JP2024079487A - Control device and control system - Google Patents

Abstract

[Problem] To provide a control device and control system that can easily accommodate changes in operation method. [Solution] A control device 2 includes a load connection unit 27, a connector, and a power control unit 25. A load 7 is connected to the load connection unit 27. Any of a plurality of types of operation modules 3 can be connected to the connector. The plurality of types of operation modules 3 have different operation methods by the user, and output an operation signal in response to the user's operation. The power control unit 25 controls the power supply to the load 7 connected to the load connection unit 27 based on the operation signal in response to the user's operation input from an operation module 3 connected to the connector out of the plurality of types of operation modules 3. [Selected Figure] Figure 2

Description

The present disclosure relates to a control device and a control system. More specifically, the present disclosure relates to a control device and a control system that controls power supplied to a load.

Patent Document 1 discloses a dimmer for adjusting the brightness of a lighting fixture. A rotary encoder control unit is disposed on the front of the main body of the dimmer. When the control unit is operated clockwise, the dimmer increases the brightness of the lighting fixture, and when the control unit is operated counterclockwise, the dimmer decreases the brightness of the lighting fixture.

JP 2021-125418 A

The dimmer device with the above configuration has only one operation method for switching the load output, and if you want to change the operation method, you have to replace the entire dimmer device.

The objective of this disclosure is to provide a control device and control system that can easily accommodate changes in operation methods.

A control device according to one aspect of the present disclosure includes a load connection unit, a connector, and a power control unit. A load can be connected to the load connection unit. Any of a plurality of types of operation modules can be connected to the connector. The plurality of types of operation modules are operated by a user in different ways, and output an operation signal in response to the user's operation. The power control unit controls the power supplied to the load connected to the load connection unit based on an operation signal in response to the user's operation input from an operation module connected to the connector among the plurality of types of operation modules.

A control system according to one embodiment of the present disclosure includes the control device and an operation module connected to the connector of the control device.

The present disclosure provides a control device and control system that can easily accommodate changes in operation methods.

FIG. 1 is an external perspective view of a control device according to an embodiment of the present disclosure, a rotation operation module connectable to the control device, and a touch operation module. FIG. 2 is a schematic block diagram of the control device, the rotation operation module, and the touch operation module. FIG. 3 is an external perspective view of the control device with a rotation operation module connected thereto. FIG. 4 is a rear view of the rotation operation module. FIG. 5 is a front view of the control device mounted on the mounting frame.

(Embodiment)
(1) Overview Each drawing described in the following embodiments is a schematic drawing, and the ratio of sizes and thicknesses of each component in each drawing does not necessarily reflect the actual dimensional ratio.

Figure 1 is an external perspective view of a control device 2 of this embodiment and an operation module 3 (here, a rotation operation module 4 and a touch operation module 5) that can be connected to the control device 2. Figure 2 is a schematic functional block diagram of the control device 2, the rotation operation module 4, and the touch operation module 5.

The control device 2 of this embodiment includes a load connection unit 27, a connector CN1 (see FIG. 1), and a power control unit 25.

The load 7 is connected to the load connection part 27.

Any of multiple types of operation modules 3 can be connected to connector CN1.

The multiple types of operation modules 3 are operated by users in different ways, and output operation signals according to the user's operations.

The power control unit 25 controls the power supply to the load 7 connected to the load connection unit 27 based on an operation signal corresponding to a user's operation input from an operation module 3 connected to the connector CN1 among the multiple types of operation modules 3.

Here, each of the multiple types of operation modules 3 has a user interface that accepts user operations. The multiple user interfaces that each of the multiple types of operation modules 3 has are different in operation method from each other. For example, the multiple types of operation modules 3 may include an operation module 3 that has an operation unit that can perform a rotation operation or a slide operation, and has a user interface that outputs an operation signal based on the operation direction and operation amount when the user operates the operation unit. In addition, the multiple types of operation modules 3 may include an operation module 3 that has a touch sensor and has a user interface that outputs an operation signal based on a touch operation (tap, swipe, etc.) detected by the touch sensor. In addition, the multiple types of operation modules 3 may include an operation module 3 that has an infrared receiving unit that receives an infrared signal transmitted from an infrared remote control device by a user operating the infrared remote control device, and has a user interface that outputs an operation signal based on information included in the infrared signal received by the infrared receiving unit.

When a desired operation module 3 out of the multiple types of operation modules 3 is connected to the connector CN1 of the control device 2, the power control unit 25 controls the power supply to the load 7 connected to the load connection unit 27 based on an operation signal corresponding to a user's operation input from the operation module 3 connected to the connector CN1. Therefore, when it is desired to change the operation method of the operation module 3, it is sufficient to connect an operation module 3 equipped with a user interface for the desired operation method to the control device 2. In other words, since the control device 2 is compatible with multiple types of operation modules 3 and an operation module 3 with a desired operation method can be connected to the control device 2 and used, it is easier to respond to changes in the operation method compared to replacing both the operation module 3 and the control device 2.

In this embodiment, the control device 2 and the operation module 3 constitute the control system 1. In other words, the control system 1 includes the control device 2 and the operation module 3 that is connected to the connector CN1 of the control device 2.

In the following embodiment, an example will be described in which the control system 1 includes a rotation operation module 4 and a touch operation module 5 as the multiple types of operation modules 3. The rotation operation module 4 includes a rotation operation unit 46 capable of performing a rotation operation as the user interface 30, and when the rotation operation unit 46 is operated, an operation signal based on the amount of rotation, the rotation speed, and the rotation direction of the rotation operation unit 46 is output to the control device 2. The touch operation module 5 includes a touch sensor 52 as the user interface 30, and when a touch operation is performed by touching the touch sensor 52, an operation signal based on the touch operation is output to the control device 2.

