JP6156794B2 - Load control system - Google Patents

Description

  The present invention relates to a load control system, in particular, a load control system suitable for non-residential facilities that performs transmission and reception of signals between a load control device that directly controls on and off of a load and a centralized control device via radio communication using radio waves. About.

  In recent years, in non-residential facilities such as factories, offices, commercial facilities, etc., a load that is remotely operated from a place where the load such as a lighting device is turned on and off remotely, or that a load is turned on or off is monitored remotely. Control systems are being put into practical use. A load control device installed in the vicinity of a load and directly controlling on and off of the load is an electronic device such as a control circuit or a communication circuit configured by a CPU or the like in order to transmit and receive signals to and from the central control device. A circuit is provided. In the case of newly constructing a non-residential facility, it is possible to wire-connect between the central control device and individual load control devices. On the other hand, when replacing a load control switch such as a tumbler switch with a mechanical switching contact with a load control device with an electronic circuit in an existing non-residential facility, the load processing is simplified in order to simplify the wiring process. Radio communication using radio waves is used to transmit and receive signals between the control device and the centralized control device.

  When performing wireless communication using radio waves between such a load control device and a centralized control device, the power of the wireless communication device cannot be increased to a certain value or more due to laws and regulations, and the wireless communication distance is several tens of meters. It is limited to the following. Therefore, when non-residential facilities are vast, it is not possible to perform radio communication by radio waves with all load control devices installed in various places of non-residential facilities with only one wireless communication device connected to the centralized control device. A plurality of wireless communication devices are installed at a certain distance. Moreover, there is a limit to the frequencies that can be used due to legal restrictions, and the radio frequencies used for communication between the plurality of radio communication devices and the load control device are the same. In order to drive each wireless communication device in synchronization, each wireless communication device and the central control device are connected by wire, and a synchronization signal is transmitted from the central control device to each wireless communication device. Each wireless communication device has a master-slave relationship set in advance with one or more load control devices, and each load control device performs wireless communication only with a specific wireless communication device with a master-slave relationship set. I do.

  A centralized control device centrally manages and displays the state of loads such as a large number of lighting devices installed in non-residential facilities, and loads connected to each load control device are turned on. Data must be collected indicating whether it is a state or an off state. When the centralized control device and each load control device are connected by wire, the centralized control device can always poll the individual load control devices. However, when the centralized control device and individual load control devices are connected wirelessly by radio waves via a wireless communication device, if the individual load control device is constantly polled, communication of other signals is performed. It becomes impossible. Therefore, in normal operation, the centralized control device stores the state of the load connected to each load control device, and only when the load state changes, the centralized control from the load control device via the wireless communication device A load state change notification signal is transmitted to the apparatus.

  By the way, in non-residential facilities, a simultaneous power outage is performed for maintenance of power supply facilities. When the power supply is restored, the centralized control device wants to immediately obtain the data on the status of each load (load status notification signal) and display the load status. When transmission of the load state notification signal to the communication device is started, radio waves collide with each other and the load state notification signal cannot be received. In addition, when wireless communication is not possible and the timing for starting retransmission of a load state notification signal or the like is synchronized in a plurality of load control devices, the load state notification signal is permanently associated with those load control devices. Etc. can not get.

  In addition, regarding the lighting control system by wireless communication for a detached house, a technique for preventing a reply signal from each slave unit from colliding with the master unit is described in Patent Document 1.

JP 2009-261209 A

  The present invention has been made to solve the above-described problems of the conventional example, and is a load control system suitable for load control such as a lighting device for a non-residential facility, between the load control device and the centralized control device. An object of the present invention is to perform data transmission / reception via radio communication using radio waves, and reliably acquire data related to the state of each load (load state notification signal) and shorten the acquisition time when the power is turned on.

