JP2024106794A - Electronic switch and electronic switching system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic switch and an electronic switch system with high control versatility.

SOLUTION: Provided is an electronic switch to switch on and off power supply to a load. The electronic switch includes: a pair of connecting terminals for connecting another electronic switch; a signal generation unit that enables a signal to be transmitted to the another electronic switch by changing a voltage between the pair of connecting terminals; a voltage detection unit that enables a signal transmitted from the another electronic switch to be received by detecting the voltage between the pair of connecting terminals; and a control unit that controls an operation of the signal generating unit, transmits a signal to the another electronic switch, and receives a signal transmitted from the another electronic switch on the basis of the voltage detected by the voltage detection unit, thereby enabling information regarding a state of the power supply to the load to be shared with the another electronic switch.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2024,JPO&INPIT

Description

Embodiments of the present invention relate to electronic switches and electronic switch systems.

There are electronic switches that switch between supplying and stopping the supply of power to a load based on input information from a sensor or the like. Electronic switches are used, for example, as non-contact switches that supply power to a load by detecting the approach of a human hand or the like in a non-contact manner, and as human-sensing switches that supply power to a load in response to the detection of a human body.

There is also an electronic switch system equipped with multiple electronic switches. The multiple electronic switches are divided into a parent device connected to a load and a child device connected to the parent device. The child device's electronic switch transmits input information to the parent device. The parent device's electronic switch switches the power supply to the load based on its own input information, and also switches the power supply to the load based on input information transmitted from the child device's electronic switch. This makes it possible to switch the power supply to the load based on input information from multiple locations, improving convenience. For example, it becomes possible to turn on and off a light installed in a hallway based on input information from the parent device's electronic switch installed at one end of the hallway and the child device's electronic switch installed at the other end of the hallway.

For electronic switches used in such electronic switch systems, it is desirable for the control to be highly versatile.

Patent No. 4654924

Embodiments of the present invention provide an electronic switch and an electronic switch system that are highly versatile in terms of control.

According to an embodiment of the present invention, there is provided an electronic switch that switches between supplying and stopping power to a load, the electronic switch comprising: a pair of connection terminals for connecting to another electronic switch; a signal generating unit that changes the voltage between the pair of connection terminals to enable a signal to be sent to the other electronic switch; a voltage detecting unit that detects the voltage between the pair of connection terminals to enable a signal sent from the other electronic switch to be received; and a control unit that controls the operation of the signal generating unit to transmit a signal to the other electronic switch and receives a signal sent from the other electronic switch based on the voltage detected by the voltage detecting unit, thereby enabling information regarding the state of power supply to the load to be shared with the other electronic switch.

An electronic switch and electronic switch system with highly versatile control are provided.

1 is a circuit diagram illustrating a schematic diagram of an electronic switch system according to a first embodiment. 2A to 2D are waveform diagrams each showing a schematic example of a signal. 1 is a table illustrating an example of a signal. FIG. 11 is an explanatory diagram illustrating a schematic diagram of an electronic switch system according to a second embodiment. 1 is a table illustrating an example of a signal.

Each embodiment will be described below with reference to the drawings.
The drawings are schematic or conceptual, and the relationship between the thickness and width of each part, the size ratio between parts, etc. are not necessarily the same as in reality. Even when the same part is shown, the dimensions and ratios of each part may be different depending on the drawing.
In this specification and each drawing, elements similar to those described above with reference to the previous drawings are given the same reference numerals and detailed descriptions thereof will be omitted as appropriate.

First Embodiment
FIG. 1 is a circuit diagram illustrating an electronic switch system according to a first embodiment.
1 , the electronic switch system 10 includes an electronic switch 11 (a first electronic switch) and an electronic switch 12 (a second electronic switch). The electronic switch 11 is connected to a power source 2 and a load 4. The electronic switch 12 is connected to the electronic switch 11.

The electronic switch 11 and the electronic switch 12 switch between supplying and stopping the supply of power to the load 4. In other words, the electronic switch 11 and the electronic switch 12 are wiring devices that switch the state of current flow from the power source 2 to the load 4.

The electronic switch 11 switches the power supply state to the load 4 based on the input to itself and the input from the electronic switch 12. The electronic switch 11 is, for example, a parent device that actually switches the power supply state of the load 4 based on an input signal. The electronic switch 12 is, for example, a child device that inputs a signal to the parent electronic switch 11.

As a result, the electronic switch system 10 can switch the power supply to the load 4 based on input from multiple locations, including the location of the parent device and the location of the child device, improving convenience and enabling the versatility of control of the load 4 to be increased. For example, if the load 4 is a light installed in a hallway, by providing an electronic switch 11 at one end of the hallway and an electronic switch 12 at the other end of the hallway, it is possible to switch the light, which is the load 4, on and off at both ends of the hallway.

The electronic switches 11 and 12 are attached to, for example, a standardized wiring device mounting frame. This allows the electronic switches 11 and 12 to be attached to, for example, the walls of buildings such as houses and factories.

However, the mounting position of the electronic switch 11 and the electronic switch 12 is not limited to the wall of the building, and may be any position. Furthermore, the electronic switch 11 and the electronic switch 12 do not necessarily have to be housed in one housing. The electronic switch 11 and the electronic switch 12 may be, for example, divided and installed in multiple housings. For example, only the input unit used to switch between supplying and stopping the supply of power to the load 4 may be installed on the wall of the building, and the other parts may be installed in another position, such as inside the wall or in the space above the ceiling. The method of installing the electronic switch 11 and the electronic switch 12 may be any method that allows the electronic switch 11 and the electronic switch 12 to be appropriately installed on a building, etc.

The power source 2 is, for example, an AC commercial power source. The power of the power source 2 is, for example, AC power. However, the power source 2 is not limited to a commercial power source, and may be a private generator or the like. The power of the power source 2 is not limited to AC power, and may be DC power or the like. The power source 2 may be any power source that can appropriately supply power to the load 4, etc.

The load 4 is, for example, a lighting device having a light source and a lighting circuit that turns on the light source. The light source is, for example, an LED (Light Emitting Diode). In this case, the load 4 (lighting device) turns on the light source in response to the supply of power from the power source 2. However, the load 4 is not limited to a lighting device, and may be any load that requires a supply of power.

The electronic switch 11 has power supply terminals 20a, 20b, load terminals 21a, 21b, an opening/closing unit 22, a pair of connection terminals 23a, 23b (a pair of first connection terminals), a conversion circuit 24, a signal generation unit 25 (a first signal generation unit), a voltage detection unit 26 (a first voltage detection unit), and a control unit 27 (a first control unit).

