JP2020027785A - Load control system - Google Patents

Abstract

To provide a load control system capable of continuing power supply to a load when a user voluntarily stops a controller or even when a failure has occurred in the controller.SOLUTION: A load control system 100 comprises: a load 40 that performs output depending on power consumption; a power supply 30 for supplying power; a switch unit 10 comprising a plurality of switches operable by a user; a controller 20 for controlling the output of the load 40 according to an instruction; first wiring for connecting the power supply 30 to the load 40 via a switch without using the controller 20 to supply power from the power supply 30 to the load 40; and second wiring for connecting the power supply 30 to the controller 20 via the switch unit 10 to supply power from the power supply 30 to the controller 20. Operation to the switch unit 10 enables connection or disconnection of the first wiring and the second wiring.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a load control system that controls a load output.

  The equipment in the house is controlled according to an instruction from an instruction device for controlling the equipment. There is also known an instruction device that transmits an instruction by wireless communication. As such an instruction device, for example, there is a remote controller that is operated by a user and wirelessly transmits an instruction according to the operation, and a computer or a sensor that controls a device in a house is used as an instruction device, and an instruction is issued from the instruction device. May be transmitted wirelessly.

  A controller for controlling a device in response to a wirelessly transmitted instruction is also known. The controller is provided, for example, on the back of a switch device installed on a wall surface, and forms a smart switch together with the switch device. The controller is capable of wireless communication with the pointing device, and is also connected to an operation device (for example, a switch device installed on a wall) for a user to control the device by manual operation. Accordingly, the controller can control the load of the device by an instruction received from the pointing device by wireless communication or an instruction by a manual operation received from the user via the switch device.

  In addition, in recent years, various actions such as sound, visible light, vibration, and infrared rays have been placed in houses to recognize residents' actions, and to predict the next actions of residents using artificial intelligence technology to control lighting and air conditioning. A house has been developed in which a living environment is controlled by controlling the living environment. Patent Document 1 discloses that wireless communication technology is used for such a purpose.

  However, in such a system, it is necessary to prevent a malicious third party from transmitting a wireless signal from outside the house and thereby controlling the device. For this reason, it is conceivable to use a short-range wireless communication standard such as ZigBee (registered trademark) described in Patent Literature 1 or prepare an emergency communication cutoff switch at home.

  Patent Literature 2 discloses a load control system including a switch device that can inhibit wireless control. In this load control system, the communication cutoff switch is arranged behind the switch operation panel. When the user removes the operation panel and operates the switch, power supply to the controller is stopped, and wireless control can be prohibited.

JP-T-2017-535084 Japanese Patent No. 6290504

  When the communication cutoff switch disclosed in Patent Document 2 is operated, the power supply to the controller is cut off and wireless control becomes impossible. However, since a load (for example, a lighting fixture) receives power supply via a controller, power supply to the load is stopped when the controller stops.

  Further, in the load control system of Patent Literature 2, since the controller is interposed in the circuit connecting the power supply and the load, even if a failure occurs in the controller, the power supply to the load is stopped.

  Therefore, an object of the present invention is to provide a load control system capable of continuing to supply power to a load even when a user voluntarily stops a controller or when a failure occurs in the controller.

  One embodiment of a load control system according to the present invention is a load control system that can connect a power supply that supplies power and a load that outputs power according to input power or output. A switch unit having a switch, a controller for controlling the output of the load in accordance with an instruction, and connecting the power supply and the load via the switch without passing through the controller, and providing power from the power supply. A first wiring for supplying the power to the load, a second wiring for connecting the power supply and the controller via the switch unit, and supplying power from the power supply to the controller, And the first wiring can be connected or disconnected by a first operation on the switch unit, and the first wiring can be connected to the switch unit. The second operation, to connect the second wiring, or can be cut.

  With this configuration, even when the power supply to the controller is cut off by disconnecting the second wiring, and when a failure occurs in the controller, the power supply and the load are connected by the first wiring, and the load is connected to the load. Power can be supplied.

  In addition, the load control system further includes a third wiring for connecting the power supply and the load via the switch unit and the controller, and supplying power from the power supply to the load. The controller may receive a wireless instruction or an instruction from the switch unit, control the power from the power supply according to the instruction and supply the power to the load, and perform the first operation and the The second operation may be an operation on the same switch, and the first wiring may be connected by an operation of disconnecting the second wiring.

  With this configuration, normally, the controller receives power supply through the second wiring, controls the power according to the instruction, and controls the load by supplying the power to the load through the third wiring. Since the controller does not function by cutting the second wiring, power cannot be supplied to the load by the third wiring, but instead, the first wiring connects the power supply to the load without the intervention of the controller. Power can be supplied to the load. That is, by operating a switch for stopping the function of the controller, power can be simultaneously supplied to the load without passing through the controller. When a failure occurs in the controller, an ON / OFF switch for supplying power to the load is provided. Can also be used.

