JP4010465B2 - Lighting control system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a lighting control system in which a central controller controls a plurality of lighting loads by controlling a plurality of control terminals by time division multiplex transmission.
[0002]
[Prior art]
Conventionally, as one of energy-saving lighting, daylight illuminance is detected by an optical sensor, and the indoor illuminance is controlled according to the daylight illuminance. A lighting control system that darkens or turns off lights has been developed to reduce power consumption. FIG. 8 is a schematic view showing a configuration example of such a conventional lighting control system.
[0003]
  The central control device 1 of this example includes a display unit and a key operation unit (not shown) that can be set and operated from the outside, and the optical sensor light receivers 21 and 22 and the control terminal unit from the display unit and key operation unit. 4 and the control status information are input and stored in a storage unit (not shown) of the central control device 1. In such a system, the optical sensor receivers 21 and 22 are connected to the central controller 1 directly or via signal lines as terminals.
[0004]
  The central controller 1 adjusts the dimming level according to the daylight illuminance detected by the optical sensor receivers 21 and 22 based on the correspondence between the optical sensor receivers 21 and 22 and the control terminal 4 and the control state information. The illuminance of the indoor lighting load is controlled according to the daylight illuminance by obtaining and transmitting this to the corresponding control terminal 4 (in practice, there are usually a plurality of cases) through the signal transmission line 3. .
[0005]
  However, since the above system is large in size and high in cost, an illumination control system using the central control device 1 having a distribution board agreement dimension as shown in FIG. 9 in order to reduce the size and cost of the central control device 1. Has been proposed (literature; Matsushita Electric Works technical data). The central control device 1 of this system stores the correspondence between the input monitoring terminal 5 and the control terminals 4a and 4b, which are input via the signal transmission line 3 by some information input means. The optical sensor receiver 91 connected to the optical sensor controller 9 detects the illuminance of daylight. The optical sensor controller 9 detects the illumination load 8 when the detected illuminance is a predetermined level or more. The off signal to be turned off is output to the input monitoring terminal 5 via the operation stop switch 6, and the input monitoring terminal 5 transmits the turn-off signal to the central control device 1 through the signal transmission line 3.
[0006]
  However, the central controller 1 can distinguish between the extinguishing signal input from the optical sensor controller 9 via the input monitoring terminal 5 and the extinguishing signal input via the signal transmission line 3 from the wall switch 7a or 7b. Since the handling is the same, the following problems occur. That is, as shown in FIG. 1010 (A), when the switch of the wall switch 7a is pressed (high level) and a lighting signal is input to the central controller 1 through the signal transmission line 3, the central controller 1 For example, the lighting load 8 of the control terminal 4a corresponding to 7a is turned on (high level) as shown in FIG. After that, when the switch of the wall switch 7a is pressed (low level), since the turn-off signal is input to the central control device 1 through the signal transmission line 3, the central control device 1 has the lighting load 8 of the control terminal 4a. Is turned off (low level) as shown in FIG.
[0007]
  Thereafter, when the daylight illuminance increases and the light sensor controller 2 inputs a turn-off signal to the input monitor terminal 5 via the operation stop switch 6, the input monitor terminal is connected to the central controller 1 through the signal line 3. As shown in FIG. 10B, a turn-off signal (high level) is input. However, normally, as shown in FIG. 10C, the operation stop switch 6 is turned on. As a result, the central control device 1 sends a turn-off signal to the control terminal 4a corresponding to the input monitoring terminal 5 to turn off the lighting load 8 as shown in FIG. 10 (D). By operating the wall switch 7a, the lighting load 8 is in the extinguished state (low level), so nothing changes.
[0008]
  Thereafter, when the daylight illuminance decreases and the light sensor controller 9 inputs a lighting signal to the input monitoring terminal 5 via the operation stop switch 6, the input monitoring terminal 5 is connected to the central controller 1 through the signal line 3. 10B, since the lighting signal (low level) is input, the central controller 1 sets the lighting load 8 of the control terminal 4a corresponding to the input monitoring terminal 5 as shown in FIG. ) Turn on (high level) as shown. Thereby, the malfunction that the illumination load 8 which existed in the light extinction state will light will generate | occur | produce.
