JP2016178044A - Apparatus controller and control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress impairment of comfort due to failure detection, even if failure detection is performed in an arbitrary time zone.SOLUTION: An apparatus controller has an illuminance comparison unit for comparing a first illuminance detected by an illuminance detector disposed at a position corresponding to one illumination apparatus, out of a plurality of illumination apparatus for illuminating the space, with a second illuminance detected by the illuminance detector, while changing the lighting state of the one illumination apparatus from the lighting state when the first illuminance is detected, and a failure determination unit for determining whether or not the one illumination apparatus is faulty depending on the comparison results.SELECTED DRAWING: Figure 16

Description

  The present invention relates to a control device and a control system for controlling lighting equipment.

  In recent years, lighting devices having various functions are becoming popular. As an example thereof, for example, an illumination device having an illumination sensor and having a dimming function that changes the brightness of light emitted from the illumination device depending on the brightness of the room is known. As another example, there is known a lighting device having a failure detection function that confirms the illuminance of the lighting device and discriminates a lighting device with extremely low illuminance as a failure.

  Conventionally, failure detection of lighting equipment is generally performed in a time zone where there is no person in the room. Conventionally, by detecting a failure in such a time zone, it is possible to prevent the comfort from being impaired due to lighting or extinguishing of lighting equipment unintended by a person in the room. For example, in an office, it is assumed that there are many people in the room during the day, so failure detection is performed at night or the like.

  As described above, it is assumed that the conventional failure detection is performed in a time zone where there is no person in the room, and it is difficult to perform the failure detection in an arbitrary time zone.

  The disclosed technology aims to suppress the loss of comfort due to failure detection even when failure detection is performed in an arbitrary time zone.

  In the disclosed technology, among a plurality of lighting devices that illuminate a space, the first illuminance detected by the illuminance detection unit arranged at a position corresponding to one lighting device, and the lighting state of the one lighting device, An illuminance comparison unit that compares the second illuminance detected by the illuminance detection unit after changing from the lighting state when the first illuminance is detected, and the one illumination device fails according to the comparison result. A failure determination unit that determines whether or not

  The disclosed technology can suppress the loss of comfort due to failure detection even when failure detection is performed in any time zone regardless of the presence / absence of a person.

It is a figure which shows an example of the system configuration | structure of a control system. It is a figure which shows the example of installation of an illuminating device, a tap, and an air conditioner. It is a figure explaining the detection of the person by a human sensor. It is a figure explaining the acquisition of the illumination data by an illumination sensor. It is a figure explaining a sensor module. It is a figure explaining lighting equipment. It is a figure which shows the example which integrated the sensor module and the illuminating device. It is a figure explaining the structure of an integrated unit. It is a figure explaining the detection direction of the human sensor which an integrated unit has. It is a figure which shows the example of arrangement | positioning of an illuminating device. It is a figure which shows an example of the hardware constitutions of a control server. It is a figure explaining functional composition of a control server of a first embodiment. It is a figure which shows an example of an illumination arrangement database. It is a figure which shows an example of a lighting state database. It is a figure explaining the function of the illumination control part of 1st embodiment. It is a flowchart explaining operation | movement of the control server of 1st embodiment. It is a figure which shows an example of the system configuration | structure of the control system of 2nd embodiment. It is a figure explaining the function which each apparatus of the control system of a second embodiment has.

  Embodiments will be described below with reference to the drawings. FIG. 1 is a diagram illustrating an example of a system configuration of a control system.

  The control system 100 includes a control server 200, a sensor module 10, a current sensor 400, a lighting device 500, a tap 600, and an air conditioner 700.

  In the control system 100, the control server 200, the sensor module 10, the current sensor 400, the lighting device 500, the tap 600, and the air conditioner 700 are connected via a network N. The control server 200 may be connected to the PC 800 via the network N. The PC 800 may be used by an administrator who manages the control server 200, for example.

  The control server 200 controls the lighting device 500, the tap 600, and the air conditioner 700 based on the data acquired from the sensor module 10 and the current sensor 400.

  The sensor module 10 includes a human sensor 251, an illuminance sensor 300, and a temperature / humidity sensor 350.

  The human sensor 251 is a thermopile sensor that detects the presence or absence of a person in the room by detecting infrared rays or the like. The human sensor 251 is connected to the control server 200, and detected human presence / absence data is transmitted to the control server 200 via the network N.

