JP6561221B2 - Control device, switch device, adapter device, socket device and load device using the same - Google Patents

Description

The present invention relates to a control device that easily realizes various energization control of loads such as a lighting device and a ventilation fan device that cannot be realized by a simple switch, and a switch device, an adapter device, a socket device, and a load device using the control device.

For example, in order to realize a function that operates only for a certain period of time by operating the switch, it is necessary to use a momentary switch that is not electrically fixed. This is because it is electrically and structurally difficult to add functions other than the original switching operation, including single-pole single-throw, 3-way, and 4-way switches.

As high-function control for loads such as lighting and ventilation fans, a fixed time operation or a delayed stop function is known. On the other hand, there is a need for more advanced control such as periodic operation control, sensor operation control, power control, and continuous operation control.

Generally, in order to give such high-function control, it is difficult to realize it by using an existing energization facility, and a fundamental change work of the energization facility is required, and the cost is increased.

Japanese Patent Laid-Open No. 07-240127

Panasonic Electric Works product catalog (Products listed, WN5275, WN5276, WN5294, WTC5383W.)

One of the objects of the present invention is a fixed time operation control, delayed stop control, periodic operation control, sensor-based operation control, power control, continuous operation control, etc. that cannot be realized only by a switch connected to a load. It is an object of the present invention to provide a control device capable of easily and inexpensively implementing various load energization controls, and a switch device, an adapter device, a socket device, and a load device using the control device.

A control device according to a first aspect of the present invention generates a control signal that operates a relay connected to a circuit that supplies power from a power source to a load so that energization of the load is controlled. And a controller.

A control device according to a second aspect of the present invention includes a relay connected to a circuit that supplies power from a power source to a load so that energization to the load is controlled, and an operation of a switch connected to the circuit. A detection unit connected to the circuit that detects an electrical change of the circuit that changes, and a controller that generates a control signal for operating the relay using the detection signal of the detection unit. Features.

A control device according to a third aspect of the present invention is connected to the circuit so as to bypass electrical disconnection of the circuit by an electrical element connected to a circuit that supplies power from a power source to a load. And a controller that generates a control signal for operating the relay so that energization to the load is controlled.

Preferably, it has a detection unit as the electrical element that detects an electrical change of the circuit that is changed by an operation of a switch connected to the circuit, and the detection unit electrically disconnects the circuit. A relay that is inserted into the circuit and connected to the circuit to bypass at least one of the switch and the detection unit to form a part of the circuit; and A control signal for operating the relay is generated using the detection signal of the detection unit so as to be controlled.

More preferably, the relay is connected to the circuit so as to bypass the switch and the detection unit.

Alternatively, the electrical element includes first and second three-way switches, and the relay includes terminal 1 or terminal 3 of the first three-way switch and terminals of the second three-way switch. Electrical connection is made between two wirings connecting between 1 and 3.

A switch device according to a first aspect of the present invention is a switch device that is applied to a circuit that supplies power from a power source to a load and executes energization control to the load, the switch being connected to the circuit; A relay connected to the circuit so that energization to the load is controlled; a detection unit connected to the circuit that detects an electrical change of the circuit that is changed by an operation of the switch; and the detection unit And a controller that generates a control signal for operating the relay by using the detection signal.

A switch device according to a second aspect of the present invention is a switch device that is applied to a circuit that supplies power from a power source to a load and performs energization control on the load, and the circuit can be electrically disconnected. A relay connected to the circuit, connected to the circuit so as to bypass electrical disconnection of the circuit by the switch, and forming a part of the circuit; and energization to the load is controlled And a controller for generating a control signal for operating the relay.

A switch device according to a third aspect of the present invention is a switch device that is applied to a circuit that supplies power from a power source to a load and executes energization control of the load, and has a switch connected to the circuit. And a detection unit that detects an electrical change of the circuit that is changed by an operation of the switch, and the detection unit is inserted into the circuit so as to electrically disconnect the circuit, and the switch and the detection unit A relay connected to the circuit so as to bypass at least one of the circuit and forming a part of the circuit, and the detection signal of the detection unit is used to control energization to the load. And a controller for generating a control signal for operating the relay.

The adapter device according to the present invention includes the above-described control device, and the circuit is electrically connected to a socket capable of mechanically connecting the load and electrically connecting the load to the circuit. A first connection part mechanically connected to the socket and electrically connectable to the control device and the circuit; the load is mechanically connected; and the load and the control device; And a second connection portion that can be electrically connected to the circuit.

The socket device of the present invention includes the above-described control device, and can mechanically and electrically connect the load and electrically connect the load to the circuit.

The load device of the present invention includes a load to which power is supplied from a power source through a circuit and the control device, and the load and the control device are integrally formed.

The control system of the present invention includes a first and a second relay connected to a circuit that supplies power from a power source to a load so that energization to the load is controlled and connected in parallel to each other; First and second controllers for generating control signals for operating the first and second relays, respectively, and the first and second controllers cooperate to control energization to the load. It works.

According to the present invention, it is possible to perform various energization control of a load that cannot be realized only by opening and closing a switch while minimal or unnecessary change to a circuit for supplying power to the load is not necessary.

The figure which shows 1st Embodiment of the circuit to which the control apparatus of this invention was applied. The circuit diagram which shows an example of a detection part. The functional block diagram which shows an example of the function of a controller. The circuit diagram which shows an example of a controller. The figure which shows 2nd Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 3rd Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 4th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 5th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 6th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 7th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 8th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 9th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 10th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 11th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 12th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 13th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 14th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 15th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows 16th Embodiment of the circuit to which the control apparatus of this invention was applied. The figure which shows one Embodiment of the adapter apparatus of this invention. The figure which shows the modification of the adapter apparatus of FIG. The figure which shows one Embodiment of the socket apparatus of this invention. The figure which shows other embodiment of the socket apparatus of this invention. The figure which shows other embodiment of the adapter apparatus of this invention. The figure which shows the modification of embodiment of FIG. The figure which shows one Embodiment of the load apparatus of this invention. The figure which shows the modification of embodiment of FIG. The figure which shows the example of the operation panel applicable to the control apparatus of this invention.

