acquired from the communication network 40 via the receiving unit 12, and stored in the storage unit 14 (S203). And the calculating part 17 processes the sunrise time (for example, 6 o'clock) as the set time m (S204). In addition, you may process the time shortened for the predetermined time (for example, 30 minutes) from the acquired sunrise time, and the extended time as the setting time m.

  Next, the calculating part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P exceeds the predetermined value X (S205, S206). The predetermined value X is a threshold value set in advance in the calculation unit 17, and is set based on, for example, the amount of solar radiation that is considered to open a shutter in daily life, the output voltage of the solar cell 20 in a time zone, and the like. The output voltage P to be compared with the predetermined value X may be an instantaneous value or an average value for a predetermined time.

  If the output voltage P exceeds the predetermined value X, the calculation unit 17 next determines whether the current time has passed the set time m (S207). When the set time m has elapsed, the calculation unit 17 opens the shutter 31 via the communication unit 16 (S208). On the other hand, when the output voltage P does not exceed the predetermined value X, or when the time has not passed the set time m, the output voltage P of the solar cell 20 is acquired again and repeated until the condition is satisfied. When it is determined that the output voltage P exceeds the predetermined value X, the output voltage P may be acquired again to determine whether the output voltage P acquired again exceeds the predetermined value X. Since the amount of solar radiation varies in a short period of time depending on the weather, etc., it is possible to judge when the sunshine has come to be stable rather than when the sunshine temporarily strengthened by performing these operations multiple times. it can.

  When the conditions are met and the opening of the shutter 31 is completed, the open state of the shutter 31 is maintained. Then, the shutter 31 is kept open until a predetermined time (for example, 12:00) elapses, and when the predetermined time elapses, the operation shifts to an operation (C) for closing the shutter 31 shown in FIG. 6 (S209). ). Although not shown in FIG. 5, if the output voltage P does not exceed the predetermined value X until a predetermined time for shifting to the operation (C) for closing the shutter 31 has elapsed, the shutter 31 is opened. Instead, the operation shifts to an operation (D) for maintaining the closed state of the shutter 31 shown in FIG. As a result, the shutter will not be opened if sufficient solar radiation is not obtained during the day (such as in extremely bad weather), but in such cases it will be unnatural even if the shutter is not opened. Absent.

  Thus, the shutter 31 is opened when both the conditions of the output voltage P and the condition of the set time m are satisfied. In other words, when the sun is enough for the house and the shutter opening time input by the user 50 has elapsed, or when the sun is enough for the house and the sunrise time acquired from the communication network 40 is obtained. When the time has elapsed, the shutter 31 is opened.

  Thereby, it is possible to prevent the shutter 31 from being opened before sufficient sunlight hits the house, and to prevent the shutter 31 from opening in a time zone earlier than the shutter opening time desired by the user 50. be able to. In addition, it is possible to reproduce the daily operation of the user 50 that changes according to the daily weather. For example, it is possible to reproduce a case where the user 50 normally opens the shutter 31 at 7 o'clock, but when the outside is still dark due to cloudy or rainy weather, the shutter 31 is opened when the outside becomes bright after 7 o'clock. it can. At this time, it is not necessary for the user 50 to reset the shutter opening time, which is convenient.

(B) When the time is within the range of 0-12 o'clock (that is, in the morning) and the shutter 31 is open As shown in FIG. 5, in this case, the time has passed a predetermined time (for example, 12:00) The shutter 31 is kept open until the predetermined time elapses, and the operation shifts to the operation of closing the shutter 31 shown in FIG. 6 (S209).

(C) When the time is outside the range of 0-12 o'clock (that is, in the afternoon) and the shutter 31 is open As shown in FIG. 6, first, the calculation unit 17 acquires the data in the storage unit 14, and the storage unit 14 determines whether or not the shutter closing time is set by the user 50 (S211). The shutter closing time is time data that the user 50 inputs to the input unit 13 of the device control device 10 in advance, and is the start time of the shutter 31 closing operation desired by the user 50.