  In addition, the load control system further includes a third wiring for connecting the power supply and the load via the switch unit and the controller, and supplying power from the power supply to the load. The controller may receive an instruction wirelessly, control the power from the power supply in accordance with the instruction, and supply the power to the load, and the first operation and the second operation may be performed separately. May be operated on the switch.

  With this configuration, the controller normally receives power supply through the second wiring, controls power in accordance with an instruction, and supplies power to the load through the third wiring to control the load. Since the controller does not function by cutting the second wiring, power cannot be supplied to the load by the third wiring. However, independent of the first operation of cutting the second wiring, another switch is used. By performing the second operation, the first wiring can connect the power supply and the load without the intervention of the controller, and supply the power to the load.

  In the above-described load control system, the controller may generate and transmit a control signal for the load in response to an operation on the switch unit, and the first operation and the second operation may be the same. The first wiring may be connected by an operation of connecting the second wiring, and the first wiring may be disconnected by an operation of cutting the second wiring.

  With this configuration, when the controller fails and no longer transmits a control signal, the load consumes power according to the supplied power. In this state, the same operation is performed in which the first operation and the second operation are performed. The power from the power supply is supplied to the load by performing the operation of connecting the first wiring to the switch, and the power from the power supply is not supplied to the load by performing the operation of disconnecting the first wiring to the switch. it can. That is, when a failure occurs in the controller, a switch for stopping the function of the controller can be used as an ON / OFF switch for supplying power to the load.

  In the above-described load control system, among the switches, a switch having a function of stopping power supply to the controller or a function of directly supplying power to the load includes a member having a different appearance from other switches. May have been.

  If a switch having a function of stopping power supply to the controller or a function of directly supplying power to a load, that is, a switch operated in an emergency can be easily distinguished from other switches in appearance, the user can make a mistake in an emergency. And the possibility of accidentally performing unnecessary emergency operations can be reduced.

  The load control system may further include a remote control device that transmits a wireless signal, wherein the controller receives the wireless signal transmitted from the remote control device, and controls the load according to the received wireless signal. The output may be controlled.

  With this configuration, the output of the load can be controlled by the remote control device, and the power supply to the controller can be cut off against malicious control that attempts to control the load by impersonating the remote control device.

  The above load control system receives information from a plurality of sensors installed in the house, detects the behavior of the inhabitants, predicts the next action, and outputs an instruction to automatically prepare the environment in the design house. The device may further include a device, and the remote control device may transmit the instruction to the controller according to an instruction from the instruction device.

  With this configuration, it is possible to realize a livable house that automatically satisfies the demand of a user who is a resident.

  In the above load control system, the control device may transmit the instruction to the controller according to an instruction from a user.

  With this configuration, the user can give an instruction for controlling the output of the load by means other than the switch unit, for example, giving an instruction to the remote control device from a terminal such as a mobile phone.

  According to the present invention, when the power supply to the controller is cut off by cutting the wiring connecting the controller and the power supply, and even when the controller fails, the power supply is connected to the wiring directly connecting the power supply and the load. By connecting to a load, an effect that power can be supplied to the load can be obtained.

FIG. 1 is a circuit diagram of the load control system according to the first embodiment of the present invention. FIG. 2 shows the first wiring according to the first embodiment of the present invention, and the bold line indicates the first wiring. FIG. 3 shows the second wiring in the first embodiment of the present invention, and the bold line indicates the second wiring. FIG. 4 shows the third wiring according to the first embodiment of the present invention, in which the bold line indicates the third wiring. FIG. 5 is a front view of the appearance of the switch unit according to the first embodiment of the present invention. FIG. 6 is a front view of the appearance of a modification of the switch unit according to the first embodiment of the present invention. FIG. 4 is a circuit diagram of the load control system according to the second embodiment of the present invention. FIG. 8 shows the first wiring according to the second embodiment of the present invention, and the bold line indicates the first wiring. FIG. 9 shows the second wiring in the second embodiment of the present invention, in which the bold line indicates the second wiring. FIG. 10 is a circuit diagram of a load control system according to the third embodiment of the present invention. FIG. 11 shows the first wiring in the third embodiment, and the bold line indicates the first wiring. FIG. 12 shows the second wiring in the third embodiment, and the bold line indicates the second wiring. FIG. 13 shows the third wiring in the third embodiment, and the bold line indicates the third wiring. FIG. 14 is a front view of the appearance of the switch unit according to the third embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The embodiment described below shows an example in which the present invention is implemented, and the present invention is not limited to the specific configuration described below. In carrying out the present invention, a specific configuration according to the embodiment may be appropriately adopted. Hereinafter, a lighting device, more specifically, a light bulb is exemplified as the load, but the load is not limited to this. Load control refers to controlling the output of the load.
(1st Embodiment)