In order to achieve the above object, a load control system according to the present invention includes:
A centralized control device that grasps and manages the status of multiple loads;
A plurality of load control devices for directly controlling on or off of one or more of the plurality of loads, and transmitting a load state notification signal regarding the state of the load via radio communication by radio waves;
A plurality of wireless communications that are wired and connected to the centralized control device, and that transmit / receive signals to / from a plurality of load control devices in which a master-slave relationship is set in advance among the plurality of load control devices Equipped with equipment,
The wireless communication devices operate in synchronization with each other based on a synchronization signal transmitted from the central control device,
The load control devices operate in synchronization with each other based on synchronization signals transmitted from the wireless communication devices, respectively.
After powering on the wireless communication device, the wireless communication device transmits a load state acquisition signal to each of the plurality of load control devices to which the master-slave relationship is set,
The load control device that has received the load status acquisition signal transmits a load status notification signal indicating a load status controlled by the load control device to the wireless communication device in which the master-slave relationship is set,
The wireless communication device that has received the load state notification signal transmits the received load state notification signal to the centralized control device via the wired connection ,
The wireless communication device transmits a beacon to the load control device at a predetermined cycle, and a frame defined by the predetermined cycle from a certain beacon to the next beacon is the load state acquisition signal and Divided into a plurality of time slots longer than the load state notification signal,
The wireless communication device
Randomly arrange communication slots with a plurality of load control devices in which the master-slave relationship is set in all slots of the frame,
After transmitting the load status acquisition signal, when the load status notification signal cannot be acquired from all of the plurality of load control devices for which the master-slave relationship is set within the predetermined period, all slots of the next frame In addition, a communication slot with a load control device that could not acquire the load state notification signal is randomly arranged again so as not to overlap, and the load state acquisition signal is retransmitted .

  Each of the wireless communication devices is preferably offset based on a preset order so that slots for transmitting the beacons do not overlap.

  Each of the wireless communication devices is preferably offset based on a preset order so that frames for transmitting the load state acquisition signal do not overlap.

  Or it is preferable that the said radio | wireless communication apparatus respectively overlaps the frame which transmits the said load condition acquisition signal.

  Each of the wireless communication devices can transmit the load state notification signal even if the load state acquisition signal is retransmitted a predetermined number of times to any one of the plurality of load control devices in which the master-slave relationship is set. It is preferable to transmit an absence signal indicating that the load control device is absent to the centralized control device.

  Each of the wireless communication devices can obtain the load state notification signal from all of the plurality of load control devices for which the master-slave relationship is set before reaching the specified number of times, up to the specified number of frames. It is preferable not to shift to normal operation.

The beacon transmitted by the wireless communication device includes a load state change notification permission signal or a load state change notification prohibition signal,
The wireless communication device acquires the load state notification signal from all of the plurality of load control devices for which the master-slave relationship is set or retransmits the load state acquisition signal a specified number of times after the power is turned on. Until the beacon is transmitted including the load state change notification prohibition signal, and then the beacon is transmitted including the load state change notification permission signal,
It is preferable that the load control device does not transmit the load state change notification signal even if the state of the load controlled by the load control device changes until the load state change notification permission signal is received.

  The load control device that has received the load state change notification permission signal confirms whether or not the wireless communication device is transmitting by carrier sense when the state of the load controlled by the load control device has changed, It is preferable to transmit the load state change notification signal using a slot to which no radio wave is transmitted.

When the load control device receives the load state change notification permission signal after the power is turned on, whether or not the wireless communication device is transmitting by carrier sense after a delay time of a random number of slots And send a startup notification signal using a slot that is not transmitting radio waves,
When the wireless communication device receives the activation notification signal from any of a plurality of load control devices for which the master-slave relationship is set, it is preferable that the wireless communication device acquires the load state notification signal by any one of the methods.

  According to the present invention, for example, when a non-residential facility is powered on, a wireless communication device does not transmit a load state notification signal indicating a load state controlled by the load control device from each load control device. Since only the load control device that received the load status acquisition signal transmits the load status notification signal, the possibility that the load status notification signals transmitted wirelessly collide with each other is reduced, and the centralized control device A load state notification signal for the load can be acquired.

