JP2022523778A - An electronic device for adaptively controlling a lamp - Google Patents

Abstract

Electronic devices according to various embodiments are hot depending on the state of the switching circuit configured to electrically connect or disconnect the hotline of the AC power supply and the electronic device, and the state of the switching circuit. Hotlines and electronic devices with control circuits, rechargeable batteries, and switching circuits that are electrically connected to or disconnected from the hotline and electrically connected to the neutral line of the AC power supply. And, when electrically connected, are obtained from the battery, depending on the control of the charging circuit, which is configured to charge the battery and emit a light, based on the AC power supply, and the control circuit. It may include a battery power supply circuit configured to emit an electric light based on the power source. [Selection diagram] Fig. 1

Description

The present invention relates to an electronic device for adaptively controlling a lamp.

Various elements are used to control lamps using electrical signals.
For example, at least one of a switch, a resistor, a diode, or an amplifier may be used to control a lamp.

In order to provide safety during a blackout, emergency lights are installed in an infrastructure such as a building.
Such emergency lights require constant power supply, even though they are used only in the event of a power outage.

The present invention has been made in view of the above-mentioned problems in the electronic device for controlling a lamp, and an object of the present invention is to provide an electronic device for adaptively controlling a lamp.

The technical problems to be solved in the present specification are not limited to the technical problems mentioned above, and other technical problems not mentioned above are ordinary technical problems to which the present invention belongs from the following description. It is clearly understood by those who have knowledge.

An electronic device according to an aspect of the present invention made to achieve the above object is configured to electrically connect or electrically disconnect an AC power supply hotline and the electronic device. Depending on the state of the switching circuit and the switching circuit, it is electrically connected to or disconnected from the hotline and electrically connected to the neutral line of the AC power supply. When the hotline and the electronic device are electrically connected by the connected control circuit, the rechargeable battery, and the switching circuit, the battery is charged based on the AC power supply. A charging circuit configured to emit an electric light, and a battery power supply circuit configured to emit an electric light based on a power source acquired from the battery according to the control of the control circuit. The control circuit is the first node of the control circuit electrically connected to the hotline while the hotline and the electronic device are electrically connected by the switching circuit. And the battery power supply circuit from the battery based on identifying that the potential difference between the neutral line and the second node of the control circuit electrically connected is within the reference range. By electrically disconnecting, the light emission of the electric lamp is cut off based on the power source obtained from the battery, and the hotline and the electronic device are electrically disconnected by the switching circuit. The battery is based on identifying that the potential difference between the first node, which is electrically disconnected from the hotline, and the second node is within the reference range. By electrically disconnecting the battery power supply circuit from the above, the light emission of the electric lamp is cut off based on the power source obtained from the battery, and the switching circuit causes the hotline and the electronic device to be connected to each other. To identify that the potential difference between the hotline and the electrically disconnected first node and the second node while being electrically disconnected is outside the reference range. Based on the above, by electrically connecting the battery power supply circuit and the battery, the electric lamp is configured to emit light based on the power source acquired from the battery. ..

Further, the electronic device according to another aspect of the present invention made to achieve the above object is a first resistor configured to electrically connect a hot line of an AC power source and the electronic device. A switching circuit configured to electrically connect or electrically disconnect both ends of the first resistor, and an electrical line of the hotline and the AC power supply. When both ends of the first resistor are electrically connected by a control circuit connected to, a rechargeable battery, and the switching circuit, the battery is charged based on the AC power supply. A charging circuit configured to emit light and a battery power supply circuit configured to emit light based on a power source acquired from the battery according to the control of the control circuit. The control circuit is electrically connected to the first resistor, electrically connected to the neutral line, and has a rectifier configured to convert the AC power supply into a DC power supply, and the rectifier and electricity. A first terminal to be electrically connected, a second terminal to be electrically connected to a ground terminal, and an amplifier including an output terminal, which are input to the control circuit via the hot line and the neutral line. When the input voltage is equal to or higher than the reference voltage, the battery power supply circuit is electrically disconnected from the battery to cut off the light emission of the electric lamp based on the power source acquired from the battery. When the input voltage is less than the reference voltage, the battery power supply circuit and the battery are electrically connected so that the electric lamp is emitted based on the power source obtained from the battery. It is characterized by being done.

According to the electronic device according to the present invention, the emergency light is adaptively controlled by detecting a power failure and identifying the connection state between the AC power supply and the electronic device.
The effects obtained in the present disclosure are not limited to the effects mentioned above, and other effects not mentioned above are clearly understood by those having ordinary knowledge in the technical field to which the present disclosure belongs from the following description. Where is it?

It is a block diagram which shows the simplified structure of the electronic device by embodiment of this invention. It is a circuit diagram which shows the example of the circuit of the electronic device by embodiment of this invention. It is a circuit diagram which shows another example of the circuit of the electronic device by embodiment of this invention. It is a circuit diagram which shows another example of the circuit of the electronic device by embodiment of this invention.

