JP2004180412A - Loading control system and management system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent loading applied on a general monitoring device from being inevitably increased and obviate the necessity for a high-cost general monitoring device even if the scale of a system is increased. <P>SOLUTION: An illumination subsystem 2 includes a plurality of lighting fixtures 21 and an illumination controller 20 which controls them. A general monitoring device 1 has a power consumption monitoring portion 12 which monitors power consumption by the lighting fixtures 21 and issues a power reduction instruction to the illumination controllers 20 if power consumption monitored by the power consumption monitoring portion 12 must be reduced. The illumination subsystems and the general monitoring device are connected to the wiring L1 of a building equipment network. The management system is constructed as above, which utilizes the result of detection by a human detecting portion in controlling the lighting fixtures 21. On receipt of a power reduction instruction from the general monitoring device 1, the illumination controller 20 determines the load output level lower than the present load output level with respect to at least some of the lighting fixtures 21 within the illumination subsystem 2 to which the controller belongs, and controls and operates them at the determined load output level. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is configured by connecting a subsystem including a load device and a controller for controlling the load device and a comprehensive monitoring device having power consumption monitoring means for monitoring power consumption by the load device in the subsystem to a network. The present invention relates to a load control system including the above subsystems in a management system, and a management system.
[0002]
[Prior art]
(First prior art)
FIG. 15 is a configuration diagram of a (building) management system of the first prior art, FIG. 16 is a configuration diagram of an integrated monitoring device in the management system, and FIG. 17 is a schematic diagram of a lighting subsystem in the management system.
[0003]
As shown in FIG. 15, the management system of the first prior art, as shown in FIG. 15, has a gateway 6 for bridging signals between the general monitoring device 1PA, various subsystems (2PA, 3, 4, 5), and the OA network system 7. Are connected to the wiring L1 of the building equipment network, and the power consumption management and the operation record management of each subsystem are performed by the integrated monitoring device 1PA.
[0004]
As shown in FIG. 16, the integrated monitoring device 1PA includes a building network interface 11 for transmitting and receiving signals to and from each subsystem, a power consumption monitoring unit 12PA that monitors power consumption of each subsystem, and a power consumption of each subsystem. A power target value management unit 14 that sets a target value of the power supply, a control determination unit 15 that calculates a control operation pattern based on the operation state of each subsystem (power reduction), operation state information of each subsystem, and power consumption. A monitoring unit 12PA, a control unit 10PA that generates an instruction signal to each subsystem based on the calculation results of the power target value management unit 14 and the control determination unit 15 performs power monitoring control of each subsystem.
[0005]
As shown in FIG. 15, the subsystem includes a lighting subsystem 2PA including a lighting fixture 21PA and a lighting control controller 20PA for controlling the lighting fixture 21PA (see FIG. 17), an air conditioner, and an air conditioning controller for controlling the same. There is an air conditioning subsystem 3 composed of a controller, a crime prevention subsystem 4 composed of crime prevention equipment and a security control controller for controlling the same, and a disaster prevention subsystem 6 composed of disaster prevention equipment and a disaster prevention control controller for controlling the same. .
[0006]
The general operation of the management system having such a configuration will be described. In the integrated monitoring device 1PA, the power consumption monitoring unit 12PA monitors the power consumption of each subsystem, and the power consumption of the subsystem is set to a predetermined power amount. If it exceeds, a power reduction request is issued. When receiving the power reduction request via control unit 10PA, power target value management unit 14 sets a power target value for reducing power consumption of each subsystem. The control determination unit 15 calculates a control operation pattern for realizing the power target value set by the power target value management unit 14 for each subsystem, and outputs the control operation pattern to the control unit 10PA. The control unit 10PA generates a power reduction control signal for executing power reduction control in each subsystem based on the control operation pattern, and outputs the power reduction control signal via the building network interface 11.
[0007]
Upon receiving the power reduction control signal from the integrated monitoring device 1PA, each subsystem performs power reduction control of its own load device in accordance with the content included in the power reduction control signal. After the power reduction control, information on the power consumption in the subsystem is fed back to the integrated monitoring device 1PA, and the power reduction control is performed in each subsystem until the reduction of the power target value is achieved.
[0008]
In FIG. 15, at least one subsystem of the same type constitutes one load control system. In this case, each subsystem in the figure is read as a load control system. For example, a lighting control system is configured by at least one lighting subsystem 2PA, and an air conditioning control system is configured by at least one air conditioning subsystem 3. In the example of FIG. 17, a lighting control system is configured by a plurality of lighting subsystems 2PA.
[0009]
(Second conventional technology)
FIG. 18 is a configuration diagram of a management system according to a second prior art, and FIGS. 19 and 20 are explanatory diagrams of the operation of the management system.
[0010]
As shown in FIG. 18, the management system of the second prior art is configured by connecting a comprehensive monitoring device 1PA similar to that of the first prior art and a plurality of lighting subsystems 2PA to a wiring L1 of a building equipment network. I have.
[0011]
The lighting subsystem 2PA includes a plurality of lighting fixtures 21PB and a lighting control controller 20PB that controls lighting, extinguishing, or dimming of the lighting fixtures 21PB.
[0012]
The lighting control controller 20PB includes a building network interface 201 for transmitting and receiving signals to and from the integrated monitoring device 1PA, a signal transmitting and receiving unit 202 for transmitting and receiving signals to and from each lighting fixture 21PB in the lighting subsystem 2PB to which it belongs, and a lighting fixture 21PB. An illumination control signal generation unit 203 that generates a control signal for performing lighting control of a person, a person detection unit 206 that detects whether a person is present, a timer circuit 207 for clocking, and performs signal arithmetic processing. It comprises an arithmetic processing unit 200PB. The lighting control controller 20PB controls the lighting of the lighting fixture 21PB based on the detection information from the human detection unit 206, and when receiving a power reduction instruction from the comprehensive monitoring device 1PA, controls the lighting of the lighting fixture 21PB according to the instruction. I do.
[0013]
Next, regarding the operation of the management system of the second conventional technique, the operation of the power reduction control by the comprehensive monitoring device 1PA will be described first.
[0014]
In the normal state, the integrated monitoring device 1PA monitors the power consumption of each subsystem (load control system) by the power consumption monitoring unit 12PA (S100 in FIG. 19). If each subsystem is operating with a power amount exceeding a predetermined amount, the process proceeds to a first step of power reduction control. Then, the power target value management unit 14 sets a power target value for reducing the power consumption of the lighting subsystem 2PB (S101), and the control determination unit 15 turns on the lighting fixture 21PB to achieve the power target value. A control operation pattern for lowering the level to 90% is calculated (S102). The control unit 10PA generates a power reduction control signal based on the control operation pattern and outputs the signal through the building network interface 11 (S103).
[0015]
When the lighting control controller 20PB receives the power reduction control signal, it turns on the lighting fixture 21PB to be controlled by the lighting control controller 20P (or the lighting fixture that is turned on by human detection when the individual lighting fixture has a human detection unit). The lighting control for reducing the level to 90% is performed, and the power consumption of the lighting fixture 21PB after the lighting control is fed back to the comprehensive monitoring device 1PA (S104 to S105).
[0016]
The comprehensive monitoring device 1PA compares the power consumption fed back from each lighting subsystem 2PB after the execution of the power reduction control with the power target value set by the power target value management unit 14, and when the target value is achieved, comprehensive monitoring. The operation state is maintained until the power reduction release is notified from the device 1PA (S106 to S108). On the other hand, in the case where the target is achieved, if further power reduction is required (S109 to S110), or if the target is not achieved (S111), the process proceeds to the second step of power reduction.
[0017]
In the second step, a control operation pattern for lowering the lighting level of the lighting equipment 21PB to 80% is calculated, and based on this, a power reduction control signal is generated and output to the lighting equipment 21PB (S112 to S113). As a result, the lighting level of the lighting fixture 21PB is reduced to 80%, and the power consumption of the lighting fixture 21PB after the lighting control is fed back to the integrated monitoring device 1PA (S114 to S115).
[0018]
The comprehensive monitoring device 1PA compares the power consumption fed back from each lighting subsystem 2PB after the execution of the power reduction control with the power target value set by the power target value management unit 14, and when the target value is achieved, comprehensive monitoring. The operation state is held until the power reduction release is notified from the device 1PA (S116 to S118). On the other hand, in the case where the target is achieved, if further power reduction is required (S119 to S120) or the target is not achieved (S121), the process proceeds to the third step of power reduction.
[0019]
In the third step, a control operation pattern for lowering the lighting level of the lighting fixture 21PB to 70% is calculated, and based on this, a power reduction control signal is generated and output to the lighting fixture 21PB (S122 to S123). Thereby, the lighting level of the lighting fixture 21PB is reduced to 70%, and the power consumption of the lighting fixture 21PB after the lighting control is fed back to the integrated monitoring device 1PA (S124 to S125). This state is maintained until notification of cancellation of power reduction is notified from the integrated monitoring device 1PA (S126).
[0020]
In addition, in various subsystems other than the illumination subsystem 2PB, similarly to the above, the power reduction control of the load device is performed based on the power reduction instruction calculated by the integrated monitoring device 1PA.
[0021]
Next, the operation of the illumination subsystem according to the detection result of the human detection unit will be described. The lighting control controller 20PB monitors the presence or absence of a person in the detection area near the installation location of the lighting control controller 20PB with the own person detection unit 206, and the lighting fixture is operated so as to operate as shown in FIG. 21PB is controlled.
[0022]
That is, if a detection result indicating that a person is present (“person detection” in the figure) is obtained from the person detection unit 206, control for operating the lighting fixture 21PB at full lighting (“lighting level 100%” in the figure) is executed. You. More specifically, the human detection unit 206 outputs the human detection information to the arithmetic processing unit 200PB, and the arithmetic processing unit 200PB receives the information, performs signal processing, and instructs the timer circuit 207 to reset (reset instruction). And an instruction (generation instruction) to the illumination control signal generation unit 203 to generate a control signal for setting the lighting level of the lighting fixture 21PB to 100%. Upon receiving the reset instruction, the timer circuit 207 enters an initialization state and starts (restarts) time measurement for a predetermined time. On the other hand, the illumination control signal generation unit 203 that has received the generation instruction generates an illumination control signal for setting the lighting level to 100%, and transmits the generated illumination control signal to the lighting fixture 21PB via the signal transmission / reception unit 202. Thereby, the lighting fixture 21PB performs the lamp power control at the lighting level of 100%. Note that, when a certain period of time has elapsed without receiving a reset instruction from the arithmetic processing unit 200PB at the time of measuring the certain time, the timer circuit 207 notifies the arithmetic processing unit 200PB of the fact (time-up of the certain time).