(2) Configuration The configuration of the control device 2 according to this embodiment and the multiple types of operation modules 3 that can be connected to the control device 2 will be described with reference to Figures 1 to 5. In the following description, the X-axis direction in Figure 1 and the like is defined as the left-right direction, the Y-axis direction as the front-rear direction (depth direction), and the Z-axis direction as the up-down direction. Furthermore, the positive direction in the X-axis direction is defined as the right side, the positive direction in the Y-axis direction as the front side, and the positive direction in the Z-axis direction as the top side. However, these directions are merely examples and are not intended to limit the directions of the control device 2 and the operation module 3 when they are used. Furthermore, the arrows indicating the respective directions in the drawings are merely indicated for the purpose of explanation and do not have any substance.

(2.1) Control Device As described above, the control device 2 includes the load connection unit 27, the connector CN1, and the power control unit 25. The control device 2 further includes a processing unit 20, a wired communication unit 21, a power control circuit 22, a setting operation unit 23, a wireless communication unit 24, and a housing 200.

The load 7 can be connected to the load connection section 27. The load connection section 27 has, for example, a pair of terminals t1, t2. An AC power source 6, such as a commercial AC power source, and a load 7 are connected in series between the pair of terminals t1, t2. The control device 2 is a two-wire wiring device in which the AC power source 6 and the load 7 are connected by two electric wires W1, but the connection form of the AC power source 6 and the load 7 can be changed as appropriate, and may be a three-wire or four-wire wiring device. The load 7 connected to the load connection section 27 is, for example, a lighting load. More specifically, the load 7 is a lighting load that has a light-emitting diode as a light source and is capable of being dimmed.

The processing unit 20 is mainly composed of a computer system having one or more processors and a memory. The functions of the processing unit 20 are realized by the processor of the computer system executing a program recorded in the memory of the computer system. The program may be recorded in the memory, or may be provided via a telecommunications line such as the Internet, or may be recorded on a non-transitory recording medium such as a memory card and provided.

The processing unit 20 has the functions of, for example, a power control unit 25 and a setting processing unit 26. Note that the power control unit 25 and the setting processing unit 26 merely indicate the functions realized by the processing unit 20 and do not necessarily indicate a physical configuration.

The power control unit 25 controls the power supply to the load 7 connected to the load connection unit 27 based on an operation signal input from the operation module 3 connected to the connector CN1. Specifically, the power control unit 25 outputs a control signal based on the operation signal to the power control circuit 22, and causes the power control circuit 22 to control the power supply to the load 7. In this embodiment, the load 7 is a lighting load, and the power control unit 25 controls the power supply to the lighting load so that the lighting load is turned on at a dimming level based on the operation signal. Note that in this embodiment, operation information indicating the amount of change and the direction of change in the dimming level of the lighting load (i.e., information indicating the dimming level relative to the current dimming level) is input from the operation module 3. The power control unit 25 controls the power supply to the lighting load based on the operation information so that the current dimming level is changed by the amount of change indicated by the operation information in the direction of change indicated by the operation information.

The setting processing unit 26 performs predetermined setting operations related to the operation of the control device 2 based on the setting information input from the setting operation unit 23.

The power control circuit 22 has a semiconductor switch, such as a triac, connected between terminals t1 and t2. The power control circuit 22 controls the power supplied from the AC power source 6 to the load 7 by controlling the conduction phase angle of the semiconductor switch in response to a control signal input from the power control unit 25. In other words, the power control circuit 22 controls the power supplied to the load 7, which is a lighting load, in response to the control signal input from the power control unit 25 so that the load 7 is turned on at a dimming level corresponding to the control signal.

The wired communication unit 21 communicates with the operation module 3 connected to the connector CN1. The wired communication unit 21 communicates with the operation module 3, for example, using the I2C (Inter-Integrated Circuit) communication method. In this embodiment, for example, the control device 2 is the master, the operation module 3 connected to the control device 2 is the slave, and serial communication is performed between the control device 2 and the operation module 3. Note that the communication method between the wired communication unit 21 and the operation module 3 is not limited to I2C, and other communication methods may be used.

The wireless communication unit 24 performs wireless communication with an external communication device 8. The external communication device 8 is, for example, another control device 2, a collective operation switch for collective operation of multiple loads 7 (for example, collective turning on or off), a gateway for connecting to a communication network, etc. The communication method between the wireless communication unit 24 and the external communication device 8 is, for example, a wireless communication method that complies with standards such as Wi-Fi (registered trademark), Bluetooth (registered trademark), Bluetooth Low Energy, ZigBee (registered trademark), or low-power radio that does not require a license (specific low-power radio).

The setting operation unit 23 is used to input setting information related to a predetermined setting task. The setting operation unit 23 includes, for example, setting buttons 231-232 that are operated to register a communication device 8 that is permitted to wirelessly communicate with the wireless communication unit 24, and setting buttons 233-234 that are operated to set a lower limit for the power supplied to the load 7 (see FIG. 5). The user can perform a predetermined setting task for the control device 2 by operating these setting buttons 231-234.

The setting buttons 231 to 234 are provided on the housing 200 of the control device 2, which has the advantage that it is not necessary to provide a setting operation unit for performing setting operations on the control device 2 on each of the multiple types of operation modules 3 that can be connected to the control device 2. Also, in the housing 200 that houses the load connection unit 27, connector CN1, power control unit 25, and setting operation unit 23, the setting operation unit 23 is provided on the surface (front surface 201) on which the connector CN1 is provided. Therefore, when the operation module 3 is not connected to the control device 2, the setting operation unit 23 is exposed and can be operated, so that predetermined setting operations can be performed on the control device 2 even when the housing 200 is attached to a wall or the like, making the setting operations easy.