[0009]
  Therefore, conventionally, in order to avoid this problem, a measure is taken to turn off the operation stop switch 6 to stop the operation of the optical sensor controller 9 in the system. However, this requires a configuration in which the operation stop switch 6 is inserted between the input monitoring terminal 5 and the optical sensor controller 9, which not only increases the number of parts of the system but increases the cost. If the operation stop switch 6 is not manually turned on and off one by one, the daylight cannot be used, or the above-described problems occur, resulting in a problem that the operability of the system is poor.
[0010]
  The wall switches 7a and 7b input information such as up / down / stop / on / off for instructing the dimming state of the lighting load 8 to the control terminals 4a and 4b by key operation. When continuous dimming control is performed by operations from these wall switches 7a and 7b, only one control terminal, for example, the control terminal 4a, corresponds to the wall switch 7a of one unique address. The operation from the switch 7a is only useful for the control terminal 4a. Therefore, there is a problem that the area dimming wider than the area covered by one control terminal 7a cannot be continuously dimmed by the wall switch 7a, and the usability is poor.
[0011]
  By the way, although the place of use is different from the above lighting control system, a plurality of, for example, HID lamps arranged along the longitudinal direction of the tunnel are turned on as the lighting system in the tunnel through which the train or car passes. There is something. However, in this type of system, the tunnel is contaminated due to the passage of trains and cars. As a result, the lamp surface becomes dirty and the light flux attenuates, and the light flux attenuates depending on the lamp usage time. Even though the illuminance in the tunnel changes and decreases, proper illuminance maintenance control has not been performed. For this reason, after replacing the lamp or cleaning the lighting fixture, the tunnel interior becomes higher than the design illuminance, resulting in wasted power, and then the illuminance in the tunnel changes in the direction in which the illuminance decreases. It was.
[0012]
[Problems to be solved by the invention]
In the small and low-cost central control device 1 shown in FIG. 9 having the distribution board agreement dimensions as described above, the operation stop switch 6 is inserted between the input monitoring terminal 5 and the optical sensor controller 9. Not only does this increase the number of system components and the cost, but if the above-described operation stop switch 6 is not turned on and off manually, daylight usage will not be smooth. There was a problem that the operability of the system was bad. Further, since only one control terminal 4a, for example, can be controlled by the operation from the wall switch 7a, the area dimming wider than the area covered by one control terminal 4a can be controlled with the wall switch 7a. There was a problem that it was not easy to use. Furthermore, the system that illuminates the tunnel has a problem that the illuminance inside the tunnel cannot be made constant.
[0013]
  Therefore, the present invention has been made to solve the above-described problems, and can smoothly use daylight without any trouble, and can operate a plurality of control terminals with a single wall switch. An object of the present invention is to provide a lighting control system with improved operability, and a lighting control system capable of controlling the illuminance in a tunnel to be constant.
[0014]
[Means for Solving the Invention]
The invention according to claim 1 is a transmission line for transmitting a signal;
At least one control terminal for dimming, lighting, and extinguishing the lighting load in accordance with a control signal received from the transmission line; and an illumination load that is dimmed and controlled by the control terminal; detecting this by detecting ambient illuminance A light sensor control device that generates a turn-off signal when the illuminance exceeds a reference value and generates a control signal such as a turn-on signal when the illuminance falls below the reference value; transmits the control signal generated by the light sensor control device A monitoring terminal for input that is sent out on the line; a switch input terminal that generates a control signal for dimming, turning on and off the lighting load in response to manual operation of the switch, and sending the generated control signal to the transmission line; A setting device for generating a corresponding setting signal when setting information for distinguishing between the input monitoring terminal and the switch input terminal is input; a switch operation monitoring terminal for sending the setting signal generated by the setting device to the transmission line; Enter An internal memory for holding a setting signal for distinguishing the monitoring terminal for power and the switch input terminal and a control signal received from the switch input terminal through the transmission line;When the light input signal from the switch input terminal is transmitted to the corresponding control terminal to turn off the lighting load, and then the signal received from the switch input terminal is the light signal, control of the optical sensor control device Regardless of the signal, control is performed to turn on the lighting load by transmitting to the control terminal, and then the control signal generated by the optical sensor control device is transmitted to the control terminal to start control of the lighting load and input. When a light extinction signal is received from the monitoring terminal, the light extinction signal is transmitted to the corresponding control terminal to control the lighting load to be extinguished.A central control unit;
