A control circuit controls a switching element including a gate and a source corresponding to the gate. The control circuit includes an inductor, a circuit element, and a resistor. The inductor is connected between the gate and the source of the switching element. The circuit element is connected in series to the inductor between the gate and the source. The circuit element allows an electric current to flow therethrough in response to generation of electromotive force in the inductor. The resistor is connected in parallel to the inductor and the circuit element between the gate and the source.

Aspects of this disclosure relate to detecting and recording information associated with electrical overstress (EOS) events, such as electrostatic discharge (ESD) events. For example, in one embodiment, an apparatus includes an electrical overstress protection device, a detection circuit configured to detect an occurrence of the EOS event, and a memory configured to store information indicative of the EOS event.

Embodiments of the present disclosure provide an over-voltage protection method, an over-voltage protection device and a display device. When the voltage value of the output signal is greater than the first preset voltage threshold, it is determined whether the voltage value of the output signal meets the preset over-voltage protection condition. If the voltage value of the output signal is detected to meet the preset over-voltage protection condition, the first control signal is output to stop output of the output signal or lower the voltage value of the output signal.

Embodiments of the present disclosure provide an over-voltage protection method, an over-voltage protection device and a display device. When the voltage value of the output signal is greater than the first preset voltage threshold, it is determined whether the voltage value of the output signal meets the preset over-voltage protection condition. If the voltage value of the output signal is detected to meet the preset over-voltage protection condition, the first control signal is output to stop output of the output signal or lower the voltage value of the output signal.

A power control device includes: an output voltage controller configured to control an output voltage based on a feedback voltage corresponding to the output voltage; and an overvoltage protector configured to continue or stop the operation of the output voltage controller based on a first detection result of whether the output voltage has exceeded an output voltage threshold value and a second detection result of whether the feedback voltage has fallen to or below a feedback voltage threshold value.

A power control device includes: an output voltage controller configured to control an output voltage based on a feedback voltage corresponding to the output voltage; and an overvoltage protector configured to continue or stop the operation of the output voltage controller based on a first detection result of whether the output voltage has exceeded an output voltage threshold value and a second detection result of whether the feedback voltage has fallen to or below a feedback voltage threshold value.

The present disclosure is directed to a safety device for photovoltaic installations. The safety device includes a first terminal adapted to connect to a first output terminal of a solar panel, a second terminal adapted to connect to a second output terminal of the solar panel, a first switching module connected between the first terminal and the second terminal. The first switching module comprising a first switch and a first impedance connected in series. The first impedance includes one terminal connected to the first terminal and the first switch includes one terminal connected to the second terminal. A control module is adapted to read a control signal and drive the operation of the first switch based on the read value of the control signal. A powersupply means is adapted to supply power to the control module.

A protective circuit (1A) is provided with: a protective element (10A): a plurality or secondary battery cells (20), (20), . . . ; an external positive electrode terminal (30a) and an external negative electrode terminal (30b); an auxiliary power supply (40); a first controlling dev ice (50): and a switch (60). The protective element (10A) includes: a first fusible conductor (15) of which the two ends are connected to a first terminal (11) and a second terminal (12): and a heat generating body (16) disposed in a first energizing path (P1.sub.A) between a third terminal (13) and a fourth terminal (14). The auxiliary power supply (40) is provided electrically independently of the plurality of secondary battery cells (20), (20), . . . . In this protective circuit (1A), a signal from the first controlling device (50) causes the switch (60) to switch in such a way as to conduct electricity, thus causing the heat generating body (16) of the protective element (10A) to generate heat which fuses the first fusible conductor (15), thereby isolating the plurality of secondary battery cells (20), (20), . . . from the external negative electrode terminal (30b).

A protective circuit (1A) is provided with: a protective element (10A): a plurality or secondary battery cells (20), (20), . . . ; an external positive electrode terminal (30a) and an external negative electrode terminal (30b); an auxiliary power supply (40); a first controlling dev ice (50): and a switch (60). The protective element (10A) includes: a first fusible conductor (15) of which the two ends are connected to a first terminal (11) and a second terminal (12): and a heat generating body (16) disposed in a first energizing path (P1.sub.A) between a third terminal (13) and a fourth terminal (14). The auxiliary power supply (40) is provided electrically independently of the plurality of secondary battery cells (20), (20), . . . . In this protective circuit (1A), a signal from the first controlling device (50) causes the switch (60) to switch in such a way as to conduct electricity, thus causing the heat generating body (16) of the protective element (10A) to generate heat which fuses the first fusible conductor (15), thereby isolating the plurality of secondary battery cells (20), (20), . . . from the external negative electrode terminal (30b).

A power supply using a microcontroller for circuit protection and an LED lighting system using the power supply are disclosed. A power supply according to embodiments of the present invention includes a floating converter and at least a first reference voltage source connected to a negative output terminal of the floating converter. A microcontroller is connected to the first reference voltage source and to a control input of the floating converter, which may be a floating buck converter. In some embodiments, a second reference voltage source is connected to the microcontroller. A voltage divider and/or a comparator can be used to provide one or both voltage reference sources.