Embodiments of the present invention will be described in detail with reference to the drawings. First Embodiment A first embodiment of the present invention will be described with reference to FIGS. The circuit 300 to which the control device 1 according to the present embodiment is applied includes an outlet 100 that receives power from a power source (not shown), a load 200, two three-way switches SW3A and SW3B, and two three-way switches SW3A and SW3B. Is connected to a four-way switch SW4. The load 200 is, for example, lighting or a ventilation fan installed indoors. The three-way switches SW3A, SW3B, and the four-way switch SW4 are wall switches for turning on / off lighting or a ventilation fan installed in a room or hallway, for example. This is merely an example, and the present invention is not limited to these.

The control device 1 includes a detection unit 10, two SSRs (Solid State Relays) 20 </ b> A and 20 </ b> B as relays, and a controller 30. In this embodiment, a semiconductor relay is used as a relay, but other relays such as an electromagnetic relay can also be used. The detection unit 10 is provided to detect an electrical change of the circuit 300 that is inserted into the circuit 300 and changes by an operation of the switches SW3A, SW3B, and SW4 connected to the circuit 300. That is, the detection unit 10 is provided to detect the operation of the switches SW3A, SW3B, and SW4. An important point is that not only the three-way switch SW3A but also the operations of the switches SW3B and SW4 can be detected. is there. As will be described later, the detection unit 10 includes a circuit that operates with a minute current that does not drive the load 200, and as a result, the detection unit 10 electrically disconnects the circuit 300. That is, the driving current of the load 200 does not flow through the detection unit 10.

The terminal 1 of the three-way switch SW3A is connected to one end of the first wiring 300a and the SSR 20A of the circuit 300, and the terminal 3 of the three-way switch SW3A is connected to one end of the second wiring 300b and the SR 20B of the circuit 300. Terminal 0 of the three-way switch SW3A
Are connected to one end of the detection unit 10, and the other ends of the SSRs 20 </ b> A and 20 </ b> B and the other end of the detection unit 10 are commonly connected to the third wiring 300 c of the circuit 300. The SSRs 20A and 20B are connected to the circuit 300 so as to bypass the three-way switch SW3A and the detection unit 10. The SSRs 20A and 20B bypass the electrical disconnection of the circuit 300.

As illustrated in FIG. 2, the detection unit 10 includes a first detection circuit 10A and a second detection circuit 10B. In FIG. 2, 11 is a resistor, 12 is a bridge diode, 15 and 17 are Schmitt type buffers, 14 and 16 are variable resistors, 15 is a photocoupler, and 18 is an electromagnetic relay. The first detection circuit 10A detects a relatively large voltage change (for example, between 0V and 100V) due to the operation of the switch when the SSRs 20A and 20B are off, and outputs a detection signal to the input 1 of the controller 30. . A minute voltage change due to the operation of the switch when the second detection circuit 10B and the SSRs 20A and 20B are on is detected, and a detection signal is output to the input 2 of the controller 30. When the SSRs 20A and 20B are turned on, an ON voltage is applied to the transistor of the second detection circuit 10B from the relay terminal of the controller 30. The detection unit 10 is configured by a circuit that operates with a minute current that does not drive the load 200. When the detection unit 10 is inserted into the circuit 300, the circuit 300 is electrically disconnected.

FIG. 3 is a functional block diagram of the controller 30. The controller 30 includes a main control unit 31 that performs various energization controls described later, a control signal output unit 32 that outputs control signals for controlling the SSRs 20A and 20B, a detection unit 10, a seismic intensity sensor, a temperature sensor, a humidity sensor, An input unit 33 for receiving signals from sensors and switches 70 including sensors such as human sensors and switches such as momentary switches, an output unit 34 for outputting signals to an output device 80 such as an LED or a speaker, and wireless It has a communication unit 35 having a communication function and a memory 36 for holding various data and programs. These functions of the controller 30 can be constituted by an electric circuit as shown in FIG. 4 to be described later, and can also be constituted by hardware such as a CPU and a memory and necessary software. Then, the controller 30 activates an energization control function prepared in advance using a signal input through the input unit 33, the communication unit 35, and the like, and executes energization control of the load 200. The energization control function prepared in advance is not limited to these, but power control that adjusts the supply power according to the switch operation, etc., time control that turns the load 200 on and off according to the set time, and a switch Delayed stop control that stops the load 00 after a certain period of time after turning off, periodic operation control that periodically drives the load 200, communication control that controls energization according to communication with a remote controller, a smartphone, etc. Examples include user program control that controls energization according to a set program. In short, the functions necessary for the energization control of the load 200 are prepared in the controller 30 in advance, and if these functions are activated in accordance with signals input through the input unit 33, the communication unit 35, etc., the switch is turned on / off. Various energization control of the load 200, which is impossible by control, can be realized. Further, the controller 30 can activate an audio output device such as a speaker and a display device such as an LED as needed for operability and visibility.