The various embodiments of this document and the terminology used herein are not intended to limit the techniques described in this document to specific embodiments, but various modifications, equivalents, and / or alternatives to such embodiments. It should be understood to include things.
In the description of the drawings, the same reference numerals are given to the same components.
The singular representation may include multiple representations, unless otherwise specified in the context.
As used herein, such as "A or B", "at least one of A and / or B", "A, B or C" or "at least one of A, B and / or C". The representation can include all possible combinations of items listed together.
Expressions such as "first", "second", "first" or "second" can modify the component regardless of order or importance, one component to the other. It is used only to distinguish it from the components of, and does not limit the components.
It is said that one (eg, first) component is "(functionally or communically) connected" or "connected" to another (eg, second) component. When present, the one component can be directly connected to the other component or can be connected via another component (eg, a third component).

FIG. 1 is a block diagram showing a simplified configuration of an electronic device according to an embodiment of the present invention.
FIG. 2 is a circuit diagram showing an example of a circuit of an electronic device according to an embodiment of the present invention.
FIG. 3 is a circuit diagram showing another example of the circuit of the electronic device according to the embodiment of the present invention.
FIG. 4 is a circuit diagram showing another example of the circuit of the electronic device according to the embodiment of the present invention.

Referring to FIG. 1, the electronic device 1 may include a control circuit 3, a charging circuit 4, a battery 5, and a battery power supply circuit 6.
In various embodiments, the LED (light emitting diode) 7 may be a component of the electronic device 1 included in the electronic device 1 or a separate device outside the electronic device 1. ..
In some embodiments, the LED 7 can also be replaced by a lamp.
That is, the LED 7 is an example of an electric lamp.

In various embodiments, the control circuit 3 detects the state of a switching circuit (not shown in FIG. 1) for electrically connecting the LED 7 and the AC power supply.
In various embodiments, the switching circuit may be a component of the electronic device 1 included in the electronic device 1 or a separate device outside the electronic device 1 depending on the embodiment. good.
In various embodiments, the control circuit 3 detects the state of the switching circuit in order to identify whether the AC power supply and the LED 7 are electrically disconnected by the switching circuit.

In various embodiments, the control circuit 3 detects the state of the AC power source.
In various embodiments, the control circuit 3 identifies, based on the detection, whether or not the environment including the electronic device 1 is in a power outage state.
In various embodiments, the control circuit 3 controls the battery power supply circuit 6.
For example, the control circuit 3 controls the battery power supply circuit 6 based on the AC power supply so that the power supply from the battery 5 is not provided to the LED 7 while the LED 7 is emitting light.
In another example, the control circuit 3 controls the battery power supply circuit 6 so that the power from the battery 5 is not provided to the LED 7 while the AC power is not provided to the LED 7 without a power failure.
In yet another example, the control circuit 3 controls the battery power supply circuit 6 so that power from the battery 5 is provided to the LED 7 in the event of a power failure.

In various embodiments, the control circuit 3 electrically connects the AC power supply and the LED 7 from the ON state in which the switching circuit state in a non-power failure state electrically connects the AC power supply and the LED 7. Identifies whether to switch to the OFF state.
For example, the control circuit 3 determines whether or not the state of the switching circuit is switched from the on state to the off state in order to turn off the LED 7 after a specified time from the time when the state of the switching circuit is switched to the off state. Identify.

In various embodiments, the charging circuit 4 is based on the AC power source when the hot line of the AC power source and the electronic device 1 (or the LED 7) are electrically connected by a switching circuit. And is used to charge the battery 5.
In various embodiments, the charging circuit 4 emits light from the LED 7 based on AC power when the hotline and the electronic device 1 (or the LED 7) are electrically connected by a switching circuit. Used for.
In various embodiments, the battery 5 is configured to be rechargeable.

In various embodiments, the battery power supply circuit 6 either provides power from the battery 5 to the LED 7 or cuts off providing power from the battery 5 to the LED 7, depending on the control of the control circuit 3.
For example, when the LED 7 emits light based on an AC power source, the battery power supply circuit 6 can block the supply of power from the battery 5 to the LED 7.
In another example, the battery power supply circuit 6 provides power from the battery 5 to the LED 7 when the AC power supply and the LED 7 are electrically disconnected by the switching circuit in a non-power failure state. Block things.
In yet another example, during a power outage, the battery power supply circuit 6 applies to provide power from the battery 5 to the LED 7.

In various embodiments, the electronic device 1 is composed of various types of circuits.
For example, referring to FIG. 2, the electronic device 1 includes a light switch 20 corresponding to a switching circuit, a power failure detection unit 10 corresponding to a control circuit 3, a charging circuit 4, and a charging unit 30 and a battery unit 50 corresponding to the battery 5. , The battery power supply unit 60 corresponding to the battery power supply circuit 6 may be included.
On the other hand, the LED 7 corresponds to the emergency lighting 40.
In various embodiments, the power failure detection unit 10 calculates, analyzes, and determines the outputs of the high voltage prevention unit 11, the comparison unit 12 that amplifies and compares the signals input from the high voltage prevention unit 11, and the comparison unit 12. , Or may include a microprocessor 13 for storage.

Although not shown in FIG. 2, depending on the embodiment, a buffer may be included in the power failure detection unit 10.
For example, the buffer is operably coupled to the microprocessor 13 outside the microprocessor 13.
In another example, the buffer may be contained within microprocessor 13, but is not limited thereto.