The power supply terminals 20a and 20b are terminals for connecting the power supply 2. The electronic switch 11 has, for example, a pair of power supply terminals 20a and 20b, and is connected to both ends of the power supply 2. The load terminals 21a and 21b are terminals for connecting the load 4. The electronic switch 11 has, for example, a pair of load terminals 21a and 21b, and is connected to both ends of the load 4.

The opening/closing unit 22 switches between a state in which the power source 2 supplies power to the load 4 and a state in which the supply of power from the power source 2 to the load 4 is stopped. The opening/closing unit 22 has a switching element such as a relay or a semiconductor switch, and switches between a state in which power is supplied to the load 4 and a state in which the supply of power to the load 4 is stopped by switching the switching element on and off.

The opening/closing unit 22 may further have a function of adjusting the amount of power supplied to the load 4, for example. When the load 4 is a lighting device, the opening/closing unit 22 may have a dimming function of changing the brightness by adjusting the amount of power supplied. However, dimming may also be performed, for example, by a lighting circuit on the lighting device side.

One load terminal 21a is connected to one power supply terminal 20a. The other load terminal 21b is connected to the other power supply terminal 20b via the opening/closing unit 22. Thus, by switching the open/closed state of the opening/closing unit 22, the load 4 is connected to the power supply 2 and the power of the power supply 2 is supplied to the load 4.

However, the configurations of the power supply terminals 20a, 20b, the load terminals 21a, 21b, and the opening/closing unit 22 are not limited to those described above. For example, if the power of the power supply 2 is three-phase AC power, the electronic switch 11 may have three power supply terminals.

In this way, the configuration of the power supply terminal and the load terminal is not limited to the above, and may be any configuration that can appropriately connect the electronic switch 11 to the power supply 2 and the load 4. The configuration of the opening/closing unit 22 may be any configuration that can appropriately switch between supplying and stopping the supply of power to the load 4. The electronic switch 11 may be a single-pole switch that can connect two wires, a three-way switch that can connect three wires, or a four-way switch that can connect four wires.

The pair of connection terminals 23a, 23b are terminals for connecting the electronic switch 12 (another electronic switch, for example, a child device for the parent electronic switch 11). The power supply terminals 20a, 20b, the load terminals 21a, 21b, and the connection terminals 23a, 23b are, for example, components for electrically and mechanically connecting wiring. However, the power supply terminals 20a, 20b, the load terminals 21a, 21b, and the connection terminals 23a, 23b are not limited to components (terminals) for connecting power lines, and may be, for example, leads of electronic components or parts of conductors included in a circuit board.

The conversion circuit 24 converts the power supplied from the power source 2 into a predetermined DC power, and enables the converted DC power to be supplied to the electronic switch 12 via a pair of connection terminals 23a, 23b. The conversion circuit 24 converts, for example, the AC power of the power source 2 of 100 V (effective value) into DC power of 12 V, and supplies the converted DC power between the pair of connection terminals 23a, 23b. The connection terminal 23a is, for example, a terminal on the high potential side. The connection terminal 23b is, for example, a terminal on the low potential side.

The conversion circuit 24 has, for example, a rectifier 24a, a smoothing capacitor 24b, a converter 24c, and an output capacitor 24d. The rectifier 24a rectifies the AC power input from the power source 2 and converts it into rectified power. The rectifier 24a is, for example, a diode bridge combining four rectifying elements. The rectifier 24a is, for example, a full-wave rectifier. The rectified power is, for example, pulsating power.

The smoothing capacitor 24b converts the rectified power output from the rectifier 24a into DC power by smoothing the rectified power. The converter 24c converts the DC power of the smoothing capacitor 24b into another DC power corresponding to the electronic switch 12, etc. The converter 24c is, for example, a step-down DC-DC converter that steps down DC power of about 140V to DC power of 12V. The output capacitor 24d suppresses noise and the like contained in the DC power output from the converter 24c, and stabilizes the DC power supplied to the pair of connection terminals 23a, 23b.

This allows the power supplied from the power source 2 to be converted into DC power compatible with the electronic switch 12, etc. However, the configuration of the conversion circuit 24 is not limited to the above. The configuration of the conversion circuit 24 may be any configuration depending on the power of the power source 2 and the magnitude of the DC power required by the electronic switch 12, etc. The configuration of the conversion circuit 24 may be any configuration that can appropriately convert the power supplied from the power source 2 into DC power compatible with the electronic switch 12, etc. Furthermore, the magnitude of the DC power (DC voltage) supplied to the pair of connection terminals 23a, 23b is not limited to the above, and may be any magnitude required by the electronic switch 12, etc.

The signal generating unit 25 is capable of transmitting a signal to the electronic switch 12 by changing the voltage between a pair of connection terminals 23a, 23b.

The signal generating unit 25 has, for example, a Zener diode 25a and a switching element 25b. The switching element 25b has, for example, a pair of main terminals and a control terminal. The switching element 25b is, for example, a semiconductor switch such as a transistor. The cathode of the Zener diode 25a is connected to the high-potential side connection terminal 23a. The anode of the Zener diode 25a is connected to one main terminal of the switching element 25b. The other main terminal of the switching element 25b is connected to the low-potential side connection terminal 23b. The control terminal of the switching element 25b is connected to the control unit 27.

When the switching element 25b is in the OFF state, the DC voltage output from the conversion circuit 24 is applied between the pair of connection terminals 23a, 23b. For example, a DC voltage of 12 V is applied between the pair of connection terminals 23a, 23b. On the other hand, when the switching element 25b is in the ON state, a part of the DC current output from the conversion circuit 24 flows to the signal generating unit 25 side, and the voltage between the pair of connection terminals 23a, 23b drops to a voltage corresponding to the breakdown voltage of the Zener diode 25a. When the switching element 25b is in the ON state, for example, the voltage between the pair of connection terminals 23a, 23b drops to about 4 V.

As a result, the voltage between the pair of connection terminals 23a, 23b can be changed by switching the switching element 25b on and off. A predetermined signal can be superimposed on the voltage between the pair of connection terminals 23a, 23b. However, the configuration of the signal generating unit 25 is not limited to the above, and any configuration that can change the voltage between the pair of connection terminals 23a, 23b may be used.