Here, as a first important merit of the present embodiment, the controller 30 can control the energization of the load 200 using the detection signal of the detection unit 10 that detects the operation of the switches SW3A, SW3B, and SW4. is there. In the switches SW3A, SW3B, and SW4, the detection unit 10 is inserted in the circuit 300. For this reason, although the energization control of the load 200 cannot be directly executed by operating the switches SW3A, SW3B, and SW4, the operation signal of the switches SW3A, SW3B, and SW4 is detected by the detection unit 10 and used by the controller 30. Each function of the controller 30 can be activated using each of the switches SW3A, SW3B, and SW4. This means that the switches SW3A, SW3B, and SW4 function not only as a switch for opening and closing the line 300 but as a highly functional switch such as a switch with a timer function. If the switches SW3A, SW3B, and SW4 are part of the existing energization equipment, the existing switches can be used as they are without providing a new switch, so that the switches can be highly functionalized. A second important advantage of the present embodiment is that the controller device 1 can be very easily connected to an existing energization facility. As shown in FIG. 1, one end of the SSRs 20A and 20B is connected to the terminals 1 and 3 of the three-way switch 3A, one end of the detection unit 10 is connected to the terminal 0, and the wiring originally connected to the terminal 0 is connected to the SSR 20A. 20B and the other end of the detection unit 10 only need to be reconnected. That is, construction costs can be minimized. Needless to say, the control device 1 is not applied only to the existing energizing equipment, but can be used together with the newly installed energizing equipment. It is also possible to apply the control device 1 to the energizing equipment as a switch device in which the control device 1 is integrated with the three-way switch SW3A. For example, if this switch device is applied to an existing energization facility instead of the existing three-way switch SW3A, the above-described remarkable advantages can be obtained similarly.

FIG. 4 is an example of the configuration of the controller 30. In FIG. 4, X1 detects a potential change between 0V and the circuit voltage. X2 is a single-pole single-throw switch (X2 is turned off in the case of the fifteenth and sixteenth embodiments described later), and X3 is a potential change between 0 V and a saturation voltage by a relay (increase in the case of an electromagnetic relay contact or low). Is detected. X4 is a switch for manually starting the timer of X5, X5 is a timer, the left is an input, the right is an output, and the upper circle is a reset input at 0V. In X6, when X54 is shifted by a continuous operation switch to increase the timer time, the timer is restarted by the first timer time end signal to increase the timer time. X7 is an operation sound generation circuit that determines the operation according to the setting of the connected switch. X8 is a time switch, which is determined to be valid / invalid depending on the setting of the connected switch. X9 is a power controller. Enable / disable is determined by the setting of the connected switch. If 90 msec on is repeated with 10 msec off, the power to the load can be reduced by 10%. X10 is a periodic operation. Enable / disable is determined by the setting of the connected switch. For example, when a continuous operation function is selected (by selecting the function three times in this circuit diagram) by continuous switch operation. It refers to an operation that repeats the operation for only 5 minutes per hour. X11 is a seismic intensity sensor, which turns on the illumination of X12 upon detection of an earthquake and cuts off the output to the load. X12 is an LED that turns on the illumination upon detection of the seismic intensity sensor. X13 collects the control output of the controller 1 and the control signal to the relay. X14 is a stop signal from the seismic intensity sensor or the outside with respect to the signals collected at X13, and erases the control signal to the relay. X15 is the output of the controller 30. Enable control signal to relay and input 2 circuit. X16 is an LED that displays the state of the switch operation while the load is operating. X17 is an LED that is lit while the load is operating. X18 to X20 are LEDs connected to the output 1-3 of X54, respectively, to display the function selection status. X21 outputs the function selected in X24 by an external signal. X22 is a switch that determines whether to output the function selected in X24. If a periodic operation is selected at X22, the controller 30 can also perform a normal operation while always performing a periodic operation. X23 summarizes the functions selected in X24. X24 selects a signal to be output from various signals. X25 is an external signal receiving unit. X26 is an external signal and a transmission / reception control signal. X27 is a transmission unit in the operating state of the controller 30. X28 wirelessly outputs X27 (in this case, light). X29 receives an external signal by wire.

X30 is a wired type of X28. X31 is a wireless type of X29. X32 is a switch having the same function, although the function can be selected by continuous operation of the switch. X33 is a power supply of the controller 30. In this case, it is a battery type, but if it is absorbed from the power supply and load circuit and used as a power supply, a battery becomes unnecessary. As the absorption circuit, a method of connecting the primary winding of the transformer and taking power from the secondary side, a method of assembling a power supply circuit by inserting a bridge diode, and the like can be considered. X34 is a manual reset input of the controller 30. X35 is a switch for selecting a function in the fourth continuous operation of the switch. X36 is a delay circuit when the delay stop of the load is selected, and the valid / invalid is determined by the setting of the connected switch. X37 cuts off an extra signal from the instantaneous detection unit when the controller output is on and off. In X38, when a momentary type switch is used as the operation switch, it is determined that the long press is reset. In order to improve the operability of the present invention, the determined reset signal is input to this gate. X39 is a gate for checking the switch operation interval at X40 and setting a reset signal when there is an interval, but when the operation of X54 is in the initial state at that time, the signal is not reset. X40 checks the switch operation interval, and operates within a predetermined time as a function selection signal, and otherwise as a reset signal. X41 inverts the signal of X6 to make a timer restart signal. X42 is a delay circuit for timing adjustment. X43 is a gate for adjusting an input signal from the detection circuit. X44 is a determination circuit for deleting the input signal to the controller 30 when, for example, a three-way circuit operation is performed by communication with another controller. X45 collects various input signals. X46 uses this input when X38 is not a long press. X47 is an input when a plurality of detection units 10 are provided. X48 is for delay circuit and timing adjustment. X49 selects the function at the time of the third continuous operation of the switch. X50 is a gate that summarizes the output of this controller. The CR integration circuit is for eliminating hazards when the timer is restarted. X51 resets the timer operation at the third continuous operation of the switch. X52 generates a signal that summarizes various states for outputting the state of the controller 30 to the outside. X53 is a circuit that makes the output of this controller continuous during the third continuous operation of the switch. X54 counts the number of continuous operation of the switch. X55 generates an operation sound of the switch, and determines validity / invalidity according to the setting of the connected switch. X56 is a speaker for operating sound of the switch. X57 is a seismic intensity sensor reset switch. X58 expresses various signals as this block. X59 is a relay, the upper two are inputs and the lower two are outputs. X60 is an additional outlet plug. X61 is an outlet plug for supplying additional power. X62 is a changeover switch for selectively switching between an outlet plug that supplies power and an outlet plug that supplies the same power as the load 200 when an additional load is detected by the seismic intensity sensor.