In various embodiments, while the light switch 20 is in the off state of electrically disconnecting the AC power source and the emergency light 40, the charging unit 30 supplies power to the emergency light 40 based on the electrical disconnection. Cut off the supply of.
On the other hand, in various embodiments, the power failure sensing unit 10 is based on a signal input via the resistor R5 while the light switch 20 is in the off state of electrically disconnecting the AC power supply and the emergency lighting 40. It is detected that the state of the light switch 20 is an off state.

On the other hand, the voltage state (or power state) at the node F and the node G may differ depending on the environmental conditions while the light switch 20 is in the off state in which the AC power supply and the emergency lighting 40 are electrically disconnected.
In other words, while the light switch 20 is in the off state in which the AC power supply and the emergency lighting 40 are electrically disconnected, the input voltages of both the nodes F and the node G of the power failure detection unit 10 depend on the environmental conditions. Can be different.
In consideration of such a point, the power failure detection unit 10 uses an amplifier composed of a resistor R1, a resistor R2, a resistor R3, and an OpAmp (U1) for the input voltage of both the terminals of the node F and the node G. By amplifying, the capacitor C2 is charged via the diode D3, and a signal at least based on the charge is output via the terminal A.

In various embodiments, the signal output via the terminal A is input into the microprocessor 13, and the signal input into the microprocessor 13 is "A-to-D (analog to)" in the microprocessor 13. After being converted into a value (for example, a digital value) by a "digital) converter", it is stored in a buffer.
If there is a previous stored value in the buffer, the microprocessor 13 compares the previous stored value with the value and stores the smaller value of the value and the previous stored value in the buffer.
Such an operation is repeated for a specified time.
After the specified time has elapsed, the microprocessor 13 interrupts the execution repeatedly, and the value stored in the buffer is used as a reference for determining whether or not the environment in which the electronic device 1 is located is a power failure. Set as a value.

On the other hand, in various embodiments, the microprocessor 13 identifies that the signal output via the terminal A of the comparison unit 12 is equal to or larger than the reference value (or reference voltage), and the terminal. A low signal is output via E. The low signal output via the terminal E is input to the battery power supply unit 60.
Since the low signal input to the battery power supply unit 6 turns off the transistor Q3, the coil corresponding to the relay K is de-energized. The battery unit 50 and the emergency lighting 40 are electrically disconnected from each other by de-energy.

On the other hand, in various embodiments, the microprocessor 13 can switch to sleep mode in order to reduce power consumption.
The microprocessor 13 in the sleep mode shifts to the wake-up state after a specified time has elapsed from the time when the microprocessor 13 is converted to the sleep mode.
The microprocessor 13 that has entered the wake-up state compares the signal input via the terminal A with the reference value, and sleeps again based on the fact that the result of the comparison indicates that there is no power failure. You can switch to the mode.

In various embodiments, the charging unit 30 charges the battery unit 50 with the battery via the diode D6 while the light switch 20 is in the on state of electrically connecting the AC power source and the emergency lighting 40. Charging the battery by supplying a charging voltage to do so.
On the other hand, in various embodiments, the diode D6 may be included in the charging unit 30 in order to prevent the current from flowing back when the battery is charged.
In various embodiments, the charging unit 30 lights the emergency light 40 via the diode D4 while the light switch 20 is in the on state of electrically connecting the AC power source and the emergency light 40.
That is, while the light switch 20 is in the ON state in which the AC power supply and the emergency light 40 are electrically connected, the emergency light 40 is used like a general light.

On the other hand, in various embodiments, the power failure detection unit 10 receives the input voltage based on the AC power supply via the node F and the node G.
In order to prevent the power failure detection unit 10 from being damaged by the input voltage, the power failure detection unit 10 may include the high voltage prevention unit 11.
For example, the high voltage prevention unit 11 may include a diode D1 and a diode D2.
In order to prevent the failure detection unit 10 from being damaged, the cathode of the diode D1 is electrically connected to the anode of the diode D2 and electrically connected to the resistor R1, and the anode of the diode D1 is connected to the diode D1. It is electrically connected to the cathode of the diode D2 and electrically connected to the resistor R2, the cathode of the diode D2 is electrically connected to the resistor R1, and the anode of the diode D2 is electrically connected to the resistor R2. ..

On the other hand, the signal (or input voltage) input via the terminal F and the terminal G is amplified by the differential amplifier via the resistors R1 and R2 of the comparison unit 12, and charges the capacitor C2 via the diode D3. ..
The signal based on charging is output via the terminal A.
In various embodiments, the signal output via the terminal A is input to the "A-to-D converter" of the microprocessor 13 and converted into a value by the "A-to-D converter".
The microprocessor 13 compares the value with the reference value, and according to the result of the comparison, identifies that the state of the environment in which the electronic device 1 is located is not a power failure, and transmits a low state signal to indicate this via the terminal E. And output.
In various embodiments, the battery power supply unit 60 receives the low signal via the terminal E, so that the coil corresponding to the relay K is de-energized by turning off the transistor Q3.
By de-energy, the battery unit 50 and the emergency lighting 40 are electrically disconnected from each other.