  If the shutter closing time is set, the calculation unit 17 processes the time (for example, 17:00) as the set time n (S212). On the other hand, if the shutter closing time is not set, today's day time entry data of the area where the house exists is acquired from the communication network 40 via the receiving unit 12, and stored in the storage unit 14 (S213). . Then, the calculation unit 17 processes the incoming time of the day (for example, 18:00) as the set time n (S214). In addition, you may process the time which shortened predetermined time (for example, 30 minutes) from the acquisition time of the acquired date, or extended time as the setting time n.

  Next, the calculating part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P is less than the predetermined value Y (S215, S216). The predetermined value Y is a threshold value set in advance in the calculation unit 17, and is set based on, for example, the amount of solar radiation that is considered to close a shutter in daily life, the output voltage of the solar cell 20 in a time zone, and the like. The predetermined value Y is a value smaller than the predetermined value X shown in FIG. 5, and different threshold values are set for opening and closing. By changing the threshold value at the time of opening and the threshold value at the time of closing, a more natural opening / closing operation can be performed. The output voltage P to be compared with the predetermined value Y may be an instantaneous value or an average value for a predetermined time.

  If the output voltage P is below the predetermined value Y, the calculation unit 17 next determines whether the current time has passed the set time n (S217). When the set time n has elapsed, the calculation unit 17 closes the shutter 31 via the communication unit 16 (S218). On the other hand, when the output voltage P is not less than the predetermined value Y, or when the time has not passed the set time n, the output voltage P of the solar cell 20 is acquired again and it is repeated until the condition is satisfied. When it is determined that the output voltage P is lower than the predetermined value Y, the output voltage P may be acquired again and it may be determined whether the output voltage P acquired again is lower than the predetermined value Y. Since the amount of solar radiation fluctuates in a short time depending on the weather or the like, by performing these operations a plurality of times, it is possible to determine not only when the sun is temporarily weakened, but when the sun is no longer shining stably.

  When the conditions are met and the closing of the shutter 31 is completed, the closed state of the shutter 31 is maintained. Then, the closed state of the shutter 31 is maintained until a predetermined time (for example, 24:00) elapses, and when the predetermined time elapses, the operation shifts to an operation (A) for opening the shutter 31 shown in FIG. 5 (S219). ).

  As described above, the shutter 31 is closed when both the condition of the output voltage P and the condition of the set time n are satisfied. In other words, when the house is no longer exposed to sufficient sunlight and the shutter closing time entered by the user 50 has elapsed, or the house is no longer exposed to sufficient sunlight, and acquired from the communication network 40 The shutter 31 is closed when the time for entering the date has passed.

  As a result, it is possible to prevent the shutter 31 from being closed when the house is still exposed to sufficient sunlight, and to close the shutter 31 in a time zone earlier than the shutter closing time desired by the user 50. Can be prevented.

(D) When the time is outside the range of 0-12 o'clock (that is, in the afternoon) and the shutter 31 is closed, as shown in FIG. 6, in this case, the time has passed a predetermined time (for example, 24:00) The closed state of the shutter 31 is maintained until the predetermined time has elapsed, and when the predetermined time has elapsed, the operation proceeds to the operation (A) for opening the shutter 31 shown in FIG. 5 (S219).

  As described above, the opening / closing operation of the shutter 31 is repeatedly performed. The operation of the security system 100 continues until the user 50 performs an operation for canceling the security mode using the input unit 13 of the device control apparatus 10. In other words, the daily opening / closing operation of the shutter 31 can be automatically performed even in the absence of a long term. Since the operation timing of the opening / closing operation is changed according to the amount of daily solar radiation that changes depending on the season, weather, etc., the opening / closing operation of the shutter 31 is not patterned, and a resident can stay indoors even when absent for a long time. It is possible to make you feel like you are in the room.

Embodiment 3 FIG.
In the first and second embodiments, the crime prevention system that operates the shutter 31 based on the output voltage of the solar cell 20 has been described. In the third embodiment, the crime prevention system that operates the air conditioner 32 and the ventilation fan 33 based on the output voltage of the solar cell 20. Will be explained. The air conditioner 32 operates an outdoor unit. In the following description, the air conditioner 32 is described as the outdoor unit 32. Although the indoor unit may be operated together, the power consumption can be minimized by operating only the outdoor unit 32.