  The illuminance sensor 300 is a sensor that detects the brightness of the room. The temperature and humidity sensor 350 is a sensor that detects the temperature and humidity of the room. The illuminance sensor 300 and the temperature / humidity sensor 350 transmit the detected data to the control server 200 via the network N.

  The current sensor 400 is connected to a power source that supplies power to the lighting device 500, the tap 600, and the air conditioner 700. The current sensor 400 detects the amount of current and transmits data on the detected amount of current to the control server 200 via the network N.

  The control server 200 may be connected to each of the sensors described above, the lighting device 500, the tap 600, and the air conditioner 700 via a wireless communication network such as Wi-Fi, for example. However, the communication method is not limited to Wi-Fi, and other wireless communication methods may be used. Wired communication systems such as Ethernet (registered trademark) cables and PLC (Power Line Communications) can also be used.

  The lighting device 500 is a lighting device using LED lighting, for example. The tap 600 is an instrument for supplying power to a plurality of devices. The air conditioner 700 is a device that adjusts the temperature, humidity, cleanliness, airflow, and the like of air in a certain place for the purpose of improving human comfort and industrial purposes in handling articles such as production, management, and storage. .

  Below, with reference to FIG. 2, the installation example in the room | chamber interior of the lighting equipment 500, the tap 600, and the air conditioner 700 is demonstrated. FIG. 2 is a diagram illustrating an installation example of lighting devices, taps, and air conditioners.

  In the example of FIG. 2, one group is formed by six desks in the room, and three groups are provided. One lighting device 500 and one tap 600 are provided for each desk. On the other hand, one air conditioner 700 is provided between two groups.

  In addition, arrangement | positioning of the illuminating device 500 shown in FIG. 2, the tap 600, and the air conditioner 700 is an example, and is not limited to this. Moreover, in this embodiment, the sum total of all the electric power in a room | chamber interior can be grasped | ascertained now by the system | strain electric power measurement apparatus installed, for example outside.

  In the room, 18 users can carry out specific business activities, and the entrance to and exit from the room is performed by two doors. In the example of FIG. 2, the layout, devices, the number of users, and the like are limited, but the present invention can be applied to a wider variety of layouts and devices.

  Each of lighting device 500, tap 600, and air conditioner 700 is remotely controlled by control server 200.

  In the illumination device 500, the illumination range and illuminance are controlled by the control server 200. More specifically, lighting device 500 is provided with an on / off switch that can be individually remotely controlled, and the on / off of the switch is controlled by a wireless control method using Wi-Fi.

  The lighting device 500 may use an LED lamp with a dimming function in consideration of low power consumption. In this case, the control server 200 may also perform remote control via Wi-Fi regarding the dimming function of the lighting device 500.

  The lighting device 500 is not limited to the one using LED lighting. The illumination device 500 includes, for example, an incandescent lamp or a fluorescent lamp.

  The air conditioner 700 is controlled to be turned on / off by the control server 200. The air conditioner 700 can be individually controlled remotely, and in addition to turning the power on / off, the air direction, the air blowing intensity, and the like are also controlled. The air conditioner 700 may also be controlled with respect to the temperature and humidity of the blowing air.

  The tap 600 is provided with a plurality of tap openings, and the control server 200 controls on / off of power supply to each tap opening. The tap 600 is provided with an on / off switch that can be remotely controlled individually for each tap opening, and the control server 200 controls on / off by a wireless control method using Wi-Fi.

  In FIG. 2, the lighting device 500, the tap 600, and the air conditioner 700 that are objects to be controlled by the control server 200 are provided in the room, but are not limited thereto. The device to be controlled by the control server 200 may be installed outdoors.

  Next, human detection by the human sensor 251 will be described with reference to FIG. FIG. 3 is a diagram for explaining human detection by the human sensor.

  FIG. 3 shows an example in which the human sensor 251 is a thermopile sensor having 4 × 4 elements (pixels), and the presence / absence of a person and the position of a person are detected for each of 16 divided areas. In FIG. 3, the human sensor 251 is provided on the ceiling of the room.

  The human sensor 251 detects the temperature for each area. When there is a person, the pixel is enabled (“1”), and when there is no person, the pixel is disabled (“0”). The simplified data to be represented is transferred to the radio device 30, for example. Data is transferred from the wireless device to the control server 200.