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a first embodiment of a lighting control system of the present invention. 1 is a central controller for controlling the operation of control terminals 4a and 4b based on a control information signal input via a signal transmission line 3, and 3 is a time division multiplex for transmitting setting signals and control signals Signal transmission lines 4a and 4b are control terminals for controlling the dimming and on / off of the illumination load 8 based on a control signal received from the signal transmission line 3, and 5 is an illumination load input from the optical sensor controller 9. 8 is an input monitoring terminal for monitoring the input of on / off information, 7a and 7b are wall switches (switch input terminals) for manually inputting the dimming level and on / off information of the lighting load 8 by switch operation, and 8 is a control terminal. An illumination load such as a fluorescent lamp that is blinked or dimmed by 4a and 4b, 9 is an optical sensor controller that generates on / off information of the illumination load 8 based on the illuminance of daylight detected by the optical sensor receiver 91; 10 Setting signal for distinguishing and controlling correspondence information between the input monitoring terminal 5 and wall switches 7a and 7b and the control terminals 4a and 4b and information from the input monitoring terminal 5 and wall switches 7a and 7b A setting device for setting the control device 1, a switch operation monitoring terminal 11 for sending a setting signal input from the setting device 10 onto the signal transmission line 3, and an optical sensor receiver 91 for detecting the illuminance of daylight It is.
[0016]
  Here, the central control device 1 is not provided with a special display unit or operation unit, and has a distribution board agreement size. The correspondence relationship information means a relationship in which the central controller 1 controls the control terminal 4a based on the control information of the input monitoring terminal 5 that monitors the optical sensor controller 9. Yes. The control information means that the illumination load 8 of the control terminal 4a is set to 0% dimming level during the optical sensor control when the detected illuminance of the optical sensor receiver 91 exceeds the reference value, and the control terminal 4b It means information such as controlling the lighting load 8 to a dimming level of 50%. The optical sensor receiver 91 and the optical sensor controller 9 constitute an optical sensor control device.
[0017]
  FIG. 2 is a detailed configuration diagram of the central controller 1 shown in FIG. 111 is a CPU that performs dimming control and setting processing, 112 is a memory with a power source backup that stores programs and data for operating the CPU 111, operation state data, and the like, and 113 is time-division transmission / reception control of data to the signal transmission line 3. A transmission control unit 114 is a power supply unit.
[0018]
  FIG. 3 is a detailed plan view of the setting device 10 shown in FIG. The setting device 10 is small and light so as to be convenient for carrying. A key operation unit 31 for inputting setting information and a liquid crystal display unit 32 for displaying setting information are provided on the front surface thereof. The setting device 10 can be used by inserting and connecting the connection jack 33 to the switch operation monitoring terminal device 11 shown in FIG.
[0019]
  Next, the operation of the present embodiment will be described. First, with the setting device 10, for example, the input monitoring terminal 5 and the control terminal 4 a are in a correspondence relationship, and the correspondence information such that the wall switch 7 a and the control terminal 4 a are in a correspondence relationship, or the control terminal During the optical sensor control of the illumination load 8 of the device 4a, various setting information such as control information for dimming 0% is input to the switch operation monitoring terminal 11. The switch operation monitoring terminal 11 transmits a setting signal corresponding to the inputted various setting information to the central controller 1 through the signal transmission line 3. When the central control device 1 receives the transmitted various setting signals by the transmission control unit 113, the CPU 111 stores them in the internal memory 112 and sets them.
[0020]
  Next, a case where the light sensor 8 is turned on while the lighting load 8 is under lighting control will be described. When the wall switch 7a is turned on (high level) as shown in FIG. 4A, a lighting signal is transmitted to the central controller 1 through the signal transmission line 3. When the central control device 1 receives the signal, it sends a control signal for dimming the lighting load 8 to the control terminal 4 a through the signal transmission line 3, for example, 80%, and holds the lighting control signal in the memory 112. As a result, the control terminal 4a performs dimming lighting (high level) of the illumination load 8 as shown in FIG. 4C. Thereafter, when the illuminance of daylight detected by the optical sensor receiver 91 exceeds the reference level, the optical sensor controller 9 performs an input monitoring terminal to perform sensor control (high level) as shown in FIG. An extinguishing signal is input to the device 5. The input monitoring terminal 5 transmits the extinguishing signal to the central controller 1 through the signal transmission line 3. When the central controller 1 receives the turn-off signal, it sends a signal for dimming the illumination load 8 to the control terminal 4a through the signal transmission line 3. As a result, the control terminal 4a turns off the lighting load 8 (low level) as shown in FIG.