On the other hand, at the time of a power failure, a minute voltage is applied via the terminal F and the terminal G of the power failure sensing unit 10.
In various embodiments, the power failure sensing unit 10 charges the capacitor C2 by amplifying a minute voltage using a differential amplifier and applying the amplified voltage to the capacitor C2 via the diode D3.
In various embodiments, the charge-based signal is output via the terminal A.
In various embodiments, the signal output via the terminal A has a lower voltage as compared to a non-power failure state.
Therefore, in the event of a power failure, the microprocessor 13 identifies from the signal received via the terminal A that the value converted by the "A-to-D converter" is smaller than the reference value, and based on the identification, A high state signal is output via the terminal E.

In various embodiments, the high state signal is input to the transistor Q3 of the battery power supply unit 60 via the terminal E, and the transistor Q3 is turned on by the high state signal.
By turn-on, the coil corresponding to the relay K is energized, and the relay terminal a and the terminal b are electrically connected to each other by the energization.
Through such an electrical connection, the battery unit 50 supplies power to the emergency lighting 40 via the battery power supply unit 60.
That is, in the event of a power failure, the emergency lighting 40 emits light based on the power supply provided from the battery unit 50 via the battery power supply unit 60.

In another example, referring to FIG. 3, the electronic device 1 includes a light switch 21 corresponding to a switching circuit, a power failure sensing unit 100 corresponding to a control circuit 3, a charging unit 30 corresponding to a charging circuit 4 and a battery 5, and a charging unit 30 corresponding to a battery 5. The battery unit 50 may include a battery power supply unit 60 corresponding to the battery power supply circuit 6.
On the other hand, the LED 7 corresponds to the emergency lighting 40.
In various embodiments, the light switch 21 is connected in parallel with the resistor R7, unlike the light switch 20.
Here, when the resistance value of the resistor R7 is set to several tens of megaohms (ohm) or more, the current flowing through the resistor R7 is 1 μA or less, so that the power consumption by the resistor R7 may be ignored.

In various embodiments, when the light switch 21 is in the ON state, the charging unit 30 acquires AC power.
The charging unit 30 lights the emergency lighting 40 by providing a signal to the emergency lighting 40 via the diode D4 based on the AC power supply.
In various embodiments, while the light switch 21 is in the on state, the charging unit 30 charges the battery by providing a signal to the battery via the diode D6 based on the AC power source.
Here, the diode D6 may be included in the battery unit 50 in order to prevent the current from flowing back during charging of the battery.

On the other hand, in various embodiments, the AC power supply is rectified by the bridge diode BD1 of the high voltage prevention unit 101 of the power failure detection unit 100 and the capacitor C3, and the DC power supply generated by the rectification is a resistor R8 and a resistor R9. It is divided by the voltage and input to the (−) terminal of OpAmp (U2) via the resistor R10 of the comparison unit 102.
Since the voltage applied to the (−) terminal is larger than the voltage applied to the (+) terminal to which the resistor R11 is connected, OpAmp (U2) outputs a low signal via the terminal E.
The low signal output via the terminal E turns off the transistor Q3 of the battery power supply unit 60, and the coil corresponding to the relay K is de-energized by the turn-off.
Based on the de-energy, the battery unit 50 and the emergency lighting 40 are electrically disconnected from each other.

On the other hand, at the time of a power failure, a minute voltage may be applied to the power failure sensing unit 100.
Since the voltage applied to the (−) terminal by such a fine voltage is smaller than the voltage applied to the (+) terminal, a high state signal is output via the output E of OpAmp (U2).
The high-state signal output via the terminal E turns on the transistor Q3 of the battery power supply unit 60, and the coil corresponding to the relay K is energized by the turn-on.
Based on the energy, the battery unit 50 and the emergency lighting 40 are electrically connected to each other.
Through such an electrical connection, the battery unit 50 provides power to the emergency lighting 40 via the battery power supply unit 60.
That is, in the event of a power failure, the emergency lighting 40 emits light based on the power supply provided from the battery unit 50 via the battery power supply unit 60.

In another example, referring to FIG. 4, the electronic device 1 corresponds to a light switch corresponding to a switching circuit (reference numeral 100 in FIG. 4, hereinafter the same), and corresponds to a control circuit 3, and the light switch sensing unit 310, A power failure sensing unit 320, a power failure sensing unit 300 including a microprocessor 330, an AC / DC converter 200 corresponding to the charging circuit 4 and the battery 5, a charging / DC converter 200 including a charging management unit 410, and a charging / driver unit 400 including a driver unit 420, and a battery. The unit 600 may include a battery switching unit 500 corresponding to the battery power supply circuit 6.
On the other hand, the LED 7 corresponds to the emergency lighting 700.

In various embodiments, the AC / DC converter 200 converts an AC power source into a DC power source and provides the converted DC power source to the charging / driver unit 400.
In various embodiments, the charge control unit 410 can be used to charge the battery using a DC power source.
In various embodiments, the diode D2 of the battery unit 600 connected to the charge control unit 410 is provided in the battery unit 600 in order to prevent the power charged in the battery from flowing back to the charge / driver unit 400. May be included.
In various embodiments, the driver unit 420 may be included within the charging / driver unit 400 to support the various capacities of the lighting.