The voltage detection unit 26 detects the voltage between the pair of connection terminals 23a, 23b, thereby making it possible to receive a signal transmitted from the electronic switch 12. The voltage detection unit 26 has, for example, a pair of resistance elements 26a, 26b connected in series between the pair of connection terminals 23a, 23b, and is able to detect the voltage between the pair of connection terminals 23a, 23b by voltage division of the pair of resistance elements 26a, 26b.

The voltage detection unit 26 inputs the detection result of the voltage between the pair of connection terminals 23a, 23b to the control unit 27. The control unit 27 is connected, for example, to the connection point of the pair of resistance elements 26a, 26b connected in series. As a result, the voltage value divided by the pair of resistance elements 26a, 26b is input to the control unit 27. However, the configuration of the voltage detection unit 26 is not limited to the above, and may be any configuration that can appropriately detect the voltage between the pair of connection terminals 23a, 23b.

The control unit 27 controls the operation of the signal generating unit 25, transmits a signal to the electronic switch 12, and receives a signal transmitted from the electronic switch 12 based on the voltage detected by the voltage detecting unit 26, thereby enabling information regarding the state of the power supply to the load 4 to be shared with the electronic switch 12.

As described above, the control unit 27 is connected to the control terminal of the switching element 25b. The control unit 27 controls the operation of the signal generating unit 25 to change the voltage between the pair of connection terminals 23a, 23b by controlling the on/off switching of the switching element 25b. However, the method of controlling the operation of the signal generating unit 25 by the control unit 27 is not limited to this, and any control method may be used depending on the configuration of the signal generating unit 25, etc.

The electronic switch 11 further includes a step-down circuit 28. The step-down circuit 28 generates a control power supply according to the control unit 27 by stepping down the voltage between the pair of connection terminals 23a, 23b to a voltage according to the control unit 27, and supplies the control power supply to the control unit 27. The control unit 27 operates in response to the supply of the control power supply from the step-down circuit 28.

The step-down circuit 28, for example, steps down the 12 V DC voltage between the pair of connection terminals 23a, 23b to a 3 V DC voltage. The step-down circuit 28 is, for example, a regulator. However, the magnitude of the voltage of the control power supply is not limited to 3 V, and may be any magnitude that is lower than the voltage between the pair of connection terminals 23a, 23b and that can properly operate the control unit 27 and the like. The step-down circuit 28 may be configured in any manner that can properly generate the control power supply.

The signal generating unit 25 changes the voltage between the pair of connection terminals 23a, 23b between a first voltage and a second voltage. The first voltage is, for example, the same as the output voltage of the conversion circuit 24. The first voltage is, for example, 12V. The second voltage is set to a value lower than the first voltage and higher than the voltage of the control power supply. For example, when the first voltage is 12V and the voltage of the control power supply is 3V, the second voltage is set to about 4V. The first voltage is, for example, the voltage when the switching element 25b is in the OFF state, and the second voltage is, for example, the voltage when the switching element 25b is in the ON state.

In this way, by setting the second voltage to a value lower than the first voltage and higher than the voltage of the control power supply, it is possible to prevent the operation of the control unit 27 from becoming unstable due to a drop in the voltage of the control power supply, even when the voltage between the pair of connection terminals 23a, 23b is changed based on the operation of the signal generation unit 25. In other words, the conversion circuit 24 converts the power supplied from the power supply 2 into DC power of a first voltage higher than the voltage of the control power supply of the control unit 27, and supplies the converted DC power between the pair of connection terminals 23a, 23b.

The electronic switch 11 further has a sensor unit 29 (input unit) and an operation unit 30 (input unit). The sensor unit 29 detects an approaching human body. The sensor unit 29 is, for example, a pyroelectric sensor, an infrared distance sensor, or a radio wave sensor. The sensor unit 29 is connected to the control unit 27, and inputs a detection signal representing the detection result of the human body detection to the control unit 27 as an input signal. The detection signal has a non-detection state representing that a human body is not detected, and a detection state representing that a human body is detected.

The control unit 27 controls the operation of the opening/closing unit 22 based on the detection signal input from the sensor unit 29. When the detection signal is in a non-detection state, the control unit 27 places the opening/closing unit 22 in a state where the supply of power to the load 4 is stopped, and when the detection signal is in a detection state, the control unit 27 places the opening/closing unit 22 in a state where the supply of power to the load 4 is started. This allows the electronic switch 11 to function as a human sensor switch. For example, if the load 4 is a lighting device, the load 4 can be turned on in response to detection by the sensor unit 29, and turned off in response to non-detection by the sensor unit 29.

The sensor unit 29 may be, for example, an electrostatic sensor that detects the approach of a human hand or the like in a non-contact manner. In this case, the electronic switch 11 can function as a non-contact switch.

The control unit 27 also controls the operation of the signal generating unit 25 based on the detection signal input from the sensor unit 29, thereby transmitting a signal corresponding to the detection signal to the electronic switch 12. This allows the state of the power supply to the load 4 based on the detection of the sensor unit 29 to be shared with the electronic switch 12. In other words, the electronic switch 12 can also determine whether the load 4 is being supplied with power or the supply of power to the load 4 has been stopped based on the detection of the sensor unit 29 of the electronic switch 11.

The operation unit 30 receives operation input. The operation unit 30 is, for example, a mechanical switch or a touch sensor. The operation unit 30 is connected to the control unit 27, and inputs an operation signal corresponding to the operation input to the control unit 27 as an input signal.

The control unit 27 has, for example, a sensor input mode in which the supply of power to the load 4 is switched based on the input of the sensor unit 29, a forced on mode in which power is supplied to the load 4 regardless of the input of the sensor unit 29, and a forced off mode in which the supply of power to the load 4 is stopped regardless of the input of the sensor unit 29.

The operation signal has, for example, a state for selecting the sensor input mode, a state for selecting the forced on mode, and a state for selecting the forced off mode. The control unit 27 controls the operation of the opening/closing unit 22 based on the operation signal input from the operation unit 30. When the sensor input mode is selected, the control unit 27 controls the operation of the opening/closing unit 22 based on the detection signal input from the sensor unit 29, as described above. When the forced on mode is selected, the control unit 27 sets the opening/closing unit 22 to a state in which it supplies power to the load 4. And when the forced off mode is selected, the control unit 27 sets the opening/closing unit 22 to a state in which it stops supplying power to the load 4.