[0023]
At time t10, a detection result indicating that a person has disappeared is obtained from the person detection unit 206, and if a certain time elapses at time t11 while the non-human detection result is held, a period until the certain time elapses ( At times t10 to t11), the lighting fixture 21PB is continuously operated with full lighting, and after a certain time has elapsed, the lighting fixture 21PB is reduced to a lighting level of 50% from full lighting over a first fade time. Is performed. More specifically, the timer circuit 207 notifies the arithmetic processing unit 200PB of the time-up of a certain period of time, and upon receiving the notification, the arithmetic processing unit 200PB performs signal processing and starts measuring the lighting holding time described later. As described above, a start instruction is issued to the timer circuit 207, and a generation instruction is issued to the illumination control signal generation unit 203 so as to generate a control signal for lowering the lighting level of the lighting fixture 21PB to 50%. Upon receiving the start instruction, the timer circuit 207 starts measuring the lighting holding time. On the other hand, the illumination control signal generation unit 203 that has received the generation instruction generates an illumination control signal for lowering the lighting level to 50%, and transmits it to the lighting fixture 21PB via the signal transmission / reception unit 202. Thereby, the lighting fixture 21PB reduces the lighting level to 50% over the first fade time, and performs the lamp power control at this level. Note that if the lighting hold time has elapsed without receiving a reset instruction from the arithmetic processing unit 200PB, the timer circuit 207 notifies the arithmetic processing unit 200PB of the fact (time-up of the lighting hold time).
[0024]
After the end time t12 of the first fade time, the lighting fixture 21PB is operated at the lighting level of 50% from the time point t11 of the fixed time until the predetermined lighting holding time elapses (t12 to t13). After the lighting hold time has elapsed, control for operating the lighting fixture 21PB is performed so that the output is reduced from the lighting level of 50% to the lighting level of 0% (“off” in the figure) over a second fade time. You. More specifically, the timer circuit 207 notifies the arithmetic processing unit 200PB of the time-up of the lighting holding time, and upon receiving the notification, the arithmetic processing unit 200PB performs signal processing to reduce the lighting level of the lighting fixture 21PB to 0%. An instruction is issued to the illumination control signal generation unit 203 to generate a control signal for reducing the power consumption. The illumination control signal generation unit 203 that has received the instruction generates an illumination control signal for setting the lighting level to 0%, and transmits the generated illumination control signal to the lighting fixture 21PB via the signal transmission / reception unit 202. As a result, the lighting fixture 21PB reduces the lighting level to 0% over the second fade time, and controls the lamp power (extinguish) at this level. In some cases, the lighting is maintained at a lighting level of 50% without being turned off.
[0025]
After this or at or after the time point t11, if a detection result indicating that a person is present is obtained from the person detection unit 206, control for operating the lighting fixture 21PB at full lighting is executed.
[0026]
As described above, by automatically controlling the lighting fixture 21PB based on the detection result of the person detection unit 206 of the lighting control controller 20PB, it becomes possible to control the lighting fixture in consideration of the presence or absence of a person. . Note that there is also a configuration in which a human detection unit is provided for each lighting fixture, and the individual lighting fixtures independently control based on the detection result of each human detection unit.
[0027]
Japanese Patent Application Laid-Open No. 11-45782 (Patent Document 1) discloses that a main control device is connected to one or a plurality of terminals including those for lighting load dimming by a transmission line. A dimming monitoring and control system is described in which an output value is transmitted as dimming control data to a dimming terminal via a transmission line, and the dimming terminal dims an illumination load according to the dimming output value. I have.
[0028]
[Patent Document 1]
JP-A-11-45782
[0029]
[Problems to be solved by the invention]
In the first prior art, the functions of power monitoring and power reduction control are concentrated on the general monitoring device. When the system scale becomes large, the power consumption monitoring of each subsystem and the calculation at the time of calculating the control operation pattern for power reduction are performed. In the processing, there is a problem that the load on the integrated monitoring device becomes heavy. In addition, in order to realize the above-described functions, the power consumption monitoring unit, the control determination unit, and the control unit in the comprehensive monitoring device require sophisticated arithmetic processing functions, which increases the cost of the comprehensive monitoring device itself. .
[0030]
In the second prior art, in the case of a lighting system, it is possible to control the lighting fixture in conjunction with the detection result of the human detection unit, and to control the lighting fixture in accordance with a power reduction instruction from the general monitoring device.
[0031]
However, these two controls are performed independently of each other, and the control based on the power reduction instruction is not optimized between the former control and the latter control. There is room.
[0032]
In addition, in the configuration in which the dimming control is performed uniformly as shown in FIG. 20, when the lighting fixtures that are turned off due to non-detection of a person are randomly present, the power target value set by the general monitoring device is achieved. Can be difficult to do. That is, the lighting level of a lighting fixture installed near a lighting fixture that is turned off due to non-detection of a person is similarly reduced, so that the visual environment near the lighting fixture that is turned off is lower in illuminance than in other places. There is a risk of deterioration due to the large amount of reduction.
[0033]
The present invention has been made in view of the above circumstances, and does not require a high-cost comprehensive monitoring device without increasing the load on the comprehensive monitoring device even when the system scale is large. The purpose is to provide a management system.
[0034]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a subsystem including a load device and a controller for controlling the load device, and a power consumption monitoring means for monitoring power consumption by the load device in the subsystem. And a general monitoring device that issues a power reduction instruction to a controller in the subsystem when it is necessary to reduce the power consumption monitored by the power consumption monitoring means. A load control system including at least one of the subsystems included in a management system in which a result of detection by a person detecting unit that detects whether the load is detected is used for control of the load device; When a power reduction instruction is received from the device, the current load is applied to the load devices in the subsystem to which the device belongs. Seeking low load output level than the output level and performs control so as to operate in the load output level.
[0035]
According to a second aspect of the present invention, in the load control system according to the first aspect, the human detecting means is provided in a load device or a controller in the subsystem, and the controller issues a power reduction instruction from the general monitoring device. In the subsystem to which it belongs, in the subsystem to which it belongs, the control of the load device performed in accordance with the detection result that the person has disappeared by the human detection means is performed by the load device when the power reduction instruction is not received from the comprehensive monitoring device. It is characterized in that control for changing so that power consumption is reduced as compared with control is performed.
[0036]
According to a third aspect of the present invention, in the load control system according to the second aspect, the load device is a lighting device, and the person detection unit uses a detection result indicating that a person is present for lighting control of the load device. The detection result that the person has disappeared is used for dimming control of the load device, and if the detection result of the presence of a person is not obtained during a predetermined lighting holding time from the start of the dimming control, the load device is detected. The controller is used for turning off or dimming control. When the controller receives a power reduction instruction from the general monitoring device, the controller adjusts the load device in the subsystem to which the controller belongs from the lighting holding time or the lighting control. To change the fade time until the transition to the light control to be shorter than the lighting holding time or the fade time when the power reduction instruction is not received from the comprehensive monitoring device. And performing control.
[0037]
According to a fourth aspect of the present invention, in the load control system according to the second aspect, the load device is a lighting device, and the person detection unit uses a detection result indicating that a person is present for lighting control of the load device. The detection result that the person has disappeared is used for dimming control of the load device. The power reduction instruction includes a plurality of levels having different power reduction amounts. Receiving a power reduction instruction from the controller, performs control for changing the dimming rate by the dimming control on the load device in the subsystem to which the self belongs in accordance with the level of the power reduction instruction. .
[0038]
According to a fifth aspect of the present invention, in the load control system according to the first or second aspect, the person detecting means is provided in a plurality of load devices in the subsystem, wherein the load device includes a light source, and includes a light source. A lighting device that turns on its own light source when a detection result that a person is present is obtained from the human detection unit, and the controller is obtained from the plurality of load devices when receiving a power reduction instruction from the comprehensive monitoring device. From the result of the detection of the presence of a person by the person detecting means, the number of lighting fixtures that turn on the light source is obtained, the load output level corresponding to the power reduction instruction is obtained from this number, and the light source is turned on. The lighting device is controlled to operate at the load output level.
[0039]
According to a sixth aspect of the present invention, in the load control system according to the first or second aspect, the human detecting means is provided in a plurality of load devices in the subsystem, and the controller reduces power from the integrated monitoring device. When the instruction is received, the detection result of the person detection means obtained from each load device in the subsystem to which the self belongs belongs to each load device in the subsystem to which the self belongs, and the current load output level is reduced. It is characterized in that control is performed such that a load output level at which a difference is detected due to a difference in detection result by the human detection means is low and operation is performed at this load output level.
[0040]
A management system according to a seventh aspect of the present invention includes the load control system according to any one of the first to sixth aspects, and power consumption monitoring means for monitoring power consumption by a load device in the load control system. When it is necessary to reduce the power consumption monitored by the power monitoring means, a general monitoring device that issues a power reduction instruction to a controller in the load control system is connected to a network, and whether or not a person is present The detection result of the person detecting means for detecting the load is used for controlling the load device.
[0041]
BEST MODE FOR CARRYING OUT THE INVENTION
(1st Embodiment)
FIG. 1 is a configuration diagram of a management system according to a first embodiment of the present invention, and FIG. 2 is a configuration diagram of a lighting fixture in FIG.
[0042]
As shown in FIG. 1, the management system according to the first embodiment is configured by connecting a comprehensive monitoring device 1 and a plurality of lighting subsystems 2 to a wiring L1 of a building equipment network, and determines whether a person is present. Building equipment (equipment) whose detection result by the human detection part is used for controlling load equipment.
[0043]
Note that the first embodiment is characterized by power reduction control based on a power reduction instruction issued by the integrated monitoring device 1. The above-described human detection unit is provided to a lighting control controller 20 or a plurality of lighting fixtures 21 described later in the lighting subsystem 2. The configuration may be provided or a configuration provided as a single terminal device, and some of them will be described in other embodiments described later.
[0044]
The integrated monitoring device 1 includes a building network interface 11 for transmitting and receiving signals to and from a plurality of subsystems (at least the lighting subsystem 2 in the example of FIG. 1) as in the first and second related arts. As a difference from the technology, a power consumption monitoring unit 12 and a control unit 10 are provided.