  The control server 200 includes a heating element relative position information acquisition unit that acquires the relative position information of the heating elements with respect to articles and structures. The control server 200 compares the indoor layout data stored in the control server 200 with any location in the room. Identify if there is a heating element, ie a person.

  Next, acquisition of illuminance data by the illuminance sensor 300 will be described with reference to FIG. FIG. 4 is a diagram for explaining the acquisition of illuminance data by the illuminance sensor.

  In FIG. 4, the illuminance sensor 300 is provided on the ceiling in the room, and acquires illuminance data of a space (illuminance detection area) below itself. The acquired illuminance data is transferred to, for example, the wireless device 30 and transferred to the control server 200.

  The illuminance sensor 300 may transmit illuminance data acquired periodically to the control server 200. The illuminance sensor 300 may transmit the illuminance data to the control server 200 when detecting the change in the illuminance data when the illuminance data is acquired.

  Next, the sensor module 10 will be described with reference to FIG. FIG. 5 is a diagram illustrating the sensor module.

  The sensor module 10 includes a sensor driver 11, a wireless module 12, an antenna I / F (interface) 13, and an antenna 14 in addition to the human sensor 251, the illuminance sensor 300, and the temperature / humidity sensor 350.

  In the sensor module 10, each sensor passes data acquired by the sensor to the wireless module 12 via the sensor driver 11. The wireless module 12 transmits data to the wireless device 30 via the antenna I / F 13 and the antenna 14.

  Next, the illumination device 500 will be described with reference to FIG. FIG. 6 is a diagram illustrating a lighting device.

  The illumination device 500 uses LED illumination and has a dimming function.

  The lighting device 500 includes an LED 501, an LED driver 502, a wireless module 503, an antenna I / F 504, and an antenna 500.

  The lighting device 500 includes a plurality of LEDs 501. The LED driver 502 receives control data for dimming from the control server 200 via the antenna 505 and the antenna I / F 504, drives the LED, and performs dimming.

  The lighting device 500 may be integrated with the sensor module 10. FIG. 7 is a diagram illustrating an example in which a sensor module and a lighting device are integrated.

  An integrated unit 500A shown in FIG. 7 includes an antenna 71, an antenna I / F 72, and a wireless module 73 that are shared by the sensor driver 11 and the LED driver 502.

  Hereinafter, the integrated unit will be further described with reference to FIG. FIG. 8 is a diagram illustrating the configuration of the integrated unit. FIG. 8A is an enlarged view of an end portion of the integrated unit 500A, and FIG. 8B is a side view of the integrated unit. The side view of FIG. 8 (B) is a side view when the integrated unit 500A is viewed in the direction of the arrow shown in FIG. 8 (A).

  In the integrated unit 500A, two human sensors 251 are attached to the LED 501. The human sensor 251 is, for example, a thermopile. The two human sensors 251 are attached to the LED 501 so that their detection directions are different.

  Since the integrated unit 500A includes various sensors, the lighting device 500 and the various sensors can be disposed at the same time, and installation labor, cost, and space can be reduced. Moreover, in the integrated unit 500A, the detection range of the temperature distribution can be expanded by changing the detection direction of the human sensor 251.

  Further, the integrated unit 500A can be rotated in the circumferential direction of the LED 501 so that the detection direction of the human sensor 251 can be adjusted.

  FIG. 9 is a diagram illustrating the detection direction of the human sensor included in the integrated unit. FIG. 9A is a first diagram illustrating the detection direction of the human sensor, and FIG. 9B is a second diagram illustrating the detection direction of the human sensor.

  For example, when the mounting surface of the LED tube 501 of the LED tube mounting tool 506 is inclined as shown in FIG. 9A, the integrated unit 500A is moved to the arrow as shown in FIG. 9B. The detection direction of the human sensor 251 can be adjusted by rotating in the direction.

  Next, the arrangement of the lighting device 500 will be described with reference to FIG. FIG. 10 is a diagram illustrating an example of the arrangement of lighting devices. In the present embodiment, the lighting device 500 is arranged indoors. Moreover, you may make the some lighting equipment 500 arrange | positioned indoors into the integrated unit 500A.