Here, in this embodiment, the predetermined setting work includes a registration work for registering a communication device 8 that is permitted to communicate wirelessly with the wireless communication unit 24. The setting buttons 231 and 232 are operated to perform the registration work. The setting button 231 is, for example, an operation button that is operated to operate the processing unit 20 in the registration mode. The registration mode is an operation mode for registering a communication device 8 that is permitted to communicate wirelessly with the wireless communication unit 24. When the setting button 231 is operated, the processing unit 20 starts operation in the registration mode and causes the indicator light 235 arranged on the front surface 201 of the housing 200 to flash. Then, when the wireless communication unit 24 receives a registration request from the communication device 8 while operating in the registration mode, the setting processing unit 26 stores the identification information (e.g., network address, IP address, MAC address, etc.) of the communication device 8 received together with the registration request in the memory as the identification number of the communication device that is permitted to communicate wirelessly. In other words, the setting processing unit 26 sets this communication device 8 as a communication device that is permitted to communicate with the wireless communication unit 24. When a predetermined time has elapsed since the processing unit 20 started operating in the registration mode, the processing unit 20 ends the registration mode and turns off the indicator light 235. Additionally, the setting button 232 is, for example, an operation button for erasing the identification information of the communication device 8 stored in the memory. When the setting button 232 is operated, the setting processing unit 26 erases the identification information of the communication device 8 stored in the memory.

In addition, in this embodiment, the predetermined setting work includes the work of setting at least one of the upper limit and the lower limit of the power supplied to the load 7. In this embodiment, since the load 7 is a lighting load, the predetermined setting work includes the work of setting at least one of the upper limit and the lower limit of the dimming range of the lighting load. Note that in this embodiment, the predetermined setting work includes the setting work of setting the lower limit of the power supplied to the load 7, that is, the lower limit of the dimming range of the lighting load. Specifically, the setting buttons 233 and 234 are used for the setting work of setting the lower limit of the dimming range. When the setting button 233 is operated once, the setting processing unit 26 brightens the lower limit of the dimming range by a predetermined level. Also, when the setting button 234 is operated once, the setting processing unit 26 darkens the lower limit of the dimming range by a predetermined level. Note that in this embodiment, the predetermined setting work is the work of setting the lower limit of the power supplied to the load 7 (i.e., the lower limit of the dimming range), but it may be the work of setting the upper limit of the power supplied to the load 7 (i.e., the upper limit of the dimming range), or it may be the work of setting both the upper limit and the lower limit.

The housing 200 is formed into a rectangular parallelepiped shape as a whole by joining a rear body 210 and a front cover 220, each of which is a molded product made of synthetic resin (see FIG. 1).

The housing 200 houses the load connection unit 27, the connector CN1, the processing unit 20, the wired communication unit 21, the power control circuit 22, the setting operation unit 23, and the wireless communication unit 24. The connector CN1 and the setting operation unit 23 are disposed on the front surface 201 of the housing 200. In other words, in this embodiment, the first member housing the second member is not limited to only the state in which the second member is stored inside the first member, but may also include the state in which the first member holds the second member with a part or the entirety of the second member exposed to the surface.

The housing 200 of the control device 2 is attached to a mounting surface such as a wall with a portion of it embedded in an embedding hole provided in the mounting surface. The housing 200 is fixed to the mounting surface such as a wall using, for example, an attachment member such as a switch box embedded in the embedding hole.

The housing 200 is fixed to a mounting member such as a switch box via a mounting frame 60. The mounting frame 60 is, for example, a mounting frame for a large rectangular interconnect wiring device standardized by the Japanese Industrial Standards. The mounting frame 60 is formed in a rectangular frame shape when viewed from the front. An opening 66 is provided in the center of the mounting frame 60 to expose almost the entire front surface 201 of the housing 200. A plurality of holes 65 are provided in the left and right long side portions 64 of the mounting frame 60 into which protrusions 204 (see FIG. 3) provided on the side surface of the housing 200 fit. The housing 200 is inserted into the frame of the mounting frame 60 from the rear side of the mounting frame 60, and is held by the mounting frame 60 by fitting the protrusions 204 on the side surface of the housing 200 into the holes 65 of the mounting frame 60 with the front surface 201 of the housing 200 exposed from the opening 66.

The mounting frame 60 is made of metal, for example. The upper and lower short side portions 61 of the mounting frame 60 are provided with mounting holes 62 and screw holes 63 for fixing the plate. The mounting frame 60 is attached to a mounting surface such as a wall by screwing a pair of mounting screws through the pair of mounting holes 62 into screw holes provided in a mounting member such as a switch box. The mounting plate is attached to the front side of the mounting frame 60 by passing a pair of fixing screws through a pair of through holes provided in a synthetic resin fixing plate and screwing the pair of fixing screws into a pair of screw holes 63. A synthetic resin decorative plate is attached to the front side of the fixing plate by concave-convex engagement. When the fixing plate and the decorative plate are attached to the front side of the mounting frame 60, the front surface 201 of the housing 200 is exposed forward through the openings provided in the fixing plate and the decorative plate, respectively.

The front surface 201 of the housing 200 is provided with the connector CN1, setting buttons 231 to 234, and indicator light 235, as described above.

In addition, the front portion of the left and right sides of the housing 200 is provided with grooves 202 (see FIG. 5) into which a pair of locking hooks 301 (see FIG. 1 and FIG. 4) provided on the operation module 3 are coupled. In addition, the four corners of the front surface 201 of the housing 200 are provided with four recesses 203 (see FIG. 5) into which four positioning protrusions 302 (see FIG. 4) provided on the four corners of the rear surface of the operation module 3 are respectively fitted.