The control unit 27 also controls the operation of the signal generating unit 25 based on the operation signal input from the operation unit 30, thereby transmitting a signal corresponding to the operation signal to the electronic switch 12. This allows the state of the power supply to the load 4 based on the operation of the operation unit 30 to be shared with the electronic switch 12. In other words, the settings of each mode, the sensor input mode, the forced on mode, and the forced off mode, can also be grasped on the electronic switch 12 side.

In this way, the control unit 27 controls the operation of the opening/closing unit 22 based on the input signals, that is, the detection signal and the operation signal, thereby switching the supply of power from the power source 2 to the load 4 in response to the detection signal and the operation signal, and transmits a signal corresponding to the detection signal and the operation signal to the electronic switch 12 by controlling the operation of the signal generating unit 25 based on the detection signal and the operation signal.

The control unit 27 may control the operation of the opening/closing unit 22 at the timing when it receives the detection signal and the operation signal (input signal), or it may control the operation of the signal generating unit 25 based on the detection signal and the operation signal, and control the operation of the opening/closing unit 22 at the timing when it receives a signal based on the operation of the signal generating unit 25 based on the voltage detected by the voltage detecting unit 26.

The electronic switch 12 has a pair of connection terminals 40a, 40b (a pair of second connection terminals), a signal generating unit 41 (a second signal generating unit), a voltage detecting unit 42 (a second voltage detecting unit), and a control unit 43 (a second control unit).

The pair of connection terminals 40a, 40b are terminals for connecting the electronic switch 11 (another electronic switch). The pair of connection terminals 40a, 40b are connected to the pair of connection terminals 23a, 23b of the electronic switch 11. More specifically, one connection terminal 40a is connected to one connection terminal 23a of the electronic switch 11, and the other connection terminal 40b is connected to the other connection terminal 23b of the electronic switch 11.

As a result, the electronic switch 12 receives power from the electronic switch 11 via the pair of connection terminals 23a, 23b and the pair of connection terminals 40a, 40b, and transmits and receives signals to and from the electronic switch 11 via the pair of connection terminals 23a, 23b and the pair of connection terminals 40a, 40b.

The signal generating unit 41 is capable of transmitting a signal to the electronic switch 11 by changing the voltage between the pair of connection terminals 40a, 40b. The signal generating unit 41 has, for example, a Zener diode 41a and a switching element 41b. The configuration of the signal generating unit 41 is substantially the same as the configuration of the signal generating unit 25, so a detailed description is omitted. However, the configuration of the signal generating unit 41 does not necessarily have to be the same as the configuration of the signal generating unit 25. The configuration of the signal generating unit 41 may be any configuration that is capable of changing the voltage between the pair of connection terminals 40a, 40b.

The voltage detection unit 42 detects the voltage between the pair of connection terminals 40a, 40b, thereby making it possible to receive a signal transmitted from the electronic switch 11. The voltage detection unit 42 has, for example, a pair of resistance elements 42a, 42b connected in series between the pair of connection terminals 40a, 40b. The configuration of the voltage detection unit 42 is substantially the same as the configuration of the voltage detection unit 26, and therefore a detailed description is omitted. However, the configuration of the voltage detection unit 42 does not necessarily have to be the same as the configuration of the voltage detection unit 26. The configuration of the voltage detection unit 42 may be any configuration that can appropriately detect the voltage between the pair of connection terminals 40a, 40b.

The control unit 43 controls the operation of the signal generation unit 41, transmits a signal to the electronic switch 11, and receives a signal transmitted from the electronic switch 11 based on the voltage detected by the voltage detection unit 42, thereby enabling information regarding the state of power supply to the load 4 to be shared with the electronic switch 11.

The control unit 43 is connected to the control terminal of the switching element 41b. The control unit 43 controls the operation of the signal generating unit 41 to change the voltage between the pair of connection terminals 40a, 40b by controlling the on/off switching of the switching element 41b. However, the method of controlling the operation of the signal generating unit 41 by the control unit 43 is not limited to this, and any control method may be used depending on the configuration of the signal generating unit 41, etc.

The electronic switch 12 further includes a step-down circuit 44. The step-down circuit 44 generates a control power supply according to the control unit 43 by stepping down the voltage between the pair of connection terminals 40a, 40b to a voltage according to the control unit 43, and supplies the control power supply to the control unit 43. The control unit 43 operates in response to the supply of the control power supply from the step-down circuit 44. The configuration of the step-down circuit 44 is substantially the same as the configuration of the step-down circuit 28, so a detailed description will be omitted.

Similar to the signal generating unit 25, the signal generating unit 41 changes the voltage between the pair of connection terminals 40a, 40b between a first voltage and a second voltage. The second voltage is set to a value lower than the first voltage and higher than the voltage of the control power supply.

The electronic switch 12 further includes a sensor unit 45 (input unit) and a display unit 46. The sensor unit 45 detects an approaching human body. The configuration of the sensor unit 45 is similar to that of the sensor unit 29, so a detailed description is omitted.

The control unit 43 controls the operation of the signal generating unit 41 based on the detection signal input from the sensor unit 45, thereby transmitting a signal corresponding to the detection signal to the electronic switch 11.

The control unit 27 of the electronic switch 11 receives a signal transmitted from the electronic switch 12 based on the voltage detected by the voltage detection unit 26, and switches the supply of power from the power source 2 to the load 4 in response to the signal transmitted from the electronic switch 12. This allows the electronic switch 12 in the electronic switch system 10 to function as a motion sensor switch or a non-contact switch. The electronic switch 11 shares the detection result of the sensor unit 45 with the electronic switch 12, and can switch the state of the power supply to the load 4 based on the detection result of the sensor unit 45.

The display unit 46 displays information related to the state of power supply to the load 4. The display unit 46 is, for example, an indicator lamp that is lit to indicate that power is being supplied to the load 4 and is turned off to indicate that power supply to the load 4 is stopped. For example, if the amount of power supplied to the load 4 can be adjusted, the display unit 46 may be a seven-segment display or liquid crystal display that numerically indicates the amount of power supplied to the load 4.

For example, if the load 4 is a lighting device and the electronic switch 11 has a function of dimming the load 4, the display unit 46 may numerically display the dimming level setting of the load 4. For example, if the electronic switch 11 has a delay function that delays the timing of switching from a state in which power is supplied to the load 4 to a state in which power supply is stopped, and the time for which the switching timing is delayed can be adjusted, the display unit 46 may numerically display the delay time setting.

However, the content displayed by the display unit 46 is not limited to the above, and may be any content depending on the state in which power is being supplied to the load 4. The configuration of the display unit 46 is not limited to the above, and may be any configuration depending on the content of the display, etc.