  As shown in FIG. 10, the lighting device 500 is managed for each column. In FIG. 10, the row on the window side closest to the window in the room is A row, and n lighting devices 500 are installed in one row. Further, in the present embodiment, the columns are identified such that the column adjacent to the A column is the B column, and the column adjacent to the B column on the side facing the interior is the C column.

  Note that the integrated unit 500A may be disposed between the lighting device 500 and the lighting device 500, for example.

  Information on the arrangement of the lighting device 500 and the integrated unit 500A is stored in the control server 200 in advance.

  FIG. 11 is a diagram illustrating an example of a hardware configuration of the control server.

  The control server 200 includes an input device 21, an output device 22, a drive device 23, an auxiliary storage device 24, a memory device 25, an arithmetic processing device 26, and an interface device 27 that are mutually connected by a bus B.

  The input device 21 includes a keyboard and a mouse, and is used for inputting various signals. The output device 22 includes a display device and the like, and is used to display various windows and data. The interface device 27 includes a modem, a LAN card, and the like, and is used for connecting to a network.

  A failure detection program to be described later is at least a part of various programs that control the control server 200. The failure detection program is provided by, for example, distribution of the recording medium 28 or downloading from a network. The recording medium 28 on which the failure detection program is recorded is information such as a CD-ROM, a flexible disk, a magneto-optical disk, etc., a recording medium for recording information optically, electrically or magnetically, a ROM, a flash memory, etc. Various types of recording media, such as a semiconductor memory that electrically records data, can be used.

  The failure detection program is installed in the auxiliary storage device 24 from the recording medium 28 via the drive device 23 when the recording medium 28 on which the failure detection program is recorded is set in the drive device 23. The failure detection program downloaded from the network is installed in the auxiliary storage device 24 via the interface device 27.

  The auxiliary storage device 24 stores the installed failure detection program and also stores necessary files, data, and the like. The memory device 25 reads and stores the failure detection program from the auxiliary storage device 24 when the computer is activated. The arithmetic processing unit 26 implements various processes as described later according to the failure detection program stored in the memory device 25.

(First embodiment)
Next, the control server 200 of the first embodiment will be described with reference to the drawings. When the control server 200 according to the present embodiment performs the failure detection process, the control server 200 detects the malfunctioning lighting device 500 or the integrated unit 500A based on the illuminance data corresponding to the lighting state of each lighting device 500 or the integrated unit 500A. Identify. In the following description, the lighting device 500 or the integrated unit 500A is simply referred to as the lighting device 500.

  That is, in this embodiment, failure detection is performed while maintaining the lighting state of each lighting device 500. Therefore, in this embodiment, failure detection can be performed while maintaining the lighting state of the lighting device 500 as intended by the person in the room.

  For this reason, in this embodiment, it is not necessary to consider the presence / absence of a person in the room, and failure detection can be performed in an arbitrary time zone.

  FIG. 12 is a diagram illustrating the functional configuration of the control server according to the first embodiment. The control server 200 of the present embodiment has a lighting arrangement database 210 and a lighting state database 220. In addition, the control server 200 according to the present embodiment includes a communication unit 230, a power consumption management unit 240, a human processing unit 250, and a device control unit 260.

The illumination arrangement database 210 stores information related to the arrangement of the lighting device 500. The lighting state database 220 stores information indicating a lighting state of each lighting device 500 or the integrated unit 500A and information indicating a failure state of the lighting device 500. The lighting state indicates whether the lighting device 500 is turned on or off. The failure state indicates whether the lighting device 500 has failed or is normal.
Note that each database of the present embodiment may be provided in the auxiliary storage device 24 of the control server 200 or the like. Details of each database will be described later.

  The communication unit 230 according to the present embodiment receives the power consumption consumed by the lighting device 500, the electric device connected to the tap 600, and the air conditioner 700. Further, the communication unit 230 transmits a control signal for performing power control to the lighting device 500, the tap 600, and the air conditioner 700. The power consumption management unit 240 manages the power consumption acquired via the communication unit 230.

  The human processing unit 250 detects the presence / absence of a person based on the data collected from the human sensor 251.

  The device control unit 260 includes an illumination control unit 270, an outlet control unit 280, and an air conditioning control unit 290.

  The illumination control unit 270 includes a failure detection unit 273, and controls the illumination device 500 and the integrated unit 500A based on data acquired from the human sensor 251 and the illuminance sensor 300, respectively. Details of the illumination control unit 270 will be described later.