[0045]
The power consumption monitoring unit 12 monitors power consumption by each load device in a plurality of subsystems. Specifically, power consumption values of the subsystems (hereinafter, referred to as “subsystem power consumption values”) are obtained from each of the plurality of subsystems via the building network interface 11, and these subsystem power consumption values are summed. To calculate the power consumption value of each subsystem as a whole (hereinafter referred to as “system power consumption value”), and reduce the power according to whether the system power consumption value exceeds the power consumption specification value held by itself. It is configured to determine whether to make a request. The power reduction instruction includes, for example, a plurality of levels in which the amount of reduction increases in the order of power reduction level 1, power reduction level 2,..., And whether a specified power consumption value according to the level issues a power reduction request of that level. Used to determine whether or not. The system power consumption value is the power consumption value of each subsystem as a whole. However, the lighting control system including at least one lighting subsystem and the air conditioning control including at least one air conditioning subsystem It may be configured to be calculated for each load control system such as a system.
[0046]
The control unit 10 performs processing such as control of the entire management system, such as giving an instruction to each subsystem via the building network interface 11, based on the operation state of each subsystem and the monitoring result of the power consumption monitoring unit 12. Is what you do. For example, when the power consumption monitoring unit 12 determines that a power reduction request is issued, a process of generating a power reduction instruction signal and transmitting it to each subsystem via the building network interface 11 is performed. The power reduction instruction signal notifies only that a power reduction request has been issued, and does not include specific contents of the load control operation.
[0047]
The lighting subsystem 2 includes a plurality of lighting devices 21 as load devices, and a lighting control controller 20 that is connected to these lighting devices 21 via a lighting signal line L2 and controls each lighting device 21. I have.
[0048]
For example, as shown in FIG. 2, the lighting fixture 21 is connected to a signal transmission / reception unit 211 for transmitting / receiving a signal to / from the illumination control controller 20 and a lamp load LD as a light source. And a lighting level detection circuit 213 for detecting a lighting level (for example, a so-called lamp voltage and lamp current level) of the lamp load LD, and a control unit 210. ing.
[0049]
The control unit 210 performs processing such as control of the entire lighting fixture 21, for example, signal processing of a lighting control signal, generation processing of an operation state information signal of the lighting fixture 21, control of the lighting device 212, and the like. More specifically, when the lighting control signal from the lighting control controller 20 is received by the signal transmission / reception unit 211, the lighting device 212 is controlled according to the control content (control operation pattern) included in the lighting control signal. Control (power control) for turning on, off, or dimming the lamp load LD is performed. In addition, based on the current lighting level detected by the lighting level detection circuit 213 and the previously held rated lamp power consumption value of the lamp load LD, the power consumption value of the lighting fixture 21 (hereinafter referred to as “load power consumption value”). ) Is generated and transmitted to the illumination controller 20 via the signal transmission / reception unit 211. Here, the rated lamp power consumption value is used because it is necessary to know the dimming rate for power control.
[0050]
Returning to FIG. 1, the lighting control controller 20 includes a building network interface 201 for transmitting and receiving signals to and from the integrated monitoring device 1 and a signal transmitting and receiving unit for transmitting and receiving signals to and from each lighting fixture 21 in the lighting subsystem 2 to which the lighting control controller 20 belongs. 202 and an illumination control signal generation unit 203 that generates an illumination control signal that matches the control operation pattern, in the same manner as in the second related art, and differs from the second related art as a power target value management unit 204. , A control determination unit 205 and an arithmetic processing unit 200.
[0051]
The power target value management unit 204 sets a target value of the power consumption of each lighting fixture 21 in the lighting subsystem 2 to which the power unit belongs (hereinafter, referred to as a “subsystem target value”). The subsystem target value is set according to the power reduction level of the power reduction instruction.
[0052]
The control determination unit 205 creates (calculates) a control operation pattern of each lighting fixture 21 in accordance with the subsystem target value set by the power target value management unit 204. For example, a load power consumption value smaller than a load power consumption value as a current load output level is obtained as an individual target value for at least a part of each lighting fixture 21 in the lighting subsystem 2 to which the self belongs, and the individual target value is obtained. A control operation pattern for operating at the target value is created.
[0053]
The arithmetic processing unit 200 performs processing such as overall control of the lighting subsystem 2 through arithmetic processing. For example, when a load power consumption value is acquired from each lighting fixture 21 via the signal transmitting / receiving unit 202, the load consumption A power value is added to obtain a subsystem power consumption value, and a process of transmitting the subsystem power consumption value to the integrated monitoring device 1 via the building network interface 201 is performed. When the power reduction instruction signal from the integrated monitoring device 1 is received by the building network interface 201, a process for creating the control operation pattern is executed in cooperation with the power target value management unit 204 and the control determination unit 205. Is done. Further, when the illumination control signal generation unit 203 generates an illumination control signal that matches the control operation pattern, a process of transmitting the illumination control signal to each lighting fixture 21 via the signal transmission / reception unit 202 is executed.
[0054]
Next, the operation of the management system of the first embodiment will be described. In each lighting fixture 21 of each lighting subsystem 2, information on the load power consumption value is created from the current lighting level detected by the lighting level detection circuit 213 and the rated lamp power consumption value, and the information is transmitted via the signal transmission / reception unit 211. It is transmitted to the lighting control controller 20.
[0055]
When the information of the load power consumption value from each lighting fixture 21 in the lighting subsystem 2 is acquired via the signal transmitting / receiving unit 202 in the lighting control controller 20 of each lighting subsystem 2, the load power consumption values are added. By doing so, a subsystem power consumption value is obtained. Thereafter, the subsystem power consumption value is transmitted to the integrated monitoring device 1 via the building network interface 201.
[0056]
When the subsystem power consumption values from the respective subsystems such as the lighting subsystem 2 are acquired via the building network interface 11 in the integrated monitoring device 1, the system power consumption values are calculated by summing the subsystem power consumption values. Is calculated. Thereafter, it is determined whether to issue a power reduction request according to whether the system power consumption value exceeds the specified power consumption value. When it is determined that the power reduction request is not issued, the current operation state of the management system is maintained. On the other hand, when it is determined that the power reduction request is issued, a power reduction instruction signal is generated. The information is transmitted to each subsystem via the building network interface 11. Here, it is assumed that, for example, a power reduction instruction signal of power reduction level 1 is generated and transmitted.
[0057]
In the lighting control controller 20 of each lighting subsystem 2, when the power reduction instruction signal of the power reduction level 1 from the integrated monitoring device 1 is received by the building network interface 201, the power reduction control mode corresponding to the power reduction level 1 is set. Transition. Then, under the cooperation of the instruction, transfer, signal processing, and the like of the arithmetic processing unit 200, the subsystem target value for the power reduction level 1 is set by the power target value management unit 204, and the control determination unit 205 An individual target value smaller than the current load power consumption value is obtained for at least a part of each lighting fixture 21 in the illumination subsystem 2, and a control operation pattern for operating at the individual target value is created. Subsequently, an illumination control signal that matches the control operation pattern is generated by the illumination control signal generation unit 203, and transmitted from the signal transmission and reception unit 202 to each lighting fixture 21.
[0058]
In each of the lighting fixtures 21 of each of the lighting subsystems 2, when the lighting control signal from the lighting control controller 20 is received by the signal transmitting / receiving unit 211, the control unit 210 according to the control content (control operation pattern) included in the lighting control signal. By controlling the lighting device 212, the lamp load LD is turned on, turned off, or dimmed. At this time, the load power consumption value of at least a part of each lighting fixture 21 in each lighting subsystem 2 is reduced to be the individual target value.
[0059]
Subsequently, the control unit 210 creates information on the load power consumption value from the current lighting level detected by the lighting level detection circuit 213 and the rated lamp power consumption value. Sent to. The transmission processing of the load power consumption value information can be omitted if the rated lamp power consumption value has already been transmitted to the lighting control controller 20.
[0060]
The lighting control controller 20 of each lighting subsystem 2 calculates a subsystem power consumption value from the latest load power consumption value and determines whether or not the power consumption value is equal to or less than the subsystem target value. Here, when information on the load power consumption value is transmitted from each lighting fixture 21, the subsystem power consumption value is calculated by adding the load power consumption values. On the other hand, when the control content included in the lighting control signal for each lighting fixture 21 is the dimming rate and the rated lamp power consumption value of each lighting fixture 21 is held, the dimming is performed to the rated lamp power consumption value. The load power consumption value is calculated by multiplying by the rate, and the subsystem power consumption value is calculated by adding the load power consumption value of each lighting fixture 21.
[0061]
If the subsystem power consumption value is equal to or less than the subsystem target value, the arithmetic processing unit 200 determines that the target has been achieved, and the current operation state of the management system is maintained. At this time, the subsystem power consumption value is transmitted to the integrated monitoring device 1. After that, when a power reduction release signal is transmitted from the comprehensive monitoring device 1, each lighting fixture 21 is turned on at a power consumption (for example, a rated lamp power consumption value) preset for normal operation in accordance with the power reduction release signal. Operate.
[0062]
On the other hand, if the subsystem power consumption value exceeds the subsystem target value and the arithmetic processing unit 200 determines that the target is not attained, or if it is switched to the power reduction level 2, the power reduction corresponding to the power reduction level 2 Move to control mode. Then, the subsystem target value for the power reduction level 2 is set by the power target value management unit 204, and the control determination unit 205 adjusts at least a part of each lighting fixture 21 in the lighting subsystem 2 in accordance with the subsystem target value. An individual target value smaller than the current load power consumption value is obtained, and a control operation pattern for operating with the individual target value is created. Subsequently, an illumination control signal that matches the control operation pattern is generated by the illumination control signal generation unit 203, and transmitted from the signal transmission and reception unit 202 to each lighting fixture 21.
[0063]
In each of the lighting fixtures 21 of each of the lighting subsystems 2, when the lighting control signal from the lighting control controller 20 is received by the signal transmitting / receiving unit 211, the control unit 210 according to the control content (control operation pattern) included in the lighting control signal. By controlling the lighting device 212, the lamp load LD is turned on, turned off, or dimmed. At this time, the load power consumption value of at least a part of each lighting fixture 21 in each lighting subsystem 2 is further reduced so as to be the individual target value.
[0064]
The lighting control controller 20 of each lighting subsystem 2 calculates a subsystem power consumption value from the latest load power consumption value and determines whether or not the power consumption value is equal to or less than the subsystem target value.
