JP2878307B2 - Multi-point dimmer - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-position dimming device in which dimming control of the same illumination load is performed by dimming control switches arranged at a plurality of locations.

[Prior Art] Conventionally, as a multi-point dimmer, as shown in FIG.
The lighting load L is controlled by the central control panel 30 via the light control device 31, and the light control level of the lighting load L is set by the light control switch (or the light control volume) 32. Therefore, a signal line 33 for transmitting a dimming control signal is individually wired from the central control panel 30 to each dimming device 31.

[Problems to be Solved by the Invention] However, in the above-described conventional example, in order to control the dimming of the same lighting load L from a plurality of locations, a dimming control operation panel (not shown) separately arranged is used. Therefore, a signal line for transmitting a dimming control signal must be wired to the dimming device 31, which causes a problem that the wiring is troublesome and the construction is difficult. Although data transmission using time division multiplex transmission is conceivable, there is no conventional time division multiplex transmission system that enables multi-point dimming.

The present invention has been made in view of the above points, and an object of the present invention is to provide a multi-point light control device that is simple in wiring and easy to construct.

[Means for Solving the Problems] A multi-point dimming device according to the present invention includes: an operation terminal for monitoring a dimming control switch; a control terminal for dimming control of a lighting load; A master unit that accesses and time-division multiplexes data is connected by a signal line, and the master unit accesses the operation terminal to return monitoring data indicating the state of the dimming control switch and the monitoring data returned. Forming dimming control data for dimming the corresponding lighting load based on the above, transmitting the dimming control data by accessing a predetermined control terminal from the master unit, and transmitting the same dimming control data to a plurality of operation terminals. , The same lighting load is controlled by a plurality of dimming control switches.

According to a second aspect of the present invention, a dimming control switch is formed by an up switch for increasing the illuminance of a lighting load and a down switch for decreasing the illuminance, and a change in the state of both switches is monitored as monitoring data from the operation terminal. By returning to the control terminal, and transmitting the dimming control data for starting or stopping the step dimming based on the monitoring data to the control terminal, so that the illuminance is stepped up or down while the up switch or the down switch is kept pressed. The dimming control of the lighting load is performed so as to step down.

Still further, the operation terminal for displaying the dimming state and the on / off state of the lighting load is provided in the operation terminal.

Furthermore, the control terminal is provided with a return means for returning monitor data indicating the operation state of the lighting load to the master unit.

Still further, according to a fifth aspect of the present invention, a group dimming control switch for dimming control of a plurality of lighting loads is provided on an operation terminal, and a plurality of lighting loads are controlled by operating the group dimming control switch. The dimming control data is transmitted to the control terminal device.

Still further, according to the sixth aspect, a function setting switch for switching a terminal device function is provided in the terminal device.

Still further, according to the seventh aspect, a non-volatile memory for storing function setting data and unique address data is provided in a terminal device, and data in the non-volatile memory can be freely rewritten by an optical wireless signal.

[Operation] The present invention is configured as described above. The operation terminal device for monitoring the dimming control switch, the control terminal device for dimming control of the lighting load, and the above-mentioned terminal devices are accessed. In a dimming control device, which is connected to a master unit for performing time-division multiplex transmission of data by a signal line and transmits monitoring data indicating a state of a dimming control switch and dimming control data for dimming control of a lighting load. The same lighting load is controlled by a plurality of dimming control switches by setting the same unique address to a plurality of operation terminals, and the same lighting load is controlled from a plurality of locations. In addition, the wiring is simple and the construction can be easily performed.

In addition, by starting or stopping the step dimming based on the state change of the up switch for increasing the illuminance and the down switch for decreasing the illuminance, the illuminance is stepped up or down while the up switch or the down switch is kept pressed. If the lighting load is dimmed and controlled, the dimming operation can be performed easily and the data transmission efficiency can be increased.

Furthermore, by providing an operation display unit for displaying the dimming state and the on / off state of the lighting load in the operation terminal, it is convenient when dimming control of a remote lighting load is performed.

Furthermore, by providing return means for returning monitoring data indicating the operating state of the lighting load to the master unit, the actual operating state of the lighting load can be accurately grasped.