  Since the configuration of the crime prevention system according to the third embodiment is the same as that of the first and second embodiments, the description thereof is omitted. FIG. 7 is a flowchart showing the operation of the crime prevention system according to the third embodiment. In the crime prevention system according to the third embodiment, weather data is acquired from the communication network, and either the outdoor unit 32 or the ventilation fan 33 is operated according to the weather data. In addition, for the outdoor unit 32, the operation start timing and operation stop timing change according to the weather data. Details will be described below.

  As shown in FIG. 7, when the security mode is set by the user 50, the operation of the security system 100 is started (S301). First, the weather data of the area where a house exists is acquired from the communication network 40 via the receiving part 12, and it memorize | stores in the memory | storage part 14 (S302). Here, the meteorological data is data such as temperature that changes according to the season and weather. In the third embodiment, today's predicted maximum temperature is used as weather data, and the predicted maximum temperature is 25 ° C or higher (assuming summer), less than 15 ° C (assuming winter), 15 ° C or higher and lower than 25 ° C (spring, autumn) Assumed), the control content changes.

The case where today's expected maximum temperature is 25 ° C. or higher will be described.
First, the calculation unit 17 acquires the output voltage P of the solar cell 20 via the detection unit 11, and determines whether the output voltage P exceeds a predetermined value V (S311 and 312). The predetermined value V is a threshold value set in advance in the calculation unit 17, and is set based on, for example, the amount of solar radiation that is considered to cause the air temperature to increase and the air-conditioner cooling operation to operate, the output voltage of the solar cell 20 in the time zone, and the like. Yes. The output voltage P to be compared with the predetermined value V may be an instantaneous value or an average value for a predetermined time.

  And when the output voltage P exceeds the predetermined value V, the calculating part 17 drives the outdoor unit 32 via the communication part 16 (S313). On the other hand, when the output voltage P does not exceed the predetermined value V, the output voltage P of the solar cell 20 is acquired again, and the process is repeated until the condition is satisfied. When it is determined that the output voltage P exceeds the predetermined value V, the output voltage P may be acquired again and it may be determined whether the newly acquired output voltage P exceeds the predetermined value V. Since the amount of solar radiation fluctuates in a short time depending on the weather, etc., by performing these operations a plurality of times, the output voltage P temporarily exceeded the predetermined value V instead of being temporarily higher than the predetermined value V. The time can be determined.

  After driving the outdoor unit 32, the calculation part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P is less than the predetermined value W (S314, 315). . And when the output voltage P is less than the predetermined value W, the calculating part 17 stops the outdoor unit 32 via the communication part 16 (S316). On the other hand, when the output voltage P is not lower than the predetermined value W, the output voltage P of the solar cell 20 is acquired again, and the process is repeated until the condition is satisfied. The predetermined value W is a threshold value set in advance in the calculation unit 17, and is set based on, for example, the amount of solar radiation that is considered to stop the air-conditioning cooling operation due to low air temperature, the output voltage of the solar cell 20 in the time zone, or the like. Yes. The predetermined value W is smaller than the predetermined value V. By setting the threshold value at the time of stop to be lower than the threshold value at the start of the operation, the outdoor unit 32 operates and the solar radiation is affected by fogging. It is possible to prevent the outdoor unit 32 from immediately stopping when the amount changes. The output voltage P to be compared with the predetermined value W may be an instantaneous value or an average value for a predetermined time.

  After the outdoor unit 32 is stopped, the apparatus enters a standby state until the time elapses at 24:00. When the time elapses at 24:00, the operation shifts to the start (E) of the operation (S317). And the weather data of the next day is acquired and the operation | movement based on the acquired weather data is continued.

  Thus, the time zone when the temperature of daytime is high is judged based on the output voltage P of the solar cell 20, and the outdoor unit 32 is operated at that time. As a result, the outdoor unit 32 is not moving during the daytime when the summer temperature is high, so that it is possible to prevent the resident from being sensed to be absent. You can feel like you are in a room.