The control unit 43 controls the operation of the display unit 46 based on the detection signal (input signal) input from the sensor unit 45, thereby causing the display unit 46 to display according to the detection signal. The control unit 43 also receives a signal transmitted from the electronic switch 11 based on the voltage detected by the voltage detection unit 42, and controls the display of the display unit 46 based on the signal transmitted from the electronic switch 11, thereby causing the display unit 46 to display according to the signal transmitted from the electronic switch 11.

As a result, even if, for example, the electronic switch 12 is installed at a position away from the load 4 and the power supply status to the load 4 cannot be confirmed visually, the power supply status to the load 4 can be confirmed by referring to the display on the display unit 46.

The control unit 43 may control the display of the display unit 46 at the timing when it receives a detection signal from the sensor unit 45, or it may control the operation of the signal generating unit 41 based on the detection signal and control the display of the display unit 46 at the timing when it receives a signal based on the operation of the signal generating unit 41 based on the voltage detected by the voltage detecting unit 42.

In the electronic switch system 10, the state of power supply to the load 4 changes based on detection by the sensor unit 29 of the electronic switch 11 or operation input by the operation unit 30, and the display of the display unit 46 of the electronic switch 12 also changes according to the state of power supply to the load 4 based on the signal sent from the electronic switch 11 to the electronic switch 12. In the electronic switch system 10, the display of the display unit 46 changes based on detection by the sensor unit 45 of the electronic switch 12, and the state of power supply to the load 4 also changes based on the signal sent from the electronic switch 12 to the electronic switch 11.

In this way, in the electronic switch system 10, both electronic switch 11 and electronic switch 12 can share information regarding the state of the power supply to load 4 and perform operations according to the information regarding the state of the power supply to load 4.

The electronic switch 11 may further include a display unit for displaying information. The electronic switch 12 may further include an operation unit for receiving operation input.

The electronic switch 12 further has a pair of connection terminals 47a, 47b (a pair of third connection terminals) connected to the pair of connection terminals 40a, 40b. The connection terminal 47a is connected to the connection terminal 40a. The connection terminal 47b is connected to the connection terminal 40b.

For example, when the electronic switch system 10 includes multiple electronic switches 12, the pair of connection terminals 47a, 47b is used to connect another electronic switch 12. The pair of connection terminals 47a, 47b is connected to the pair of connection terminals 40a, 40b of the other electronic switch 12. The pair of connection terminals 47a, 47b is, for example, a feed terminal.

One of the multiple electronic switches 12 is connected to the electronic switch 11 by connecting a pair of connection terminals 40a, 40b to a pair of connection terminals 23a, 23b of the electronic switch 11, and another of the multiple electronic switches 12 is connected to the electronic switch 11 via the one electronic switch 12 by connecting a pair of connection terminals 40a, 40b to a pair of connection terminals 47a, 47b of the one electronic switch 12.

In this way, the multiple electronic switches 12 are connected to the electronic switch 11 via a pair of connection terminals 47a, 47b of another electronic switch 12. The electronic switch 11 is connected to the multiple electronic switches 12 via a pair of connection terminals 23a, 23b. However, the electronic switch 12 does not necessarily have to have a pair of connection terminals 47a, 47b. The pair of connection terminals 47a, 47b does not necessarily have to be provided on each of the multiple electronic switches 12.

The multiple electronic switches 12 are connected in parallel to a pair of connection terminals 23a, 23b of the electronic switch 11. This makes it possible to change the voltage between the pair of connection terminals 23a, 23b by the operation of the signal generating unit 41 of any of the multiple electronic switches 12, and send a signal to the electronic switch 11 and each of the multiple electronic switches 12. Therefore, information regarding the state of power supply to the load 4 can be shared between the electronic switch 11 and each of the multiple electronic switches 12.

However, when the electronic switch system 10 includes multiple electronic switches 12 (multiple child devices), the connection form of the multiple electronic switches 12 to the electronic switch 11 (parent device) is not limited to the above. The connection form of the multiple electronic switches 12 to the electronic switch 11 may be any connection form that allows the electronic switch 11 and each of the multiple electronic switches 12 to share information about the state of power supply to the load 4.

2A to 2D are waveform diagrams each showing a schematic example of a signal.
FIG. 3 is a table showing a schematic example of a signal.
2A and 2C are schematic diagrams showing an example of a signal input from the control unit 27, 43 to the signal generating unit 25, 41. More specifically, they are schematic diagrams showing an example of a signal input from the control unit 27, 43 to the control terminal of the switching element 25b, 41b of the signal generating unit 25, 41.
2(b) and 2(d) show schematic examples of signals generated by the signal generating units 25 and 41. In other words, FIG. 2(b) and FIG. 2(d) show schematic examples of voltages between the pair of connection terminals 23a and 23b (between the pair of connection terminals 40a and 40b).

As shown in Figures 2(a) to 2(d) and 3, the signal generating units 25 and 41 generate a pulse signal containing multiple pulses by changing the voltage between a pair of connection terminals 23a and 23b (between a pair of connection terminals 40a and 40b), and can generate multiple pulse signals with different contents by combining high and low states of the multiple pulses.

The pulse signal (the voltage between the pair of connection terminals 23a, 23b) becomes high, for example, by setting the voltage of the control terminals of the switching elements 25b, 41b low and turning the switching elements 25b, 41b off, and becomes low by setting the voltage of the control terminals of the switching elements 25b, 41b high and turning the switching elements 25b, 41b on. However, the method of setting the pulse signal high and low is not limited to the above, and any method may be used depending on the configuration of the signal generating units 25, 41, etc.

By changing the pulse width and number of times, it is possible to handle multiple different signals. For example, as shown in Figure 3, in addition to the normal on/off, a forced on/off mode that forces the sensor units 29 and 45 to be on/off regardless of their state can be provided, making it possible to handle situations where it is not desired to operate the sensor units 29 and 45, such as during maintenance.

The first pulse of the multiple pulses of the multiple pulse signal represents the priority of the pulse signal. The remaining pulses of the multiple pulse signal represent the content of the pulse signal. This example shows a case where multiple contents are represented by combinations of high and low pulses.

The multiple pulse signals are divided into a first pulse signal and a second pulse signal that has a higher priority than the first pulse signal. Figures 2(a) and 2(b) show an example of a first pulse signal. Figures 2(c) and 2(d) show an example of a second pulse signal.