The rear surface of the housing 200 is provided with a wire insertion hole into which the wire W1 (see FIG. 2) is inserted, which connects the load 7 and the AC power source 6 with the control device 2. Inside the housing 200, a terminal device is housed to which the wire W1 inserted from the wire insertion hole is connected. This terminal device is, for example, a quick-connect terminal that allows the wire to be connected without tools.

(2.2) Operation Module A plurality of types of operation modules 3 can be connected to the control device 2. In this embodiment, a rotation operation module 4 and a touch operation module 5 are used as the plurality of types of operation modules 3 that can be connected to the control device 2.

(2.2.1) Rotation Operation Module The rotation operation module 4 includes a rotation operation unit 46 that is rotatably arranged, a rotation detection unit 42 that detects the rotation of the rotation operation unit 46, and a control unit 40 that outputs an operation signal to the control device 2 based on the detection result of the rotation detection unit 42. The rotation operation module 4 further includes a communication unit 41, a push button switch 43, a handle 47, and a housing 300. Here, the rotation operation module 4 has the rotation operation unit 46, the rotation detection unit 42, etc. as a user interface 30.

The housing 300 houses the control unit 40, the communication unit 41, the rotation detection unit 42, the push button switch 43, the rotation operation unit 46, and the handle 47. The rotation operation unit 46 and the handle 47 are held in the housing 300 in a state where they are exposed to the front surface of the housing 300.

As shown in FIG. 1, the housing 300 has a common configuration among the multiple types of operation modules 3, except for the operation surface 400 on the front side. The housing 300 is formed into a vertically long rectangular shape when viewed from the front.

As shown in FIG. 4, a connector CN2 that can be coupled to the connector CN1 of the control device 2 is provided on the rear surface of the housing 300. A pair of locking hooks 301 that can be coupled to a pair of grooves 202 provided on the control device 2 are provided on the left and right sides of the rear surface of the housing 300. In addition, four protrusions 302 that fit into four recesses 203 provided on the four corners of the front surface 201 of the control device 2 are provided on the four corners of the rear surface of the housing 300.

A handle 47 is disposed on the lower side of the operation surface 400 on the front side of the housing 300, and a rotation operation unit 46 is disposed on the upper side (see Figs. 1 and 3). The rotation operation unit 46 is formed in a cylindrical shape with a height smaller than its diameter, and is disposed on the operation surface 400 in a state in which it can be rotated in both directions. The handle 47 is formed in a horizontally long rectangular shape when viewed from the front. The handle 47 is supported, for example, at one end side in the left-right direction (e.g. the left side) in a state in which it can be rotated relative to the operation surface 400, and is disposed on the operation surface 400 in a state in which it can be pressed at the other end side in the left-right direction (e.g. the right side).

The communication unit 41 communicates with the wired communication unit 21 of the control device 2, for example, using the I2C communication method.

The rotation detection unit 42 includes a rotary encoder that outputs a two-phase (A-phase and B-phase) pulse train according to the rotation angle of the rotary operation unit 46. The rotary encoder is configured to output, for example, three pulses per rotation. The rotary encoder is also configured to output a two-phase pulse train having a phase difference of 1/4 period from each other according to the rotation of the rotary operation unit 46.

The push button switch 43 is a switch that performs a momentary operation. When the user pushes the handle 47 backwards, the handle 47 presses the push button of the push button switch 43, and the on/off state of the contact is reversed. For example, the push button switch 43 is off when the handle 47 is not being pressed, and turns on when the handle 47 is pressed.

The control unit 40 mainly comprises a computer system having one or more processors and a memory. The functions of the control unit 40 are realized by the processor of the computer system executing a program recorded in the memory of the computer system. The program may be recorded in the memory, or may be provided via a telecommunications line such as the Internet, or may be recorded on a non-transitory recording medium such as a memory card and provided.

The control unit 40 detects a change in the rotation angle (rotation position) of the rotary operation unit 46 based on a combination of the signal levels of the two-phase pulse train output from the rotary encoder. The control unit 40 calculates the rotation direction, rotation speed, and rotation amount per unit time of the rotary operation unit 46 based on the change in the rotation angle of the rotary operation unit 46. The control unit 40 determines whether the operation is to brighten or darken the dimming level of the lighting load, that is, the direction of change in the dimming level of the lighting load, based on the rotation direction of the rotary operation unit 46. The control unit 40 also determines the amount of change in the dimming level of the lighting load from the current dimming level based on the rotation direction, rotation speed, and rotation amount per unit time of the rotary operation unit 46. Then, the control unit 40 transmits an operation signal including dimming information indicating the direction and amount of change in the dimming level from the communication unit 41 to the control device 2. In other words, the control unit 40 calculates the amount of rotation and rotation speed of the rotary operation unit 46 based on the detection result of the rotation detection unit 42, and outputs an operation signal based on the calculation result of the amount of rotation and rotation speed to the power control unit 25. This allows the power control unit 25 to control the power supplied to the load 7 according to the direction, speed, and amount of rotation of the rotation operation unit 46 by the user, thereby adjusting the brightness of the lighting device, which is the load 7. In addition, the control unit 40 of the rotation operation module 3 calculates the amount of rotation and the rotation speed of the rotation operation unit 46 based on the detection result of the rotation detection unit 42, so the calculation processing load on the control device 2 side can be reduced.

When the handle 47 is pressed and the push button switch 43 is switched from off to on, the control unit 40 causes the communication unit 41 to transmit an operation signal including reversal information for reversing the on/off state of the load 7 to the control device 2. In other words, when the handle 47 is pressed while the load 7 is on and an operation signal including reversal information is transmitted from the rotary operation module 4 to the control device 2, the power control unit 25 of the control device 2 cuts off the power supply to the load 7 and turns off the load 7. On the other hand, when the handle 47 is pressed while the load 7 is off and an operation signal including reversal information is transmitted from the rotary operation module 4 to the control device 2, the power control unit 25 of the control device 2 starts supplying power to the load 7 and turns on the load 7 at the dimming level before the load 7 is turned off, for example. It is assumed that the dimming level before the load 7 is turned off is stored in the memory of the processing unit 20.