[0021]
  Further, after that, when the illuminance of daylight detected by the optical sensor receiver 91 falls below the reference level, the optical sensor controller 9 inputs to end the sensor control (low level) as shown in FIG. A lighting signal is input to the monitoring terminal 5 for use. The input monitoring terminal 5 transmits the lighting signal to the central controller 1 through the signal transmission line 3. When the central control device 1 receives the lighting signal, the central control device 1 determines that the optical sensor control is finished, and sends a lighting control signal for dimming and lighting the lighting load 8 held in the memory 112 through the signal transmission line 3. To the device 4a. As a result, the control terminal 4a lights the lighting load 8 by, for example, 80% dimming (low level) as shown in FIG. Next, when the turn-off switch of the wall switch 7a is pressed (low level) as shown in FIG. 4A, a turn-off signal is transmitted to the central controller 1 through the signal transmission line 3. When the central control device 1 receives the signal, it sends a control signal for dimming the lighting load 8 to the control terminal 4 a through the signal transmission line 3 and holds the control signal in the memory 112. As a result, the control terminal 4a turns off the lighting load 8 (low level) as shown in FIG.
[0022]
  That is, when the central control device 1 is controlling the lighting of the illumination load 8 and the detected illuminance of the optical sensor receiver 91 exceeds the reference value, the central control device 1 performs optical sensor control on the illumination load 8 and the optical sensor receiver 91. When the detected illuminance falls below the reference value, the optical sensor control ends, and the control returns to the control before entering the optical sensor control.
[0023]
  Next, a case will be described in which light sensor control is turned on during lighting control of the lighting load 8 and a light-off operation is performed from the wall switch 7a or the like during the control. When the on / off switch of the wall switch 7a is pressed (high level) as shown in FIG. 4D, the central controller 1 holds the 80% dimming lighting control signal in the memory 112 and controls this control signal. To the terminal 4a, and the lighting load 8 is dimmed 80% (high level) as shown in FIG. Thereafter, when the illuminance of daylight detected by the optical sensor receiver 91 exceeds the reference level, the optical sensor controller 9 monitors the input to perform optical sensor control (high level) as shown in FIG. A turn-off signal is input to the terminal device 5. As a result, the central control device 1 starts optical sensor control, sends a turn-off signal to the control terminal 4a, and turns off the lighting load 8 (low level) as shown in FIG.
[0024]
  When the turn-off switch of the wall switch 7a is pressed (low level) as shown in FIG. 4D during this optical sensor control, the central controller 1 receives this via the signal transmission line 3 and turns off the control signal. Is stored in the memory 112, but since the optical sensor is currently being controlled, the lighting load 8 of the control terminal 4a is kept off (low level) as shown in FIG. 4R> 4 (F). . Thereafter, when the illuminance of daylight detected by the optical sensor receiver 91 falls below the reference level, the optical sensor controller 9 monitors the input to end the sensor control (low level) as shown in FIG. A lighting signal is input to the terminal device 5. When the central control device 1 receives the lighting signal from the input monitoring terminal 5 through the signal transmission line 3, the central control device 1 determines that the optical sensor control is finished and controls the extinction control signal held in the memory 112. As shown in FIG. 4 (F), the lighting load 8 of the control terminal 4a is kept off (low level).
[0025]
  That is, when the central control device 1 is controlling the lighting of the illumination load 8 and the detected illuminance of the optical sensor receiver 91 exceeds the reference value, the central control device 1 performs optical sensor control on the illumination load 8 and the optical sensor receiver 91. When the detected illuminance falls below the reference value and the optical sensor control ends, the control held in the memory 112 during the optical sensor control, in this case, the light extinction control is returned, so in the above example, the optical sensor control ends. However, the lighting load 8 does not light up.