[0065]
If the subsystem power consumption value is equal to or less than the subsystem target value, the arithmetic processing unit 200 determines that the target has been achieved, and the current operation state of the management system is maintained. At this time, the subsystem power consumption value is transmitted to the integrated monitoring device 1. After that, when a power reduction release signal is transmitted from the comprehensive monitoring device 1, each lighting fixture 21 operates with power consumption preset for normal operation in accordance with the power reduction release signal.
[0066]
On the other hand, if the subsystem power consumption value exceeds the subsystem target value and the arithmetic processing unit 200 determines that the target is not achieved or is switched to a power reduction level of 3 or more, the power reduction level of 3 or more To the power reduction control mode corresponding to the above, and the same processing as described above is executed. When the power reduction level is the maximum level of the power reduction amount, the operation state of the maximum power reduction level is maintained until the power reduction release signal is transmitted from the general monitoring device 1 as in step S126 of FIG. May be maintained.
[0067]
As described above, according to the first embodiment, the lighting control controller 20 included in each lighting subsystem 2 supplies the current load power consumption value to at least a part of each lighting fixture 21 in the lighting subsystem 2 to which the lighting subsystem 2 belongs. Since the individual target value smaller than that is obtained and the control is performed so as to operate with the individual target value, the comprehensive monitoring device 1 does not need to perform the specific control of each lighting fixture 21 only by giving the power reduction instruction. Therefore, the load of the arithmetic processing of the integrated monitoring device 1 can be reduced, and the configuration can be simplified and the cost can be reduced. This makes it possible to provide a load control system that does not require a high-cost integrated monitoring device without increasing the load on the integrated monitoring device even when the system scale increases.
[0068]
(2nd Embodiment)
FIG. 3 is a configuration diagram of a management system according to a second embodiment of the present invention, and FIG. 4 is an operation explanatory diagram of a lighting subsystem in the management system.
[0069]
As shown in FIG. 3, the management system according to the second embodiment includes an integrated monitoring device 1 similar to the first embodiment and a plurality of lighting subsystems 2A different from the first embodiment, and a wiring L1 of a building equipment network. It is configured to be connected to.
[0070]
However, the power reduction instruction of the second embodiment has three levels with different power reduction amounts. If the power reduction amount for the lighting subsystem increases in the order of power reduction level 1, power reduction level 2, and power reduction level 3, I do. In the case of the power reduction instruction signals of the power reduction levels 1, 2, and 3, the control determination unit 205 determines the load power consumption value for at least a part of each of the lighting fixtures 21 in the lighting subsystem 2A to which the control unit 205 belongs. , 90%, 80%, and 70%, respectively, and a control operation pattern for operating with the individual target values is created. Note that 90%, 80%, and 70% are the ratios of the lighting level (load output level) to the rated lamp power consumption value.
[0071]
The lighting subsystem 2A includes a plurality of lighting fixtures 21 similar to the first embodiment, and a lighting control controller 20A that is connected to these lighting fixtures 21 via an illumination signal line L2 and controls each lighting fixture 21. Have.
[0072]
The lighting control controller 20A includes a building network interface 201, a signal transmission / reception unit 202, a lighting control signal generation unit 203, a power target value management unit 204, and a control determination unit 205 with the lighting control controller 20 of the first embodiment. In addition to being provided in the same manner, the lighting control controller 20 includes a human detection unit 206, a timer circuit 207A, and an arithmetic processing unit 200A.
[0073]
The human detection unit 206 is a so-called human sensor that is configured by, for example, a heat ray sensor and detects whether or not a person is within a predetermined detection area, and the detection result is taken into the arithmetic processing unit 200A as a detection signal. It has become.
[0074]
As shown in FIG. 4, the timer circuit 207A includes, in addition to the lighting holding time T similar to that of the timer circuit 207 of the second related art, a lighting holding time shorter than this, and a lighting holding time shorter in the order of T1, T2, and T3. It has a switching function for switching from the four lighting holding times T, T1, T2, and T3 to any one of the lighting holding times, and a timing function, and measures various times. For example, when the timer circuit 207A receives a reset instruction from the arithmetic processing unit 200A, the timer circuit 207A enters an initialization state and starts (restarts) the time measurement for a certain time, and does not receive the reset instruction for the time measurement for the certain time. Is passed to the arithmetic processing unit 200A. Further, when receiving a start instruction from the arithmetic processing unit 200A to start timing of the lighting holding time, the timer circuit 207A starts timing of the lighting holding time switched by the switching function, and counts the lighting holding time. If the lighting hold time elapses without receiving a reset instruction at this time, the fact (time-up of the lighting hold time) is notified to the arithmetic processing unit 200A.
[0075]
The arithmetic processing unit 200A is different from the arithmetic processing unit 200 according to the first embodiment in that when a power reduction instruction is received from the general monitoring device 1, a person detected by the human detection unit 206 is present in the lighting subsystem 2 to which the arithmetic processing unit 200A belongs. In order to change the control of each lighting device 21 performed according to the detection result indicating that the light source has disappeared so that the power consumption is reduced as compared with the control of each lighting device 21 when no power reduction instruction is received from the comprehensive monitoring device 1. Control.
[0076]
More specifically, when a power reduction instruction of the power reduction level 1, the power reduction level 2, and the power reduction level 3 is received from the comprehensive monitoring device 1, each of the lighting fixtures 21 in the lighting subsystem 2 to which the device belongs belongs. Control is performed to change the lighting holding time to the lighting holding times T1, T2, and T3 so as to be shorter than the lighting holding time T. On the other hand, when the power reduction cancellation is notified from the general monitoring device 1 and the power reduction instruction is not received, the lighting holding time for each lighting fixture 21 in the lighting subsystem 2 to which the lighting device 21 belongs is returned to the lighting holding time T. Control is performed.
[0077]
Next, the operation of the management system according to the second embodiment will be described. First, the operation of the power reduction control by the integrated monitoring device 1 will be described. In each lighting fixture 21 of each lighting subsystem 2A, load consumption is determined based on the current lighting level detected by the lighting level detection circuit 213 and the rated lamp power consumption value. Power value information is created and transmitted to the lighting control controller 20 via the signal transmission / reception unit 211.
[0078]
In the lighting control controller 20A of each lighting subsystem 2A, when the information of the load power consumption value from each lighting fixture 21 in the lighting subsystem 2A is obtained via the signal transmitting / receiving unit 202, the load power consumption values are added. By doing so, a subsystem power consumption value is obtained. Thereafter, the subsystem power consumption value is transmitted to the integrated monitoring device 1 via the building network interface 201.
[0079]
When the subsystem power consumption value from each lighting subsystem 2A is acquired via the building network interface 11 in the integrated monitoring device 1, the system power consumption value is calculated by summing the subsystem power consumption values. . Thereafter, it is determined whether to issue a power reduction request according to whether the system power consumption value exceeds the specified power consumption value. When it is determined that the power reduction request is not issued, the current operation state of the management system is maintained. On the other hand, when it is determined that the power reduction request is issued, a power reduction instruction signal is generated. The information is transmitted to each lighting subsystem 2A via the building network interface 11. Here, for example, it is assumed that a power reduction instruction signal of power reduction level 1 has been generated and transmitted.
[0080]
In the lighting control controller 20A of each lighting subsystem 2A, when a power reduction level 1 power reduction instruction signal from the integrated monitoring device 1 is received by the building network interface 201, the power reduction control mode corresponding to the power reduction level 1 is set. Transition. Then, a subsystem target value for the power reduction level 1 is set by the power target value management unit 204, and in accordance with this, the control determination unit 205 controls at least a part of each lighting fixture 21 in the lighting subsystem 2A. An individual target value at which the load power consumption value becomes, for example, 90% is obtained, and a control operation pattern for operating with the individual target value is created. Subsequently, an illumination control signal that matches the control operation pattern is generated by the illumination control signal generation unit 203, and transmitted from the signal transmission and reception unit 202 to each lighting fixture 21.
[0081]
In each lighting fixture 21 of each lighting subsystem 2A, when the lighting control signal from the lighting control controller 20 is received by the signal transmitting / receiving unit 211, the control unit 210 according to the control content (control operation pattern) included in the lighting control signal. By controlling the lighting device 212, the lamp load LD is turned on, turned off, or dimmed. At this time, the load power consumption value of at least a part of each lighting fixture 21 in each lighting subsystem 2 is reduced to 90%. Subsequently, the control unit 210 creates information on the load power consumption value from the current lighting level detected by the lighting level detection circuit 213 and the rated lamp power consumption value. Sent to. Note that the process of transmitting the load power consumption value information can be omitted if the rated lamp power consumption value has already been transmitted to the lighting control controller 20A.
[0082]
In the lighting controller 20A of each lighting subsystem 2A, the arithmetic processing unit 200A calculates the subsystem power consumption value from the latest load power consumption value, and determines whether or not the subsystem power consumption value is equal to or less than the subsystem target value. .
[0083]
If the subsystem power consumption value is equal to or less than the subsystem target value, the arithmetic processing unit 200A determines that the target has been achieved, and the current operation state of the management system is maintained. At this time, the subsystem power consumption value is transmitted to the integrated monitoring device 1. After that, when a power reduction release signal is transmitted from the comprehensive monitoring device 1, each lighting fixture 21 operates with power consumption preset for normal operation in accordance with the power reduction release signal.
[0084]
On the other hand, if the subsystem power consumption value exceeds the subsystem target value and the arithmetic processing unit 200A determines that the target has not been achieved or is switched to the power reduction level 2, the power reduction corresponding to the power reduction level 2 Move to control mode. Then, a subsystem target value for the power reduction level 2 is set, and the control determination unit 205 adjusts the load power consumption value to at least a part of each lighting fixture 21 in each lighting subsystem 2A according to the target value. An individual target value of 80% is obtained, and a control operation pattern for operating with this individual target value is created. Subsequently, an illumination control signal that matches the control operation pattern is generated by the illumination control signal generation unit 203, and transmitted from the signal transmission and reception unit 202 to each lighting fixture 21.
[0085]
In each lighting fixture 21 of each lighting subsystem 2A, when the lighting control signal from the lighting control controller 20A is received by the signal transmitting / receiving unit 211, the control unit 210 according to the control content (control operation pattern) included in the lighting control signal. By controlling the lighting device 212, the lamp load LD is turned on, turned off, or dimmed. At this time, the load power consumption value of at least a part of each lighting fixture 21 in each lighting subsystem 2 is reduced to 80%.