  Outlet control unit 280 transmits a control signal for turning on / off the switch of the tap port to the tap port of tap 600. The air conditioning control unit 290 controls the power on / off of the air conditioner 700 according to the presence / absence of a human being by the human detection processing unit 250.

  Below, with reference to FIG.13 and FIG.14, each database which the control server 200 has is demonstrated.

  FIG. 13 is a diagram illustrating an example of an illumination arrangement database. The illumination arrangement database 210 of the present embodiment includes an illuminance sensor ID, an illuminance detection area, an illumination ID, and an array as information items. In the illumination arrangement database 210, the value of the item “illuminance sensor ID” is associated with the values of other items. In the following description, data including the value of the item “illuminance sensor ID” and values of other items is referred to as illumination arrangement data.

  The value of the item “illuminance sensor ID” is identification information given to each of the illuminance sensors 300, and is for specifying the illuminance sensor 300. The value of the item “illuminance detection area” is a coordinate indicating an area where illuminance is detected by the illuminance sensor 300 to which the corresponding illuminance sensor ID is assigned. In the present embodiment, the value of the item “illuminance detection area” is a coordinate value of four points.

  The value of the item “lighting ID” is identification information given to each of the lighting device 500 and the integrated unit 500A. The value of the item “array” indicates a column including the lighting device 500 to which the corresponding lighting ID is assigned and the integrated unit 500A.

  FIG. 14 is a diagram illustrating an example of a lighting state database. The lighting state database 220 of this embodiment includes a lighting ID, a lighting flag, and a failure flag as information items, and the two flags are associated with the lighting ID.

  In the lighting state database 220 of this embodiment, when the value of the item “lighting flag” is ON, it indicates that the lighting device 500 specified by the corresponding lighting ID is turned on. In the lighting state database 220, when the value of the item “lighting flag” is OFF, it indicates that the lighting device 500 specified by the corresponding lighting ID is turned off.

  In this embodiment, when the value of the item “failure flag” is “1”, it indicates that the lighting device 500 to which the corresponding illumination ID is assigned is determined to be a failure. Further, when the value of the item “failure flag” is “0”, it indicates that the lighting device 500 to which the corresponding lighting ID is assigned is determined to be normal.

In the following description, information including the value of the item “lighting ID” and the values of other items associated with the item “lighting ID” is referred to as lighting state information.
Next, the illumination control unit 270 will be described with reference to FIG. FIG. 16 is a diagram illustrating the function of the illumination control unit of the first embodiment.

  The illumination control unit 270 of this embodiment includes a sensor data acquisition unit 271, a lighting control unit 272, and a failure detection unit 273.

  The sensor data acquisition unit 271 acquires illuminance data from the illuminance sensor 300. The lighting control unit 272 controls lighting / extinguishing and illuminance of the LED 501 of the lighting device 500 and the integrated unit 500A according to the acquired illuminance. Specifically, for example, if there is no person in the area where the illuminance is obtained from the illuminance sensor 300, the lighting control unit 272 lowers the illuminance of the lighting device 500 and the integrated unit 500A below a predetermined value.

  The failure detection unit 273 of the present embodiment detects a failure of the indoor lighting device 500 and the integrated unit 500A.

  The failure detection unit 273 of the present embodiment includes a lighting state acquisition unit 274, an illuminance comparison unit 275, a failure determination unit 276, and a failure notification unit 277.

  When the lighting state acquisition unit 274 of the present embodiment receives an instruction to execute the failure detection process, the lighting state acquisition unit 274 refers to the lighting state database 220 and acquires the lighting state of each lighting device 500.

  The illuminance comparison unit 275 compares the illuminance data acquired in the lighting state for each lighting device 500 with the illuminance data acquired by changing the lighting state for each lighting device 500.

  The failure determination unit 276 specifies the lighting device 500 in which the difference in illuminance is a predetermined value or more according to the comparison result.

  The failure notifying unit 277 notifies the administrator of the control server 200 of the failure when there is the lighting device 500 or the integrated unit 500A that is determined to be broken. The failure notification unit 277 may notify, for example, the PC 800 or the like that the failure has been detected and the lighting device 500 or the integrated unit 500A that has been determined to be defective.