[0026]
  Next, the operation when the light load control is performed while the illumination load 8 is in the extinction control will be described. The cut-off switch of the wall switch 7a is pressed (low level) as shown in FIG. 4G, whereby the central controller 1 holds the extinguishing control signal in the memory 112 and sends it to the control terminal 4a. Then, as shown in FIG. 4I, the illumination load 8 is turned off (low level). Thereafter, when the illuminance of daylight detected by the optical sensor receiver 91 exceeds the reference level, the optical sensor controller 9 performs input sensor monitoring so as to perform optical sensor control (high level) as shown in FIG. A turn-off signal is input to the terminal device 5. As a result, the central controller 1 sends a turn-off control signal to the control terminal 4a, and continues the turn-off (low level) state of the illumination load 8 as shown in FIG.
[0027]
  Thereafter, when the illuminance of daylight detected by the optical sensor receiver 91 falls below the reference level, the optical sensor controller 9 monitors the input to end the sensor control (low level) as shown in FIG. A lighting signal is input to the terminal device 5. When the central control device 1 receives the lighting signal from the input monitoring terminal 5 through the signal transmission line 3, the central control device 1 determines that the optical sensor control is finished and controls the extinction control signal held in the memory 112. Then, the lighting load 8 is turned off (low level) as shown in FIG. 4 (I).
[0028]
  That is, when the central control device 1 is controlling the turning-off of the illumination load 8 and the detected illuminance of the photosensor light receiver 91 exceeds the reference value and then falls below, the illumination load 8 is controlled regardless of the start and end of the photosensor control. Remains off.
[0029]
  Next, the operation when the lighting load 8 is turned on during the optical sensor control, and the optical sensor control is turned on again after the optical sensor control is finished during the lighting control will be described. Initially, the cut-off switch of the wall switch 7a is pressed (low level) as shown in FIG. 4 (J), whereby the central controller 1 sends a turn-off control signal to the control terminal 4a, and FIG. The lighting load 8 is turned off (low level) as indicated by L). At this time, the turn-off control signal is held in the internal memory 112. Thereafter, when the illuminance of daylight detected by the optical sensor receiver 91 exceeds the reference level, the optical sensor controller 9 performs an input monitoring terminal to perform sensor control (high level) as shown in FIG. An extinguishing signal is input to the device 5.
[0030]
  As a result, the central controller 1 sends a turn-off signal to the control terminal 4a, and continues the turn-off (low level) state of the illumination load 8 as shown in FIG. When the wall switch 7a is turned on (high level) as shown in FIG. 4J during the optical sensor control, the central controller 1 inputs a lighting signal from the signal transmission line 3, and the lighting control signal Is stored in the internal memory 112 and sent to the control terminal 4a through the signal transmission line 3, so that the control terminal 4a lights the lighting load 8 with 80% dimming as shown in FIG. (High level). That is, the central control device 1 gives priority to manual operation after entering the optical sensor control, and performs the control as described above.
[0031]
  Thereafter, when the illuminance of daylight detected by the optical sensor receiver 91 falls below the reference level, the optical sensor controller 9 monitors the input for terminating the sensor control (low level) as shown in FIG. A lighting signal is input to the terminal device 5. When the central controller 1 receives the lighting signal from the input monitoring terminal 5 through the signal transmission line 3, the central controller 1 determines that the optical sensor control is finished, and controls the lighting control signal held in the memory 112. To the terminal 4a, and the lighting (high level) state of the lighting load 8 is continued as shown in FIG. Further, after that, when the illuminance of daylight detected by the optical sensor receiver 91 exceeds the reference level, the optical sensor controller 9 performs input control to perform sensor control (high level) as shown in FIG. A turn-off signal is input to the monitoring terminal 5. When the central control device 1 knows that the sensor control has been entered through the signal transmission line 3, the central control device 1 controls the control terminal 4 a to be turned off through the signal transmission line 3.