Next, the case where today's predicted maximum temperature is less than 15 ° C. will be described.
First, the calculation part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P is larger than 0 and less than the predetermined value W (S321, 322). The predetermined value W is a threshold value set in advance in the calculation unit 17, and is set based on, for example, the amount of solar radiation considered to cause the air conditioner to operate the heating operation at a low temperature, the output voltage of the solar cell 20 in the time zone, or the like. . The predetermined value W is common to the predetermined value W described in the operation when the predicted maximum temperature is 25 ° C. or higher. However, a different value may be set. The output voltage P to be compared with the predetermined value W may be an instantaneous value or an average value for a predetermined time.

  If the output voltage P is greater than 0 and less than the predetermined value W, the calculation unit 17 drives the outdoor unit 32 via the communication unit 16 (S323). On the other hand, if the output voltage P is greater than or equal to the predetermined value W, the output voltage P of the solar cell 20 is acquired again and repeated until the condition is satisfied. When it is determined that the output voltage P is larger than 0 and lower than the predetermined value W, the output voltage P is acquired again and the output voltage P newly acquired is larger than 0 and the predetermined value W is decreased. You may make it judge whether it is less. Since the amount of solar radiation fluctuates in a short time depending on the weather, etc., by performing these operations a plurality of times, the output voltage P temporarily falls below the predetermined value W instead of being temporarily lower than the predetermined value W. You can determine when.

  After driving the outdoor unit 32, the calculation part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P exceeds the predetermined value W (S324, 325). . And when the output voltage P is over the predetermined value W, the calculating part 17 stops the outdoor unit 32 via the communication part 16 (S326). On the other hand, when the output voltage P does not exceed the predetermined value W, the output voltage P of the solar cell 20 is acquired again, and the process is repeated until the condition is satisfied. Thereby, for example, it is determined that the amount of solar radiation is considered to be high due to an increase in temperature and to stop the heating operation of the air conditioner. The output voltage P to be compared with the predetermined value W may be an instantaneous value or an average value for a predetermined time.

  After the outdoor unit 32 is stopped, the apparatus enters a standby state until the time elapses at 24:00, and when the time elapses at 24:00, the operation shifts to the start of operation (E) (S327). And the weather data of the next day is acquired and the operation | movement based on the acquired weather data is continued.

  Thus, the time zone when the morning air temperature is low is determined based on the output voltage P of the solar battery 20, and the outdoor unit 32 is operated at that time. This prevents the outdoor unit 32 from moving in the morning when the temperature is low in winter, so that it is possible to prevent the resident from being sensed to be absent. You can make it feel like you are.

Next, the case where today's predicted maximum temperature is 15 ° C. or higher and lower than 25 ° C. will be described.
First, the calculation part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P exceeds the predetermined value V (S331, 332). The predetermined value V is a threshold value set in advance in the calculation unit 17 and is set based on, for example, the amount of solar radiation that is considered to cause the indoor air temperature to increase and the ventilation fan 33 to operate, the output voltage of the solar cell 20 in the time zone, and the like. Yes. The predetermined value V is common to the predetermined value V described in the operation when the predicted maximum temperature is 25 ° C. or higher, but a different value may be set. The output voltage P to be compared with the predetermined value V may be an instantaneous value or an average value for a predetermined time.

  And when the output voltage P exceeds the predetermined value V, the calculating part 17 drives the ventilation fan 33 via the communication part 16 (S333). On the other hand, when the output voltage P does not exceed the predetermined value V, the output voltage P of the solar cell 20 is acquired again, and the process is repeated until the condition is satisfied. When it is determined that the output voltage P exceeds the predetermined value V, the output voltage P may be acquired again and it may be determined whether the newly acquired output voltage P exceeds the predetermined value V. Since the amount of solar radiation fluctuates in a short time depending on the weather, etc., by performing these operations a plurality of times, the output voltage P temporarily exceeded the predetermined value V instead of being temporarily higher than the predetermined value V. The time can be determined.