Furthermore, a group dimming control switch for dimming and controlling a plurality of lighting loads is provided on the operation terminal, and a plurality of control terminals for controlling the lighting load by operating the group dimming control switch are provided. By transmitting the light control data, it is possible to easily control a plurality of lighting loads.

Furthermore, by providing a function setting switch for switching the terminal device function in the terminal device, a versatile system can be configured.

Still further, according to the seventh aspect, a nonvolatile memory for storing function setting data and unique address data is provided in a terminal device, and is rewritable by an optical wireless signal, so that a system change or correction of a setting error can be easily performed. It can be carried out.

[Embodiment] FIGS. 1 to 7 show an embodiment of the present invention, wherein a dimming control switch (up switch SWa, down switch SW) is shown.
b, operation terminal 2 for monitoring the blinking control switch SWc)
And a control terminal 3 for controlling the dimming of the lighting load L and a master unit 1 for accessing each of the terminals 2 and 3 and performing time-division multiplexing and transmitting data through a signal line 4. From the operating terminal 2 to return monitoring data indicating the state of the dimming control switch, and form dimming control data for dimming control of the corresponding lighting load L based on the returned monitoring data; A predetermined control terminal 3 is accessed from the base unit 1 to transmit the dimming control data, and the same unique address is set in a plurality of operation terminals 2 so that the same dimming control switch can be used. Is controlled. Here, the transmission signal Vs transmitted from the base unit 1 to the signal line 4 is, as shown in FIG.
A start pulse signal ST indicating the start of signal transmission, a mode data signal MD indicating a signal mode, and an address data signal A transmitting 8-bit address data for calling the terminals 2 and 3.
D, a control data signal CD for transmitting control data for controlling the lighting load L, a checksum data signal CS and a terminal 2,
This is a bipolar (± 24 V) time-division multiplex signal composed of a return wait signal WT for setting a return period from 3, and data is transmitted by pulse width modulation. Each terminal
In steps 2 and 3, when the address data of the transmission signal Vs received via the signal line 4 matches the own address data, the control data of the transmission signal Vs is taken in.
The monitoring data signal is returned as a current mode signal (a signal transmitted by short-circuiting the signal lines 4 via a suitable low impedance) in synchronization with the return signal WT of the transmission signal Vs. The master unit 1 also has a mode data signal.
When a dummy signal transmitting means for constantly transmitting a dummy transmission signal in which the MD is set to the dummy mode and an interrupt signal Vi as shown in FIG. 2B returned from one of the operation terminals 2 are received, There is provided an interrupt processing means for detecting the interrupt generation terminal 2 and accessing the terminal 2 to return the monitoring data. In the base unit 1, control data to be transmitted to the control terminal unit 3 for controlling the corresponding lighting load L is created based on the monitoring data returned from the operation terminal unit 2 to the base unit 1 as described above. In addition, the control data is time-division multiplexed and transmitted to the control terminal 3 via the signal line 4 to control the lighting load L. Here, the operation terminal unit 2, the calculation processing circuit 10 consisting of CPU, and the signal transceiver 11 for transmitting and receiving a transmission signal Vs and return signal V _B, up switch SWa, down switch SWb, set flashing switch SWc and function Switch SWd
When any one of the switches SWa to SWc is pressed, an interrupt request signal Vi is sent out, and when accessed from the master unit 1, the switches SWa to SW
Wc is adapted to return to the main unit 1 the monitoring data showing that it is operated as a return signal V _B of the current mode. Further, the control terminal 3 is provided with an arithmetic processing circuit 20 comprising a CPU.
And a signal transmission / reception circuit 21, a zero-cross point detection unit 22, a phase control unit 23 using a triac, and an ON / OFF control and a control monitoring unit 24 for monitoring an operation state. The dimming control data transmitted from the master unit 1 controls the dimming of the lighting load L whose phase of the triac is controlled, and controls the flickering of the lighting load L by a relay contact.