  FIG. 1 is a circuit diagram of a load control system 100 according to the first embodiment of the present invention. The load control system 100 includes a switch unit 10, a controller 20, a power supply 30, a load 40, a remote control device 50, a wireless router 60, a terminal device 70, and a pointing device 80. The power supply 30 is a commercial power supply that supplies a rated AC voltage.

  The switch unit 10 and the controller 20 cooperate to function as the load control device 90, but may be configured separately from each other and connected to each other by an electric wire, or the switch unit 10 and the controller 20 may be integrated into a smart switch. It may be constituted as.

  The switch unit 10 includes a first operation switch 11, a wireless control stop switch 12, and a second operation switch 13. In the present embodiment, the first operation switch 11 and the second operation switch 13 are normally open (A contact) momentary operation switches, and the wireless control stop switch 12 is a three-way (C contact) alternate operation switch. . Each of the switches 11 to 13 is independently operated by the user.

  The power supply side of each of the switches 11 to 13 is connected to the live line L of the power supply 30. Also, in the example of FIG. 1, the wiring extending from the live line L of the power supply 30 is branched and connected to each of the switches 11 to 13. However, the switches 11 to 13 are connected to the power supply 30 by different wirings. You may. The controller 20 side of each of the switches 11 to 13 is connected to a corresponding terminal of the controller 20 described later. However, when the wireless control stop switch 12 is operated on the wireless control stop side (cutoff side), the live line L of the power supply 30 is connected to the controlled output terminal (NO1) of the controller 20 without passing through the controller 20. It is connected to the wiring connecting to the load 40.

  The controller 20 includes a plurality of terminals including an N terminal 21, an S1 terminal 22, an S2 terminal 23, a NO1 terminal 24, and an L terminal 25. The N terminal 21 is a neutral input terminal, and is connected to a neutral line (ground side electric wire) N connected to the power supply 30. The wiring from the first operation switch 11 is connected to the S1 terminal 22. Wiring from the second operation switch 13 is connected to the S2 terminal 23. The NO1 terminal 24 is a controlled output terminal (live output terminal). The wiring from the NO1 terminal 24 is connected to the load 40. The neutral line N of the power supply 30 is connected to the load 40. The L terminal 25 is a live input terminal that is a target of load control output and also supplies power to the controller 20, and is connected to a wire from the wireless control stop switch 12 in a normal state.

  The controller 20 includes a wireless communication module 28, a power adjustment module 27, and a control module 26. The wireless communication module 28 has a wireless communication function, and performs wireless communication with the remote control device 50 as needed. The control module 26 is configured by a microcomputer, has a storage unit (not shown) that stores the current power output to the load 40, and receives inputs from the first operation switch 11 and the second operation switch 13 and remote control. The load output is determined by communication from the device 50.

  Due to the specification that the power supply may be cut off, it is desirable that a nonvolatile memory such as an EEPROM be used as the storage unit to be connected. However, if the load 40 is limited to lighting fixtures, storage is not so important, and a volatile memory may be employed as the storage unit.

(Load control by switch operation)
When the first operation switch 11 is pressed (connected), the S1 terminal 22 of the controller 20 is connected to the live line L. When the second operation switch 13 is pressed (connected), the live line L is connected to the S2 terminal 23 of the controller 20. The control module 26 detects the connection state of each of the S1 terminal 22 and the S2 terminal 23. When the first operation switch 11 or the second operation switch 13 is pressed in a predetermined procedure, the control module 26 controls the power adjustment module 27 described later to perform output control according to the operation. . For example, when the button is shortly pressed, the light is turned on / off, and when the button is pressed for a long time, the output is gradually increased or decreased. As described above, the controller 20 receives an instruction by the user operation performed on the switch unit 10. The control module 26 generates a dimming parameter according to an instruction by operating the first operation switch 11 or the second operation switch 13 and outputs the parameter to the power adjustment module 27.

  The power adjustment module 27 adjusts the power supplied from the live line L to the L terminal 25 via the wireless control stop switch 12 in the normal state according to the dimming parameter received from the control module 26, and Output. The power adjustment module 27 supplies 100% power to the load 40 by outputting the power from the power supply 30 without adjusting the power, and cuts off the power from the power supply 30 to reduce the power supplied to the load 40. Can be zero. When the load 40 is an incandescent light bulb or an LED light bulb having a dimming function, the power adjustment module 27 performs pulse modulation or phase control to perform arbitrary dimming in the range of 0 to 100%. Can be realized.