[0086]
In the lighting controller 20A of each lighting subsystem 2A, the arithmetic processing unit 200A calculates the subsystem power consumption value from the latest load power consumption value, and determines whether or not the subsystem power consumption value is equal to or less than the subsystem target value. .
[0087]
If the subsystem power consumption value is equal to or less than the subsystem target value, the arithmetic processing unit 200A determines that the target has been achieved, and the current operation state of the management system is maintained. At this time, the subsystem power consumption value is transmitted to the integrated monitoring device 1. After that, when a power reduction release signal is transmitted from the comprehensive monitoring device 1, each lighting fixture 21 operates with power consumption preset for normal operation in accordance with the power reduction release signal.
[0088]
On the other hand, if the subsystem power consumption value exceeds the subsystem target value and the arithmetic processing unit 200A determines that the target is not attained, or switches to the power reduction level 3, the power reduction level 3 is supported. Shift to the power reduction control mode. Thereafter, the same processing as described above is performed. For example, the operation state of the power reduction level 3 is maintained until the power monitoring cancellation signal is transmitted from the integrated monitoring device 1.
[0089]
Next, the operation of the illumination subsystem 2A according to the detection result of the human detection unit 206 will be described. The lighting control controller 20A of each lighting subsystem 2A calculates the lighting holding time of the timer circuit 207A during normal times when the building network interface 201 does not receive the power reduction instruction signals of the power reduction levels 1, 2, and 3 from the comprehensive monitoring device 1. While the processing unit 200A switches to the lighting holding time T, when the received power is reduced, the arithmetic processing unit 200A switches the lighting holding time of the timer circuit 207A to the lighting holding time of T1, T2, and T3.
[0090]
Then, the lighting controller 20 </ b> A monitors the presence or absence of a person in a detection area near the installation location of the lighting control controller 20 </ b> A with the own person detection unit 206 and controls the lighting apparatus 21.
[0091]
That is, if a detection result indicating that a person is present is obtained from the person detection unit 206, control is performed so that the load power consumption value is normally 100% during normal operation. Control is executed so that the load power consumption values become 90%, 80%, and 70%, respectively, in accordance with (3).
[0092]
Subsequently, a detection result indicating that the person has disappeared is obtained from the person detection unit 206, and if a certain time elapses while the non-human detection result is held, the illumination is continued until the certain time elapses. After the fixture 21 is operated at the above-described load power consumption value, and after a certain period of time has elapsed, control for operating the lighting fixture 21 is performed so that the output is reduced to a load power consumption value of 50%.
[0093]
Subsequently, the lighting fixture 21 is operated at the lighting level of 50% from the elapse of the certain time until the switched lighting holding time elapses, and after the lighting holding time elapses, the lighting fixture 21 is changed from the lighting level of 50%. Control is performed to operate the lighting apparatus 21 so as to reduce the output to a lighting level of 0% (extinguished).
[0094]
After this or after the elapse of the predetermined time, if a detection result indicating that a person is present is obtained from the person detection unit 206, control is performed so that the load power consumption value is normally 100%, while the power is At the time of reduction, control is performed so that the load power consumption values are 90%, 80%, and 70%, respectively, according to the power reduction levels 1, 2, and 3.
[0095]
As described above, by switching the lighting hold time according to the power reduction level of the power reduction instruction from the comprehensive monitoring device 1, the lighting time of the lighting fixture 21 when no person is detected can be shortened, and the power reduction instruction is received. It is possible to increase the power reduction amount more than the lighting holding time in the case where the lighting is not performed.
[0096]
As described above, according to the second embodiment, when the power reduction instruction is received, the control of the lighting apparatus 21 performed when no person is detected reduces the power consumption as compared to the control of the lighting apparatus 21 when the power reduction instruction is not received. Therefore, the amount of power reduction can be increased correspondingly to the first embodiment.
[0097]
(Third embodiment)
FIG. 5 is an operation explanatory diagram of the lighting subsystem in the management system according to the third embodiment of the present invention.
[0098]
The management system of the third embodiment is configured in the same manner as the second embodiment shown in FIG. 3, and controls the lighting fixture 21 performed in accordance with the detection result of the absence of a person by the person detection unit 206. It is characterized in that the power consumption is changed so as to reduce the power consumption as compared to the control of the lighting apparatus 21 when the power reduction instruction is not received from the monitoring device 1.
[0099]
Specifically, when the lighting control controller 20A of the third embodiment receives a power reduction instruction of the power reduction level 1, the power reduction level 2, and the power reduction level 3 from the comprehensive monitoring device 1, as illustrated in FIG. For each lighting fixture 21 in the lighting subsystem 2A to which it belongs, the fade time (first fade time) from the lighting control to the completion of the shift to the dimming control is not received from the comprehensive monitoring device 1 as a power reduction instruction. Control is performed to change to the fade times t1, t2, and t3, respectively, so as to be shorter than the fade time t in the case.
[0100]
Here, the fade time (t, t1, t2, t3) in which the operation time of the lighting control is set when the lighting control of the lighting fixture 21 is performed is stored in the timer circuit 207A in the lighting control controller 20A. .
[0101]
For example, when the power reduction instruction is not received from the comprehensive monitoring device 1 and the lighting level of the lighting fixture 21 is reduced from the full lighting state of 100% to the lighting level of 50% in response to non-detection of a person, the lighting fixture 21 fades. During the time t, the lighting level is reduced from 100% to 50%. On the other hand, when receiving a power reduction instruction from the comprehensive monitoring device 1, when the lighting level of the lighting fixture 21 is reduced from the full lighting state of 100% to the lighting level of 50% in response to non-detection of a person, the lighting fixture 21 The lighting level is reduced from 100% to 50% during the fade time corresponding to the reduction level.
[0102]
Next, the operation of the management system according to the third embodiment will be described. However, since the operation of the power reduction control by the comprehensive monitoring device 1 is the same as that of the second embodiment, the operation of the lighting subsystem 2A according to the detection result of the human detection unit 206 will be described.
[0103]
The lighting control controller 20A of each lighting subsystem 2A sets the fade time of the timer circuit 207A to the fade time when the building network interface 201 does not normally receive the power reduction instruction signals of the power reduction levels 1, 2, and 3 from the integrated monitoring device 1. On the other hand, when the received power is reduced, the fade time of the timer circuit 207A is changed to fade times t1, t2, and t3, respectively. For example, the control determination unit 205 changes the setting of the fade time t preset by the timer circuit 207A to t1, t2, and t3 that are shorter than this, in accordance with the shift notification to the power reduction control from the arithmetic processing unit 200A. The lighting holding time may be fixed to T or may be switched to the lighting holding times of T1, T2, and T3 as in the second embodiment.
[0104]
Then, the lighting controller 20 </ b> A monitors the presence or absence of a person in a detection area near the installation location of the lighting control controller 20 </ b> A with the own person detection unit 206 and controls the lighting apparatus 21.
[0105]
That is, if a detection result indicating that a person is present is obtained from the person detection unit 206, control is performed so that the load power consumption value is normally 100% during normal operation. Control is executed so that the load power consumption values become 90%, 80%, and 70%, respectively, in accordance with (3).
[0106]
Subsequently, a detection result indicating that the person has disappeared is obtained from the person detection unit 206, and if a certain time elapses while the non-human detection result is held, the illumination is continued until the certain time elapses. The appliance 21 is operated at the above-mentioned load power consumption value, and after a certain period of time has elapsed, the output is reduced to a load power consumption value of 50% over the changed fade time (t, t1, t2, t3). Thus, the control for operating the lighting apparatus 21 is executed. Specifically, after a predetermined time has elapsed, the arithmetic processing unit 200A instructs the lighting control signal generation unit 203 to generate a control signal for lowering the lighting level of the lighting fixture 21, and the timer circuit 207A sets the lighting holding time. Start counting. Upon receiving an instruction from the arithmetic processing unit 200A, the lighting control signal generating unit 203 lowers the lighting level of the lighting fixture 21 to 50%, and includes the contents of the fade times (t, t1, t2, t3) of the lighting control. A lighting control signal is generated and transmitted to the lighting fixture 21 via the signal transmitting / receiving unit 202. Upon receiving the lighting control signal, the lighting fixture 21 performs lamp power control to reduce the lamp lighting level to 50% according to the fade time (t, t1, t2, t3).
[0107]
Subsequently, the lighting fixture 21 is operated at the lighting level of 50% from the elapse of the fixed time to the elapse of the lighting holding time, and after the elapse of the lighting holding time, the lighting level is changed from the lighting level of 50% to the lighting level of 0%. Control for operating the lighting apparatus 21 so as to reduce the output to (turn off) is executed. When the output is reduced from the lighting level of 50% to the lighting level of 0% (extinguished), the output may be reduced over the changed fade time.
[0108]
After this or after the elapse of the predetermined time, if a detection result indicating that a person is present is obtained from the person detection unit 206, control is performed so that the load power consumption value is normally 100%, while the power is At the time of reduction, control is performed so that the load power consumption values are 90%, 80%, and 70%, respectively, according to the power reduction levels 1, 2, and 3.
[0109]
As described above, according to the third embodiment, when the lighting control controller 20A receives the power reduction instruction from the integrated monitoring device 1, the lighting control controller 20A controls the lighting fixtures 21 in the lighting subsystem 2A to which the lighting control controller 20A belongs from lighting control to dimming control. Control is performed to change the fade time until the completion of the transition to the lighting control so as to be shorter than the fade time when the power reduction instruction is not received from the integrated monitoring device 1. And the power consumption of the lighting fixture 21 can be reduced accordingly.
[0110]
In the third embodiment, the lighting control signal including the content of the fade time of the lighting control is configured to be generated and transmitted to the lighting fixture. A configuration in which the fade time is transmitted to the lighting equipment and the lighting equipment changes the fade time according to the power reduction level may be used.
[0111]
(Fourth embodiment)
The management system according to the fourth embodiment is configured in the same manner as the second and third embodiments, and performs control of the lighting apparatus 21 performed in accordance with a detection result indicating that a person has disappeared by the person detection unit 206, by using a comprehensive monitoring device. 1 is characterized in that the power consumption is reduced so as to be lower than the control of the lighting apparatus 21 in the case where the power reduction instruction is not received from 1.