  After driving the ventilation fan 33, the calculation part 17 acquires the output voltage P of the solar cell 20 via the detection part 11, and judges whether the output voltage P is less than the predetermined value W (S334, 335). And when the output voltage P is less than the predetermined value W, the calculating part 17 stops the ventilation fan 33 via the communication part 16 (S336). On the other hand, when the output voltage P is not lower than the predetermined value W, the output voltage P of the solar cell 20 is acquired again, and the process is repeated until the condition is satisfied. Thereby, for example, it is determined that the amount of solar radiation is considered to be high due to an increase in temperature and to stop the heating operation of the air conditioner. Further, the predetermined value W is a value smaller than the predetermined value V, and the amount of solar radiation is influenced by fogging and the like after the ventilation fan 33 is operated by setting the threshold value at the time of stop to be lower than the threshold value at the start of operation. It is possible to prevent the ventilation fan 33 from immediately stopping due to fluctuations. The output voltage P to be compared with the predetermined value W may be an instantaneous value or an average value for a predetermined time.

  After stopping the ventilation fan 33, it will be in a standby state until the time of 24:00 has passed, and when the time of 24:00 has passed, it shifts to the start of the operation (E) (S337). And the weather data of the next day is acquired and the operation | movement based on the acquired weather data is continued.

  Thus, the time zone when the temperature of daytime is high is judged based on the output voltage P of the solar cell 20, and the ventilation fan 33 is operated at that time. In this way, in the season when there is relatively little opportunity to operate the air conditioner 32 such as spring or autumn, the ventilation fan 33 is operated instead of the air conditioner 32 to make it feel like a resident is indoors. Can do.

  As described above, the operation of the outdoor unit 32 or the ventilation fan 33 is repeatedly performed. The operation of the security system 100 continues until the user 50 performs an operation for canceling the security mode using the input unit 13 of the device control apparatus 10. In other words, the outdoor unit 32 or the ventilation fan 33 can be automatically operated every day even in the absence of a long period of time, and the crime prevention effect can be exhibited. And since the equipment to be operated and the operation timing are changed according to the amount of daily solar radiation that changes according to the season and weather, it is possible to make it feel like a resident is indoors even when absent for a long time. .

  Here, the television 34 in the house may be operated similarly to the operation of the outdoor unit 32 described in the third embodiment. In this case, by appropriately setting the values of the two threshold values (predetermined values V and W in the third embodiment), the solar radiation 20 is automatically given a certain amount of solar radiation according to the output voltage P. It is possible to operate the television 34 or to operate the television 34 after sunset. Then, it is possible to make it feel as if a resident is present indoors by the sound of the television. When operating the television 34, the power consumption can be minimized by outputting only the sound.

  Further, in the opening / closing operation of the shutter 31 described in the first and second embodiments, the lighting 35 in the house may be turned on / off in accordance with the operation of the shutter 31. For example, since it is common to turn on the illumination 35 from the time when the shutter 31 is closed to bedtime in daily life, the process of closing the shutter 31 shown in FIGS. 4 and 6 (S117, S218). The illumination 35 is turned on for a predetermined time later. Further, since it is common to turn off the illumination 35 when the shutter 31 is opened in daily life, the illumination 35 is temporarily provided before the process (S107, S208) for opening the shutter 31 shown in FIGS. Is turned on, and the illumination 35 is turned off after the process of opening the shutter 31. As a result, after the shutter 31 is closed, the light of the lighting 35 leaks from other windows of the house, and after the shutter 31 is opened, the lighting 35 is turned off, so that the resident is in the room. Is possible.

  The conditions for starting and stopping the operation of the outdoor unit 32 or the ventilation fan 33 described in the third embodiment are not only determined based on the output voltage P of the solar battery 20, but also described in the first and second embodiments. The operation start and operation stop may be determined by combining the set times m and n. In addition, in the opening / closing operation of the shutter 31 described in the first and second embodiments, the weather data described in the third embodiment may be adopted, and a more detailed opening / closing operation of the shutter 31 is performed according to the season. And the crime prevention effect can be further improved. Furthermore, the operation timing of the opening / closing operation of the shutter 31 described in the first and second embodiments may be determined based only on the output voltage P as described in the third embodiment.