The circuit shown in FIG. 4 is used as the controller 30 of the first embodiment and is basically used as a controller of each embodiment to be described later, although there are some modifications depending on the form.

FIG. 5 is a configuration diagram of the second embodiment. In addition, the same code | symbol is used about the component same as 1st Embodiment. A single pole single throw switch SW2 (hereinafter referred to as switch SW2) is connected to the circuit 300 to which the control device 1A is applied, and the detection unit 10 is inserted in series in the switch SW2. The first terminal 302a of the circuit 300 and one end of the SSR 20 are connected to the left terminal of the switch SW2, the one end of the detection unit 10 is connected to the other terminal of the switch SW2, and the other end of the SSR 20 and the detection unit. The other end of 10 is connected to the second wiring 302b of the circuit. In the circuit 300, the path where the detection unit 10 is inserted is electrically disconnected, while the SSR 20 is connected to the circuit 300 so as to bypass the SW2 and the detection unit 10 to form a part of the circuit 300. Yes. The switch SW2 cannot directly control the energization of the load 200, but the operation of the switch SW2 is detected by the detection unit 10, and the controller 30 has an energization control function prepared in advance according to the detection signal of the detection unit 10 or the like. Execute. That is, highly functional energization control can be performed by operating the switch SW2. Further, similarly to the first embodiment, the connection of the control device 1A to the circuit 300 including the switch SW2 is very prepared, and the existing energization equipment can be used as it is. The control device 1 </ b> A is not applied only to the existing energizing equipment, but can be used with the newly installed energizing equipment. As a switch device in which the control device 1A is integrated with the switch SW2, the control device 1A can be applied to an energizing facility.

FIG. 6 is a configuration diagram of the third embodiment. In addition, the same code | symbol is used about the component same as 2nd Embodiment. In this embodiment, the difference from the second embodiment is that the SSR 20 bypasses the detection unit 10 but is connected to the circuit 300 without bypassing the switch SW2. According to the present embodiment, the switch SW2 can directly turn off the energization to the load 200, and when the switch SW2 is detected to be on, the controller 30 performs the high-function energization control of the load 200. .

FIG. 7 is a configuration diagram of the fourth embodiment. In addition, the same code | symbol is used about the same component as said each embodiment. In FIG. 7, the detection unit 10 is connected in parallel to the switch SW2. When the switch SW2 is turned on, the SSR 20 is connected so as to bypass the detection unit 10 in the electrical result using the switch SW2. As described above, the detection unit 10 includes a circuit that operates with a minute current that does not drive the load 200. When the SSR 20 is in an off state (the load 200 is off), the resistor 50 is connected in series to the detection unit 10 in order to prevent a passage through which a minute current flows. According to the present embodiment, the switch SW2 can directly turn off the power supply to the load 200, and when the switch SW2 is detected to be turned on, the high-function power supply control of the load 200 by the controller 30 of the load 200 is performed. Executed. For example, when a predetermined time elapses after the switch SW2 is turned on, the SSR 20 is turned off and the load 200 is energized. A predetermined time elapses after a human being is not detected using a human sensor or the like. Then, energization control such as turning off the SSR 20 and energizing the load 200 is possible. The present invention is not limited to these. In the control device 1 </ b> C of the present embodiment, the detection unit 10 is a type in which the circuit 300 is not electrically disconnected, and the SSR 20 does not bypass the switch and the detection unit 10.

FIG. 8 is a configuration diagram of the fifth embodiment. In addition, the same code | symbol is used about the same component as said each embodiment. Switch SW2 is electrically disconnected when switch SW2 connected to circuit 300 is in the OFF state. The SSR 20 is connected in parallel to the switch SW2 so as to bypass the switch SW2. In the present embodiment, the energization to the load 200 can be directly turned on / off by the switch SW2, but the high-function energization control of the load 200 by the controller 30 is executed in a state where the switch SW2 is turned off.

FIG. 9 is a configuration diagram of the sixth embodiment. The difference between this embodiment and the first embodiment is that the SSR 20 is connected to the circuit 300 so that only the detection unit 10 is bypassed, and the SW 3A is not bypassed. In this embodiment, the circuit 300 can be electrically disconnected by a combination of the switches SW3A, SW3B, and SW4, and when the conduction of the circuit 300 is ensured by the combination of the switches SW3A, SW3B, and SW4, the controller 30 High-function energization control of the load 200 is executed.

FIG. 10 is a configuration diagram of the seventh embodiment. In the present embodiment, the detection unit 10 detects a potential change between 0 V and a high voltage, and detects only whether the circuit 300 is conductive or nonconductive. When the circuit 300 is turned on by the three-way switches SW3A, SW3B, and the four-way switch SW4, for example, the SSR 20 executes control functions such as time control of the load 200 and operation for a fixed time, and then automatically shifts to periodic operation and sensor operation. You may let them. In addition, when the circuit 300 is turned off by the three-way switches SW3A, SW3B, and the four-way switch SW4, the controller 30 can be reset to return to the initial state and wait. Note that the SSR 20 of the control device 1F of the present embodiment is only inserted in the circuit 300, and controls the circuit 300 without bypassing the switch or the detection unit.

FIG. 11 is a configuration diagram of the eighth embodiment. In this embodiment, a two-pole double-headed switch 60 is provided between the two SSRs 20 and the controller 30, and when the two-pole double-headed switch 60 is connected to the upper side by a lever operation or the like, the load is applied by the switches SW3A, SW3B, and SW4. In the normal mode in which the power supply control 200 is directly controlled, and the two-pole double-headed switch 60 is connected to the lower side, the high-function power supply control of the load 200 by the controller 30 is executed using the two SSRs 20.