[0112]
Specifically, when the lighting control controller 20A of the fourth embodiment receives a power reduction instruction of the power reduction level 1, the power reduction level 2, and the power reduction level 3 from the general monitoring device 1, the lighting control controller 20A changes to the level of the power reduction instruction. Accordingly, control is performed to change the dimming rate by the dimming control to 40%, 20%, and 0% for each lighting fixture 21 in the lighting subsystem 2A to which the self belongs. The dimming rate is not limited to this, and as shown in the example of FIG. 6, the dimming rate is set to 30%, 10%,... 0% according to the power reduction level 1, the power reduction level 2,. It may be a configuration that changes.
[0113]
Next, the operation of the management system according to the fourth embodiment will be described. However, since the operation of the power reduction control by the comprehensive monitoring device 1 is the same as that of the second embodiment, the operation of the lighting subsystem 2A according to the detection result of the human detection unit 206 will be described.
[0114]
When the building network interface 201 does not normally receive the power reduction instruction signals of the power reduction levels 1, 2, and 3 from the integrated monitoring device 1 in the lighting subsystem 2A, the lighting controller 20A of each lighting subsystem 2A While changing the dimming rate of each lighting fixture 21 by the dimming control to 50%, when reducing the received power, the dimming of each lighting fixture 21 in the lighting subsystem 2A to which the self belongs belongs by the dimming control. Change the rates to 40%, 20% and 0%, respectively.
[0115]
Then, the lighting controller 20 </ b> A monitors the presence or absence of a person in a detection area near the installation location of the lighting control controller 20 </ b> A with the own person detection unit 206 and controls the lighting apparatus 21.
[0116]
That is, if a detection result indicating that a person is present is obtained from the person detection unit 206, control is performed so that the load power consumption value is normally 100% during normal operation. Control is executed so that the load power consumption values become 90%, 80%, and 70%, respectively, in accordance with (3).
[0117]
Subsequently, a detection result indicating that the person has disappeared is obtained from the person detection unit 206, and if a certain time elapses while the non-human detection result is held, the illumination is continued until the certain time elapses. The appliance 21 is operated at the above-mentioned load power consumption value, and after a certain time has elapsed, the output is reduced to the load power consumption value of the changed dimming rate (50%, 40%, 20%, 0%). Thus, the control for operating the lighting apparatus 21 is executed. Specifically, after a certain period of time, the control determining unit 205 creates a control operation pattern for setting the lighting level of the lighting fixture to the changed dimming rate, and the illumination control signal generation unit 203 sets the control operation pattern as the control operation pattern. A lighting control signal for lowering the lighting level of the lighting fixture 21 to the changed dimming rate is generated based on the lighting control signal, and the lighting control signal is transmitted to the lighting fixture 21 via the signal transmission / reception unit 202. Upon receiving the lighting control signal, the lighting fixture 21 performs lamp power control to reduce the lamp lighting level to the changed dimming rate.
[0118]
Subsequently, the lighting fixture 21 is operated at the lighting level of the changed dimming rate from the point in time when the fixed time elapses until the lighting holding time elapses, and after the lighting holding time elapses, the lighting level is 0%. Control for operating the lighting apparatus 21 so as to reduce the output to (turn off) is executed. However, when the changed dimming rate is 0%, the dimming rate is maintained.
[0119]
After this or after the elapse of the predetermined time, if a detection result indicating that a person is present is obtained from the person detection unit 206, control is performed so that the load power consumption value is normally 100%, while the power is At the time of reduction, control is performed so that the load power consumption values are 90%, 80%, and 70%, respectively, according to the power reduction levels 1, 2, and 3.
[0120]
In addition, when the lighting fixture 21 is operating without detecting a person at the time of power reduction, the lighting control controller 20A does not immediately change the lighting level upon receiving an instruction to reduce the level or cancel the power reduction from the comprehensive monitoring device. Then, after the lighting fixture 21 is turned on by the human detection, the lighting control of the lighting fixture 21 is performed at the lighting level according to the above instruction when the lighting level is lowered again by the non-detection of the person.
[0121]
As described above, according to the fourth embodiment, when the lighting control controller 20A receives the power reduction instruction from the comprehensive monitoring device 1, each lighting fixture in the lighting subsystem 2A to which the lighting control controller 20A belongs belongs according to the level of the power reduction instruction. Since the control for changing the dimming rate by the dimming control is performed on the lighting control 21, the power consumption of the lighting fixture 21 can be reduced by the change in the dimming rate.
[0122]
In the second to fourth embodiments, the human detection unit 206 and the timer circuit 207A are configured to be provided in the lighting control controller 20A. However, as shown in FIG. A configuration 215 may be provided in the lighting fixture 21A. Also in this configuration, when the lighting control controller receives a power reduction instruction from the comprehensive monitoring device, the lighting subsystem of the lighting subsystem to which the lighting controller 21A performs in accordance with the detection result indicating that the person has disappeared by the person detection unit 214. As a control for changing the control so that the power consumption is reduced as compared with the control of the lighting fixture 21A when the power reduction instruction is not received from the general monitoring device, the power reduction instruction signal received from the general monitoring device is used for each lighting. If the control unit 210A that has transmitted the signal to the appliance 21A and received it performs control so as to perform the operation described in the second to fourth embodiments, the same effect as in the second to fourth embodiments can be obtained. Note that in FIG. 7, a configuration in which a lighting level detection circuit 213 similar to that in FIG. 2 is further provided may be employed.
[0123]
For example, the control unit 210A of the lighting fixture 21A switches the lighting holding time of the timer circuit 215 to the lighting holding time T during normal times when the power reduction instruction signals of the power reduction levels 1, 2, and 3 are not received from the lighting controller. When the received power is reduced, the lighting holding time of the timer circuit 215 is switched to the lighting holding time of T1, T2, and T3, respectively. Then, the control unit 210A monitors the presence or absence of a person in the detection area near the installation location by the own person detection unit 214, and controls the lamp load LD through the lighting device 212. Subsequent operations may be replaced with the human detection unit 206 and the lamp load LD in the description of the operation of the second embodiment, respectively.
[0124]
In addition, the control unit 210A of the lighting fixture 21A changes the fade time of the timer circuit 215 to the fade time t while receiving the power reduction instruction signals of the power reduction levels 1, 2, and 3 from the lighting control controller during normal times. When the power is reduced, the fade time of the timer circuit 215 is changed to fade times t1, t2, and t3, respectively. Then, the control unit 210A monitors the presence or absence of a person in the detection area near the installation location by the own person detection unit 214, and controls the lamp load LD through the lighting device 212. Subsequent operations may be performed by replacing the human detection unit 206 and the lighting fixture 21 with the human detection unit 214 and the lamp load LD in the description of the operation of the third embodiment.
[0125]
Furthermore, the control unit 210A of the lighting fixture 21A sets the dimming rate by its dimming control to its own lamp load LD during normal times when it does not receive the power reduction instruction signals of the power reduction levels 1, 2, and 3 from the lighting control controller. On the other hand, when the received power is reduced, the dimming rate of the own lamp load LD by the dimming control is changed to 40%, 20%, and 0%. Then, the control unit 210A monitors the presence or absence of a person in the detection area near the installation location by the own person detection unit 214, and controls the lamp load LD through the lighting device 212. Subsequent operations may be read by replacing the human detection unit 206 and the lighting fixture 21 with the human detection unit 214 and the lamp load LD in the description of the operation of the fourth embodiment, respectively.
[0126]
(Fifth embodiment)
FIG. 8 is a configuration diagram of a management system according to a fifth embodiment of the present invention, FIG. 9 is a configuration diagram of the lighting fixture in FIG. 8, and FIGS. 10 and 11 are diagrams illustrating the operation of the management system.
[0127]
As shown in FIG. 8, the management system according to the fifth embodiment includes an integrated monitoring device 1 similar to that of the first embodiment and a plurality of lighting subsystems 2B different from the first embodiment. It is configured to be connected to.
[0128]
The lighting subsystem 2B includes a plurality of lighting fixtures 21B, and a lighting control controller 20B that is connected to these lighting fixtures 21B via an illumination signal line L2 and controls each lighting fixture 21B.
[0129]
As shown in FIG. 9, the lighting fixture 21B includes a signal transmission / reception unit 211 and a lighting device 212 in the same manner as the lighting fixture 21 of the first embodiment. Is provided with a human detection unit 214 and a timer circuit 215, and a control unit 210B, which are the same as those in the above configuration.
[0130]
The control unit 210B is different from the control unit 210A of the configuration in FIG. 7 in that, when receiving a person detection status answer request requesting the detection result by the person detection unit 214 from the lighting control controller 20B, the detection result by the person detection unit 214 And a process of returning the own lighting device address to the lighting control controller 20B. Note that this processing may be further periodically executed.
[0131]
As shown in FIG. 8, the lighting control controller 20B includes a building network interface 201, a signal transmission / reception unit 202, a lighting control signal generation unit 203, and a power target value management unit 204 according to the first embodiment. In addition to the above, the lighting control controller 20 is different from the lighting control controller 20 in that a control determining unit 205A and an arithmetic processing unit 200B are provided.
[0132]
The control determining unit 205A is different from the control determining unit 205 of the first embodiment in that upon receiving a power reduction instruction signal from the comprehensive monitoring device 1, the control determining unit 205A issues the above-described human detection status response request. The number of lighting fixtures 21B that are illuminating the lamp load LD is determined from the detection result of the presence of a person by the person detection unit 214 obtained from the number 21B, and the number of lighting fixtures 21B as a load power consumption value according to the power reduction instruction is determined from the number. An individual target value is obtained, and a control operation pattern for operating with the individual target value is created. In addition, the lighting level lower limit Lmin for limiting the lower limit of the individual target value when the control operation pattern is created is set in the control determining unit 205A.
[0133]
The arithmetic processing unit 200B further executes a process of transmitting a power reduction instruction signal received from the integrated monitoring device 1 to the lighting fixture 21B as a difference from the arithmetic processing unit 200 of the first embodiment.
[0134]
Next, an operation of power reduction control by the comprehensive monitoring device 1 in the management system of the fifth embodiment will be described.
[0135]
In the lighting control controller 20B of each lighting subsystem 2B, when a power reduction instruction signal of any one of the power reduction levels 1 to 3 is received by the building network interface 201 from the integrated monitoring device 1 (S1 in FIG. 10), the power is reduced. Shift to the power reduction control mode corresponding to the reduction level. Then, the subsystem target value according to the power reduction level is set by the power target value management unit 204 (S2), a human detection status response request is issued by the control determination unit 205A, and the signal transmission / reception unit is cooperated by the arithmetic processing unit 200B. It is transmitted to each lighting fixture 21B via 202 (S3).