(2.2.2) Touch Operation Module The touch operation module 5 includes a touch sensor 52 that receives a touch operation by a user, and a control unit 50 that outputs an operation signal to the control device 2 based on the touch operation received by the touch sensor 52. The touch operation module 5 further includes a communication unit 51 and a housing 300. Here, the touch operation module 5 has, as the user interface 30, the touch sensor 52 that receives a touch operation by a user and the like.

The housing 300 houses the control unit 50, the communication unit 51, and the touch sensor 52. Note that the housing 300 of the touch operation module 5 has the same configuration as the housing 300 of the rotation operation module 4, except for the operation surface 500. Therefore, the same components are given the same reference numerals and their description is omitted.

The operation surface 500 on the front side of the housing 300 is formed flat, and a touch sensor 52 is provided on the operation surface 500 to detect touch operations by the user.

The communication unit 51 communicates with the wired communication unit 21 of the control device 2 using, for example, the I2C communication method.

The touch sensor 52 is, for example, a capacitive touch sensor, and detects the position touched by the user's body from a change in capacitance that occurs when a part of the user's body (for example, a finger) touches the operation surface 500. The touch sensor 52 can detect operations such as a touch operation or a swipe operation by the user from a change in the position of the operation surface 500 touched by the user's body.

The control unit 50 determines the direction and amount of change for changing the dimming level of the lighting load, which is the load 7, based on the touch operation detected by the touch sensor 52, and transmits an operation signal including dimming information indicating the direction and amount of change in the dimming level from the communication unit 51 to the control device 2.

For example, when the touch sensor 52 detects an upward swipe operation, the control unit 50 generates an operation signal including dimming information for increasing the dimming level of the lighting load by a predetermined dimming level, and transmits this operation signal to the control device 2. Note that the control unit 50 may determine the dimming information such that the faster the finger moves in the swipe operation, or the greater the amount of finger movement in the swipe operation, the greater the amount of change in the dimming level.

When the touch sensor 52 detects a downward swipe operation, the control unit 50 generates an operation signal including dimming information for dimming the dimming level of the lighting load by a predetermined dimming level, and transmits this operation signal to the control device 2. Note that the control unit 50 may determine the dimming information such that the faster the finger moves in the swipe operation, or the greater the amount of finger movement in the swipe operation, the greater the amount of change in the dimming level.

When the touch sensor 52 detects a tap operation, the control unit 50 causes the communication unit 51 to transmit an operation signal including inversion information for inverting the on/off state of the load 7 to the control device 2. When a tap operation is performed while the load 7 is on and an operation signal including inversion information is transmitted from the touch operation module 5 to the control device 2, the power control unit 25 of the control device 2 cuts off the power supply to the load 7 and turns off the load 7. On the other hand, when a tap operation is performed while the load 7 is off and an operation signal including inversion information is transmitted from the touch operation module 5 to the control device 2, the power control unit 25 of the control device 2 starts supplying power to the load 7 and turns on the load 7 at the dimming level before the load 7 is turned off, for example. It is assumed that the dimming level before the load 7 is turned off is stored in the memory of the processing unit 20.

(3) Operation Description The control device 2 can be connected to any of a plurality of types of operation modules 3. In this embodiment, a rotation operation module 4 and a touch operation module 5 are provided as the plurality of types of operation modules 3.

The control device 2 is used with either the rotation operation module 4 or the touch operation module 5 connected.

First, we will explain how the control device 2 operates when combined with the rotation operation module 4.

The control device 2 is fixed to a wall or the like using a mounting frame 60, and a series circuit of the load 7 and AC power source 6 is connected to the load connection part 27 of the control device 2 via an electric wire W1.

The user holds the rotation operation module 4 in his/her hand, brings it close to the front surface 201 of the control device 2, and connects the connector CN2 of the rotation operation module 4 to the connector CN1 of the control device 2. At this time, the protrusions 302 on the four corners of the rear surface of the rotation operation module 4 fit into the recesses 203 on the four corners of the front surface 201 of the control device 2, thereby positioning the rotation operation module 4. In addition, the locking hooks 301 of the rotation operation module 4 fit into the grooves 202 of the control device 2, thereby preventing the rotation operation module 4 from coming loose.

When the connector CN2 of the rotation operation module 4 is connected to the connector CN1 of the control device 2, power is supplied from the control device 2 to the rotation operation module 4, and the rotation operation module 4 starts operating. Also, I2C communication is performed between the wired communication unit 21 of the control device 2 and the communication unit 41 of the rotation operation module 4. Here, type information indicating the types of multiple types of operation modules 3 that can be connected to the control device 2 is registered in the control device 2. When I2C communication is started between the control device 2 and the rotation operation module 4, the wired communication unit 21 of the control device 2 acquires the type information transmitted from the rotation operation module 4, and the power control unit 25 of the control device 2 determines the type of the currently connected operation module 3 based on the type information acquired by the wired communication unit 21. That is, the power control unit 25 determines the type of the operation module 3 connected to the connector CN1 based on the type information transmitted from the operation module 3 connected to the connector CN1 among the multiple types of operation modules 3. As a result, even if the format of the operation signal is different among the multiple types of operation modules 3, for example, the power control unit 25 can control the supply power based on the operation signal corresponding to the type of the operation module 3.