(Load control by wireless communication)
The remote control device 50 includes a dongle 51 for transmitting / receiving a wireless signal to / from (the wireless communication module 28 of) the controller 20. As a communication method between the controller 20 and the dongle 51 of the remote control device 50, for example, Z-Wave (registered trademark) which is a wireless communication standard can be adopted.

  The remote control device 50 is associated with a wireless router 60 having a wireless communication function. Communication between the wireless router 60 and the remote control device 50 may be wire communication or wireless communication.

  The wireless router 60 is further associated with the terminal device 70. The terminal device 70 is, for example, a computer terminal such as a mobile phone owned by the user, and is connected to the wireless router 60 by a wireless communication standard such as Wi-Fi (registered trademark). Further, the communication path between the terminal device 70 and the wireless router 60 may be once via the Internet via an LTE line or the like.

  The method by which the terminal device 70 controls the controller 20 may be provided in the form of application software or the like for transmitting a control signal. The user can issue an instruction for controlling the load 40 from the terminal device 70 through the application software. As an example in the case where the load 40 is a lighting fixture, the contents of the instruction include lighting, turning off, dimming, timer control, and the like.

  The control signal transmitted from the terminal device 70 is transmitted to the controller 20 via the wireless router 60 and the remote control device 50. The wireless communication module 28 of the controller 20 receives a control signal from the terminal device 70. The control module 26 controls the power adjustment module 27 according to the control signal received by the wireless communication module 28, thereby adjusting the power sent from the NO1 terminal to the load 40.

  The pointing device 80 may be connected to the remote control device 50. The pointing device 80 is a computer on which a home control OS is mounted and to which a plurality of home sensors are connected. The home control OS is equipped with AI (Artificial Intelligence), and recognizes the behavior of residents from information of various sensors (for example, infrared sensors, vibration sensors, sound sensors, etc.) installed in a house, The purpose is to predict the next action and prepare the living environment for the next action.

  The instruction transmitted from the instruction device 80 is transmitted to the controller 20 via the remote control device 50. The wireless communication module 28 of the controller 20 receives an instruction from the instruction device 80. The control module 26 outputs a dimming parameter to the power adjustment module 27 according to the instruction received by the wireless communication module 28. The power adjustment module 27 adjusts the power sent from the NO1 terminal 24 to the load 40 according to the dimming parameter. Thereby, automatic control of the living environment is realized.

(First Wiring in First Embodiment)
FIG. 2 shows the first wiring in the first embodiment, and the bold line indicates the first wiring. When a failure occurs in the controller 20 and the power supply from the NO1 terminal 24 is cut off, the power supply to the load 40 is stopped. Thus, when the load 40 is a lighting fixture, the load 40 remains off. In such a case, when the user operates the wireless control switch 12 of the switch unit 10 to the wireless control stop side (cuts off), the wiring from the switch unit 10 to the load 40 does not pass through the controller 20. Directly connected to load 40.

  If malicious control is suspected, the user operates the wireless control stop switch 12 of the switch unit 10 to the wireless control stop side. With this operation, the live input to the L terminal 25 of the controller 20 is cut off, and the power supply to the controller 20 is stopped. As a result, the function of the controller 20 is stopped, the built-in wireless communication module 28 is also stopped, and the wireless control is stopped, but the wiring from the switch unit 10 to the load 40 does not pass through the controller 20. Power is supplied to the load 40 by being directly connected to the load 40.

  As described above, the load 40 is connected to the neutral line N of the power supply 30. Therefore, for example, when the load 40 is a lighting fixture, if the user operates the wireless control stop switch 12 to the wireless control stop side, electricity flows to the first wiring, and the load 40 is turned on with 100% illuminance. I do.

  With the first wiring, when a failure occurs in the controller 20, the wireless control stop switch 12 can be used as a normal ON / OFF switch. Further, even when the wireless control is stopped by the user's intention, the power supply to the load 40 can be continued.

(Second wiring in the first embodiment)
FIG. 3 shows the second wiring in the first embodiment, and the bold line indicates the second wiring. When the wireless control stop switch 12 is not operated to the wireless control stop side (that is, in a normal state), the live line L from the power supply 30 is connected to the L terminal 25 of the controller 20. Since the N terminal 21 of the controller 20 is connected to the neutral line N of the power supply 30, an electric circuit connecting the controller 20 and the power supply 30 is formed, and the controller 20 obtains the driving power. The control module 26 in the controller 20 is energized by the second wiring, and the control module 26 performs adjustment based on a radio signal received by the wireless communication module 28 or an operation of the first operation switch 11 and the second operation switch 13. Optical parameters can be generated to control the power adjustment module 27.