The block diagram which shows the structure of the load control system which concerns on one Embodiment of this invention. The block diagram which shows the structure of the 2-wire type load control apparatus used for the said load control system. The conceptual diagram which shows the basic operation | movement of the radio | wireless communication between the radio | wireless communication apparatus and load control apparatus in the said load control system. The conceptual diagram which shows the operation | movement of the modification of the radio | wireless communication between the radio | wireless communication apparatus and load control apparatus in the said load control system. The conceptual diagram which shows operation | movement when the signal from a some load control apparatus collides in the radio | wireless communication between the radio | wireless communication apparatus and load control apparatus in the said load control system. The conceptual diagram which shows operation | movement of the other modification of the radio | wireless communication between the radio | wireless communication apparatus and load control apparatus in the said load control system. The conceptual diagram which shows operation | movement when the power activation of a load control apparatus delays rather than the power activation of a radio | wireless communication apparatus in the radio | wireless communication between the radio | wireless communication apparatus and load control apparatus in the said load control system. The conceptual diagram which shows the operation | movement of the modification when the power activation of a load control apparatus delays rather than the power activation of a radio | wireless communication apparatus in the radio | wireless communication between the radio | wireless communication apparatus and load control apparatus in the said load control system.

  A load control system according to an embodiment of the present invention will be described. FIG. 1 shows an overall configuration of a load control system according to the present embodiment. This load control system is installed in non-residential facilities such as factories, offices, commercial facilities, etc., and is remotely controlled from a place where loads such as lighting devices are turned on and off, or a place where loads are turned on or off. It is a system to monitor with. The load control system is installed on, for example, a distribution board, and the central control device 1 that grasps and manages the state of a plurality of loads, and the plurality of wireless communication devices 2, 3 that are wired to the central control device 1. And a plurality of load control devices 21, 22,. Each of the wireless communication devices 2, 3,... Is set so as to transmit / receive signals to / from a plurality of load control devices 21, 22,. ing.

  The centralized control device 1 inputs a predetermined or arbitrary control command with a transmission unit 11 that transmits / receives a predetermined signal to / from each wireless communication device 2, 3. The input / output device 12 that displays predetermined information and the display of the loads 121, 122,... Connected to the load control devices 21, 22,. It consists of a panel 13 and the like. In addition to connecting one load 121, 122,... To one load control device 21, 22,..., For example, a plurality of loads 133a, 133b may be connected as in the load control device 33. . The load control device 33 to which a plurality of loads are connected may collectively control the on and off of the plurality of loads 133a and 133b, or may individually control the on and off of the plurality of loads 133a and 133b. Also good. In the latter case, it is assumed that the load control device 33 has a plurality of opening / closing sections. Although not particularly illustrated, the wireless communication devices 2, 3... Transmit a wireless communication circuit that performs wireless communication with the load control device using radio waves, a control unit configured by a CPU, a memory, and the like, and transmission. It is composed of a wired communication circuit that performs wired communication with the unit 11. It is possible to transmit a control signal for turning on or off the loads 121, 122... From the central control device 1 to the load control devices 21, 22,. Needless to say.

  The load control apparatuses 21 to 25 have a master-slave relationship set in advance with the wireless communication apparatus 2 on the left side in the figure, and the load control apparatuses 31 to 35 have communication with the wireless communication apparatus 3 on the right side in the figure. Assume that a master-slave relationship is set in advance. Even if the load control device 22 is at a distance where radio communication with the right wireless communication device 3 is possible by radio waves, the master-slave relationship is set with the left wireless communication device 2. No wireless communication is performed with the wireless communication device 3 on the right side. The same applies to other load control devices. In the following description, the wireless communication devices 2, 3... Operate in synchronization with each other based on a synchronization signal transmitted from the central control device 1, and the load control devices 21, 22. It is assumed that they are operating in synchronization with each other based on a synchronization signal transmitted from the communication devices 2, 3.