In various embodiments, when the light switch 100 is in the on state, the light switch sensing unit 310 rectifies the AC power supply using the diode D6, and the rectified power supply is via the resistor R5. Provided to the photocoupler U3.
The transistor Q3 of the photocoupler U3 is turned on by the provided power supply, and a low state signal is output via the terminal J in response to the turn-on.
The low signal output via the terminal J is provided to the input I2 connected to the terminal J of the microprocessor 330.
Through the signal received at input I2, the microprocessor 330 identifies that the light switch 100 is in the on state.

In various embodiments, when the light switch 100 is in the off state and there is no power failure, the light switch 100 is rectified via the diode D6 of the light switch sensing unit 310 while the light switch 100 is in the on state, and then the resistance. The current flowing through the photocoupler U3 via R5 can be cut off.
By such a cutoff, the transistor Q3 is turned off, and a high state signal is output via the terminal J according to the turn-off.
The high-state signal output via the terminal J is provided to the input I2 connected to the terminal J of the microprocessor 330.
Through the signal received at input I2, the microprocessor 330 identifies that the light switch 100 is in the off state.

On the other hand, while the light switch 100 is in the off state and there is no power failure, an induced voltage is generated at the terminal F and the terminal G of the power failure sensing unit 320 according to the environmental conditions.
The induced voltage is amplified by being applied to OpAmp (U1) via the diode D4, the diode D5, the resistor R1 and the resistor R2 corresponding to the protection circuit.
The amplified induced voltage charges the capacitor C2 via the diode D7.
By charging, a signal is output via the terminal A.

In various embodiments, the signal output via the terminal A is input into the microprocessor 330, and the signal input into the microprocessor 330 is "A-to-D (analog to)" in the microprocessor 330. It is converted into a value (for example, a digital value) by a "digital) converter" and then stored in a buffer.
If there is a previous stored value in the buffer, the microprocessor 330 compares the previous stored value with the value and stores the smaller of the value and the previous stored value in the buffer.
Such an operation is repeated for a specified time.
After the specified time has elapsed, the microprocessor 330 interrupts the execution repeatedly, and the value stored in the buffer is used to determine whether or not the environment in which the electronic device 1 is located is a power failure. Set as a reference value.

On the other hand, while the light switch 100 is in the ON state, the AC voltage can be converted into a DC voltage by the AC / DC converter 200.
The DC voltage is provided to the battery unit 600 via the charge control unit 410, and the battery is charged based on the DC voltage.
In various embodiments, the charge management unit 410 stops charging when the battery is fully charged.
On the other hand, the microprocessor 330 outputs a low state signal via the terminal E while the light switch 100 is in the on state.
The low signal turns off the transistor Q2 and the FET (Q3) of the switching unit 500.
By turn-off, the power supply from the battery unit 600 is cut off from the charge / driver unit 400.

On the other hand, the microprocessor 330 outputs a signal for activating the driver unit 420 via the terminal K while the light switch 100 is in the ON state.
The driver unit 420 is activated by the signal output via the terminal K, and the emergency lighting 700 emits light by the activation.
On the other hand, when the electric light switch 100 is switched to the off state, the AC power supply is cut off, so that the emergency lighting 700 is immediately turned off (immediately).
However, such an immediate turn-off makes it difficult for the user to distinguish things.
That is, such an immediate turn-off may cause inconvenience.

In order to solve such an inconvenience, the light switch sensing unit 310 outputs a high state signal via the terminal J in response to identifying that the light switch 100 switches from the on state to the off state. ..
The high state signal is input to input I2 of the microprocessor 330.
The microprocessor 330 outputs a high state signal via the terminal E based on the signal input to the input I2.
The high-state signal output via the terminal E turns on the transistor Q2 and the FET (Q3) of the switching unit 500.
By turning on, the power of the battery in the battery unit 600 is provided to the emergency lighting 700, so that the emergency lighting 700 keeps the lighting state.

On the other hand, after a designated time has elapsed from the time when the light switch 100 is switched from the on state to the off state, the microprocessor 330 outputs a low state signal via the terminal E.
The low signal output via the terminal E turns off the transistor Q2 and the FET (Q3) of the switching unit 500.
By turn-off, the power supplied from the battery in the battery unit 600 to the driver unit 420 may be cut off.
That is, the emergency lighting 700 is turned off.

On the other hand, at the time of a power failure, a minute voltage may be applied to the terminal F and the terminal G of the power failure sensing unit 320.
Such a fine voltage is amplified by a differential amplifier composed of a resistor R1, a resistor R2, a resistor R3, and an OpAmp (U1), and then applied to the capacitor C2 via the diode D7.
The application charges the capacitor C2.
Based on the charge, the signal is output via the terminal A.
The signal output via the terminal A is converted into a value by the converter in the microprocessor 330, and the microprocessor 330 compares the value with the reference value, so that the environment in which the electronic device 1 is located is a power failure. Identify that.
For example, the microprocessor 330 identifies that the value is smaller than the reference value, and based on the identification, outputs a high state signal via the terminal E in order to perform an operation at the time of a power failure.
The high-state signal output via the terminal E turns on the transistor Q2 and the FET (Q3) of the switching unit 500.
By turn-on, power can be provided from the battery in the battery unit 600 to the emergency light 700 via the driver unit 420.
That is, in the event of a power failure, the emergency lighting 700 emits light.