  Next, the operation of the control server 200 of this embodiment will be described with reference to FIG. FIG. 16 is a flowchart for explaining the operation of the control server of the first embodiment.

  In the control server 200 of the present embodiment, the lighting state acquisition unit 274 sets the variable i = 1 indicating the column number of the lighting device 500 (step S1601). Subsequently, the control server 200 sets the variable k = 1 indicating the number of the lighting device 500 arranged in the i row by the lighting state acquisition unit 274 (step S1602).

  Subsequently, the control server 200 refers to the illumination arrangement database 210 by the illuminance comparison unit 275, and acquires the illuminance (initial value) of the illuminance sensor 300 arranged around the illuminating device 500 arranged in the i-th row k-th. (Step S1603). That is, the illuminance comparison unit 275 acquires the illuminance of the illuminance sensor 300 corresponding to the illuminating device 500 arranged in the i-th row k-th in the illumination arrangement database 210.

  Subsequently, the control server 200 refers to the lighting state database 220 by using the lighting state acquisition unit 274, and refers to the lighting state of the lighting device 500 arranged in the i-th row k-th (step S1604).

  In step S1604, when the lighting flag corresponding to the i-th row k-th illumination ID in the lighting state database 220 is ON (step S1605), the illuminance comparison unit 275 is arranged in the i-th row k-th by the lighting control unit 272. The illuminated lighting device 500 is turned off (step S1606). At this time, in the lighting state database 220, the lighting flag of the corresponding lighting device 500 is set to OFF.

  Subsequently, the illuminance comparison unit 275 acquires the illuminance of the illuminance sensor 300 arranged around the illumination device 500 arranged in the i-th row k-th (step S1607). The illuminance sensor 300 whose value is acquired in step S1607 is the same position as the illuminance sensor 300 whose value is acquired in step S1603.

  Subsequently, the illuminance comparison unit 275 determines whether or not the initial value acquired in step S1603 is larger than the value acquired in step S1607 (step S1608). That is, the illuminance comparison unit 275 compares the illuminance when the i-th row k-th lighting device 500 is turned on with the illuminance when the illuminator 500 is turned off, and determines whether or not the illuminance when turned on is larger than the illuminance when turned off. doing.

  In step S1608, when the value acquired in step S1603 is larger than the value acquired in step S1607, failure determination unit 276 determines that lighting device 500 arranged in i-th row k-th is normal. Then, the failure determination unit 276 sets the value of the corresponding failure determination flag to “0” in the lighting state database 220 (step S1609).

  In step S1608, when the initial value acquired in step S1603 is equal to or less than the value acquired in step S1607, the failure determination unit 276 determines that the lighting device 500 arranged in the i-th row k-th is a failure. Then, the failure determination unit 276 sets the value of the corresponding failure determination flag to “1” in the lighting state database 220 (step S1610).

  Next, in step S1604, when the lighting flag corresponding to the i-th row k-th illumination ID in the lighting state database 220 is OFF (step S1611), the illuminance comparison unit 275 causes the lighting control unit 272 to execute the i-th row k. The lighting device 500 arranged in the second position is turned on (step S1612). At this time, in the lighting state database 220, the lighting flag of the corresponding lighting device 500 is turned ON.

  Subsequently, the illuminance comparison unit 275 acquires the illuminance of the illuminance sensor 300 arranged around the illumination device 500 arranged in the i-th row k-th (step S1613). Note that the illuminance sensor 300 whose value is acquired in step S1613 is the same position as the illuminance sensor 300 whose value is acquired in step S1603.

  Subsequently, the illuminance comparison unit 275 determines whether or not the value acquired in step S1603 is smaller than the value acquired in step S1613 (step S1614). That is, the illuminance comparison unit 275 compares the illuminance when the i-th row k-th lighting device 500 is turned off with the illuminance when the illuminant is turned on, and determines whether or not the illuminance when turned off is smaller than the illuminance when turned on. doing.

  In step S1614, when the value acquired in step S1603 is smaller than the value acquired in step S1613, failure determination unit 276 proceeds to step S1609 and determines that lighting device 500 arranged in i-th row k-th is normal.

  In step S1614, if the value acquired in step S1603 is greater than or equal to the value acquired in step S1613, the failure determination unit 276 proceeds to step S1610 and determines that the lighting device 500 arranged in the i-th row k-th is a failure. .