  FIG. 2 shows a block configuration of the load control device 200 as a component used as the load control devices 21, 22,. The load control device 200 is for so-called two-wire wiring. For example, a series circuit of a primary winding of an open / close unit 203 and a current transformer 204 configured by a relay switch element or the like includes a commercial power source 201 and a load 202. Are connected in series. Both terminals of the opening / closing unit 203 are connected to an off power source unit 210 for securing driving power of the control unit 205 and the wireless communication unit 207 when the load 202 is in an off state. In addition, an on power supply unit 220 for securing drive power of the control unit 205 and the wireless communication unit 207 when the load 202 is in an on state is connected to the secondary winding of the current transformer 204. In the two-wire load control apparatus 200, even when the load 202 is in an off state, a weak current that does not turn on the load 202 flows from the commercial power supply 201 to the off power supply unit 210 via the load 202. The off power supply unit 210 rectifies an alternating current that flows when the load 202 is in an off state by the rectifier circuit 211 and converts the alternating current to a DC constant voltage of 1.5 to 6 V for driving the CPU and the like by the constant voltage circuit 212. Output. The on-power supply unit 220 rectifies the alternating current flowing through the secondary winding of the current transformer 204 by the rectifier circuit 221 configured by a diode bridge or the like, and after stepping up or stepping down by the step-up / step-down circuit, the constant voltage circuit 223 It is converted to a DC constant voltage of 1.5-6V and output. Since the voltage generated in the secondary winding of the current transformer 204 is determined by the impedance of the primary winding of the current transformer 204 and the load current, depending on the impedance of the load 202 connected to the load control device 200, The voltage generated in the secondary winding of the current transformer 204 may be boosted.

  The control unit 205 is a control circuit composed of, for example, a CPU, a ROM, a RAM, and the like, and controls opening / closing of the opening / closing unit 203 based on operation information from the operation unit 206 such as a push button switch operated by the user. , Thereby controlling on and off of the load 202. The control unit 205 stores information such as which wireless communication device performs wireless communication, and what number load control device is the wireless communication device. The wireless communication unit 207 performs wireless two-way communication using radio waves with a designated wireless communication device.

  Next, wireless communication between the wireless communication device and the load control device in the present embodiment will be described. The following explanation is the communication for the central control device to acquire data (load state notification signal) regarding the state of each load when the power of the non-residential facility is turned on, and the state of the load has changed thereafter. This is different from the normal operation of transmitting and receiving data (load state change notification signal). In order to simplify the description, only the wireless communication devices 2 and 3 are wired to the centralized control device 1, only the load control devices 21 to 25 are connected to the wireless communication device 2, and the load is connected to the wireless communication device 3. It is assumed that only the control devices 31 to 35 are connected. The wireless communication devices 2 and 3 are supplied with power superimposed on the signal from the central control device 1. On the other hand, since each load control device 21-35 is installed in a place away from the central control device 1, power may be supplied from a power source different from the central control device 1, but here the same power source is used. A description will be given assuming that power is supplied.

  FIG. 3 shows the relationship between the wireless communication devices 2, 3... And the load control devices 21, 22,. The basic operation of wireless communication to be performed will be described. The wireless communication devices 2 and 3 transmit a beacon B with a predetermined cycle to the load control device, and a frame defined with a predetermined cycle from one beacon B to the next beacon B has a load described later. It is divided into a plurality of time slots longer than the state acquisition signal and the load state notification signal. Although one frame is divided into 11 slots for drawing, the length of one frame and the number of slots are not particularly limited.

  As described above, the wireless communication devices 2 and 3 and the load control devices 21 to 35 operate in synchronization, and each wireless communication device 2 and 3 transmits a beacon based on a preset order. Are offset so that they do not overlap. For example, when the wireless communication device 2 transmits a beacon in the first slot of one frame, the wireless communication device 3 transmits a beacon in the second slot of one frame. In addition, the wireless communication devices 2 and 3 are offset so that frames transmitting beacons including a load state acquisition signal do not overlap based on a preset order. For example, when the wireless communication device 2 transmits a beacon including a load state acquisition signal in one frame after power-on, the wireless communication device 3 transmits a beacon including a load state acquisition signal in the next frame.