As described above, the electronic device according to various embodiments is a switching configured to electrically connect or disconnect the hot line of the AC power supply and the electronic device. A control circuit that is electrically connected to or disconnected from the hotline and electrically connected to the neutral line of the AC power supply, depending on the state of the circuit and the switching circuit. A rechargeable battery and a switching circuit are configured to charge the battery and emit a light when the hotline and the electronic device are electrically connected, based on an AC power source. It has a charging circuit and a battery power supply circuit configured to emit a light based on the power source obtained from the battery according to the control of the control circuit, the control circuit being hot by the switching circuit. While the line and the electronic device are electrically connected, the first node of the control circuit electrically connected to the hotline and the second node of the control circuit electrically connected to the neutral line. To emit a light based on the power source obtained from the battery by electrically disconnecting the battery power supply circuit from the battery based on identifying that the potential difference between them is within the reference range. The potential difference between the first node and the second node, which is electrically disconnected from the hotline, is the reference while the hotline and the electronic device are electrically disconnected by the switching circuit. By electrically disconnecting the battery power supply circuit from the battery based on identifying that it is within range, it cuts off the emission of the light based on the power source obtained from the battery, and the switching circuit. The potential difference between the hotline and the electrically disconnected first node and the second node is outside the reference range while the hotline and the electronic device are electrically disconnected. Based on the identification, the battery power supply circuit and the battery are electrically connected so as to emit an electric light based on the power source obtained from the battery.

In various embodiments, the control circuit comprises a comparison circuit, a buffer, and a microprocessor, the comparison circuit producing a first signal to indicate a potential difference between a first node and a second node, first. The signal is configured to be provided to the microprocessor, which compares each of the values of the first signal obtained from the comparison circuit with the reference value stored in the buffer so that the potential difference is the reference. The second signal of the first state is sent to the battery power supply circuit based on identifying that the potential difference is within the reference range according to the comparison, which is configured to identify that it is within the range. By providing, the battery power supply circuit is electrically disconnected from the battery, and according to comparison, the battery power supply circuit is in a second state based on identifying that the potential difference is outside the reference range. It is preferable that the battery power supply circuit and the battery are electrically connected by providing the second signal.
In various embodiments, the microprocessor specifies while the switching circuit electrically disconnects the hotline from the electronic device and the potential difference between the first node and the second node is within the reference range. The first signal is repeatedly acquired from the comparison circuit for the specified time, and the minimum value among the plurality of values indicated by the repeatedly acquired first signal is used as the reference value in the buffer for the specified time. It is preferably configured to be stowed.

In various embodiments, the comparison circuit comprises an amplifier connected to the first node via a first resistor and connected to a second node via a second resistor, and the control circuit comprises a comparison circuit from an AC power source. Further including a protection circuit for protection, the protection circuit includes a first diode and a second diode, the cathode of the first diode is electrically connected to the anode of the second diode, and the amplifier and the first resistor. Electrically connected to the third node between, the anode of the first diode is electrically connected to the cathode of the second diode, and electrically connected to the fourth node between the amplifier and the second resistor. It is preferable that the cathode of the second diode is electrically connected to the fourth node and the anode of the second diode is electrically connected to the third node.
In various embodiments, the battery power supply circuit comprises a transistor, the battery power supply circuit further comprises a coil or a field effect transistor (FET), and the transistor comprises a coil if the battery power supply circuit comprises a coil. Based on the acquisition of the second signal in the first state from the microprocessor, the coil is de-energized to electrically disconnect the battery power supply circuit from the battery, and the second signal is taken from the microprocessor. When the coil is energized to electrically connect the battery power supply circuit and the battery based on the acquisition of the second signal in the state of 2, and the battery power supply circuit includes the FET. Based on the acquisition of the second signal of the first state from the microprocessor, the FET is turned off in order to electrically disconnect the battery power supply circuit from the battery, and the second signal of the second state is obtained from the microprocessor. It is preferable that the FET is configured to turn on in order to electrically connect the battery power supply circuit and the battery based on the acquisition of the above.

In various embodiments, the microprocessor preferably further includes terminals for detecting the state of the switching circuit.
In various embodiments, the control circuit identifies that the state of the switching circuit switches from an on state, which electrically connects the hotline to the electronic device, to an off state, which electrically disconnects the electronic device from the hotline. Therefore, it is preferable that the battery power supply circuit and the battery are electrically connected for a specified time, and then the battery power supply circuit is electrically disconnected from the battery.
In various embodiments, the control circuit comprises a microcontroller, which receives a third signal for identifying the switching of the state of the switching circuit, the third signal turning on the state of the switching circuit. When indicating to switch from to to the off state, the battery is provided by providing the second signal of the second state for a specified time and then providing the second signal of the first state to the battery power supply circuit. It is preferable that the power supply circuit and the battery are electrically connected for a specified time, and then the battery power supply circuit is electrically disconnected from the battery.