  Subsequent to steps S1609 and 1710, the lighting state acquisition unit 274 determines whether or not the lighting flag of the i-th row k-th lighting device 500 in the lighting state database 220 is ON (step S1615).

  In step S1615, when the lighting flag is ON, the lighting state acquisition unit 274 causes the lighting control unit 272 to turn off the corresponding lighting device 500 and turn off the lighting flag of the corresponding lighting device 500 in the lighting state database 220. (Step S1616).

  In step S1615, when the lighting flag is not ON, the lighting state acquisition unit 274 causes the lighting control unit 272 to turn on the corresponding lighting device 500 and set the lighting flag of the corresponding lighting device 500 in the lighting state database 220 to ON. (Step S1617).

  That is, the failure detection unit 273 of the present embodiment returns the lighting state of the lighting device 500 to the initial value.

  Subsequent to steps S1616 and 1717, the failure detection unit 273 refers to the illumination arrangement database 210 and determines whether or not the kth illumination device 500 is the last in the i-th row (step S1618). In step S1618, if it is not the last lighting device 500, the failure detection unit 273 sets the variable k = k + 1 (step S1619) and returns to step S1603.

  In step S1619, if it is the last lighting device 500, the failure detection unit 273 sets the variable i = i + 1 (step S1620). Subsequently, the failure detection unit 273 determines whether there is no next column (step S1621). That is, the failure detection unit 273 determines whether or not the i-th column is the last column.

  If there is the next column in step S1621, the failure detection unit 273 returns to step S1602. If there is no next column in step S1621, the process ends.

  The control server 200 according to the present embodiment uses the failure notification unit 277 to indicate the illumination ID of the lighting device 500 whose failure flag in the lighting state database 220 is “1” after the processing of the failure detection unit 273 is completed. The PC 800 or the like may be notified.

  As described above, in the present embodiment, it is determined whether or not the lighting device 500 has failed based on the illuminance in the lighting state when the failure detection process is started and the illuminance after the lighting state is changed. After the determination, the lighting state is restored.

  That is, in the present embodiment, the lighting devices 500 other than the lighting device 500 that is a determination target of whether or not there is a failure can maintain the state before the start of the failure detection process. Therefore, according to the present embodiment, the comfort of a person in an area other than the area illuminated by the failure detection target lighting device 500 is not impaired, and the influence of the failure detection can be limited to the minimum area. In the present embodiment, the lighting device 500 is returned to its original lighting state after the determination has been made for the lighting device 500 that is a failure detection target. Therefore, in this embodiment, the time affected by the failure detection can be shortened.

  Thus, in this embodiment, since the comfort for the person in the room when performing the failure detection process is taken into consideration, the failure detection can be performed at an arbitrary time zone. Therefore, according to this embodiment, the burden on the administrator of the control system 100 can be reduced.

(Second embodiment)
The second embodiment will be described below with reference to the drawings. This embodiment is different from the first embodiment in that the function of the failure detection unit 273 is provided in a device external to the control server 200. Therefore, in the following description of the second embodiment, only differences from the first embodiment will be described, and those having the same functional configuration as the first embodiment will be described for the first embodiment. The same reference numerals as those used in FIG.

  FIG. 17 is a diagram illustrating an example of a system configuration of a control system according to the second embodiment. The control system 100A of this embodiment includes a control server 200A and a server 900. The control server 200A and the server 900 are connected via a network, for example.

  In the control system 100 </ b> A of the present embodiment, the control server 200 </ b> A acquires the illuminance of the illuminance sensor 300 corresponding to the illumination device 500 subject to failure detection, and transmits it to the server 900 together with the value of the lighting flag of the illumination device 500.

  The server 900 includes a sensor data acquisition unit 901, a lighting state acquisition unit 902, and a failure detection unit 273. The sensor data acquisition unit 901 acquires illuminance from the control server 200A. The lighting information acquisition unit 902 acquires the value of the lighting flag from the control server 200A. The failure detection unit 273 performs the above-described failure detection process using the illuminance and the value of the lighting flag.

  FIG. 18 is a diagram illustrating functions of each device of the control system according to the second embodiment.