Further, in the embodiment, a dimming control switch is formed by an up switch SWa for increasing the illuminance of the lighting load L and a down switch SWb for decreasing the illuminance, and the state change of both switches SWa and SWb is monitored. By pressing the up switch or the down switch by returning control data to the control terminal 2 to start or stop step dimming based on the monitoring data, the control data is returned from the operation terminal 2 to the master device 1 as data. The lighting load L is controlled so as to step up or step down the illuminance at regular intervals (for example, 0.5 sec) during the continuation. The operation terminal 2 is also provided with a blinking switch SWc for turning on and off the lighting load L, and the lighting load L can be turned on and off by the blinking switch SWc.

Furthermore, the operation terminal device 2 is provided with an operation display section DP composed of a bar graph using a light emitting diode for displaying the dimming state and the on / off state of the lighting load. The operation state of the lighting load L can be grasped even in the case where the light control state is not visible due to being placed away from the lighting load L. In addition, since the operation state (dimming level, blinking state) of the lighting load L is displayed in a bar graph, the dimming level (100% lighting, 80% lighting, 50% lighting ... off) can be intuitively grasped. become. Furthermore, in the embodiment, the control terminal 3 is provided with a return unit that returns monitoring data indicating the operation state of the lighting load L to the master unit 1. The status is transmitted to the operation terminal 2 via the master unit 1 and the operation display unit DP
The operation state of the lighting load L can be accurately grasped on the operation side by being displayed. In addition,
SW ₀ is an address setting switch for setting a unique address.

A group dimming control switch for dimming control of a plurality of lighting loads L collectively includes the dimming control switches SWa and SW.
The group dimming control switch SWa,
The dimming control data is transmitted to a plurality of control terminals 3 that control the lighting load L by operating SWb. Note that the group control data is stored in the data memory provided in the base unit 1, and when the operation terminal 2 returns monitoring data indicating that the group dimming control switches SWa and SWb have been operated. The group control data indicating which control terminal 3 transmits the dimming control data (which lighting load L is controlled) corresponding to the operation terminal 2 is read out from the data memory, and a plurality of lights are read. The dimming control of the load L is performed collectively at the same dimming level. It goes without saying that the blinking of the lighting load L is also controlled collectively by operating the blinking switch SWc.

In addition, the above function setting switch for switching terminal functions
SWd is provided on the back of the terminal device 2. The terminal function is switched by the function setting switch SWd. In addition to the group control function, a normal dimming control and blinking control function, a 30-second delay light-off function It is possible to realize a 5 minute delay lighting function, a 30 second temporary lighting function, a 5 minute temporary lighting function, and the like.

Further, the operation display of the lighting load L by the operation display portion DP is as follows.
In the display example shown in FIG. 8, the dimming level is displayed as a bar graph using light emitting diodes, and the dimming level is displayed in a bar graph using the remaining elements for displaying the light off. Is off, FIG. 8 (b) is 10% lighted, FIG. 8 (b) is 20% lighted, FIG. 8 (c) is 50% lighted, FIG. 8 (d) is 100% lighted, FIG. FIG. 7E shows an operation display state at the time of 10% lighting and delayed light-out operation.

FIG. 9 shows still another embodiment, in which a non-volatile memory M for storing function setting data and unique address data is provided in the terminal device 2, and is provided by an optical wireless signal transmitted from the data setting device 17. The data in the nonvolatile memory M can be freely rewritten. In the figure, 15a is a light receiving unit for receiving the optical wireless signal from the data setting unit 17, 15
b denotes a light emitting unit for transmitting an optical wireless signal to the data setting unit 17, and 16 denotes a CPU for controlling data transmission / reception with the data setting unit 17 and rewriting data in the data memory M.
Sub-processing circuit.

[Effects of the Invention] The present invention is configured as described above, and has access to the operation terminal for monitoring the dimming control switch, the control terminal for dimming control of the lighting load, and the terminals. Dimming control device connected to a master unit for time-division multiplexing data transmission by a signal line, and transmitting monitoring data indicating the state of a dimming control switch and dimming control data for dimming control of a lighting load. , The same lighting load is controlled by a plurality of dimming control switches by setting the same unique address to a plurality of operation terminals, and the same lighting load is dimmed from a plurality of locations. Thus, there is an effect that the wiring can be controlled easily and the construction can be easily performed.