Further, the electronic device according to various embodiments as described above includes a first resistor configured to electrically connect the hot line of the AC power supply and the electronic device, and a first resistor. A switching circuit configured to electrically connect or disconnect both ends of one resistor, and a control circuit electrically connected to the hotline and the neutral line of the AC power supply. A charging circuit configured to charge the battery and emit an electric light based on the AC power supply when both ends of the first resistor are electrically connected by a rechargeable battery and a switching circuit. And a battery power supply circuit configured to emit a light based on the power source obtained from the battery according to the control of the control circuit, the control circuit electrically with a first resistor. A rectifier that is connected, electrically connected to the neutral line, and configured to convert AC power to DC power, a first terminal that is electrically connected to the rectifier, and a first that is electrically connected to the ground terminal. When the input voltage input to the control circuit via the hot line and the neutral line, including an amplifier including two terminals and an output terminal, is equal to or higher than the reference voltage, the battery power supply circuit is electrically disconnected from the battery. By doing so, it cuts off the light emission based on the power supply obtained from the battery, and when the input voltage is less than the reference voltage, by electrically connecting the battery power supply circuit and the battery. It is characterized in that it is configured to emit an electric light based on the power source obtained from the battery.

In various embodiments, the rectifier preferably includes a bridge diode and a capacitor.
In various embodiments, the battery power supply circuit comprises a transistor, the battery power supply circuit further comprises a coil or a field effect transistor (FET), and the transistor comprises a coil if the battery power supply circuit comprises a coil. Based on the acquisition of the second signal in the first state from the output terminal, the coil is de-energized in order to electrically disconnect the battery power supply circuit from the battery, and the second signal from the output terminal. Based on the acquisition of the second signal in the state of, the coil is energized to electrically connect the battery power supply circuit and the battery, and if the battery power supply circuit includes a FET, the output terminal. Based on the acquisition of the second signal in the first state from, the FET is turned off in order to electrically disconnect the battery power supply circuit from the battery, and the second signal in the second state is acquired from the output terminal. Based on the above, it is preferable to configure the FET to turn on in order to electrically connect the battery power supply circuit and the battery.

In the specific embodiments of the present disclosure described above, the components included in the disclosure are represented in the singular or plural by the specific embodiments presented.
However, the singular or plural representations have been chosen for convenience of explanation to suit the circumstances presented, and the present disclosure is not limited to the singular or plural components and is expressed in plurals. It may be a component, it may be composed of a singular number, it may be a component expressed in the singular form, or it may be composed of a plurality of components.
On the other hand, in the detailed description of the present disclosure, a specific embodiment has been described, but it goes without saying that various modifications are possible within the scope of the present disclosure.
Therefore, the scope of the present disclosure should not be limited to the embodiments described, and should be defined not only by the claims described below but also by the equivalent of the claims.

1 Electronic device 3 Control circuit 4 Charging circuit 5 Battery 6 Battery power supply circuit 7 LED
10 Power failure detection unit 11, 101 High voltage prevention unit 12, 102 Comparison unit 13, 330 Microprocessor 20, 21, (100 in Fig. 4) Electric light switch 30 Charging unit 40, 700 Emergency lighting 50, 600 Battery unit 60 Battery power supply Supply unit 100, 300 Power failure detection unit 200 AC / DC converter 310 Light switch sensing unit 320 Power failure sensing unit 400 Charging / driver unit 410 Charge management unit 420 Driver unit 500 Battery switching unit

Claims (11)