  After the power is turned on, the wireless communication devices 2 and 3 transmit a load state acquisition signal to each of the plurality of load control devices 21 to 35 for which a master-slave relationship is set in advance. In FIG. 3, a beacon including a load state acquisition signal is transmitted from the wireless communication device 2 in the first slot of the first frame. In this basic operation, the wireless communication devices 2 and 3 are offset so that the slots for transmitting the beacons and the frames for transmitting the beacons including the load state acquisition signals do not overlap. The load control devices 31 to 35 whose master-slave relationship is set with respect to the other wireless communication devices 3 while performing wireless communication by radio waves with the load control devices 21 to 25 for which the Do not communicate. Therefore, radio communication radio waves do not collide with each other, and the centralized control device 1 can reliably acquire load state notification signals from all the load control devices 21 to 35. However, as the number of installed wireless communication devices and load control devices increases, the time required for acquiring the load state notification signal becomes longer.

  In the modification shown in FIG. 4, the wireless communication devices 2 and 3 are randomly arranged in all slots of one frame so as not to overlap communication slots with a plurality of load control devices 21 to 25 for which a master-slave relationship is set. ing. In this case, a load state acquisition signal can be transmitted simultaneously from a plurality of (for example, two) wireless communication apparatuses. Actually, since the number of slots included in one frame is larger than the number of load control devices that are in a master-slave relationship with one wireless communication device, there are many slots that are not used for wireless communication. Communication slots may overlap between different wireless communication devices and load control devices in a master-slave relationship with them, but the probability is low. In addition, even if the communication slot overlaps and the load state notification signal cannot be acquired, the communication slot with the load control device that could not acquire the load state notification signal is randomly arranged again so as not to overlap, The load state acquisition signal may be retransmitted.

  FIG. 5 shows an example in which the wireless communication devices 2 and 3 transmit beacons including a load state acquisition signal in the same frame and communication slots overlap. In FIG. 5, the communication slots of the wireless communication device 2 and the load control device 23 overlap the communication slots of the wireless communication device 3 and the load control device 31, and the communication slots of the wireless communication device 2 and the load control device 25 are wireless. The communication device 3 and the communication slot of the load control device 35 overlap. In the next frame for retransmitting the beacon including the load status acquisition signal, the communication slots of the wireless communication device 2 and the load control devices 23 and 25, and the communication slots of the wireless communication device 3 and the load control devices 31 and 35, respectively, Has been shuffled. In this way, by shuffling the communication slots of the wireless communication device and the load control device each time a beacon including a load state acquisition signal is retransmitted, the possibility of overlapping communication slots is gradually reduced. In addition, since the load state acquisition signal is not retransmitted to the load control device that has acquired the load state notification signal, the number of empty slots increases each time a beacon including the load state acquisition signal is retransmitted, and communication slots overlap. The possibility is even less.

  Further, when the wireless communication devices 2 and 3 fail to acquire the load state notification signal even if the load state acquisition signal is retransmitted a predetermined number of times to any of the load control devices, The load control device transmits an absence signal indicating that the load control device is absent. For example, when there is a problem with the load control device itself, or when there is an abnormality in the communication state between the wireless communication device and the load control device, the load control device 1 side transmits the absence signal so that the load control device 1 It is possible to grasp that an abnormality has occurred in the device.

  In addition, the wireless communication devices 2 and 3 can normally receive the load state notification signal from all of the plurality of load control devices for which the master-slave relationship is set before the specified number of times is reached. You may be comprised so that it may not transfer to operation | movement. Thereby, all the radio communication devices and the load control device simultaneously shift to the normal operation, so that the control program can be simplified. In addition, in any of the wireless communication devices, when all the load state notification signals of the load control device for which the master-slave relationship is set can be acquired, the load state change is performed between the wireless communication device and the load control device. It is possible to shift to a normal operation for transmitting and receiving the load state change notification signal shown. However, if the load state change notification signal is transmitted randomly when the acquisition of the load state notification signal is not completed between the other wireless communication device and the load control device, the other wireless communication device and the load control device May collide with the communication between them. In addition, the control program is complicated to prevent this. As described above, by setting so as not to shift to the normal operation until a predetermined number of frames, it is possible to avoid a communication collision and simplify the control program.

