A testing method has corresponding a contacts group to a key of a computer keyboard; corresponding a contacts group state to a key state; corresponding a first keys group and a second keys group to a first power contacts group and a second power contacts group respectively; obtaining and storing a first values group and a second values group when the first keys group and the second keys group are closed respectively; respectively calculating difference values between one value in the first or second values group and other values thereof; dividing the difference values by the device frequency value to obtain a first or second difference values group; and storing the difference values groups. The first and second difference values groups accurately reflect conduct synchronism of each pole of dual power transfer switch.

The present disclosure relates to a contact point monitoring device for a vacuum circuit breaker, and a correction method performed through same, wherein deviations due to temperature in a sensor for monitoring the amount of wear at a contact point may be compensated for. According to the present disclosure, the amount of wear at the contact point may be accurately detected by correcting a characteristic value of a photosensor according to operation temperature, by taking into consideration the temperature characteristics of the photosensor.

The present disclosure relates to a monitoring system for a plurality of power devices serially connected in a main circuit of a current transmission path comprising a first power device and a second power device each including a semiconductor element; a first sensor connected to the first and second power devices, and which senses information related to a first current flowing in the first power device; a second sensor for sensing information related to a second current flowing in the second power device; a third sensor for sensing information related to a third current flowing between the first power device and the second power device; and a control unit for comparing the first current and the second current on the basis of the third current measured by the third sensor, and determining whether the state of each power device is abnormal based on a difference with the third current.

The present invention relates to a solid testing platform and method for function testing of an intelligent phase-change switch. The testing platform includes a primary controller, a first module, a second module, a capacitor C, an intelligent phase-change switch, and a transformer. The primary controller is respectively connected to the first module and the second module, and is configured to control the operation of the first module and the second module. The first module and the second module are connected in parallel to the capacitor C. the first module is configured to feed back excess energy of the capacitor C to a distribution network. The second module is configured to control magnitude and direction of a current that flows through the intelligent phase-change switch. The capacitor C is configured to perform energy support, filtering, and smoothing. According to the present invention, not only all unbalanced operation conditions can be simulated, but also simulated power is equitably fed back to a power grid by using the testing platform, to achieve a test in a state of no power loss, without affecting a main power grid.

A process tests an operability of a circuit breaker device (18, 20, 34) to establish/sever a connection of two circuit areas (36, 38, 40, 42). The circuit breaker device includes a MOSFET (44) with a source terminal (46) connected with a circuit area, a drain terminal (48) connected with a circuit area, and a gate terminal (50) with a gate voltage applied by an associated gate driver device (52) to switch into a connection switching state connecting the two circuit areas during a connection phase. The gate voltage is monitored during the connection phase, a base voltage being applied to the source terminal or/and to the drain terminal during the connection phase is monitored. If a difference between the gate voltage and the base voltage falls below a predefined reference difference during the connection phase, it is determined that a circuit defect is present in the MOSFET.

The application provide a high-voltage interlock device and a fault detection method thereof. The high-voltage interlock device includes: a first signal detection circuit, configured to collect a first original electric signal from a high-voltage interlock component and convert the first original electric signal into a first sampled signal while ensuring that the high-voltage interlock component is isolated from a fault diagnosis module; a second signal detection circuit, configured to collect a second original electric signal from the high-voltage interlock component and convert the second original electric signal into a second sampled signal while ensuring that the high-voltage interlock component is isolated from the fault diagnosis module; the fault diagnosis module, configured to determine a fault of the high-voltage interlock component according to the first and/or the second sampled signal, under a condition that at least one of the first and the second switch modules is in an OFF state.

Method, device and system for determining a line property in the form of an arc on a power transmission line, wherein at least one test signal is coupled into the power transmission and an interference signal at an interference point, which is formed by the arc, is generated along the power transmission line with the aid of the at least one test signal, which interference signal is acquired as at least one measuring signal, and the line property is determined from the at least one measuring signal, where the line property is determined by detecting at least one intermodulation product from the at least one test signal and the mains signal of the power transmission line in the at least one measuring signal.

The present invention is notably directed to methods for estimating a degradation of an electronically controlled electro-mechanical switch. The methods comprise determining a change of state of the contactor. They also comprise, computing, for each determined change of state, a wear increment W.sub.I of the contactor by: identifying a wear coefficient using a mapping between a last measured current through the contactor and a current range associated with a given wear coefficient; computing the actual wear W.sub.N of the contactor by adding the computed wear increment W.sub.I to a former known wear W.sub.I−1 of the contactor.

There is provided a short circuit determination apparatus including: a sensor configured to detect, in a switching device that has a control terminal, a first main terminal, and a second main terminal, a temporal change of a main current flowing between the first main terminal and the second main terminal; and a short circuit determination unit configured to determine that the switching device is short-circuited, in a case where the temporal change of the main current is larger than or equal to a first threshold value, after a first timing after a control signal for driving the control terminal is turned on.

A solid state switch (SSS) monitoring system of an electronic device includes a SSS sensing component that is electrically coupled to a solid state switch. The SSS sensing component periodically generates a clocked pulse that polls the solid state switch. The SSS sensing component determines whether an electrical characteristic of an output of the solid state switch indicates that the solid state switch is actuated. The SSS sensing component generates a switch state signal to indicate a corresponding one of an actuated and an unactuated state of the solid state switch. A controller is communicatively coupled to the SSS sensing component. The controller restarts the SSS sensing component in response to determining that the SSS sensing component is in an inoperative state.