FIG. 12 is a configuration diagram of the ninth embodiment. SSR20 of one control device IH-1 is 3 when Michikai path is electrically disconnected by a switch in the three-way circuit is provided et al is in so that turning periphrastic this cleavage. In the present embodiment, the following operation can be considered. 1... High-function energization control of the load 200 by the controller 30 is executed using the three SSRs 20. 2. Normal 3 way circuit with controller 30A off and 30B on. 3. The forced operation of the load 200 by 30A in the state 2 above. 4. The load 200 is forcibly turned off by turning off 30B. Furthermore, when there are a plurality of controllers, remote control operations from a plurality of locations are possible.

FIG. 13 is a configuration diagram of the tenth embodiment. As shown in FIG. 13, when the two wires of the three-way circuit are electrically disconnected by the four-way switch SW4, the SSR 20 is provided so as to bypass the disconnection and connect the two wires. As a result, a mode in which the load 200 is directly energized and controlled by the switches SW3A, SW3B, and SW4 and a mode in which the load 200 is directly energized and controlled by the switches SW3A, SW3B, and SW4 can be realized.

FIG. 14 is a configuration diagram of the eleventh embodiment. In the present embodiment, a single three-way switch SW3B is used for the three-way circuit, and instead, two SSRs 20 and a detection unit 10 are provided at a place where the three-way switch SW3A is to be inserted. Even in such a configuration, the same function as in the first embodiment can be realized.

FIG. 15 is a configuration diagram of the twelfth embodiment. In the present embodiment, the detection unit 10 is provided only in one control device 1L-2 of the two control devices 1L-1 and 1L-2, and an electrical change due to the operation of the switch SW2 and the single pole three throw switch SW5 is further performed. The operating states of the first and second SSRs 20A and 20B can be detected. Various information can be exchanged between the two control devices 1L-1 and 1L-2 by wire or wirelessly, and the detection information of the detection unit 10 is also shared by the two devices. The first and second SSRs 20A and 20B are connected in parallel to each other as a bypass unit of SW2 to a circuit that supplies power from the power supply 100 to the load 200. The first and second controllers 30A and 30B that control the first and second SSRs 20A and 20B, respectively, cooperate so that energization to the load 200 is controlled. For example, a momentary switch is provided in the control devices 1L-1 and 1L-2, and a signal of this switch and a detection signal of the detection unit 10 are used or various information is wired or wirelessly between the control devices 1L-1 and 1L-2. By giving and receiving, energization control similar to a circuit using a three-way switch and a four-way switch can be performed. In addition, high-function energization control such as timer operation and periodic operation can be performed. For example, when one control device is operated, various information is exchanged between the detection unit 10 or the control devices 1L-1 and 1L-2 by wire or wireless, and the other SSR 20 is detected to be on. It becomes possible to turn off the SSR 20 that is turned on. Further, by using a sensor such as a human sensor together, more advanced energization control becomes possible. The switch SW5 enables this circuit at the upper position, turns off all the intermediate positions, and turns on the load at the lower position. In other words, the user can turn on / off the load using the lower position and the intermediate position, and can use the circuit at the intermediate position and the upper position, either valid or completely off. In the present embodiment, the detection unit 10 of the control device 1L-2 has no meaning of electrical disconnection with respect to the circuit 300 and the load 200, but the detection unit 10 itself is electrically disconnected with respect to the line to be inserted. The SSR 20 also bypasses the detection unit 10. The detection unit 10 can detect the operation states of the switches SW2 and SW5 and can detect the electrical states of the two SSRs 20. However, if it is not necessary to detect the operation state of the switches SW2 and SW5, the detection unit 10 becomes unnecessary by exchanging various information between the control devices 1L-1 and 1L-2 by wire or wirelessly. Although the detection unit 10 is built in one control device 1L-1, the detection unit 10 may be connected independently, or may be built in the other control device 1L-2. Moreover, although the case where two SSR20 and the controller 30 were used was mentioned as an example, three or more may be connected in parallel, and it is not limited to two. Installation is possible without worrying about wiring and electrical installation position when using a switch or 4-way switch.

FIG. 16 is a configuration diagram of the thirteenth embodiment. In this embodiment, the concept of the twelfth embodiment shown in FIG. 15 is applied to a three-way switch line. Two three-way switches may be used, but the three-way switch can be omitted as shown in circle C1. In the state of this figure, SW3 is not a function of a three-way switch but is an on / off switch. When SW3 is off with respect to the load 200, control by the control devices 1M-1 and 1M-2 is possible. The operation as shown in FIG. 15 is possible. If C1 is a three-way switch, it can be used as a normal three-way circuit together with SW3. When the circuit to the load 200 is not connected by the three-way switch, the control devices 1M-1 and 1M-2 are used. The operation as shown in FIG. 15 is possible. Also, the quantity of SSR 20 is the same as in FIG.

17 to 19 are configuration diagrams of the thirteenth to fifteenth embodiments. Although these configurations are different from those of the first embodiment, the same functions as those of the first embodiment can be realized. In FIG. 17, signals from the two detection units 10 are input to the common controller 30. The controller 30 is provided with the input units of the two detection units 10 and, for example, the output of these detection circuits can be taken and used as a detection signal.

FIG. 20 is a block diagram showing an embodiment of the adapter of the present invention. The adapter 500 includes the detection unit 10, the SSR 20, and the controller 30 as described above, and also includes a one-shot switch 510, a load side connector 520, and a socket side connector 530. The electrical connection relationship between the detection unit 10, the SSR 20, and the controller 30 is the same as that of the controller device 1B shown in FIG. A load 200 such as a lighting device is detachably attached to the load side connector 520 and is electrically connected to the circuit 300 by being attached to the load side connector 520. The socket-side connector 530 is detachable from the socket 310 connected to the circuit 300, and is electrically connected to the circuit 300 when the socket-side connector 530 is attached to the socket 310. The socket 310 is formed so that the load 200 can be attached and detached without using the adapter 500. When the load 200 is attached to the socket 310, the load 200 is electrically connected to the circuit 300. The signal of the one-shot switch 510 can be used for energization control of the controller 30. It is possible to arbitrarily set how to use the signal generated by the one-shot switch 510. According to the present embodiment, the load 200 can be easily connected to the circuit 300 via the adapter 500 without wiring work, and various energization controls of the load 200 are possible. The adapter device 500 according to the present embodiment includes the controller device 1B illustrated in FIG. 6, but is not limited thereto, and includes the functions of other embodiments including a three-way circuit. Of course it is possible to do.