In this example, the signal that switches the power supply to the load 4 based on the detection of the sensor units 29 and 45 is a first pulse signal with a low priority, and the signal that sets and cancels the forced-on mode and the forced-off mode is a second pulse signal with a high priority. However, the signal set as the first pulse signal and the signal set as the second pulse signal are not limited to the above and may be any signal.

As shown in Figures 2(a) to 2(d), in the first pulse signal and the second pulse signal, the pulse width of the first pulse is longer than the pulse width of the remaining pulses. For example, the pulse width of the first pulse of the first pulse signal is set to 5 ms, and the pulse width of the remaining pulses of the first pulse signal is set to 2 ms. The pulse width of the first pulse of the second pulse signal is set to 20 ms, and the pulse width of the remaining pulses of the second pulse signal is set to 2 ms. In addition, the interval between each pulse is set to 2 ms.

The control units 27 and 43 stop transmitting signals from themselves in response to receiving the first pulse, for example. This can prevent, for example, signals from both the electronic switches 11 and 12 being transmitted, causing the operation of the electronic switches 11 and 12 to become unstable. For example, it can prevent the pulse signal transmitted from the electronic switch 11 and the pulse signal transmitted from the electronic switch 12 from overlapping with a slight misalignment, resulting in an unintended control state.

2(a) to 2(d), the pulse width T1 of the first pulse of the second pulse signal is longer than the total length T2 of the remaining pulses of the first pulse signal. For example, when the control unit 27 of the electronic switch 11 receives an operation signal from the operation unit 30 while receiving the first pulse signal transmitted from the electronic switch 12, the control unit 27 may transmit the second pulse signal without waiting for the completion of reception of the first pulse signal. In this case, as described above, the pulse width T1 of the first pulse of the second pulse signal is made longer than the total length T2 of the remaining pulses of the first pulse signal, so that the first pulse of the second pulse signal can be overlapped with the remaining pulses of the first pulse signal. This allows the electronic switch 12 to appropriately receive the second pulse signal with a higher priority even when the transmission of the second pulse signal is started while receiving the first pulse signal. For example, it is possible to prevent the remaining pulses of the first pulse signal from overlapping with the remaining pulses of the second pulse signal, resulting in an unintended control state. The pulse width T1 of the first pulse of the second pulse signal may be longer than the total length of the first pulse signal, for example. This allows the second pulse signal, which has a higher priority, to be received more appropriately.

For example, when two electronic switches are connected by two wires, one of which acts as a parent device connected to a power source and load, and the other as a child device connected to the parent device, the child device may only have a transmission function to the parent device and no reception function. In this case, the child device will not be able to grasp the contents of the operations performed on the parent device, and its functionality will be limited.

In contrast, in the electronic switch system 10 according to this embodiment, both the electronic switch 11 and the electronic switch 12 share information about the state of the power supply to the load 4 with each other, and can perform operations according to the information about the state of the power supply to the load 4. This allows the electronic switch 11 and the electronic switch 12 to have more functions. In other words, it is possible to realize an electronic switch with high control versatility.

For example, a display unit 46 can be provided on the child electronic switch 12, and the display corresponding to the operation performed on the parent electronic switch 11 can be reflected on the display unit 46 of the electronic switch 12.

Furthermore, electronic switch 11 and electronic switch 12 transmit and receive signals by changing the voltage between the two wires connected to each other. With electronic switch 11 and electronic switch 12, the supply of power from electronic switch 11 to electronic switch 12 and the transmission and reception of signals can be achieved using only the same two wires. Therefore, there is no need to add wiring for transmitting and receiving signals, and information can be shared with a simpler configuration. With electronic switch 11 and electronic switch 12, it is possible to provide more functions with a simple configuration. In other words, an electronic switch with high control versatility can be realized.

In the above embodiment, the sensor units 29, 45 and the operation unit 30 are shown as examples of input units that input an input signal to the control unit. The input unit is not limited to this. The input unit may be, for example, a receiver for receiving a signal from a remote control or a smartphone, a light sensor for switching the power supply to the load 4 depending on the ambient brightness, a microphone for switching the power supply to the load 4 by voice operation, or a camera for switching the power supply to the load 4 by image processing. The input unit is not limited to the above and may be any device for inputting any input signal.

Second Embodiment
FIG. 4 is an explanatory diagram illustrating a schematic diagram of an electronic switch system according to the second embodiment.
FIG. 5 is a table showing an example of a signal.
4, the electronic switch system 10a further includes an electronic switch 13 (a second electronic switch) and an electronic switch 14 (a second electronic switch). Note that the same reference numerals are used for components that are substantially the same in function and configuration as those in the above embodiment, and detailed descriptions thereof will be omitted.

Like electronic switch 12, electronic switches 13 and 14 are child devices connected to electronic switch 11, which is a parent device. Electronic switch system 10a includes multiple child devices (multiple second electronic switches). The configuration of electronic switches 13 and 14 can be the same as that of electronic switch 12, so detailed description will be omitted.

The electronic switch 11 is connected to the multiple electronic switches 12 to 14 via a pair of connection terminals 23a, 23b. The electronic switch 12 is connected to the electronic switch 11 by connecting a pair of connection terminals 40a, 40b to a pair of connection terminals 23a, 23b of the electronic switch 11. The electronic switch 13 is connected to the electronic switch 11 via the electronic switch 12 by connecting a pair of connection terminals 40a, 40b to a pair of connection terminals 47a, 47b of the electronic switch 12. The electronic switch 14 is connected to the electronic switch 11 via the electronic switches 12 and 13 by connecting a pair of connection terminals 40a, 40b to a pair of connection terminals 47a, 47b of the electronic switch 13.

In this way, one electronic switch 12 of the multiple electronic switches 12 to 14 is connected to the electronic switch 11 by connecting a pair of connection terminals 40a, 40b to a pair of connection terminals 23a, 23b of the electronic switch 11, and another electronic switch 13 of the multiple electronic switches 12 to 14 is connected to the electronic switch 11 via the one electronic switch 12 by connecting a pair of connection terminals 40a, 40b to a pair of connection terminals 47a, 47b of the one electronic switch 12.

In this example, the load 4 is, for example, a lighting device. The electronic switch 12 functions, for example, as a switch that switches the load 4 on and off. The electronic switch 12 has, for example, a sensor unit 45, and switches the load 4 on and off (switches between supplying and stopping power) based on detection by the sensor unit 45. The electronic switch 12 may also have multiple operation units 48, and be able to switch the load 4 on and off based on the operation of the multiple operation units 48. The configuration of the operation unit 48 can be the same as the configuration of the operation unit 30, so a detailed description will be omitted.