In addition, by starting or stopping the step dimming based on the state change of the up switch for increasing the illuminance and the down switch for decreasing the illuminance, the illuminance is stepped up or down while the up switch or the down switch is kept pressed. If the lighting load is dimmed in such a manner, the dimming operation can be easily performed and the data transmission efficiency can be improved.

Furthermore, by providing an operation display unit for displaying the dimming state and the on / off state of the lighting load in the operation terminal, it is convenient when dimming control of a remote lighting load is performed.

Furthermore, by providing the control terminal with a return means for changing the monitoring data indicating the operating state of the lighting load to the master unit, there is an effect that the actual operating state of the lighting load can be accurately grasped.

Furthermore, a group dimming control switch for dimming control of a plurality of lighting loads is provided on the operating terminal, and a dimming control switch for controlling a plurality of lighting loads by operating the group dimming control switch is provided. By transmitting the light control data, there is an effect that a plurality of lighting loads can be easily controlled.

Furthermore, by providing a function setting switch for switching the terminal device function in the terminal device, there is an effect that a versatile system can be configured.

Still further, according to the seventh aspect, a nonvolatile memory for storing function setting data and unique address data is provided in a terminal device, and is rewritable by an optical wireless signal, so that a system change or correction of a setting error can be easily performed. There is an effect that can be performed.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of one embodiment of the present invention, FIG. 2 is an explanatory diagram of the operation of the above, FIG.
FIG. 5 is a perspective view of an essential part of the embodiment, FIG. 5 is a perspective view of an essential part of another embodiment, FIG. 6 is a block circuit diagram of the embodiment, FIG. 7 is a perspective view of an essential part of the embodiment, and FIG. FIG. 9 is an operation explanatory view, FIG. 9 is a main part block circuit diagram of still another embodiment, and FIG. 10 is a schematic configuration diagram of a conventional example. 1 is a master terminal, 2 is an operation terminal, 3 is a control terminal, 4 is a signal line, SWa and SWb are switches, DP is an operation display unit, L is a lighting load, and SWd is a function setting switch.

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁶ , DB name) H05B 37/02

Claims (7)

(57) [Claims] An operation terminal for monitoring a dimming operation switch, a control terminal for dimming control of a lighting load, and a master unit for accessing the respective terminals and time-division multiplex-transmitting data. Dimming that connects with the signal line, accesses the operation terminal from the master unit, returns monitoring data indicating the state of the dimming control switch, and dims the corresponding lighting load based on the returned monitoring data. A plurality of dimming control switches are formed by forming control data, transmitting a predetermined dimming control data by accessing a predetermined controlling terminal from the master unit, and setting the same unique address to a plurality of operating terminals. Wherein the same lighting load is controlled by the multi-point light control device. 2. A dimming control switch is formed by an up switch for increasing the illuminance of a lighting load and a down switch for decreasing the illuminance, and a change in the state of both switches is returned as monitoring data from the operation terminal to the master unit. By transmitting control data for starting or stopping the step dimming to the control terminal based on the monitoring data, the illumination can be stepped up or down while the up switch or the down switch is kept pressed. The dimming device according to claim 1, wherein the load is dimmed. 3. The multi-point light control device according to claim 1, wherein an operation display unit for displaying a light control state and an on / off state of the lighting load is provided in the operation terminal. 4. The multi-point dimming device according to claim 1, wherein return means for returning monitoring data indicating an operation state of the lighting load to the master unit is provided in the control terminal. 5. A plurality of control terminals for providing a group dimming control switch for dimming control of a plurality of lighting loads collectively on an operation terminal, and controlling a lighting load by operating the group dimming control switch. 2. The multi-point light control device according to claim 1, wherein the light control data is transmitted to the multi-point light control device. 6. The multi-point light control device according to claim 1, wherein a function setting switch for switching the terminal device function is provided in the terminal device. 7. The multi-point dimming control according to claim 1, wherein a non-volatile memory for storing function setting data and unique address data is provided in the terminal device, and data in the non-volatile memory can be freely rewritten by an optical wireless signal. apparatus.