20B is a configuration diagram illustrating a modification of the adapter of FIG. 20B, the plug 210 electrically connected to the load 200 is detachable, and the plug provided on the socket-side connector 530 is detachable from the connector 151 of the extension cable 150. It is free. The plug 152 of the extension cable 150 is inserted into and removed from a power receptacle provided on the wall or the like. According to this configuration, for example, the adapter device 500A of the present embodiment can be applied to an existing load such as a ventilation fan without any work. Alternatively, the adapter device 500A may be integrated with 150 and 152 except 530 and 151.

FIG. 21 is a block diagram showing an embodiment of the socket of the present invention. The same components as those in the embodiment shown in FIG. The socket device 600 of the present embodiment incorporates the controller device 1B shown in FIG. 6, and the socket 310 is formed so that the load 200 is detachable, and the load 200 can be electrically connected to the circuit 300. It has become. According to the present embodiment, if the socket device 600 is applied to the circuit 300 in advance, various energization controls of the load 200 can be performed without wiring work. In addition, since there are only two points where the socket device 600 is connected to the circuit 300, the operation is very easy. The socket device 500 according to the present embodiment includes the controller device 1B illustrated in FIG. 6, but is not limited thereto, and includes the functions of other embodiments including a three-way circuit. Of course it is possible to do.

FIG. 22 is a modification of the socket device 600 of FIG. The same components as those in the embodiment shown in FIG. The socket device 600A of this embodiment incorporates the controller device 1B shown in FIG. 6, and further includes a connection plug 320 for connecting to a power source. By attaching the load 200 to the socket 310 and inserting the connection plug 320 into an outlet (not shown), various energization controls of the load 200 can be performed. In this embodiment, no facility work is required.

23 and 23B are modifications of the adapter device 500 of FIG. 23 and 23B require some wiring work for the circuit 300, but only one connection is required, and equipment work is required, but various energization control of the load 200 is possible with minimum equipment work. become. The wiring to the circuit 300 may be connected there if there is a spare connection hole in the switch SW2. Further, the controller 30 has a communication function, and can be operated wirelessly and remotely without using the 510 switch.

FIG. 24 is a block diagram showing an embodiment of the load device of the present invention. In FIG. 24, the same reference numerals are used for the same components as in the above embodiments. A load device 700 illustrated in FIG. 24 is an LED lighting device including an LED 250. By connecting one end of the detection unit 10 to the existing circuit 300 and mounting the LED lighting device on the existing power supply equipment provided on the ceiling or the like, various power supply controls of the LED lighting device can be performed with minimal equipment work. It becomes possible. This can be an illumination incorporating the present invention, such as a fluorescent tube replacement operation. The load device 700 may be regarded as a fluorescent tube. In this example, an LED is used. The two wires on the left and right of the load device 700 are the electrodes of the fluorescent lamp socket. Further, the controller 30 has a communication function, and can be operated wirelessly and remotely without using the 510 switch.

FIG. 24B is a modification of the load device of FIG. FIG. 24B is a block diagram showing one embodiment. A load device 700A shown in FIG. 24B is an LED lighting device, and by attaching the LED lighting device to an existing power supply facility provided on a ceiling or the like, various power supply controls of the LED lighting device can be performed without facility work. Become.

FIG. 25 is a diagram illustrating an example of an operation panel provided in the above-described various control devices or switch devices. Although not limited to these examples, as shown in the first and second embodiments, for example, a display unit 801 including a plurality of LEDs 1 to 5 is provided, and the LEDs corresponding to the energization control being performed are turned on. Can be made. Instead of the LEDs 1 to 5, a display function and a switch function may be provided as a lighting type switch. If the switch can be reset by long-pressing or pressing twice within a certain time, the convenience is increased. The switch structure can be selected arbitrarily according to the function, such as momentary, alternate, multi-function, push-pull, etc. A three-way switch or a single-pole single-throw switch 803 connected to the circuit 300 can be provided on the panel. A reset switch 804 may be provided so that the circuit 300 can be reset or a part of functions can be reset. A function selection switch 808 that selects an energization control function can also be provided, and a switch 807 that activates the selected function can also be provided. A sensor window, an external signal reception window, or a buzzer window 806 may be provided. The external signal reception may be a portion hidden from the surface instead of the panel surface. Moreover, it is provided if necessary. A display device 803 such as a liquid crystal panel for displaying the operating state and the activated function may be provided. In addition, it is possible to adjust the period and duty of the periodic operation and power control operation, or to provide a function that allows volume operation to adjust sensitivity such as sensor operation and adjustment for a certain period of time. It is also possible to provide an operation display lamp for displaying the above. Further, the external input (wireless or wired) and the installation position are not necessarily the surface of the panel. Communication input / output (wireless or wired), installation location is not necessarily the surface of the panel