[0032]
  Thereby, the control terminal 4a turns off the lighting load 8 (low level) as shown in FIG. Further, after that, when the illuminance of daylight detected by the optical sensor receiver 91 falls below the reference level, the optical sensor controller 9 inputs to end the sensor control (low level) as shown in FIG. A lighting signal is input to the monitoring terminal 5 for use. When the central control device 1 receives the lighting signal from the input monitoring terminal 5 through the signal transmission line 3, the central control device 1 determines that the optical sensor control is finished, and signals the lighting control signal held in the memory 112. The light is sent to the control terminal 4a through the transmission line 3 and the lighting load 8 is turned on (high level) as shown in FIG. Thereafter, when the switch of the wall switch 7a is pressed (low level) as shown in FIG. 4 (J), the central controller 1 inputs a light-off signal from the signal transmission line 3, and the light-off control signal is stored in the internal memory. 112, and this is sent to the control terminal 4a through the signal transmission line 3. As a result, the control terminal 4a turns off the lighting load 8 (low level) as shown in FIG.
[0033]
  That is, the central control device 1 enters the optical sensor control during the extinction control, and when the lighting control is applied by manual operation during the optical sensor control, the lighting load 8 is turned on as the post-operation priority. Thereafter, once the optical sensor control is finished and the optical sensor control is started again, the central control device 1 performs the optical sensor control.
[0034]
  Note that, as shown in FIG. 4 (O), when the illumination load 8 is under extinction control (low level), the optical sensor control (high level) is input from the optical sensor controller 9 as shown in FIG. 4 (N). Then, the central controller 1 starts the optical sensor control, but the illumination load 8 remains under the extinction control as shown in FIG. Thereafter, even if the lighting control (high level) is input to the lighting load 8 as shown in FIG. 4 (M) from the not-shown internal monitoring terminal (T / U) during the optical sensor control, such manual operation is not performed. For the control from the terminal, priority is given to the optical sensor control, and the central controller 1 continues the optical sensor control, and performs the extinction control (low level) of the illumination load 8 as shown in FIG. continue. Thereafter, as shown in FIG. 4R> 4 (N), when the optical sensor control end (low level) is input from the optical sensor controller 9, the central controller 1 sends a lighting control signal to the control terminal 4a. Then, lighting control (high level) of the lighting load 8 is performed. Thereafter, when a turn-off signal (low level) is input from the internal monitoring terminal (T / U) as shown in FIG. 4 (M), the central controller 1 sends a turn-off control signal to the control terminal 4a. As shown in FIG. 4 (O), the lighting load 8 is turned off (low level).
[0035]
  Next, the setting of the correspondence between the control terminals 4a and 4b that can be controlled by the wall switches 7a and 7b and the wall switches 7a and 7b will be described. The grouping of the wall switches 7a and 7b and the control terminals 4a and 4b to be operated is performed by inputting the correspondence information to the switch operation monitoring terminal 11 by the setting device 10 and by using the central control device via the signal transmission line. 1, and correspondence information is stored in the memory 112.
[0036]
  In the setting device 10, for example, a unique address of the wall switch 7 a to be set, for example, 101 is specified, and when the unique addresses 301 and 302 of the control terminals 4 a and 4 b to be grouped are selected, these setting information is set. It is displayed on the liquid crystal display unit 32 of the device 10 and is transmitted from the switch operation monitoring terminal 11 to the central controller 1 through the signal transmission line 3. The central controller 1 recognizes the setting information received from the signal transmission line 3 and then stores and sets the setting information in the internal memory 112.
[0037]
  FIG. 5 is a schematic diagram showing an example of setting contents of the memory 112 described above. For the address of the wall switch, the addresses of a plurality of control terminals that are the operation targets of the wall switch are set. For example, the wall switch 7a having the unique address 101 forms a group with the control terminals 4a and 4b having the unique addresses 311 and 312, and the control terminals 4a and 4b are controlled by the operation of the wall switch 7a. Corresponding relationship is set. The parentheses after the address of the control terminal are the dimming level given to the control terminal.
[0038]
  Here, it is assumed that the wall switch 7a is operated. This operation signal is transmitted to the central controller 1 through the signal transmission line 3. As a result, the central controller 1 checks the address of the wall switch 7a and refers to the setting data shown in FIG. 5 in the memory 112 using the unique address 101 of the wall switch 7a as a key, thereby operating the wall switch 7a. It is recognized that the target is the control terminals 4a and 4b at addresses 311 and 312. Thereafter, the central controller 1 performs dimming control of the illumination load 8 by sending a control signal corresponding to the operation signal to the control terminals 4a and 4b through the signal transmission line 3. When the dimming control is performed based on the operation information, the central controller 1 writes the dimming level for the control terminals 4a and 4b at that time in the memory 112 as shown in FIG.