(Third wiring in the first embodiment)
FIG. 4 shows the third wiring in the first embodiment, and the bold line indicates the third wiring. When the wireless control stop switch 12 is not operated to the wireless control stop side (that is, in a normal state), an electric circuit between the load 40 and the live line L of the power supply 30 passes through the controller 20 once. The power input to the L terminal 25 of the controller 20 is adjusted by the power adjustment module 27 inside the controller 20, output from the NO1 terminal 24 of the controller 20, and supplied to the load 40. The load 40 is connected to the power supply 30 via a neutral line N.

  With the third wiring, the load 40 can be controlled by operating the switch unit 10 or by wireless communication from the remote control device 50. Note that, when the wireless control stop switch 12 is operated to the wireless control stop side, the third wiring is disconnected similarly to the second wiring, and the first wiring supplies power to the load 40 instead. .

(Form of switch part)
FIG. 5 is a front view of the appearance of the switch unit 10 according to the embodiment of the present invention. The switch unit 10 includes a decorative plate 101 provided at an outer edge portion and a plurality of large handles 111 to 113 provided at a central portion. A first operation switch 11 is provided on the back of the handle 111, a wireless control stop switch 12 is provided on the back of the handle 112, and a second operation switch 13 is provided on the back of the handle 113. . Further, electrical wirings as shown in FIG. 1 are connected to the rear surfaces of the switches 11 to 13. Note that, as described above, the controller 20 and the switch unit 10 may be integrated.

  A translucent window can be provided in a part of the handles 111 to 113. A small light source such as an LED or a neon lamp can be provided in a corresponding portion of each of the switches 11 to 13, and can emit light in accordance with the energized state of the switches 11 to 13. The user can know the current energization state of the switch from the light leaked from the light transmitting window (for example, green when energized, red when disconnected). Further, as the switches 11 to 13, those in which a small light source is turned on only at the time of interruption may be adopted. With these small light sources and translucent windows, the user can easily know the position of the switch in a state where the night illumination is turned off.

  FIG. 6 is a front view of the appearance of a modified example of the switch unit 10 in the present embodiment. In this modification, the structure of a handle 111 corresponding to the first operation switch 11 and a handle 113 corresponding to the second operation switch 13 used for normal dimming control is the same as that of FIG. The corresponding handle 112 has a different appearance (size, shape, color, etc.) from the handle 111 and the handle 113, and is configured as, for example, a tumbler switch. The handle 112 may also have a function of expressing the energized state by emitting light. With this configuration, it is possible to prevent the user from accidentally stopping the control by wireless communication in a normal state, and to perform the control when there is a possibility that malicious control may be performed or when the controller 20 has a problem. Thus, the user can quickly operate the wireless control stop switch 12 without mistake.

(Switch operation)
In the present embodiment, by operating the wireless control stop switch 12, the connection between the first wiring and the second wiring is exclusively switched, and the connection state of the third wiring is linked with the second wiring. That is, the first operation and the second operation on the switch unit 10 are realized by operating the wireless control stop switch 12, which is the same switch.

(Effect of First Embodiment)
As described above, according to the present embodiment, even if a failure occurs in the controller 20, the wireless control stop switch 12 is operated to connect the first wiring, thereby supplying power to the load 40. The wireless control stop switch 12 can be used as an ON / OFF switch for the load 40 until the power can be supplied and the malfunction of the controller 20 is eliminated. In addition, even when the wireless communication module 28 may be illegally controlled and the control by wireless communication is interrupted, the power supply to the load 40 can be maintained.

(2nd Embodiment)
FIG. 4 is a circuit diagram of a load control system 100 ′ according to the second embodiment of the present invention. The functions of the switch 11 and the switch 13 are the same as those of the first embodiment, but the wireless control stop switch 12 is an alternate operation switch in a normally energized state (B contact). In this embodiment, the appearance of the switch device may be the same as that shown in the first embodiment (FIGS. 2 and 3).

  In the present embodiment, a load provided with a load-side output control device 41 is used as the load 40. The load-side output control device 41 may be provided near the load 40, or may be incorporated inside the load 40. Power from the power supply 30 is supplied to the load-side output control device 41. The load-side output control device 41 receives a control signal transmitted by wireless communication, and controls the output of the load 40 according to the control signal.

  The wireless control stop switch 12 is provided on a circuit that connects the live line L of the power supply 30 and the L terminal 25 of the controller 20. A branch circuit is provided between the wireless control stop switch 12 and the controller 20, and is connected to the load 40 via the load-side output control device 41.