  In addition, the operations of the shutter 31, the outdoor unit 32, the ventilation fan 33, the television 34, and the lighting 35 described so far may be performed in parallel, and by operating a plurality of electrical devices 30, there are residents in the room. It is possible to feel more like a room.

DESCRIPTION OF SYMBOLS 10 Device control apparatus, 11 Detection part, 12 Reception part, 13 Input part, 14 Storage part, 15 Clock part, 16 Communication part, 17 Calculation part, 20 Solar cell, 30 Electric equipment, 31 Shutter, 32 Air conditioner (outdoor unit) , 33 Ventilation fan, 34 Television, 35 Lighting, 40 Communication network, 50 users, 100 Security system.

Claims (9)

A solar cell that is a power generation device, an electrical device provided in a house, and a device control device that is connected to the solar cell, the electrical device, and a communication network, and controls the operation of the electrical device,
The device control device
A detection unit for detecting output voltage data of the solar cell;
A receiver for receiving data from the communication network;
An input unit that accepts user input;
A storage unit for storing the time data received by the receiving unit and the time data received by the input unit;
A calculation unit that determines the timing of operation start or operation stop of the electrical device based on the output voltage data detected by the detection unit and the time data stored in the storage unit;
A crime prevention system characterized in that, when a crime prevention mode for crime prevention is set by a user, an operation of the electric device is automatically controlled based on a determination result of the calculation unit.   The crime prevention system according to claim 1, wherein the time data received by the input unit is time data related to an operation start time of the electric device desired by a user.   The crime prevention system according to claim 1, wherein the time data received by the receiving unit is time data relating to a sunrise time or a sunset time corresponding to an area where the house is present. . In the arithmetic unit, a first threshold value to be compared with the output voltage data and a second threshold value different from the first threshold value are set,
The calculation unit determines the operation start of the electric device on the condition that at least the output voltage data exceeds the first threshold, and at least the condition that the output voltage data falls below the second threshold. The crime prevention system according to claim 1, wherein operation stop of the electric device is determined. In the arithmetic unit, a first threshold value to be compared with the output voltage data and a second threshold value different from the first threshold value are set,
The electrical device has two modes of operation;
The computing unit determines the start of operation of the first operation mode of the electrical device on the condition that at least the output voltage data exceeds the first threshold value, and at least the output voltage data is the second threshold value. The crime prevention system according to any one of claims 1 to 3, wherein the operation start of the second operation mode of the electric device is determined on condition that the value is less than. In the arithmetic unit, a first threshold value to be compared with the output voltage data and a second threshold value different from the first threshold value are set,
The calculation unit determines the operation start of the electric device when the output voltage data exceeds the first threshold and the time has passed a first set time based on the time data stored in the storage unit. And determining that the operation of the electric device is stopped when the output voltage data falls below the second threshold and the second set time based on the time data stored in the storage unit has elapsed. The crime prevention system according to any one of claims 1 to 3. In the arithmetic unit, a first threshold value to be compared with the output voltage data and a second threshold value different from the first threshold value are set,
The electrical device has two modes of operation;
The computing unit performs a first operation of the electrical device when the output voltage data exceeds the first threshold and a first set time based on time data stored in the storage unit has elapsed. When the output voltage data falls below the second threshold and the second set time based on the time data stored in the storage unit has elapsed, The crime prevention system according to claim 1, wherein the operation start of the second operation mode is determined. The receiving unit receives weather data corresponding to an area where the house exists from a communication network,
The crime prevention system according to claim 1, wherein the calculation unit changes a timing of starting or stopping the operation of the electric device according to the weather data. A detection unit for detecting output voltage data of the solar cell;
A communication unit that transmits a signal including an operation instruction to an electrical device;
When a crime prevention mode for crime prevention is set by a user, the timing for starting or stopping the operation of the electrical device is determined based on the output voltage data detected by the detection unit, and the communication is performed based on the determination result. An arithmetic unit that controls the operation of the electrical device via the unit;
Equipment control device with

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