[0039]
  According to the present embodiment, since the light sensor 8 enters the light load control under the light extinction control and then the light load control under the light extinction control is not turned on even after the light sensor control ends, the manual switch Therefore, energy saving control using daylight can be smoothly performed without turning on / off the optical sensor control, and the operability of the system can be remarkably improved. Further, since the manual switch can be omitted, the number of parts can be reduced and the system can be constructed at low cost. Furthermore, since the setting device 10 is portable and can be carried, it is not necessary to install one setter in the system. From this point, the system can be made inexpensive. Further, in this example, the correspondence between one wall switch and a plurality of control terminals is set in the central control device 1 from the setting device 10 via the signal transmission line 3, thereby operating one wall switch. Thus, a plurality of control terminals can be controlled, and the usability of the system can be improved.
[0040]
  FIG. 6 is a block diagram showing a third embodiment of the lighting control system of the present invention. This example is an example of a system for controlling lighting in a tunnel. 61 is a central control device that controls a plurality of control terminals 631, 632, 633 to control the lighting load 64, 62 is a signal transmission line for transmitting control signals and the like by time division multiplexing, and 64 is arranged in the tunnel. Illuminated loads such as fluorescent lamps, 65 is a timer for supplying time information such as date and time to the central controller 1, 66 is a ROM storing data for dimming control of the illumination load 64 to a constant illuminance, 631 and 632 , 633 is a control terminal that performs dimming control of the illumination load 64 under the control of the central controller 61.
[0041]
  Next, the operation of the present embodiment will be described. The ROM 66 of the central controller 1 stores data for dimming control as described below. The illumination load 64 decreases in illuminance according to the elapsed time from lamp replacement (including installation), and the illuminance in accordance with the elapsed time after cleaning the lamp surface (including installation). Decreases. Therefore, the lamp beam attenuation rate is calculated as a function of the elapsed time since lamp replacement (including installation), and the lamp beam attenuation rate is calculated as a function of the elapsed time after cleaning the lamp surface (including installation). The value obtained by multiplying these attenuation factors is taken as the total attenuation factor. For this reason, the illuminance of the current illumination load 64 can be obtained from the total attenuation rate corresponding to the elapsed time from the time of lamp replacement and the most recent cleaning of the lamp surface dirt. Therefore, the data for obtaining the attenuation factors of the two kinds of lamp light beams described above are stored in the ROM 66 corresponding to the respective elapsed times. However, the illuminance of the current illumination load 64 is the illuminance when the reference power is supplied to the illumination load.
[0042]
  Next, the operation of the present embodiment will be described with reference to the flowchart of FIG. When the central controller 1 obtains the elapsed time from the lamp replacement and the elapsed time from the last cleaning by the timer 65 in step 701, the elapsed time is used as an address in step 702 and the ROM 66 is accessed to access the above data. From these data, the attenuation rate of the lamp luminous flux according to the elapsed time from lamp replacement (including installation) and the attenuation rate of the lamp luminous flux according to the elapsed time after cleaning the lamp surface (including installation) are obtained. Thus, the illuminance of the current illumination load 64 is obtained. Next, the central control device 1 obtains a difference between the current illuminance obtained in step 703 and a preset reference illuminance, determines a dimming level that eliminates this difference, and determines the dimming level as a control terminal. 631, 632, and 633 are transmitted in step 704, and the illumination load 64 is dimmed and controlled, thereby setting the illuminance to the reference illuminance. The central control device 1 performs the dimming control for a predetermined time. When the predetermined time has passed in step 705, the central control device 1 returns to step 701 to obtain the elapsed time from the lamp replacement and the previous cleaning, thereby making the control constant. Repeats cyclically every hour. Thus, the amount of illuminance of the lighting load 64 decreases as time passes, and power above the reference power is supplied to the lighting load 64 by dimming control of the central control device 1 to compensate for the decrease in illuminance. The illuminance of the illumination load 64 is kept constant.