  In the present embodiment, since the NO1 terminal 24 of the controller 20 is not connected to the load 40, the load 40 does not receive power supply via the controller 20, and the controller 20 does not have the power adjustment module 27. The controller 20 receives the load control operation by the switch unit 10 in the control module 26, and the wireless communication module 28 transmits this as a wireless signal. The remote control device 50 receives the wireless signal.

  The remote control device 50 receives an instruction from the instruction device 80 as described in the first embodiment. The remote control device 50 collects these signals and transmits them to the wireless router 60. The wireless router 60 wirelessly transmits a control signal, and the load-side output control device 41 receives the control signal. The load-side output control device 41 controls power or a phase supplied to the load 40.

  The wireless router 60 may be further controlled by the terminal device 70 owned by the user. In the first embodiment, the wireless router 60 controlled by the terminal device 70 transmits a control signal to the controller 20 via the remote control device 50, and the controller 20 performs load control. In the embodiment, the wireless router 60 itself may transmit the control signal without passing through the remote control device 50. In this case, a wireless communication method with the load-side output control device 41 is a wireless LAN standard such as Wi-Fi (registered trademark). Of course, the control signal transmitted from the wireless router 60 by wire or wireless may be received by the remote control device 50 and transmitted wirelessly to the load-side output control device 41. In this case, the communication method is as follows. Z-Wave (registered trademark) or the like may be used.

  Although not shown, the load-side output control device 41 includes a communication unit, a control unit, and a storage unit. The communication unit transmits a control signal received by wireless communication from the wireless router 60 or the remote control device 50 to the control unit. The control unit adjusts power to be provided to the load 40 and stores the content of the output control currently received. Hold in part. Further, the load-side output control device 41 may periodically check the control signal and record the latest communication state. The storage unit may be a volatile memory, but if there is a need for maintenance, a nonvolatile memory such as an EEPROM may be used so that the record remains.

  When the wireless communication continuously fails and the number of failures exceeds the threshold value, the control unit of the load-side output control device 41 ignores the control received so far and applies the supplied power to the load 40 as it is. This state is released when the load-side output control device 41 receives the control signal again. With this configuration, even if a failure occurs in any of the devices that take the communication path of the present embodiment, power supply to the load 40 can be maintained unless the wireless control stop switch 12 is operated.

(First Wiring in Second Embodiment)
FIG. 8 illustrates the first wiring in the second embodiment, and the bold line indicates the first wiring. In the present embodiment, the wiring from the wireless control stop switch 12 branches to the load 40 side and the controller 20 side through the branch circuit after passing through the wireless control stop switch 12, so that the power supply to the load 40 and the controller 20 are linked. .

  For this reason, even if some trouble occurs in the controller 20, only the switches 11 and 13 of the switch unit 10 do not operate, and the power supply to the load 40 is performed by the first wiring without requiring any special operation by the user. Continue to be secured. The transmission of the control signal by wireless communication is performed by the remote control device 50 or the wireless router 60, and the load-side output control device 41 receives the control signal and controls the output of the load 40. The load control through the pointing device 80 and the terminal device 70 operates normally only by stopping the operation by the user 13.

  When the wireless control stop switch is operated to the wireless control stop side, power supply to the controller 20 and the load 40 is stopped. Since the load 40 is wirelessly controlled by the load-side output control device 41, the power is not supplied to these devices, so that the light is turned off when the load is a lighting fixture, and the wireless control of the load 40 is also on the receiving side. Since the power supply to the load-side output control device 41 is stopped, it is shut off.

(2nd wiring in 2nd Embodiment)
FIG. 9 shows the second wiring in the second embodiment, and the bold line indicates the second wiring. The second wiring forms an electric circuit in which the live line L of the power supply 30 is input to the L terminal 25 of the controller 20 via the wireless control stop switch 12 and connected from the N terminal 21 to the neutral line N of the power supply 30. Since the branch point between the first wiring and the second wiring is provided before the wireless control stop switch 12, the state of energization of the first wiring and the second wiring is determined by operating the wireless control stop switch 12. Link with.

  When the wireless control stop switch 12 is operated to the wireless control stop side, power supply to the controller 20 is stopped, and the controller 20 stops. When the wireless control stop switch is operated to the wireless control stop side, the first wiring is also cut off, and the power supply to the load 40 and the wireless control to the load 40 are also stopped.

(Third wiring in the second embodiment)
In the present embodiment, the control of the load 40 is performed not by controlling the power supplied from the controller 20 to the load 40 but by wireless communication to the load-side output control device 41. The power control is performed by the load-side output control device 41. There is no third wiring connecting the load 30 and the load 40 via the controller 20.

