The disclosure includes a method of diagnosing a grounding system of a structure that includes a charge collecting structure conductively connected to the ground via a grounding path, where diagnosing involves an act of monitoring output of a voltage and/or a current and/or an electrostatic detector connected to the grounding path.

A power stage includes a control device and a power transistor, the control device comprising a primary circuit comprising: a control module able to generate a control current, a primary circuit malfunction detector able to detect a malfunction, a pulse transformer comprising a primary winding connected to the primary circuit, comprising a secondary winding connected to the secondary circuit, magnetically coupled to the primary winding and able to generate, from the control current, an induced pulse current making it possible to drive the power transistor, a secondary circuit comprising: a power and fault detection controller able to detect a malfunction of the secondary circuit or of the power transistor, the power and fault detection controller being able to communicate the malfunction of the secondary circuit or of the power transistor to the primary circuit malfunction detector.

A vacuum pump includes a control unit that monitors and controls a motor and a magnetic bearing, each being stored in a pump body. A temperature-adjustment function unit measures a temperature of the pump body by at least one temperature sensor disposed in the pump body and controls at least one heater or solenoid controlled valve based on the temperature. The temperature-adjustment function unit includes a first terminal capable of connecting or disconnecting the temperature sensor and a second terminal capable of connecting or disconnecting one of the heater and the solenoid controlled valve. A self-diagnosis unit capable of conducting a self-diagnosis of whether an input signal to the first terminal has been normally inputted or whether the signal has been normally outputted from the second terminal.

A vacuum pump includes a control unit that monitors and controls a motor and a magnetic bearing, each being stored in a pump body. A temperature-adjustment function unit measures a temperature of the pump body by at least one temperature sensor disposed in the pump body and controls at least one heater or solenoid controlled valve based on the temperature. The temperature-adjustment function unit includes a first terminal capable of connecting or disconnecting the temperature sensor and a second terminal capable of connecting or disconnecting one of the heater and the solenoid controlled valve. A self-diagnosis unit capable of conducting a self-diagnosis of whether an input signal to the first terminal has been normally inputted or whether the signal has been normally outputted from the second terminal.

An apparatus and method for testing a battery pack are provided. Measurement components are configured to measure parameters of battery components (e.g., batteries and battery connection components) within the battery pack. Trained models are applied to signals measured by the measurement components and provide an output indicative of a condition of the battery components.

An apparatus and method for testing a battery pack are provided. Measurement components are configured to measure parameters of battery components (e.g., batteries and battery connection components) within the battery pack. Trained models are applied to signals measured by the measurement components and provide an output indicative of a condition of the battery components.

The charge control circuit includes a cell connection detection circuit monitoring a voltage between input ports to which terminals of a cell pack are connected, an overvoltage detection circuit monitoring an overvoltage of the secondary cells, a first latch circuit receiving a signal output by the cell connection detection circuit, a second latch circuit receiving a signal output by the overvoltage detection circuit, a reset circuit outputting a signal to the first latch circuit and the second latch circuit when the charge control circuit is activated, and a control circuit receiving a signal output from the second latch circuit and outputting a signal for protecting the cell pack from the overvoltage. The control circuit does not output a signal for blowing the fuse until the first latch circuit receives a detection signal of the cell connection detection circuit.

A contact test device for a hi-pot test includes: a contact test device connected to a hi-pot test device in parallel by lines branched from first and second lines of the hi-pot test device by being connected to first and second terminals of a battery through first and second probes, respectively, and having third and fourth probes directly connected to the first and second terminals, wherein the contact test device includes: a first closed loop including first to third switch units, a direct current (DC) voltage source and a first continuity detection unit; a second closed loop including fourth to sixth switch units, the DC voltage source and a second continuity detection unit; and a control unit controlling turning the first to sixth switch units on and off and detecting a continuity signal of each of the first and second continuity detection units.

A contact test device for a hi-pot test includes: a contact test device connected to a hi-pot test device in parallel by lines branched from first and second lines of the hi-pot test device by being connected to first and second terminals of a battery through first and second probes, respectively, and having third and fourth probes directly connected to the first and second terminals, wherein the contact test device includes: a first closed loop including first to third switch units, a direct current (DC) voltage source and a first continuity detection unit; a second closed loop including fourth to sixth switch units, the DC voltage source and a second continuity detection unit; and a control unit controlling turning the first to sixth switch units on and off and detecting a continuity signal of each of the first and second continuity detection units.

Voltage samples are collected for a source and loads connected thereto by an electrical network. Respective negative sequence voltage difference values are generated for respective source/load pairs from the voltage sample. A connection (e.g., a loose connection) in the electrical network is identified based on the generated negative sequence voltage difference values. The identified connection is reported to a user. Identifying a connection in the electrical network may include identifying at least one source/load pair having an associated negative sequence voltage difference value that meets a predetermined criterion and identifying the connection based on the identified at least one source/load pair. Identifying the connection may include identifying at least one source/load pair having an associated negative sequence voltage difference value with a magnitude falling outside of at least one range associated with the at least one source/load pair.