The electronic switch 13 functions, for example, as a dimmer that switches the brightness of the light emitted from the load 4 (the amount of power supplied to the load 4). The electronic switch 13 has, for example, a plurality of operation units 48, and can set the degree of dimming based on the operation of the plurality of operation units 48. The electronic switch 13 also has, for example, a display unit 46, and can display the set degree of dimming on the display unit 46.

The electronic switch 14 functions, for example, as a delay switch for setting a delay time for delaying the timing of switching the power supplied to the load 4. The electronic switch 14 has, for example, a plurality of operation units 48, and is capable of setting the delay time based on the operation of the plurality of operation units 48. The electronic switch 14 also has, for example, a display unit 46, and is capable of displaying the set delay time on the display unit 46.

For example, as shown in FIG. 5, by setting the pulse width and number of times so that different processes are performed in response to various types of signals, multiple child devices (electronic switches 12-14) with different functions according to the application can be connected to the parent device (electronic switch 11). In addition, since all of these signals are shared by both the parent device and the child device, the user can be informed of the status by displaying it on the child device's display unit 46.

In this way, the number of child devices connected to the electronic switch 11 as the parent device is not limited to one, but may be multiple. The number of child electronic switches connected to the electronic switch 11 as the parent device is not limited to three as described above, but may be any number. The functions of the electronic switch 11 as the parent device are not limited to the above, but may be any function. The functions of the electronic switches 12 to 14 as the child devices are not limited to the above, but may be any function. The functions of each electronic switch may be set appropriately depending on the function of the load 4, etc. When multiple child devices are connected to the parent device, the pair of connection terminals 47a, 47b may not necessarily be provided on each of the multiple child devices. For example, in the above example, the electronic switch 14 located at the very end may not have a pair of connection terminals 47a, 47b (a pair of third connection terminals). The pair of connection terminals 47a, 47b may be provided on at least one child device located between the parent device and another child device.

The present embodiment includes the following aspects.
(Appendix 1)
An electronic switch that switches between supplying and stopping power to a load,
a pair of connection terminals for connecting another electronic switch;
a signal generating unit capable of transmitting a signal to the other electronic switch by changing a voltage between the pair of connection terminals;
a voltage detection unit that detects a voltage between the pair of connection terminals to thereby be able to receive a signal transmitted from the other electronic switch;
a control unit that controls an operation of the signal generating unit, transmits a signal to the other electronic switch, and receives a signal transmitted from the other electronic switch based on a voltage detected by the voltage detecting unit, thereby enabling information regarding a state of power supply to the load to be shared with the other electronic switch;
An electronic switch with

(Appendix 2)
An input unit that inputs an input signal to the control unit,
2. The electronic switch according to claim 1, wherein the control unit controls an operation of the signal generating unit based on the input signal to transmit a signal corresponding to the input signal to the other electronic switch.

(Appendix 3)
A display unit that displays information related to a state of power supply to the load,
3. The electronic switch according to claim 1, wherein the control unit controls a display on the display unit based on a signal transmitted from the other electronic switch.

(Appendix 4)
the signal generating unit generates a pulse signal including a plurality of pulses by changing a voltage between the pair of connection terminals, and is capable of generating a plurality of the pulse signals having different contents by a combination of high and low of the plurality of pulses;
a first pulse of the plurality of pulses of a plurality of the pulse signals indicates a priority of the pulse signal;
a remaining pulse of the plurality of pulses of the plurality of pulse signals represents content of the pulse signal;
The plurality of pulse signals are divided into a first pulse signal and a second pulse signal having a higher priority than the first pulse signal,
4. The electronic switch according to claim 1, wherein a pulse width of the first pulse of the second pulse signal is longer than an overall length of the remaining pulses of the first pulse signal.

(Appendix 5)
a step-down circuit that generates a control power supply corresponding to the control unit by stepping down the voltage between the pair of connection terminals to a voltage corresponding to the control unit and supplies the control power supply to the control unit;
5. The electronic switch according to claim 1, wherein the signal generating unit changes a voltage between the pair of connection terminals between a first voltage and a second voltage that is lower than the first voltage and higher than a voltage of the control power supply.

(Appendix 6)
a power terminal for connecting a power source;
a load terminal for connecting a load;
a switching unit that switches between a state in which the power source supplies power to the load and a state in which the power source stops supplying power to the load;
a pair of connection terminals for connecting another electronic switch;
a conversion circuit that converts the power supplied from the power source into a predetermined DC power and enables the converted DC power to be supplied to the other electronic switch via the pair of connection terminals;
a signal generating unit capable of transmitting a signal to the other electronic switch by changing a voltage between the pair of connection terminals;
a control unit that controls an operation of the signal generating unit and transmits a signal to the other electronic switch, thereby enabling information regarding a state of power supply to the load to be shared with the other electronic switch;
An electronic switch with

(Appendix 7)
An input unit that inputs an input signal to the control unit,
The control unit controls the operation of the opening/closing unit based on the input signal to switch the supply of power from the power source to the load in accordance with the input signal, and controls the operation of the signal generating unit based on the input signal to transmit a signal in accordance with the input signal to the other electronic switch.

(Appendix 8)
a voltage detection unit that detects a voltage between the pair of connection terminals to receive a signal transmitted from the other electronic switch,
The electronic switch according to claim 6 or 7, wherein the control unit receives a signal transmitted from the other electronic switch based on the voltage detected by the voltage detection unit, and switches the supply of power from the power source to the load in response to the signal transmitted from the other electronic switch.