(Switch operation)
In the present embodiment, by operating the wireless control stop switch 12, the connection between the first wiring and the second wiring is switched in conjunction. That is, the first operation and the second operation on the switch unit 10 are realized by the operation of the wireless control stop switch 12 that is the same switch, but the first wiring is also connected by the operation of connecting the second wiring. Then, the operation of cutting the second wiring also cuts the first wiring.

(Effect of Second Embodiment)
In the present embodiment, even if a failure occurs in the controller 20, the user cannot perform load control by operating the first operation switch 11 and the second operation switch 13 provided in the switch unit 10. Can be continued. In addition, automatic load control by the instruction device 80 can be received. Further, similarly to the first embodiment, the wireless control stop switch 12 can be used as an ON / OFF switch for supplying power to the load 40.

(Third embodiment)
FIG. 10 is a circuit diagram of a load control system 100 ″ having still another circuit configuration in the switch unit 10. In the present embodiment, the method of load control is the same as that of the first embodiment, but the wireless control stop switch 12 is an alternate operation switch in a normally energized state (B contact), and the live line L of the power supply 30 It is connected only to the L terminal 25 of the controller 20. When the malicious control from the outside is suspected, the power supply to the controller 20 can be stopped by operating the wireless control stop switch 12 to the wireless control stop side. As a result, the function of the controller 20 is stopped, and the wireless control performed by the controller 20 is also stopped.

  Further, in the present embodiment, the switch unit 10 newly includes a third operation switch 14 which is an alternate operation switch in a normally disconnected state (A contact). The power supply 30 side of the third operation switch 14 is connected to the live line L of the power supply 30 directly or branched from a circuit connected to another switch through a branch circuit, and the load 40 side is connected to the controller 20 without the controller 20. Is connected in the wiring connecting the NO1 terminal 24 and the load 40.

(First Wiring in Third Embodiment)
FIG. 11 shows the first wiring in the third embodiment, and the bold line indicates the first wiring. Normally, the wireless control stop switch 12 is in an energized state, so that the load 40 receives power supply and load control from the NO1 terminal 24 of the controller 20. However, when the user stops the power supply to the controller 20 by operating the wireless control stop switch 12 to the wireless control stop side to stop the wireless control, or when a malfunction occurs in the controller 20, the NO1 terminal 24 is used. , The power supply to the load 40 also stops.

  In such a case, when the user operates the third operation switch 14 to the connection side, the first wiring not passing through the controller 20 is formed as shown in FIG. As described above, the load-side wiring of the third operation switch is directly connected to the load 40. The user can supply power to the load 40 regardless of the state of the controller 20 by operating the third operation switch 14 and connecting the wiring.

(Second Wiring in Third Embodiment)
FIG. 12 shows the second wiring in the third embodiment, and the bold line indicates the second wiring. When the wireless control stop switch 12 is not operated, the wiring from the power supply 30 is connected to the L terminal 25 of the controller 20. Since the N terminal 21 of the controller 20 is connected to the neutral line N of the power supply 30, an electric circuit is formed via the controller 20, and the second wiring for supplying power to the internal functions of the controller 20 is connected. Power is supplied to the control module 26 inside the controller 20 by the second wiring, and the control module 26 receives an instruction received by the wireless communication module 28 or operates the first operation switch 11 and the second operation switch 13 by the user. , The power adjustment module 27 can be controlled.

(Third wiring in the third embodiment)
FIG. 13 shows the third wiring in the third embodiment, and the bold line indicates the third wiring. When the wireless control stop switch 12 is not operated to the wireless control stop side (that is, in a normal state), an electric circuit between the load 40 and the live line L of the power supply 30 passes through the controller 20 once. The power input to the L terminal 25 of the controller 20 is adjusted by the power adjustment module 27 inside the controller 20, output from the NO1 terminal 24 of the controller 20, and supplied to the load 40.

  The third wiring allows the load 40 to be controlled by operating the first operation switch 11 and the second operation switch 13 of the switch unit 10 or by wireless communication. The third wiring is cut off in the same manner as the second wiring when a failure occurs in the controller 20 or when the wireless control stop switch 12 is operated to the wireless control stop side. In such a case, in the present embodiment, the user can turn on / off the power supply to the load 40 by the first wiring by operating the third operation switch 14.

  FIG. 14 is a front view of the appearance of the switch unit 10 of the third embodiment. As in the first embodiment, the switch unit 10 includes a decorative plate 101 provided at the outer edge and a plurality of large handles 111 to 113 provided at the center. A first operation switch 11 is provided on the back of the handle 111, a wireless control stop switch 12 is provided on the back of the handle 112, and a second operation switch 13 is provided on the back of the handle 113. .