When the rotary operation module 4 is connected to the control device 2 and the user rotates the rotary operation unit 46, for example, clockwise when viewed from the front, the control unit 40 generates dimming information that brightens the dimming level of the lighting load by an amount of change corresponding to the rotation speed and amount of rotation of the rotary operation unit 46, and transmits an operation signal including this dimming information from the communication unit 41 to the control device 2. When the wired communication unit 21 of the control device 2 receives the operation signal from the rotary operation module 4, the power control unit 25 outputs a control command to the power control circuit 22 to change the power supply to the load 7 based on the dimming information included in the operation signal so that the load 7 is turned on at a dimming level brighter than the current dimming level by the amount of change represented by the dimming information. The power control circuit 22 changes the power supply to the load 7 in response to the control command, and turns on the load 7 at a dimming level brighter than the current dimming level by the amount of change represented by the dimming information.

When the user rotates the rotary operation unit 46, for example, counterclockwise when viewed from the front, the control unit 40 generates dimming information for darkening the dimming level of the lighting load by an amount of change corresponding to the rotation speed and amount of rotation of the rotary operation unit 46, and causes the communication unit 41 to transmit an operation signal including this dimming information to the control device 2. When the wired communication unit 21 of the control device 2 receives an operation signal from the rotary operation module 4, the power control unit 25 outputs a control command to the power control circuit 22 to change the power supplied to the load 7 based on the dimming information included in the operation signal so that the load 7 is turned on at a dimming level that is darker than the current dimming level by the amount of change represented by the dimming information. The power control circuit 22 changes the power supplied to the load 7 in response to the control command, and turns on the load 7 at a dimming level that is darker than the current dimming level by the amount of change represented by the dimming information.

When the user pushes the handle 47, the control unit 40 generates inversion information for inverting the on/off state of the lighting load, and causes the communication unit 41 to transmit an operation signal including this inversion information to the control device 2. When the wired communication unit 21 of the control device 2 receives an operation signal from the rotation operation module 4, the power control unit 25 turns off the load 7 by stopping the power supply to the load 7 if it is currently on, based on the inversion information included in the operation signal, or turns on the load 7 by starting the power supply to the load 7 if it is currently off.

Next, the operation of the control device 2 in combination with the touch operation module 5 will be described. Note that the method for attaching the touch operation module 5 to the control device 2 is similar to the method for attaching the rotation operation module 4, so its description will be omitted. In addition, the power control unit 25 of the control device 2 determines that the operation module 3 currently connected to the connector CN1 is the touch operation module 5 based on the type information transmitted from the touch operation module 5.

When the touch operation module 5 is connected to the control device 2 and the user performs a swipe operation by tracing the operation surface 500 of the touch operation module 5 from bottom to top with a finger, the touch sensor 52 outputs the detection result of the swipe operation to the control unit 50. The control unit 50 generates dimming information for brightening the dimming level of the lighting load by a predetermined change amount based on the detection result of the touch sensor 52, and causes the communication unit 51 to transmit an operation signal including this dimming information to the control device 2. When the wired communication unit 21 of the control device 2 receives the operation signal from the touch operation module 5, the power control unit 25 outputs a control command to the power control circuit 22 to change the power supply to the load 7 based on the dimming information included in the operation signal so that the load 7 is turned on at a dimming level brighter than the current dimming level by the change amount represented by the dimming information. The power control circuit 22 changes the power supply to the load 7 in response to the control command, and turns on the load 7 at a dimming level brighter than the current dimming level by the change amount represented by the dimming information.

When a user performs a swipe operation by tracing the operation surface 500 of the touch operation module 5 from top to bottom with a finger, the touch sensor 52 outputs the detection result of the swipe operation to the control unit 50. The control unit 50 generates dimming information for darkening the dimming level of the lighting load by a predetermined change amount based on the detection result of the touch sensor 52, and transmits an operation signal including this dimming information from the communication unit 51 to the control device 2. When the wired communication unit 21 of the control device 2 receives the operation signal from the touch operation module 5, the power control unit 25 outputs a control command to the power control circuit 22 to change the power supply to the load 7 based on the dimming information included in the operation signal so that the load 7 is turned on at a dimming level that is darker than the current dimming level by the change amount represented by the dimming information. The power control circuit 22 changes the power supply to the load 7 in response to the control command, and turns on the load 7 at a dimming level that is darker than the current dimming level by the change amount represented by the dimming information.

When the user performs a tap operation by tapping the operation surface 500 once with a finger, the touch sensor 52 outputs the detection result of the tap operation to the control unit 50. The control unit 50 generates inversion information for inverting the on/off state of the lighting load based on the detection result of the touch sensor 52, and causes the communication unit 51 to transmit an operation signal including this inversion information to the control device 2. When the wired communication unit 21 of the control device 2 receives an operation signal from the touch operation module 5, the power control unit 25 turns off the load 7 by stopping the power supply to the load 7 if the load 7 is currently on, based on the inversion information included in the operation signal, or turns on the load 7 by starting the power supply to the load 7 if the load 7 is currently off.

The control device 2 of this embodiment can be connected to any of a plurality of types of operation modules 3, so that an operation module 3 having a desired operation method can be connected to the control device 2 and used from among the plurality of types of operation modules 3. Therefore, even if the operation method of the operation module 3 is changed, there is no need to change the control device 2, which has the advantage that it is easy to accommodate changes in the operation method.

(4) Modifications The above embodiment is merely one of various embodiments of the present disclosure. The above embodiment can be modified in various ways depending on the design, etc., as long as the object of the present disclosure can be achieved.

Below, we will list some variations of the above embodiment. The variations described below can be applied in appropriate combinations.