  FIG. 6 illustrates a case where, for example, the wireless communication device 2 can acquire load state notification signals from all the load control devices 21 to 25 having a master-slave relationship with them. The beacon transmitted from the wireless communication devices 2 and 3 includes a signal that permits or prohibits transmission of the load state change notification signal. For example, after the power is turned on, the wireless communication device acquires load state notification signals from all load control devices for which the master-slave relationship is set or retransmits a beacon including a specified number of load state acquisition signals Transmits a beacon including a load state change notification prohibition signal and thereafter transmits a beacon including a load state change notification permission signal. In FIG. 6, when the wireless communication device 2 transmits the second beacon B, the wireless communication device 3 completes the acquisition of the load state notification signals from all the load control devices 31 to 35 for which the master-slave relationship is set. Therefore, the second beacon B includes a load state change notification prohibition signal. Until the load control devices 21 to 25 receive the load state change notification permission signal (the third beacon B in the figure), even if the load state controlled by the load control device changes, the load state change notification signal Do not send. In the meantime, for example, it is assumed that the state of the load connected to the load control device 23 has changed from on to off, for example. At this time, the load control device 23 does not transmit a load state change notification signal. On the other hand, when the wireless communication device 2 transmits the third beacon B, the wireless communication device 3 has completed the acquisition of the load state notification signals from all the load control devices 31 to 35. The beacon B includes a load state change notification permission signal. The load control device 23 that has received the load state change notification permission signal changes the state of the load controlled by the load control device, so that any one of the wireless communication devices 2 and 3 receives the load state acquisition signal due to carrier sense. It is confirmed whether or not a beacon including the same is transmitted, and a load state change notification signal is transmitted using a slot in which no radio wave is transmitted. Thereby, it is possible to notify the central control device 1 of a change in the load state without interfering with the acquisition of the load state notification signal between the other wireless communication device and the load control device.

  FIG. 7 shows a case where the load control devices 21 to 35 are turned on after the wireless communication devices 2 and 3 are turned on. When the wireless communication devices 2 and 3 are powered on, the wireless communication devices 2 and 3 try to acquire load state notification signals from the load control devices 21 to 35 according to the above-described procedure. However, since the load control devices 21 to 35 are not turned on and are not activated, no load state notification signals are transmitted from the load control devices 21 to 35. Thereafter, it is assumed that the load control devices 21 to 35 are powered on and activated. If the power supply to the load control devices 21 to 35 is before the beacon including the load state acquisition signal is retransmitted a predetermined number of times, the load state acquisition signal is transmitted to the beacon B transmitted from the wireless communication devices 2 and 3. Is included. In addition, if the power supply to the load control devices 21 to 35 is after the beacon including the load state acquisition signal has been retransmitted a predetermined number of times, the beacon B transmitted from the wireless communication devices 2 and 3 has a load A state change notification permission signal is included. When the load control devices 21 to 35 receive a load state acquisition signal or a load state change notification permission signal after the power is turned on, the load control devices 21 to 35 are after a predetermined number of slots assigned to the load control device. Alternatively, a load state notification signal is transmitted after a delay time of a random number of slots. FIG. 6 shows a case where a load state notification signal is transmitted after a delay time of a random number of slots. Since the load control device side determines the random number of slots, for example, it is assumed that the load control devices 24 and 25 transmit the load state notification signal in the same communication slot. Since the wireless communication device 2 could not receive the load state notification signals from the load control devices 24 and 25, the load control devices 24 and 25 are added to the beacon transmitted in the next frame (the third beacon B in the figure). Including the load status acquisition signal for. The load control devices 24 and 25 retransmit the load state notification signal after a delay time of a random number of slots. Thereby, the centralized control device 1 can quickly grasp the state of the load even when the load control device is activated later.