[0136]
In each lighting fixture 21B of each lighting subsystem 2B, when a person detection status response request is received from the lighting control controller 20B via the signal transmission / reception unit 211, when the lamp load LD is turned on or dimming, The operation result information including the detection result by the detection unit 214 and the lighting fixture address is transmitted to the illumination control controller 20B via the signal transmission / reception unit 211.
[0137]
In the lighting control controller 20B of each lighting subsystem 2B, when the detection result by the human detection unit 214 and the lighting fixture address are acquired from each lighting fixture 21B via the signal transmitting / receiving unit 202, the control determining unit 205A causes the plurality of lightings to be performed. From the detection result that there is a person obtained from the fixture 21B, the number of the lighting fixtures 21B that are lighting the lamp load LD is obtained, and the individual target value as the load power consumption value according to the power reduction instruction is obtained from the number. It is determined (S4, S5), and a control operation pattern for operating with this individual target value is created. At this time, the amount of reduction per lighting fixture is obtained by dividing the subsystem target value set by the power target value management unit 204 by the number of lighting fixtures 21B that are lighting the lamp load LD. An individual target value is obtained from this reduction amount. If the individual target value is lower than the lighting level lower limit Lmin, a control operation pattern is created such that the individual target value becomes the lighting level lower limit Lmin (S7). Otherwise, steps S4 and S5 are performed. A control operation pattern is created from the individual target values obtained in step (S8). Thereafter, a lighting control signal including the lighting fixture address of the lighting fixture 21B that is lighting the lamp load LD and matching the control operation pattern is generated by the lighting control signal generation unit 203, and transmitted from the signal transmission / reception unit 202 to each lighting fixture 21B. Is done.
[0138]
In each of the lighting fixtures 21B of each of the lighting subsystems 2B, when the signal transmission / reception unit 211 receives a lighting control signal including its own lighting fixture address from the lighting control controller 20B, the control content included in the lighting control signal ( The control unit 210B controls the lighting device 212 according to the control operation pattern), so that the lamp load LD is turned on, turned off, or dimmed (see FIG. 11).
[0139]
When the power reduction level is switched and the subsystem target value is changed in the power target value management unit 204, the control operation pattern of the lighting fixture 21B is calculated again in the same procedure as described above, and the lighting fixture 21B is controlled. Control for reducing power consumption is performed.
[0140]
As described above, according to the fifth embodiment, when the lighting control controller 20B receives the power reduction instruction from the integrated monitoring device 1, the lighting control controller 20B obtains a person detection unit 214 obtained from the plurality of lighting fixtures 21B from the detection result indicating that there is a person. The number of lighting fixtures 21B that are lighting the lamp load LD is obtained, and an individual target value as a load power consumption value according to the power reduction instruction is obtained from the number, and the lamp load LD is turned on with this individual target value. Since the control is performed to operate the lighting fixture 21B, the accuracy of achieving the power reduction target can be improved.
[0141]
In the fifth embodiment, the control operation pattern is created from the detection result by the human detection unit 214. However, the control operation pattern can be created from the operation state information of the lighting fixture 21B.
[0142]
(Sixth embodiment)
FIG. 12 is a configuration diagram of a management system according to a sixth embodiment of the present invention, and FIGS. 13 and 14 are explanatory diagrams of the operation of the management system.
[0143]
As shown in FIG. 12, the management system according to the sixth embodiment includes an integrated monitoring device 1 similar to that of the fifth embodiment and a plurality of lighting subsystems 2C different from the fifth embodiment. It is configured to be connected to.
[0144]
The lighting subsystem 2C includes a plurality of lighting fixtures 21B similar to the fifth embodiment, and a lighting control controller 20C that is connected to these lighting fixtures 21B via an illumination signal line L2 and controls each lighting fixture 21B. Have.
[0145]
The lighting control controller 20B includes a building network interface 201, a signal transmission / reception unit 202, a lighting control signal generation unit 203, and a power target value management unit 204, similarly to the lighting control controller 20B of the fifth embodiment. As a difference from the illumination control controller 20B, an arithmetic processing unit 200C and a control determination unit 205B are provided.
[0146]
The arithmetic processing unit 200C is different from the arithmetic processing unit 200B of the fifth embodiment in that when a human detection status response request is issued from the control determining unit 205B, the request is sent to each lighting fixture 21B via the signal transmitting / receiving unit 202. Then, when the detection result by the human detection unit 214 and the lighting fixture address are obtained from each lighting fixture 21B via the signal transmission / reception unit 202, the data in which the detection result by the human detection unit 214 is associated with the lighting fixture address. The process of creating a table and passing it to the control determination unit 205B is further executed.
[0147]
When the subsystem target value is set by the power target value management unit 204, the control determination unit 205B issues a human detection status response request. Thereafter, when the data table is obtained from the arithmetic processing unit 200C, it is used. Then, for each lighting fixture 2B in the lighting subsystem 2C to which it belongs, the load output level that is lower than the load power consumption value as the current load output level and that differs due to the difference in the detection result by the human detection unit 214 is determined. Is obtained, and a control operation pattern for operating with the individual target value is created. For example, when the power reduction instruction is the power reduction level 1, the lighting level (load output level) of the lighting fixture 21B in the vicinity of the lighting fixture 21B that is turned off due to non-detection of a person is reduced by 10%. For the lighting fixture 21B, a control operation pattern that lowers the lighting level by 20% is created. When the power reduction instruction is at power reduction levels 2 and 3, a control operation pattern is created in a similar manner.
[0148]
Next, an operation that is a characteristic of the management system according to the sixth embodiment will be described. Each lighting fixture 2B controls the lamp load LD in accordance with the result of detection by its own human detection unit 214.
[0149]
In the lighting control controller 20C of each lighting subsystem 2C, when the power reduction instruction signal of the power reduction level 1 from the comprehensive monitoring device 1 is received by the building network interface 201 (S11 in FIG. 13), it corresponds to the power reduction level 1. To the power reduction control mode. Then, a subsystem target value for the power reduction level 1 is set by the power target value management unit 204, a human detection status response request is issued by the control determination unit 205B, and the signal processing unit 200C cooperates through the signal transmission / reception unit 202 with the request. Transmitted to each lighting fixture 21B.
[0150]
In each lighting fixture 21B of each lighting subsystem 2B, when a person detection status response request is received from the lighting control controller 20C via the signal transmission / reception unit 211, the person detection unit 214 regardless of the operation state of the lamp load LD. Is transmitted to the lighting control controller 20C via the signal transmission / reception unit 211 (S12).
[0151]
In the lighting control controller 20C of each lighting subsystem 2C, when the detection result by the human detection unit 214 and the lighting fixture address are acquired from each lighting fixture 21B via the signal transmitting / receiving unit 202, the arithmetic processing unit 200C converts the lighting fixture address into the lighting fixture address. A data table in which the detection results by the human detection unit 214 are associated is created (S13). After that, the control determining unit 205B determines, based on the data table, the lighting fixture 2B in the lighting subsystem 2C to which the lighting unit 2C belongs due to the difference in the detection result by the human detecting unit 214 that is lower than the current load power consumption value. An individual target value having a difference is obtained, and a control operation pattern for operating with the individual target value is created (S14). Thereafter, a lighting control signal including the lighting fixture address of the lighting fixture 21B and matching the control operation pattern is generated by the lighting control signal generation unit 203, and transmitted from the signal transmission / reception unit 202 to each lighting fixture 21B.
[0152]
In each lighting fixture 21B of each lighting subsystem 2C, when the signal transmission / reception unit 211 receives a lighting control signal including its own lighting fixture address from the lighting control controller 20C, the control contents included in the lighting control signal ( The control unit 210B controls the lighting device 212 according to the control operation pattern), so that the lamp load LD is turned on, turned off, or dimmed. At this time, the lighting level of the lighting fixture 21B adjacent to the lighting fixture 21B that is turned off due to no detection of a person is reduced by 10%, and the lighting levels of the other lighting fixtures 21B are reduced by 20% (see FIG. 14). In the example of FIG. 14, the lighting level of the lighting fixture 21B that is turned off due to non-detection of a person, the lighting fixture 21B adjacent thereto, and the lighting fixture 21B adjacent to the lighting fixture 21B is “small dimming” (corresponding to 10%). The lighting level of the other lighting fixtures 21B is “large dimming” (corresponding to 20%).
[0153]
Also, when the general monitoring apparatus 1 issues a further power reduction request and shifts to the corresponding power reduction control mode, the individual detection information is acquired and the individual The power reduction control of each lighting fixture 21B is executed through operations such as creation of a control operation pattern that differs from the target value.
[0154]
As described above, according to the sixth embodiment, when the lighting control controller 20C receives the power reduction instruction from the comprehensive monitoring device 1, the lighting control controller 20C uses the person detection unit 214 obtained from each lighting fixture 21B in the lighting subsystem 2C to which it belongs. Utilizing the detection result, an individual target value which is lower than the current load power consumption value and which differs depending on the detection result by the human detection unit 214 is obtained for each lighting fixture 21B in the lighting subsystem 2C to which the self belongs. Since control is performed so as to operate at the individual target value of the lever, for example, for a lighting fixture near a lighting fixture that is turned off or dimmed (for example, 50% dimming) without detecting a person, the amount of decrease in the lighting level is reduced. Control that can be suppressed can be performed. In this case, there is an effect that a change in the visual environment due to the power reduction control can be reduced.
[0155]
【The invention's effect】
As is apparent from the above description, the invention according to claim 1 provides a subsystem including a load device and a controller that controls the load device, and a power consumption monitor that monitors power consumption by the load device in the subsystem. Means for monitoring the power consumption monitored by the power consumption monitoring means, and outputting a power reduction instruction to a controller in the subsystem. A load control system including at least one of the subsystems included in a management system used for control of the load device, wherein a detection result obtained by a human detection unit that detects whether or not there is a controller; When a power reduction instruction is received from the integrated monitoring device, the load device in the subsystem to which the Since the control is performed to obtain a load output level lower than the load output level and operate at this load output level, it is necessary for the comprehensive monitoring device to perform specific control of the load devices only by giving the power reduction instruction. Therefore, the load of the arithmetic processing of the integrated monitoring device can be reduced, and the configuration can be simplified and the cost can be reduced. This makes it possible to provide a load control system that does not require a high-cost integrated monitoring device without increasing the load on the integrated monitoring device even when the system scale increases. For example, a subsystem is provided with a plurality of load devices, a plurality of subsystems is provided, or a plurality of types of subsystems are provided, thereby increasing the system scale. Even if the control is performed to obtain a load output level lower than the current load output level and operate at this load output level, the control is performed mainly by the controller, not by the general monitoring device. This enables efficient power reduction control of load devices without increasing the burden on the integrated monitoring device, and reduces the psychological adverse effects due to changes in the lighting environment when lighting devices are provided as load devices. Control is also possible.