  The control server 200A of this embodiment includes an illumination arrangement database 210, a lighting state database 220, a communication unit 230, a power consumption management unit 240, a human detection processing unit 250, and a device control unit 260A. The appliance control unit 260A includes an illumination control unit 270A, an outlet control unit 280, and an air conditioning control unit 290. The communication unit 230 also performs communication with the server 900.

  The illumination control unit 270A includes a sensor data acquisition unit 271 and a lighting control unit 272, and does not include the failure detection unit 273.

  The server 900 of this embodiment includes a sensor data acquisition unit 901, a lighting state acquisition unit 902, and a failure detection unit 273.

  In the present embodiment, when an instruction to execute failure detection processing is issued in the control server 200A, the control server 200A transmits the illuminance data acquired by the sensor data acquisition unit 271 of the illumination control unit 270A to the server 900.

  When the server 900 acquires the illuminance by the sensor data acquisition unit 901, the lighting state acquisition unit 902 refers to the lighting state database 220 and acquires the value of the lighting flag. Then, failure detection processing by the failure detection unit 273 is performed.

  When a failure is detected, the server 900 notifies the control server 200A that the failure has been detected and the lighting device 500 and / or the integrated unit 500A that has failed.

  As mentioned above, although this invention has been demonstrated based on each embodiment, this invention is not limited to the requirements shown in the said embodiment. With respect to these points, the gist of the present invention can be changed without departing from the scope of the present invention, and can be appropriately determined according to the application form.

100, 100A Control system 200, 200A Control server 210 Lighting arrangement database 220 Lighting state database 251 Human sensor 260 Device control unit 270 Lighting control unit 271, 901 Sensor data acquisition unit 272 Lighting control unit 273 Failure detection unit 274 Lighting state acquisition unit 275 Illuminance comparison unit 276 Failure determination unit 277 Failure notification unit 290 Air conditioning control unit 300 Illuminance sensor 350 Temperature / humidity sensor 400 Current sensor 900 Server 902 Lighting state acquisition unit

JP 2012-43729 A

Claims (7)

Of the plurality of lighting devices that illuminate the space, the first illuminance detected by the illuminance detection unit disposed at a position corresponding to the one lighting device, and the lighting state of the one lighting device, the first illuminance An illuminance comparison unit that compares the second illuminance detected by the illuminance detection unit by changing from the lighting state when detecting
And a failure determination unit that determines whether or not the one lighting device has failed according to a comparison result.   The control device according to claim 1, further comprising: a lighting control unit that returns the lighting state of the one lighting device to the lighting state when the first illuminance is acquired after acquiring the second illuminance. The lighting state when the first illuminance is detected is that the one lighting device is lit,
The lighting state when the second illuminance is detected is a state where the one lighting device is turned off,
The failure determination unit
The control device according to claim 1, wherein when the first illuminance is equal to or less than the second illuminance, the one lighting device is determined to be a failure. The lighting state when the first illuminance is detected is that the one lighting device is turned off,
The lighting state when the second illuminance is detected is a state where the one lighting device is turned on,
The failure determination unit
The control device according to any one of claims 1 to 3, wherein when the first illuminance is equal to or higher than the second illuminance, the one illumination device is determined to be out of order.   The control device according to any one of claims 1 to 4, wherein the illuminance detection unit is provided integrally with the lighting device in a part or all of the plurality of lighting devices. A control system comprising: a plurality of lighting devices that illuminate a space; an illuminance detection unit that is provided integrally with the lighting device in part or all of the lighting device; and a control device that controls the lighting device. ,
Among the plurality of lighting devices, the first illuminance is detected based on the first illuminance detected by the illuminance detection unit disposed at a position corresponding to the one lighting device, and the lighting state of the one lighting device. An illuminance comparison unit that compares the second illuminance detected by the illuminance detection unit after changing from the lighting state when
And a failure determination unit that determines whether or not the one lighting device has failed according to a comparison result. A control system having a first control device that controls a plurality of lighting devices that illuminate a space, and a second control device that communicates with the first control device,
Among the plurality of lighting devices, the first illuminance is detected based on the first illuminance detected by the illuminance detection unit arranged at a position corresponding to the one lighting device and the lighting state of the one lighting device. An illuminance comparison unit that compares the second illuminance detected by the illuminance detection unit after changing from the lighting state at the time,
And a failure determination unit that determines whether or not the one lighting device has failed according to a comparison result.

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