As described above, according to various embodiments of the present invention, unlike a delayed stop, a problem caused by forgetting to turn off can be solved. This is particularly effective in a place where an unspecified majority uses. According to the present invention, it is possible to cope with a usage that requires a delayed stop, which is impossible by a fixed time operation with a push button switch. The device of the present invention can be used in various environments, and can be operated for a certain period of time regardless of which switch is tilted, such as a single-pole single-throw switch as well as a 3-way switch or 4-way switch. Depending on the continuous switch operation, it is also possible to make a sensor operation or continuous operation. In this case, the switch is reset when conditions such as continuous switch operation after a certain time elapses or switch operation while the relay is operating are reset. Etc. can also be used. Even in a circuit using three paths (or four paths), it is not necessary to add or route a wiring other than the switch, so that it is particularly easy to introduce in existing equipment. It is only necessary to install the switch in one place or replace the switch incorporating the present invention. Even if there are no additional switches, various functions can be selected only by the number of switch operations. Products using human sensors cannot be used for a variety of functions such as periodic operation with only operation for a certain period of time, and must be installed in all switches, and are restricted to use within the sensor sensitivity range. . On the other hand, in the present invention, various functions such as periodic operation, illuminance sensor, humidity sensor, etc. can be incorporated, and combined operation can be easily realized, and the control device is installed only on a single switch. Mu In the above embodiment, a single four-way switch is used in the three-way circuit. However, the present invention is not limited to this, and the four-way switch may not be used, and a plurality of four-way switches are used. You can also.

DESCRIPTION OF SYMBOLS 1 Control apparatus 10 Detection part 20 SSR30 Controller 100 Power supply 200 Load 300 Circuit 500 Adapter apparatus 600 Socket apparatus 700 Load apparatus

Claims (22)