The control device 2 and the operation module 3 in the present disclosure include a computer system. The computer system is mainly composed of a processor and a memory as hardware. The functions of the control device 2 and the operation module 3 in the present disclosure are realized by the processor executing a program recorded in the memory of the computer system. The program may be pre-recorded in the memory of the computer system, may be provided through an electric communication line, or may be recorded and provided in a non-transitory recording medium such as a memory card, an optical disk, or a hard disk drive that can be read by the computer system. The processor of the computer system is composed of one or more electronic circuits including a semiconductor integrated circuit (IC) or a large-scale integrated circuit (LSI). The integrated circuits such as IC or LSI referred to here are called different names depending on the degree of integration, and include integrated circuits called system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). Furthermore, a field-programmable gate array (FPGA) that is programmed after the manufacture of the LSI, or a logic device that can reconfigure the connection relationship inside the LSI or reconfigure the circuit partition inside the LSI, can also be adopted as a processor. The multiple electronic circuits may be integrated into one chip, or may be distributed across multiple chips. The multiple chips may be integrated into one device, or may be distributed across multiple devices. The computer system referred to here includes a microcontroller having one or more processors and one or more memories. Therefore, the microcontroller is also composed of one or more electronic circuits including a semiconductor integrated circuit or a large-scale integrated circuit.

The shapes of the rotation operation module 4 and the touch operation module 5 described in the above embodiment are merely examples and can be modified as appropriate.

The control system 1 of this embodiment includes a rotation operation module 4 and a touch operation module 5 as the operation module 3, but the operation module 3 is not limited to these operation modules. The operation module 3 may be, for example, a slide operation module that accepts a slide operation in which the user slides the operation unit as an operation input. The operation module 3 may also be a remote operation module that receives, as an operation input, a signal transmitted from an infrared remote control device when the user operates the infrared remote control device. The operation module 3 may also be a voice operation module that accepts, as an operation input, voice information obtained by using a voice recognition engine to recognize the voice of the user speaking the operation content.

The load 7 that is the object of control by the control device 2 in this embodiment is, for example, a lighting fixture, but it may also be a ventilation fan, a blower, etc. other than a lighting fixture.

(summary)
The above-described embodiments and the like disclose the following aspects.

The control device (2) of the first aspect includes a load connection unit (27), a connector (CN1), and a power control unit (25). A load (7) can be connected to the load connection unit (27). Any of a plurality of types of operation modules (3) can be connected to the connector (CN1). The plurality of types of operation modules (3) are operated by a user in different ways, and output an operation signal in response to the user's operation. The power control unit (25) controls the power supply to the load (7) connected to the load connection unit (27) based on an operation signal in response to the user's operation input from an operation module (3) connected to the connector (CN1) among the plurality of types of operation modules (3).

According to this aspect, the control device (2) is compatible with multiple types of operation modules (3), and an operation module (3) having a desired operation method can be connected to the control device (2) and used. Therefore, when changing the operation method of the operation module (3), it is possible to change only the operation module (3), so that it is easier to change the operation method compared to replacing both the operation module (3) and the control device (2).

In the control device (2) of the second aspect, in the first aspect, the multiple types of operation modules (3) include a rotation operation module (4). The rotation operation module (4) includes a rotation operation unit (46) that is rotatably arranged, a rotation detection unit (42) that detects the rotation of the rotation operation unit (46), and a control unit (40) that outputs an operation signal to the control device based on the detection result of the rotation detection unit (42).

According to this embodiment, by connecting the rotation operation module (4) to the control device (2), it is possible to change the power supplied to the load (7) according to the rotation operation of the rotation operation unit (46).

In the control device (2) of the third aspect, in the second aspect, the control unit (40) calculates the amount of rotation and the rotation speed of the rotation operation unit (46) based on the detection result of the rotation detection unit (42), and outputs an operation signal based on the calculation result of the amount of rotation and the rotation speed to the power control unit (25).

According to this aspect, the control unit (40) of the rotation operation module (4) calculates the amount of rotation and the rotation speed of the rotation operation unit (46) and transmits an operation signal based on the calculation results of the amount of rotation and the rotation speed to the control device (2), thereby reducing the load of calculation processing on the control device (2).

In the fourth aspect of the control device (2) in any one of the first to third aspects, the multiple types of operation modules (3) include a touch operation module (5). The touch operation module (5) includes a touch sensor (52) that receives a touch operation by a user, and a control unit (50) that outputs an operation signal to the control device (2) based on the touch operation received by the touch sensor (52).

According to this embodiment, by connecting the touch operation module (5) to the control device (2), it is possible to change the power supplied to the load (7) in response to the touch operation.

In the control device (2) of the fifth aspect, in any one of the first to fourth aspects, the load (7) is a lighting load. The power control unit (25) controls the power supplied to the lighting load so as to turn on the lighting load at a dimming level based on the operation signal.

According to this embodiment, the dimming level of the lighting load can be changed according to the operation input received by the operation module (3).

The control device (2) of the sixth aspect further includes a setting operation unit (23) for inputting setting information related to a specified setting task in any of the first to fifth aspects.

According to this aspect, the setting operation unit (23) provided in the control device (2) can be used to perform setting operations on the control device (2).

The seventh aspect of the control device (2) is the sixth aspect, and further includes a wireless communication unit (24) for wirelessly communicating with an external communication device (8). The predetermined setting operation includes a registration operation for registering a communication device (8) that is permitted to wirelessly communicate with the wireless communication unit (24).

According to this aspect, a setting operation unit (23) provided in the control device (2) can be used to perform a registration operation to register a communication device (8) that is permitted to communicate wirelessly with the wireless communication unit (24).

In the control device (2) of the eighth aspect, in the sixth aspect, the predetermined setting operation includes the operation of setting at least one of the upper and lower limits of the power supplied to the load (7).