  FIG. 8 shows a modification in the case where the load control devices 21 to 35 are turned on after the wireless communication devices 2 and 3 are turned on. When the load control devices 21 to 25 receive the load state change notification permission signal after the power is turned on, the wireless communication devices 2 and 3 transmit by carrier sense after a delay time of a random number of slots. The activation notification signal D is transmitted using a slot to which no radio wave is transmitted. The wireless communication device 2 or 3 that has received the activation notification signal D from any one of the load control devices 21 to 35 for which the master-slave relationship is set transmits a beacon B including the activation notification prohibition signal, and loads by any of the above methods. A load state notification signal is acquired from the control devices 21 to 35. After the power is turned on, a slight time lag occurs in the activation of the load control devices 21 to 35 and the reception of the load state acquisition signal or the load state change notification permission signal. Regarding the wireless communication device 2, it is assumed that the load control device 22 is activated first and transmits the activation notification signal D. The wireless communication device 2 that has received the activation notification signal D immediately transmits an activation notification prohibition signal (the third beacon B in the figure), and all the load control devices 21 in which the master-slave relationship including the load control device 22 is set. ˜25, the transmission of the start notification signal is prohibited and the load state notification signal is transmitted. Regarding the wireless communication device 3 as well, the load control device 33 is first activated almost simultaneously and transmits an activation notification signal D. When the load control devices 21 to 35 are supplied with power from the same power source, the activation notification signal D is transmitted almost simultaneously from the plurality of load control devices, and the load state notification signals transmitted from the load control devices 21 to 35 collide with each other. The centralized control device 1 can be used when the load control device is activated later by retransmitting the load status acquisition signal to the load control device that could not acquire the load status notification signal. Even if it exists, the state of the load can be quickly grasped.

  As a reference example, the wireless communication devices 2, 3... Are provided with a non-volatile memory, and the load states of the load control devices 21, 22,. Remember. The wireless communication devices 2, 3... Control each load using the load state stored in the wireless communication devices 2, 3. Multicast to the device. The load control devices 21, 22,... Correspond to the wireless communication devices 2, 3,... Only when the load state at power-on and the load state transmitted from the wireless communication devices 2, 3. The current load status notification signal is transmitted. In general, it is considered that the state of the load has not changed much before and after power-on (the pushbutton switch of the load control device is rarely operated during a power failure). The time required for the central control apparatus to grasp the state of each load can be shortened.

  As described above, according to the present invention, in a load control system suitable for lighting control of a non-residential facility, one unit is provided for a plurality of load control devices in which a master-slave relationship is set from a wireless communication device when power is turned on. The load control device that has transmitted the load status acquisition signal and received the load status acquisition signal each time transmits the load status notification signal indicating the status of the load controlled by the load control device, and has received the load status notification signal. Since the communication device transmits the received load state notification signal to the centralized control device via a wired connection, the load state notification signal related to the state of each load can be acquired within a short time after the power is turned on.

  Also, frames defined in a predetermined cycle from one beacon to the next beacon transmitted from the wireless communication device to the load control device are placed in a plurality of time slots longer than the load state acquisition signal and the load state notification signal. By dividing and randomly arranging communication slots with a plurality of load control devices for which master-slave relationships are set in all slots of the frame so as not to overlap, a plurality of wireless communication devices and a plurality of loads in a master-slave relationship with it Wireless communication using radio waves can be performed simultaneously with the control device. In addition, when load state notification signals are transmitted from a plurality of load control devices in the same slot, signal collision occurs, but the load control device that could not acquire the load state notification signal in all slots of the next frame The communication slots are randomly arranged again so as not to overlap, and the load state acquisition signals from all the load control devices can be acquired in a short time by repeating the retransmission of the load state acquisition signal.