[0043]
  According to the present embodiment, since the central control device 1 performs dimming control of the lighting load 64 according to the usage time and the degree of contamination of the lighting load 64, the illuminance of the lighting load 64 can be kept constant. For this reason, not only wasteful power is not consumed when replacing the lamp, but also the tunnel is always maintained at a constant brightness, so that the safety of traffic and the like can be improved.
[0044]
  In addition, since the dirt of the equipment in the tunnel differs depending on the entrance, exit, and center side of the tunnel, the attenuation rate of the equipment dirt is determined for each area of the entrance, exit, and center side of the tunnel, and the central controller 1 To obtain the dimming level for each area, separately transmit these dimming levels to the respective control terminals 631, 632, 633, and perform dimming control of the lighting load 64 of each area separately, thereby allowing tunneling. The illuminance inside can be made more uniform at the entrance, exit, and central areas. The same effect can be obtained by calculating the attenuation rate of the luminous flux of the lamp 64 by the elapsed time by the central controller 1.
[0045]
【The invention's effect】
As described above, according to the invention of claim 1,If lighting control is applied by manual operation during this optical sensor control, the illumination load is turned on as a post-operation priority regardless of the control signal of the optical sensor control device. Thereafter, when the optical sensor control is once ended and the optical sensor control is started again, the central control device can provide an illumination control system for performing the optical sensor control.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment of a lighting control system of the present invention.
FIG. 2 is a block diagram showing a detailed configuration example of a central control device shown in FIG.
FIG. 3 is a plan view showing a detailed example of the setting device shown in FIG. 1;
4 is a timing chart for explaining the operation of the system shown in FIG.
FIG. 5 is a schematic diagram showing an example of setting contents of the memory shown in FIG. 2;
FIG. 6 is a block diagram showing a second embodiment of the lighting control system of the present invention.
7 is a flowchart showing a dimming control processing procedure of the central control unit shown in FIG. 6;
FIG. 8 is a block diagram showing a configuration example of a conventional lighting control system.
FIG. 9 is a block diagram showing another configuration example of a conventional lighting control system.
10 is a timing chart for explaining the operation of the system shown in FIG. 9;
[Explanation of symbols]
1, 61 Central control unit
3, 62 Signal transmission line
4a, 4b, 631, 632, 633 Control terminal
5 Monitoring terminal for input
7a, 7b Wall switch
8, 64 Lighting load
9 Light sensor controller
10 Setting device
11 Switch operation monitoring terminal
31 Key operation section
32 Liquid crystal display
33 connection jack
91 Optical sensor receiver
111 CPU
112 memory
113 Transmission control unit
114 Power supply

Claims (1)

A transmission line for transmitting signals;
At least one control terminal for dimming, turning on and off the lighting load according to the control signal received from the transmission line;
A lighting load that is dimmed and controlled by a control terminal;
An optical sensor control device that detects ambient illuminance and generates a turn-off signal when the detected illuminance exceeds a reference value and generates a control signal such as a turn-on signal when the detected illuminance falls below the reference value;
An input monitoring terminal for sending a control signal generated by the optical sensor control device onto the transmission line;
A switch input terminal that generates a control signal for dimming, turning on and off the lighting load in response to manual operation of the switch, and sending the generated control signal to the transmission line;
A setting device for generating a corresponding setting signal when inputting setting information for distinguishing between the input monitoring terminal and the switch input terminal;
A switch operation monitoring terminal for sending a setting signal generated by the setting device to the transmission line;
It has an internal memory that holds the setting signal that distinguishes the monitoring terminal from the input terminal and the switch input terminal and the control signal received from the switch input terminal through the transmission line, and is used for the control corresponding to the turn-off signal from the switch input terminal. When the signal received from the switch input terminal is a lighting signal, it is transmitted to the control terminal regardless of the control signal of the optical sensor control device, and the lighting load is turned off. Control is performed to turn on the load, and then the control signal generated by the optical sensor control device is transmitted to the control terminal to start controlling the lighting load. When the turn-off signal is received from the input monitoring terminal, the turn-off signal is A central control unit that controls to turn off the lighting load by transmitting to the corresponding control terminal ;
An illumination control system comprising:

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