According to this aspect, the setting operation unit (23) provided in the control device (2) can be used to set at least one of the upper and lower limits of the power supplied to the load (7).

The control device (2) of the ninth aspect is the sixth aspect, and further includes a housing (200) that houses a load connection unit (27), a connector (CN1), a power control unit (25), and a setting operation unit (23). The setting operation unit (23) is provided on the surface of the housing (200) on which the connector (CN1) is provided.

According to this embodiment, by removing the operation module (3) from the control device (2), the setting operation unit (23) is exposed, and setting operations can be performed using the setting operation unit (23).

In the control device (2) of the tenth aspect, in any of the first to ninth aspects, the power control unit (25) determines the type of the operation module (3) connected to the connector (CN1) based on type information transmitted from the operation module (3) connected to the connector (CN1) among multiple types of operation modules (3).

According to this embodiment, regardless of which of the multiple types of operation modules (3) is connected to the connector (CN1), the power control unit (25) can control the supply power based on an operation signal corresponding to the type of operation module (3).

The control system (1) of the eleventh aspect includes a control device (2) of any one of the first to tenth aspects and an operation module (3) connected to the connector (CN1) of the control device (2).

According to this aspect, the control device (2) is compatible with multiple types of operation modules (3), and an operation module (3) having a desired operation method can be connected to the control device (2) and used. Therefore, when changing the operation method of the operation module (3), it is possible to change only the operation module (3), so that it is easier to change the operation method compared to replacing both the operation module (3) and the control device (2).

In the twelfth aspect of the control system (1), in the eleventh aspect, the operation module (3) includes a rotation operation module (4). The rotation operation module (4) includes a rotation operation unit (46) that is rotatably arranged, a rotation detection unit (42) that detects the rotation of the rotation operation unit (46), and a control unit (40) that outputs an operation signal to the power control unit (25) based on the detection result of the rotation detection unit (42).

According to this embodiment, by connecting the rotation operation module (4) to the control device (2), it is possible to change the power supplied to the load (7) according to the rotation operation of the rotation operation unit (46).

In the control system (1) of the thirteenth aspect, in the eleventh or twelfth aspect, the operation module (3) includes a touch operation module (5). The touch operation module (5) includes a touch sensor (52) that receives a touch operation by a user, and a control unit (50) that outputs an operation signal to the power control unit (25) based on the touch operation received by the touch sensor (52).

According to this embodiment, by connecting the touch operation module (5) to the control device (2), it is possible to change the power supplied to the load (7) in response to the touch operation.

The configurations according to the second to tenth aspects are not essential for the control device (2) and may be omitted as appropriate. The configurations according to the twelfth and thirteenth aspects are not essential for the control system (1) and may be omitted as appropriate.

REFERENCE SIGNS LIST 1 control system 2 control device 3 operation module 4 rotation operation module 5 touch operation module 7 load 8 communication device 23 setting operation section 24 wireless communication section 25 power control section 27 load connection section 40, 50 control section 42 rotation detection section 46 rotation operation section 52 touch sensor 200 housing CN1 connector

Claims (13)

a load connection portion to which a load can be connected;
a connector to which any of a plurality of types of operation modules, each of which has a different operation method by a user and outputs an operation signal in response to the user's operation, can be connected;
and a power control unit that controls power supplied to the load connected to the load connection unit based on an operation signal corresponding to the user's operation input from an operation module connected to the connector among the plurality of types of operation modules.
Control device. The plurality of types of operation modules include a rotation operation module,
The rotation operation module includes:
A rotation operation unit that is rotatably arranged;
A rotation detection unit that detects rotation of the rotary operation unit;
A control unit that outputs the operation signal to the control device based on a detection result of the rotation detection unit.
The control device according to claim 1 . The control unit calculates a rotation amount and a rotation speed of the rotary operation unit based on a detection result of the rotation detection unit, and outputs the operation signal based on a calculation result of the rotation amount and the rotation speed to the power control unit.
The control device according to claim 2. The plurality of types of operation modules include a touch operation module;
The touch operation module includes:
a touch sensor that receives a touch operation by the user;
A control unit that outputs the operation signal to the control device based on a touch operation received by the touch sensor.
The control device according to claim 1 . the load is a lighting load;
The power control unit controls power supplied to the lighting load so as to turn on the lighting load at a dimming level based on the operation signal.
The control device according to claim 1 . Further comprising a setting operation unit for inputting setting information related to a predetermined setting operation.
The control device according to claim 1 . Further comprising a wireless communication unit for wirelessly communicating with an external communication device;
The predetermined setting operation includes a registration operation of registering the communication device that is permitted to wirelessly communicate with the wireless communication unit.
The control device according to claim 6. The predetermined setting operation includes an operation of setting at least one of an upper limit and a lower limit of the power supplied to the load.
The control device according to claim 6. a housing that houses the load connection unit, the connector, the power control unit, and the setting operation unit;
The setting operation unit is provided on a surface of the housing on which the connector is provided.
The control device according to claim 6. The power control unit determines a type of the operation module connected to the connector based on type information transmitted from an operation module connected to the connector among the plurality of types of operation modules.
The control device according to claim 1 . A control device according to any one of claims 1 to 10, and an operation module connected to the connector of the control device.
Control system. the manipulation module includes a rotation manipulation module;
The rotation operation module includes:
A rotation operation unit that is rotatably arranged;
A rotation detection unit that detects rotation of the rotary operation unit;
A control unit that outputs the operation signal to the power control unit based on a detection result of the rotation detection unit.
12. The control system of claim 11. The operation module includes a touch operation module;
The touch operation module includes:
a touch sensor that receives a touch operation by the user;
A control unit that outputs the operation signal to the power control unit based on a touch operation received by the touch sensor.
12. The control system of claim 11.

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