  A handle 114 is provided below the handles 111 to 113. The third operation switch 14 is provided on the back of the handle 114. The handle 114 is different in appearance (size, shape, color, etc.) from the other handles 111 to 113, and is configured as, for example, a tumbler switch. The third operation switch 14 may also have a function of expressing the energized state by emitting light.

  Further, electric wiring shown in FIG. 10 is connected to the rear surfaces of the switches 11 to 14. When the controller 20 is integrated with the switch, the controller 20 is further provided. As in the first embodiment, a connection state display function using a light transmitting window can be provided.

  With this configuration, while the controller 20 is operating normally, erroneous operation of the switch 14 by the user can be prevented. In a state where the controller 20 is stopped by operating to the control stop side, the switch 14 can turn ON / OFF the power supply to the load.

(Switch operation)
In the present embodiment, by operating the wireless control stop switch 12, the connection state of the second wiring and the connection state of the third wiring are switched in conjunction. On the other hand, the first wiring is switched by operating the third operation switch 14. That is, the first operation and the second operation are operations on different switches, and can be performed independently of each other.

(Effect of Third Embodiment)
According to the present embodiment, the user can select whether or not to supply power to the load irrespective of the malfunction of the controller 20 or the operation state of the controller 20 due to the operation of the wireless control stop switch 12.

(Modification)
The embodiments have been described above, but the present invention is not limited to these embodiments. For example, in the second embodiment, the power adjustment module 27 is removed from the controller 20, and the remote control device 50 and the wireless router 60 take charge of wireless control of the load 40, but the controller 20 itself further performs wireless control of the load 40. It may have a function to perform. Even with this configuration, the form of the first wiring that does not pass through the controller 20 and the form of the second wiring that passes through the controller 20 do not change. If the controller 20 directly communicates with the load 40, the functions of the other devices will be different. No major changes are required.

Reference Signs List 10 switch unit 11 first operation switch 12 wireless control stop switch 13 second operation switch 14 third operation switch 20 controller 26 control module 27 power adjustment module 28 wireless communication module 30 power supply 40 load 41 load-side output control device 50 remote control device Reference Signs List 60 wireless router 70 terminal device 80 indicating device 90, 90 ′, 90 ″ load control device 100, 100 ′, 100 ″ load control system L live line N neutral line

Claims (8)

A load control system that can connect a power supply that supplies power and a load that outputs according to input power or output,
A switch unit including a plurality of switches that can be operated by a user,
A controller that controls the output of the load according to an instruction;
A first wiring for connecting the power supply and the load via the switch without passing through the controller, and supplying power from the power supply to the load;
A second wiring for connecting the power supply and the controller via the switch unit to supply power from the power supply to the controller;
With
By a first operation on the switch unit, it is possible to connect or disconnect the first wiring,
A load control system, wherein the second wiring can be connected or disconnected by a second operation on the switch unit. A third wiring for connecting the power supply and the load via the switch unit and the controller, and for supplying power from the power supply to the load;
The controller receives a wireless instruction or an instruction from the switch unit, controls the power from the power supply according to the instruction, and supplies the power to the load,
The load control according to claim 1, wherein the first operation and the second operation are operations on the same switch, and the first wiring is connected by an operation of disconnecting the second wiring. system. A third wiring for connecting the power supply and the load via the switch unit and the controller, and for supplying power from the power supply to the load;
The controller receives an instruction wirelessly, controls the power from the power supply according to the instruction, and supplies the power to the load,
The load control system according to claim 1, wherein the first operation and the second operation are operations on different switches. The controller generates and transmits a control signal for the load according to an operation on the switch unit,
The first operation and the second operation are operations on the same switch, and the operation of connecting the second wiring connects the first wiring and disconnects the second wiring. 2. The load control system according to claim 1, wherein the first wiring is disconnected by the operation. 3.   The switch having a function of stopping power supply to the controller or a function of directly supplying power to the load among the switches is configured by a member having a different appearance from other switches. 5. The load control system according to any one of claims 1 to 4. A remote control device that wirelessly transmits the instruction,
The load control system according to claim 2, wherein the controller receives the instruction wirelessly transmitted from the remote control device. Further comprising an instruction device that receives information from a plurality of sensors installed in the house, detects the behavior of the inhabitants, and outputs an instruction to automatically prepare the environment in the house by predicting the next action,
The load control system according to claim 6, wherein the control device transmits the instruction to the controller according to an instruction from the instruction device.   The load control system according to claim 6, wherein the control device transmits the instruction to the controller according to an instruction from a user.

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