In the circuit including a switch that controls the load connected to a circuit that supplies power from a power source to a load, a relay that is connected to the circuit and forms part of the circuit, and a controller that controls the relay The circuit further includes a detection unit that detects an electrical change of the circuit that is changed by the operation of the switch, and the detection unit is connected and arranged in parallel to the switching output of the relay,
The controller controls the relay using a detection signal of the detection unit. In the circuit including a switch that controls the load connected to a circuit that supplies power from a power source to a load, a relay that is connected to the circuit and forms part of the circuit, and a controller that controls the relay Said circuit comprising:
A detector that detects an electrical change of the circuit that is changed by operation of the switch; the detector is connected in parallel to the switch; and the controller uses a detection signal of the detector Control device for controlling the relay In the circuit including a switch that controls the load connected to a circuit that supplies power from a power source to a load, a relay that is connected to the circuit and forms part of the circuit, and a controller that controls the relay Said circuit comprising:
The circuit further includes a detection unit that detects an electrical change of the circuit that is changed by the operation of the switch, and the detection unit includes the 3-way switch even when the circuit includes a 3-way switch or a 4-way switch. A control device which is connected to a line switch or a line of terminals 1 and 3 of the four-way switch, and wherein the controller controls the relay using a detection signal of the detection unit. In the circuit including a three-way switch as a switch for controlling the load of the circuit for supplying power from the power source to the load,
A first or second relay that bypasses the electrical disconnection of the circuit by the switch; a controller that generates a signal for controlling the two relays; and a double-pole double-throw that switches a control signal to the two relays. Have a switch,
The first relay is connected to the line between the terminal 1 and the terminal 3 of the three-way switch or the four-way switch, and the second relay is connected so as to cut off the energization to the terminal 0 of the three-way switch. In the inserted and connected circuit,
By the first selection of the double-pole double-throw switch, the first relay is turned off and only the second relay is always energized to function as a normal three-way circuit. It can be the first relay circuit for supplying power to the load from the power supply by the three-way switch or the 4-way switch when turning on the open state can Ru to operate the load ,
In the second selection of the double-pole double-throw switch, the control device of the first relay and the second relay is connected to the controller, whereby the circuit is controlled by the controller. In the circuit including a three-way switch as a switch for controlling the load of the circuit for supplying power from the power source to the load,
A first to a third relay that bypasses the electrical disconnection of the circuit by the switch; and a controller that generates a signal for controlling the three relays;
The first relay is connected so as to control the opening and closing of the line between the terminal 1 and the terminal 3 of the three-way switch or the four-way switch, and the second relay is connected to the terminal of the three-way switch or the four-way switch. A control device inserted and connected so as to cut off the line 1, and the third relay inserted and connected so as to cut off the line of the terminal 3 of the three-way switch or the four-way switch In the circuit including a three-way switch as a switch for controlling the load of the circuit for supplying power from the power source to the load,
Using first and second relays that bypass the electrical disconnection of the circuit by the switch, a detection unit that detects an electrical change of the circuit that changes due to the operation of the switch, and a signal from the detection unit A controller for generating a signal for controlling the two relays,
One of the three-way switches is omitted, and instead, one end of the first relay and one end of the detection unit are connected to the line of terminal 1 of the three-way switch, and the first of the three-way switch is connected to the line of terminal 0 of the three-way switch. Connecting the other end of one relay, the other end of the detection unit, and one end of the second relay;
The control device characterized in that the other end of the second relay is connected to the line of the terminal 3 of the three-way switch, and the detection unit electrically disconnects the circuit. In the circuit including a single-pole three-throw switch and a single-pole single-throw switch as a switch for controlling the load of a circuit that supplies power from a power source to a load, the electrical of the circuit by the single-pole single-throw switch A relay connected to bypass the disconnection, a detection unit that detects an electrical change of the circuit that is changed by the operation of the switch, and a signal that controls the relay using a signal from the detection unit A controller,
The first selection of the single-pole / three-throw switch energizes the power supply to the single-pole / single-throw switch, the second selection terminal of the single-pole / three-throw switch is open, and the single-pole / three-throw switch is open. The third selection of the switch is a circuit for connecting the power supply directly to the load,
A control device in which the relay and the detection unit are connected in parallel to the single-pole single-throw switch. In the circuit including a three-way switch as a switch for controlling the load of a circuit for supplying power from a power source to a load, a relay connected to control the load, and the electrical of the circuit that changes depending on the operation of the switch A detection unit for detecting a mechanical change, and a controller for controlling the relay using a signal from the detection unit,
Even when the three-way switch or the four-way switch is included , one end of the relay and one end of the detection unit are connected to the line of the terminal 1, and the three-way switch or the four-way switch is included. Also, the other end of the relay and the other end of the detection unit are connected to the line of the terminal 3 and connected to the terminal 0 and the terminal 1 or the terminal 3 of one of the three-way switches. Control device without the 3-way switch. In the circuit including a four-way switch as a switch for controlling the load of a circuit for supplying power from a power source to a load, first to third relays for bypassing electrical disconnection of the circuit by the four-way switch, It has first to second detection parts for detecting an electrical change of the circuit that changes due to operation of the switch, and the two detection parts are inserted and connected to the circuit so as to electrically disconnect the circuit, respectively. And
And a controller for controlling the three relays using signals from the two detection units,
One end of the first relay and one end of the second relay are connected to the line of the terminal 1 of the four-way switch, and the other end of the first relay and the first relay are connected to the line of the terminal 3 of the four-way switch. Connect one end of the three relays, connect only one end of the first detector to the terminal 2 of the four-way switch, and connect only one end of the second detector to the terminal 4 of the four-way switch. ,
Originally, the other end of the first detecting unit and the other end of the second relay are connected to the wiring connected to the terminal 2 of the four-way switch, and originally connected to the terminal 4 of the four-way switch. Control device in which the other end of the second detector and the other end of the third relay are connected to the wiring to be connected A switch device that is applied to a circuit that supplies power from a power source to a load and performs energization control to the load,
A switch connected to the circuit;
A detection unit that detects an electrical change of the circuit that is changed by an operation of a switch of the circuit, and the detection unit is inserted into the circuit so as to electrically disconnect the circuit;
A relay that is connected to the circuit so as to bypass at least one of the switch and the detection unit and forms a part of the circuit;
A controller that generates a control signal for operating the relay using a detection signal of the detection unit so that energization to the load is controlled;
A switch device comprising: A switch device that is applied to a circuit that supplies power from a power source to a load and performs energization control to the load,
 3. A switch device comprising the control device according to claim 1 or 2, wherein the switch device is connected to the circuit and replaced with a switch for controlling the load. A switch device that is applied to a circuit that supplies power from a power source to a load and performs energization control to the load,
 A switch device comprising the control device according to any one of claims 3, 5, 6 or 8, and being replaced with a three-way switch or a four-way switch connected to the circuit and controlling the load. A switch device that is applied to a circuit that supplies power from a power source to a load and performs energization control to the load,
 5. A switch device comprising the control device according to claim 4, wherein the switch device is replaced with a three-way switch connected to the circuit and controlling the load. A switch device that is applied to a circuit that supplies power from a power source to a load and performs energization control to the load,
 8. A switch device comprising the control device according to claim 7 and replaced with a single-pole three-throw switch or a two-way switch connected to the circuit and controlling the load A switch device that is applied to a circuit that supplies power from a power source to a load and performs energization control to the load,
 10. A switching device having the control device according to claim 9, wherein the switching device is replaced with a four-way switch connected to the circuit and controlling the load. A relay connected to and forming part of the circuit to bypass electrical disconnection of the circuit by an electrical element connected to the circuit supplying power from the power source to the load;
A detection unit that detects an electrical change of the circuit that is changed by an operation of a switch as the electrical element of a circuit having a controller that generates a control signal for operating the relay so that energization to the load is controlled The detection unit is inserted into the circuit so as to electrically disconnect the circuit,
The relay is connected to the circuit so as to bypass at least one of the switch and the detection unit,
The controller generates the control signal using a detection signal of the detection unit;
An adapter having a control device, characterized in that
A socket capable of mechanically connecting the load and electrically connecting the load to the circuit is electrically connected to the circuit,
A first connection portion mechanically connected to the socket and electrically connectable to the control device and the circuit;
An adapter comprising: a second connection portion to which the load is mechanically connected and capable of electrically connecting the load to the control device and the circuit. An adapter having the control device according to any one of claims 1 to 9 ,
A socket capable of mechanically connecting the load and electrically connecting the load to the circuit is electrically connected to the circuit,
A first connection portion mechanically connected to the socket and electrically connectable to the control device and the circuit;
An adapter comprising: a second connection portion to which the load is mechanically connected and capable of electrically connecting the load to the control device and the circuit. 18. The adapter according to claim 16 , wherein the load is integrally connected to the adapter. A socket having the control device according to any one of claims 1 to 9 ,
A socket capable of mechanically and electrically connecting the load and electrically connecting the load to the circuit. A relay connected to and forming part of the circuit to bypass electrical disconnection of the circuit by an electrical element connected to the circuit supplying power from the power source to the load;
A detection unit that detects an electrical change of the circuit that is changed by an operation of a switch as the electrical element of a circuit having a controller that generates a control signal for operating the relay so that energization to the load is controlled The detection unit is inserted into the circuit so as to electrically disconnect the circuit,
The relay is connected to the circuit so as to bypass at least one of the switch and the detection unit,
The controller generates the control signal using a detection signal of the detection unit;
A socket having a control device, characterized in that
A socket capable of mechanically and electrically connecting the load and electrically connecting the load to the circuit. A load supplied with power from a power source through a circuit;
A control device according to any one of claims 1 to 9 ,
The load device, wherein the load and the control device are integrally formed. A load supplied with power from a power source through a circuit;
A relay connected to the circuit to form a part of the circuit to bypass electrical disconnection of the circuit by an electrical element connected to the circuit supplying power from the power source to the load; and energizing the load A detection unit for detecting an electrical change of the circuit that is changed by an operation of a switch as the electrical element of the circuit having a controller that generates a control signal for operating the relay so as to be controlled; The detection unit is inserted into the circuit so as to electrically disconnect the circuit, and the relay is connected to the circuit so as to bypass at least one of the switch and the detection unit,
The controller has a control device that generates the control signal using a detection signal of the detection unit, and
The load device, wherein the load and the control device are integrally formed.

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