[0156]
According to a second aspect of the present invention, in the load control system according to the first aspect, the human detecting means is provided in a load device or a controller in the subsystem, and the controller issues a power reduction instruction from the general monitoring device. In the subsystem to which it belongs, in the subsystem to which it belongs, the control of the load device performed in accordance with the detection result that the person has disappeared by the human detection means is performed by the load device when the power reduction instruction is not received from the comprehensive monitoring device. Since the control for changing the power consumption to be lower than the control is performed, the power reduction amount can be increased accordingly.
[0157]
According to a third aspect of the present invention, in the load control system according to the second aspect, the load device is a lighting device, and the person detection unit uses a detection result indicating that a person is present for lighting control of the load device. The detection result that the person has disappeared is used for dimming control of the load device, and if the detection result of the presence of a person is not obtained during a predetermined lighting holding time from the start of the dimming control, the load device is detected. The controller is used for turning off or dimming control. When the controller receives a power reduction instruction from the general monitoring device, the controller adjusts the load device in the subsystem to which the controller belongs from the lighting holding time or the lighting control. To change the fade time until the transition to the light control to be shorter than the lighting holding time or the fade time when the power reduction instruction is not received from the comprehensive monitoring device. Since the control amount that shortens the turn-on duration or fade time, it is possible to increase the power reduction amount.
[0158]
According to a fourth aspect of the present invention, in the load control system according to the second aspect, the load device is a lighting device, and the person detection unit uses a detection result indicating that a person is present for lighting control of the load device. The detection result that the person has disappeared is used for dimming control of the load device. The power reduction instruction includes a plurality of levels having different power reduction amounts. When the power reduction instruction is received from the power supply control unit, the load control unit performs control for changing the dimming rate by the dimming control for the load device in the subsystem to which the self belongs in accordance with the level of the power reduction instruction. , The power consumption can be reduced.
[0159]
According to a fifth aspect of the present invention, in the load control system according to the first or second aspect, in the load control system according to the first or second aspect, the human detecting means is provided in a plurality of load devices in the subsystem. The load device is a lighting device that includes a light source, and turns on its own light source when a detection result indicating that a person is present is obtained from its own human detection means; and the controller is a power reduction instruction from the comprehensive monitoring device. Received from the plurality of load devices, the number of lighting fixtures that turn on the light source is obtained from the detection result that the person is detected by the person detection unit, and the load corresponding to the power reduction instruction is determined from this number. Since the output level is determined and control is performed so that the lighting fixture that turns on the light source is operated at the load output level, the accuracy of achieving the power reduction target can be improved. .
[0160]
According to a sixth aspect of the present invention, in the load control system according to the first or second aspect, the human detecting means is provided in a plurality of load devices in the subsystem, and the controller reduces power from the integrated monitoring device. When the instruction is received, the detection result of the person detection means obtained from each load device in the subsystem to which the self belongs belongs to each load device in the subsystem to which the self belongs, and the current load output level is reduced. Since the control is performed so as to obtain a load output level at which a difference occurs due to a difference in the detection result by the human detection means and operate at this load output level, for example, the light may be turned off or dimmed according to the detection result indicating that no one is present. It becomes possible to control the lighting equipment near the lighting equipment in which the reduction in the load output level is suppressed. In this case, there is an effect that a change in the visual environment due to the power reduction control can be reduced.
[0161]
A management system according to a seventh aspect of the present invention includes the load control system according to any one of the first to sixth aspects, and power consumption monitoring means for monitoring power consumption by a load device in the load control system. When it is necessary to reduce the power consumption monitored by the power monitoring means, a general monitoring device that issues a power reduction instruction to a controller in the load control system is connected to a network, and whether or not a person is present Since the detection result of the person detecting means for detecting the load is used for controlling the load device, the general monitoring device does not need to perform the specific control of the load device only by giving the power reduction instruction. The load on the arithmetic processing of the device can be reduced, and the configuration can be simplified and the cost can be reduced. This makes it possible to provide a load control system that does not require a high-cost integrated monitoring device without increasing the load on the integrated monitoring device even when the system scale increases.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a management system according to a first embodiment of the present invention.
FIG. 2 is a configuration diagram of the lighting fixture in FIG. 1;
FIG. 3 is a configuration diagram of a management system according to a second embodiment of the present invention.
FIG. 4 is an explanatory diagram of an operation of a lighting subsystem in the management system.
FIG. 5 is an operation explanatory diagram of a lighting subsystem in a management system according to a third embodiment of the present invention.
FIG. 6 is a diagram illustrating an operation example related to a management system according to a fourth embodiment of the present invention.
FIG. 7 is an explanatory diagram of another example of the second to fourth embodiments.
FIG. 8 is a configuration diagram of a management system according to a fifth embodiment of the present invention.
FIG. 9 is a configuration diagram of the lighting fixture in FIG. 8;
FIG. 10 is an explanatory diagram of the operation of the management system.
FIG. 11 is an explanatory diagram of the operation of the management system.
FIG. 12 is a configuration diagram of a management system according to a sixth embodiment of the present invention.
FIG. 13 is an explanatory diagram of the operation of the management system.
FIG. 14 is an explanatory diagram of the operation of the management system.
FIG. 15 is a configuration diagram of a management system of the first related art.
FIG. 16 is a configuration diagram of a comprehensive monitoring device in the management system.
FIG. 17 is a schematic diagram of a lighting subsystem in the management system.
FIG. 18 is a configuration diagram of a management system according to a second related art.
FIG. 19 is an explanatory diagram of the operation of the management system.
FIG. 20 is an explanatory diagram of the operation of the management system.
[Explanation of symbols]
1 Comprehensive monitoring device
11 Building Network Interface
12 Power consumption monitoring unit
13 Control unit
2,2A, 2B, 2C lighting subsystem
20, 20A, 20B, 20C Lighting controller
200, 200A, 200B, 200C Arithmetic processing unit
201 Building Network Interface
202 signal transmitting / receiving unit
203 Lighting control signal generator
204 Power target value management unit
205, 205A, 205B control judgment unit
206 person detection unit
207A timer circuit
21,21A, 21B Lighting equipment
210, 210A, 210B control unit
211 signal transmitting / receiving unit
212 Lighting device
213 Lighting level detection circuit
214 person detection unit
215 Timer circuit

Claims (7)

A subsystem including a load device and a controller that controls the load device;
Power consumption monitoring means for monitoring the power consumption by the load devices in the subsystem, and when it is necessary to reduce the power consumption monitored by the power consumption monitoring means, a power reduction instruction to the controller in the subsystem. And a comprehensive monitoring device that outputs a signal to a network, and a detection result of a person detecting unit that detects whether a person is present is included in a management system used for controlling the load device. A load control system including a subsystem,
The controller, when receiving the power reduction instruction from the comprehensive monitoring device, obtains a load output level lower than the current load output level for the load device in the subsystem to which the controller belongs, and operates at the load output level. A load control system, wherein the load control system controls the load. The human detection means is provided in a load device or a controller in the subsystem,
The controller, when receiving the power reduction instruction from the comprehensive monitoring device, controls the load device in the subsystem to which the controller belongs in accordance with the result of the detection by the human detection means that the person has disappeared. 2. The load control system according to claim 1, wherein control is performed to change the power consumption so as to reduce power consumption as compared with control of the load device when no power reduction instruction is received from the device. The load device is a lighting fixture,
The human detection means uses a detection result indicating that a person is present for lighting control of the load device, and uses a detection result indicating that no person is present for dimming control of the load device, and starts the dimming control. If a detection result of the presence of a person is not obtained during a predetermined lighting holding time from the time point, it is used for turning off or dimming control of the load device,
The controller, when receiving the power reduction instruction from the comprehensive monitoring device, for the load device in the subsystem to which it belongs, the lighting holding time or the fade time from the lighting control to the completion of the transition to the dimming control, 3. The load control system according to claim 2, wherein control is performed to change the lighting hold time or the fade time to be shorter than when the power reduction instruction is not received from the comprehensive monitoring device. The load device is a lighting fixture,
The human detection means, a detection result that a person is present is used for lighting control of the load device, and a detection result that a person is gone is used for dimming control of the load device,
The power reduction instruction has a plurality of levels with different power reduction amounts,
The controller, when receiving a power reduction instruction from the general monitoring device, changes a dimming rate by a dimming control for a load device in a subsystem to which the controller belongs according to a level of the power reduction instruction. The load control system according to claim 2, wherein control is performed. The human detection means is provided in a plurality of load devices in the subsystem,
The load device is a lighting device that includes a light source and turns on its own light source when a detection result indicating that a person is present is obtained from its own human detection means,
When receiving the power reduction instruction from the comprehensive monitoring device, the controller obtains the number of lighting fixtures that are illuminating the light source from the detection result of the presence of a person by the person detection unit obtained from the plurality of load devices. 3. A load output level corresponding to the power reduction instruction is obtained from the number, and control is performed so that a lighting fixture that turns on the light source is operated at the load output level. Load control system. The human detection means is provided in a plurality of load devices in the subsystem,
When the controller receives the power reduction instruction from the general monitoring device, the controller uses the detection result of the person detection unit obtained from each load device in the subsystem to which the controller belongs to, and uses the detection result by the human detection unit to load each load in the subsystem to which the controller belongs. 2. The apparatus according to claim 1, wherein the apparatus is controlled to determine a load output level which is lower than the current load output level and which is different from the result of detection by the human detection means and operates at the load output level. Or the load control system according to 2. A load control system according to any one of claims 1 to 6, and power consumption monitoring means for monitoring power consumption by a load device in the load control system, wherein the power consumption monitored by the power consumption monitoring means is monitored. When it is necessary to reduce the power consumption, a general monitoring device that issues a power reduction instruction to a controller in the load control system is connected to a network. A management system used for controlling the load device.

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