DESCRIPTION OF SYMBOLS 1 Centralized control apparatus 2,3 Wireless communication apparatus 21-25, 31-35 Load control apparatus

Claims (9)

A centralized control device that grasps and manages the status of multiple loads;
A plurality of load control devices for directly controlling on or off of one or more of the plurality of loads, and transmitting a load state notification signal regarding the state of the load via radio communication by radio waves;
A plurality of wireless communications that are wired and connected to the centralized control device, and that transmit / receive signals to / from a plurality of load control devices in which a master-slave relationship is set in advance among the plurality of load control devices Equipped with equipment,
The wireless communication devices operate in synchronization with each other based on a synchronization signal transmitted from the central control device,
The load control devices operate in synchronization with each other based on synchronization signals transmitted from the wireless communication devices, respectively.
After powering on the wireless communication device, the wireless communication device transmits a load state acquisition signal to each of the plurality of load control devices to which the master-slave relationship is set,
The load control device that has received the load status acquisition signal transmits a load status notification signal indicating a load status controlled by the load control device to the wireless communication device in which the master-slave relationship is set,
The wireless communication device that has received the load state notification signal transmits the received load state notification signal to the centralized control device via the wired connection ,
The wireless communication device transmits a beacon to the load control device at a predetermined cycle, and a frame defined by the predetermined cycle from a certain beacon to the next beacon is the load state acquisition signal and Divided into a plurality of time slots longer than the load state notification signal,
The wireless communication device
Randomly arrange communication slots with a plurality of load control devices in which the master-slave relationship is set in all slots of the frame,
After transmitting the load status acquisition signal, when the load status notification signal cannot be acquired from all of the plurality of load control devices for which the master-slave relationship is set within the predetermined period, all slots of the next frame In addition, the load control system is characterized in that communication slots with the load control device that could not acquire the load status notification signal are randomly arranged again so as not to overlap, and the load status acquisition signal is retransmitted . 2. The load control system according to claim 1 , wherein each of the wireless communication devices is offset based on a preset order so that slots for transmitting the beacons do not overlap each other . The wireless communications apparatus, respectively, based on the order set in advance, according to claim 1 or claim 2 frame to transmit the load state acquisition signal, characterized in that it is offset so as not to overlap Load control system. The wireless communications apparatus, respectively, the load control system according to claim 1 or claim 2, characterized in that the frame for transmitting the load status acquisition signal is duplicated. Even if the wireless communication device retransmits a beacon including the load state acquisition signal a predetermined number of times to any one of the plurality of load control devices for which the master-slave relationship is set, the load state notification when unable to acquire the signal, in any one of claims 1 to 4 wherein its load control device with respect to the centralized control device and transmits an absence signal indicating the absence of The load control system described. Even when the wireless communication device can obtain the load state notification signal from all of the plurality of load control devices to which the master-slave relationship is set before reaching the prescribed number of times, The load control system according to claim 5 , wherein the load control system does not shift to an operation . The beacon transmitted by the wireless communication device includes a load state change notification permission signal or a load state change notification prohibition signal,
The wireless communication device acquires a load state notification signal from all of a plurality of load control devices to which the master-slave relationship is set after power is turned on or includes a beacon including the load state acquisition signal for a specified number of times. Until it retransmits, it transmits the beacon including the load state change notification prohibition signal, and then transmits it including the load state change notification permission signal,
The load control device does not transmit the load state change notification signal even if the load state controlled by the load control device changes until the load state change notification permission signal is received. The load control system according to any one of claims 1 to 4 . The load control device that has received the load state change notification permission signal confirms whether or not the wireless communication device is transmitting by carrier sense when the state of the load controlled by the load control device has changed, The load control system according to claim 7 , wherein the load state change notification signal is transmitted using a slot to which no radio wave is transmitted . When the load control device receives the load state change notification permission signal after the power is turned on, whether or not the wireless communication device is transmitting by carrier sense after a delay time of a random number of slots And send a startup notification signal using a slot that is not transmitting radio waves,
When the wireless communication device receives the activation notification signal from any one of a plurality of load control devices for which the master-slave relationship is set, the load state notification signal is obtained by the method according to claim 7 or 8. A load control system characterized by acquiring

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