(Appendix 9)
a first electronic switch coupled to the power source and to the load;
a second electronic switch connected to the first electronic switch;
Equipped with
The first electronic switch is
a power supply terminal for connecting the power supply;
a load terminal for connecting the load;
a switching unit that switches between a state in which the power source supplies power to the load and a state in which the power source stops supplying power to the load;
a pair of first connection terminals for connecting the second electronic switch;
a conversion circuit that converts the power supplied from the power source into a predetermined DC power and enables the converted DC power to be supplied to the second electronic switch via the pair of first connection terminals;
a first signal generating unit capable of transmitting a signal to the second electronic switch by changing a voltage between the pair of first connection terminals;
a first voltage detection unit that detects a voltage between the pair of first connection terminals to receive a signal transmitted from the second electronic switch;
a first control unit that controls an operation of the first signal generating unit, transmits a signal to the second electronic switch, and receives a signal transmitted from the second electronic switch based on a voltage detected by the first voltage detecting unit, thereby enabling information regarding a state of power supply to the load to be shared with the second electronic switch;
having
The second electronic switch is
a pair of second connection terminals for connecting the first electronic switch;
a second signal generating unit capable of transmitting a signal to the first electronic switch by changing a voltage between the pair of second connection terminals;
a second voltage detection unit that detects a voltage between the pair of second connection terminals to receive a signal transmitted from the first electronic switch;
a second control unit that controls an operation of the second signal generating unit, transmits a signal to the first electronic switch, and receives a signal transmitted from the first electronic switch based on a voltage detected by the second voltage detecting unit, thereby enabling information regarding a state of power supply to the load to be shared with the first electronic switch;
An electronic switch system having

(Appendix 10)
A plurality of the second electronic switches are provided,
10. The electronic switch system according to claim 9, wherein the first electronic switch is connected to a plurality of the second electronic switches via the pair of first connection terminals.

(Appendix 11)
Each of the second electronic switches further includes a pair of third connection terminals connected to the pair of second connection terminals,
a second electronic switch among the plurality of second electronic switches is connected to the first electronic switch by connecting the pair of second connection terminals to the pair of first connection terminals of the first electronic switch;
11. The electronic switch system of claim 10, wherein another one of the plurality of second electronic switches is connected to the first electronic switch via the one second electronic switch by connecting the pair of second connection terminals to the pair of third connection terminals of the one second electronic switch.

Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the gist of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are included in the scope of the invention and its equivalents described in the claims.

2...power source, 4...load, 10, 10a...electronic switch system, 11 to 14...electronic switch, 20a, 20b...power source terminal, 21a, 21b...load terminal, 22...opening/closing section, 23a, 23b...connection terminal, 24...conversion circuit, 25...signal generation section, 26...voltage detection section, 27...control section, 28...step-down circuit, 29...sensor section, 30...operation section, 40a, 40b connection terminal, 41 signal generation section, 42 voltage detection section, 43 control section, 44...step-down circuit, 45...sensor section, 46...display section, 47a, 47b...connection terminal, 48...operation section

Claims (7)

An electronic switch that switches between supplying and stopping power to a load,
a pair of connection terminals for connecting another electronic switch;
a signal generating unit capable of transmitting a signal to the other electronic switch by changing a voltage between the pair of connection terminals;
a voltage detection unit that detects a voltage between the pair of connection terminals to thereby be able to receive a signal transmitted from the other electronic switch;
a control unit that controls an operation of the signal generating unit, transmits a signal to the other electronic switch, and receives a signal transmitted from the other electronic switch based on a voltage detected by the voltage detecting unit, thereby enabling information regarding a state of power supply to the load to be shared with the other electronic switch;
An electronic switch with the signal generating unit generates a pulse signal including a plurality of pulses by changing a voltage between the pair of connection terminals, and is capable of generating a plurality of the pulse signals having different contents by a combination of high and low of the plurality of pulses;
2. The electronic switch of claim 1, wherein a first pulse of said plurality of pulses of said pulse signal indicates a priority of said pulse signal. a step-down circuit that generates a control power supply corresponding to the control unit by stepping down the voltage between the pair of connection terminals to a voltage corresponding to the control unit and supplies the control power supply to the control unit;
3. The electronic switch according to claim 1, wherein the signal generating unit changes the voltage between the pair of connection terminals between a first voltage and a second voltage that is lower than the first voltage and higher than a voltage of the control power supply. a power terminal for connecting a power source;
a load terminal for connecting a load;
a switching unit that switches between a state in which the power source supplies power to the load and a state in which the power source stops supplying power to the load;
a pair of connection terminals for connecting another electronic switch;
a conversion circuit that converts the power supplied from the power source into a predetermined DC power and enables the converted DC power to be supplied to the other electronic switch via the pair of connection terminals;
a signal generating unit capable of transmitting a signal to the other electronic switch by changing a voltage between the pair of connection terminals;
a control unit that controls an operation of the signal generating unit and transmits a signal to the other electronic switch, thereby enabling information regarding a state of power supply to the load to be shared with the other electronic switch;
An electronic switch with a first electronic switch coupled to the power source and to the load;
a second electronic switch connected to the first electronic switch;
Equipped with
The first electronic switch is
a power supply terminal for connecting the power supply;
a load terminal for connecting the load;
a switching unit that switches between a state in which the power source supplies power to the load and a state in which the power source stops supplying power to the load;
a pair of first connection terminals for connecting the second electronic switch;
a conversion circuit that converts the power supplied from the power source into a predetermined DC power and enables the converted DC power to be supplied to the second electronic switch via the pair of first connection terminals;
a first signal generating unit capable of transmitting a signal to the second electronic switch by changing a voltage between the pair of first connection terminals;
a first voltage detection unit that detects a voltage between the pair of first connection terminals to receive a signal transmitted from the second electronic switch;
a first control unit that controls an operation of the first signal generating unit, transmits a signal to the second electronic switch, and receives a signal transmitted from the second electronic switch based on a voltage detected by the first voltage detecting unit, thereby enabling information regarding a state of power supply to the load to be shared with the second electronic switch;
having
The second electronic switch is
a pair of second connection terminals for connecting the first electronic switch;
a second signal generating unit capable of transmitting a signal to the first electronic switch by changing a voltage between the pair of second connection terminals;
a second voltage detection unit that detects a voltage between the pair of second connection terminals to receive a signal transmitted from the first electronic switch;
a second control unit that controls an operation of the second signal generating unit, transmits a signal to the first electronic switch, and receives a signal transmitted from the first electronic switch based on a voltage detected by the second voltage detecting unit, thereby enabling information regarding a state of power supply to the load to be shared with the first electronic switch;
An electronic switch system having A plurality of the second electronic switches are provided,
6. The electronic switch system according to claim 5, wherein the first electronic switch is connected to a plurality of the second electronic switches via the pair of first connection terminals. one second electronic switch among the plurality of second electronic switches is connected to the first electronic switch by connecting the pair of second connection terminals to the pair of first connection terminals of the first electronic switch, and further has a pair of third connection terminals connected to the pair of second connection terminals;
7. The electronic switch system according to claim 6, wherein another one of the plurality of second electronic switches is connected to the first electronic switch via the one second electronic switch by connecting the pair of second connection terminals to the pair of third connection terminals of the one second electronic switch.

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