In electronic devices
A switching circuit configured to electrically connect or disconnect the hotline of the AC power supply and the electronic device.
A control circuit that is electrically connected to or disconnected from the hotline and electrically connected to the neutral line of the AC power supply, depending on the state of the switching circuit. When,
With a rechargeable battery,
When the hotline and the electronic device are electrically connected by the switching circuit, a charging circuit configured to charge the battery and emit a lamp based on the AC power supply. ,
It has a battery power supply circuit configured to emit a lamp based on a power source obtained from the battery according to the control of the control circuit.
The control circuit is
While the hotline and the electronic device are electrically connected by the switching circuit, the first node of the control circuit electrically connected to the hotline is electrically connected to the neutral line. By electrically disconnecting the battery power supply circuit from the battery based on identifying that the potential difference between the second node of the control circuit and the second node of the control circuit is within the reference range. Based on the power source obtained from the battery, the light is cut off from emitting light.
While the hotline and the electronic device are electrically disconnected by the switching circuit, the potential difference between the first node and the second node electrically disconnected from the hotline is increased. By electrically disconnecting the battery power supply circuit from the battery based on identifying that it is within the reference range, the lamp emits light based on the power source obtained from the battery. Block that
The potential difference between the first node and the second node electrically disconnected from the hotline while the hotline and the electronic device are electrically disconnected by the switching circuit. Based on the power source obtained from the battery by electrically connecting the battery power supply circuit and the battery based on identifying that the battery is outside the reference range. An electronic device characterized by being configured to emit an electric lamp. The control circuit includes a comparison circuit, a buffer, and a microprocessor.
The comparison circuit generates a first signal to indicate the potential difference between the first node and the second node.
It is configured to provide the first signal to the microprocessor.
The microprocessor determines that the potential difference is within the reference range by comparing each of the values of the first signal acquired from the comparison circuit with the reference value stored in the buffer. Is configured to identify
According to the comparison, from the battery to the battery by providing the second signal of the first state to the battery power supply circuit based on identifying that the potential difference is within the reference range. Electrically disconnect the power supply circuit,
According to the comparison, the battery power supply circuit is provided with a second signal in the second state based on identifying that the potential difference is outside the reference range. The electronic device according to claim 1, wherein the battery and the battery are configured to be electrically connected to each other. In the microprocessor, the hotline and the electronic device are electrically disconnected by the switching circuit, and the potential difference between the first node and the second node is within the reference range. , The first signal is repeatedly acquired from the comparison circuit for a specified time.
A claim characterized in that the minimum value among a plurality of values indicated by the first signal repeatedly acquired for a specified time is stored in the buffer as the reference value. Item 2. The electronic device according to item 2. The comparison circuit includes an amplifier connected to the first node via a first resistor and connected to the second node via a second resistor.
The control circuit further includes a protection circuit for protecting the comparison circuit from the AC power source.
The protection circuit includes a first diode and a second diode.
The cathode of the first diode is electrically connected to the anode of the second diode and electrically to the third node between the amplifier and the first resistance.
The anode of the first diode is electrically connected to the cathode of the second diode and electrically to the fourth node between the amplifier and the second resistance.
The cathode of the second diode is electrically connected to the fourth node.
The electronic device according to claim 3, wherein the anode of the second diode is electrically connected to the third node. The battery power supply circuit includes a transistor and includes a transistor.
The battery power supply circuit further includes a coil or a field effect transistor (FET).
The transistor electrifies the battery power supply circuit from the battery based on the acquisition of the second signal in the first state from the microprocessor when the battery power supply circuit includes the coil. The coil is de-energized in order to cut the coil.
Based on the acquisition of the second signal in the second state from the microprocessor, the coil is energized in order to electrically connect the battery power supply circuit and the battery.
When the battery power supply circuit includes the FET, the battery power supply circuit is electrically disconnected from the battery based on the acquisition of the second signal of the first state from the microprocessor. Therefore, in order to electrically connect the battery power supply circuit and the battery based on the fact that the FET is turned off and the second signal of the second state is acquired from the microprocessor. The electronic device according to claim 4, wherein the FET is configured to turn on. The electronic device according to claim 5, wherein the microprocessor further includes a terminal for detecting the state of the switching circuit. The control circuit identifies that the state of the switching circuit switches from an on state that electrically connects the hotline and the electronic device to an off state that electrically disconnects the electronic device from the hotline. Accordingly, the battery power supply circuit and the battery are electrically connected for a specified time, and then the battery power supply circuit is electrically disconnected from the battery. The electronic device according to claim 1, wherein the electronic device is characterized by the above. The control circuit includes a microprocessor.
The microprocessor receives a third signal for identifying the switching of the state of the switching circuit.
When the third signal indicates that the state of the switching circuit is switched from the on state to the off state, after providing the second signal of the second state for the specified time, the first signal. By providing the second signal in the state of the above to the battery power supply circuit, the battery power supply circuit and the battery are electrically connected for the specified time, and then the battery power supply from the battery The electronic device according to claim 7, wherein the supply circuit is configured to be electrically disconnected. In electronic devices
A first resistor configured to electrically connect the hotline of the AC power source to the electronic device.
A switching circuit configured to electrically connect or disconnect both ends of the first resistance,
A control circuit electrically connected to the hotline and the neutral line of the AC power source,
With a rechargeable battery,
A charging circuit configured to charge the battery and emit a lamp based on the AC power supply when both ends of the first resistor are electrically connected by the switching circuit.
It has a battery power supply circuit configured to emit a lamp based on a power source obtained from the battery according to the control of the control circuit.
The control circuit is electrically connected to the first resistance, electrically connected to the neutral line, and has a rectifier configured to convert the AC power supply into a DC power supply.
The amplifier includes a first terminal electrically connected to the rectifier, a second terminal electrically connected to the ground terminal, and an output terminal.
When the input voltage input to the control circuit via the hot line and the neutral line is equal to or higher than the reference voltage, it is acquired from the battery by electrically disconnecting the battery power supply circuit from the battery. Based on the power supply, it shuts off the light emission of the electric lamp,
When the input voltage is less than the reference voltage, the battery power supply circuit and the battery are electrically connected so that the lamp emits light based on the power source obtained from the battery. An electronic device characterized by being configured. The electronic device according to claim 9, wherein the rectifier includes a bridge diode and a capacitor. The battery power supply circuit includes a transistor and includes a transistor.
The battery power supply circuit further includes a coil or a field effect transistor (FET).
The transistor electrically connects the battery power supply circuit from the battery based on the acquisition of the second signal in the first state from the output terminal when the battery power supply circuit includes the coil. The battery power supply circuit and the battery are electrically connected based on the fact that the coil is de-energized and the second signal in the second state is obtained from the output terminal in order to disconnect the coil. Energize the coil to connect to
When the battery power supply circuit includes the FET, the battery power supply circuit is electrically disconnected from the battery based on the acquisition of the second signal in the first state from the output terminal. Therefore, the FET is turned off and
Based on the acquisition of the second signal in the second state from the output terminal, the FET is configured to turn on in order to electrically connect the battery power supply circuit and the battery. The electronic device according to claim 10.

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