Rechargeable battery monitoring and control is provided using a non-linear rate-of-change failure threshold. A non-linear rate-of-change failure threshold is obtained indicative of an operational state abnormality in a rechargeable battery cell, and during the operational state of the rechargeable battery cell, a control compares an actual voltage rate-of-change of the rechargeable battery cell to the non-linear rate-of-change failure threshold. Based on the actual voltage rate-of-change of the rechargeable battery cell exceeding the non-linear rate-of-change failure threshold, the control identifies the operational state abnormality in the rechargeable battery cell. Based on identifying the operational state abnormality in the rechargeable battery cell, the control discontinues the operational state of the rechargeable battery cell.

A computer-implemented method and system is provided. The system adaptively switches prediction strategies to optimize time-variant energy demand and consumption of built environments associated with renewable energy sources. The system analyzes a first, second, third, fourth and a fifth set of statistical data. The system derives of a set of prediction strategies for controlled and directional execution of analysis and evaluation of a set of predictions for optimum usage and operation of the plurality of energy consuming devices. The system monitors a set of factors corresponding to the set of prediction strategies and switches a prediction strategy from the set of derived prediction strategies. The system predicts a set of predictions for identification of a potential future time-variant energy demand and consumption and predicts a set of predictions. The system manipulates an operational state of the plurality of energy consuming devices and the plurality of energy storage and supply means.

A respiratory therapy device generates a flow of breathable gas for therapy. The apparatus may include a flow generator in a housing to generate the breathable gas flow. The flow generator may have an operating voltage for such operations. The device may include a battery pack that is engageable with the housing. The battery pack may be configured to power the flow generator and may include a stand-by circuit configured to switch between stand-by and operating modes. The stand-by circuit may be configured to provide a stand-by operations voltage while in the stand-by mode that is less than an operating voltage of the flow generator and may be configured to detect current demand of the flow generator with the stand-by operations voltage while in stand-by mode such as for enabling an increase voltage from the battery pack to produce the operating voltage in the operating mode for the flow generator.

Examples of the disclosure include an uninterruptible power supply comprising an input configured to be coupled to a power source, an output configured to output power to a load, a main controller, a main logic power supply, an auxiliary logic power supply, and an auxiliary controller configured to receive power from the auxiliary logic power supply, the auxiliary controller being configured to receive a signal indicating that the load is not powered by the uninterruptible power supply, output a first signal to initiate shutdown of the main controller and the main logic power supply, and output a second signal to power-up the main controller and the main logic power supply after a predetermined period of time elapses after outputting the first signal.

In the case where a predetermined condition related to a load is satisfied in a first state in which electric power is supplied from a second power supply source to the load via a second electric circuit and not supplied to the load via a third electric circuit when electric power cannot be supplied from a first power supply source to the load, a control unit controls a converting unit and a switching unit to establish a second state in which electric power is supplied from the second power supply source to the load via the second electric circuit and the third electric circuit.

The present disclosure relates to an uninterruptible power supply (UPS) system and, more specifically, to a static transfer switch (STS) that can be applied to a UPS module, the static transfer switch comprising: one semiconductor rectifying element connected to either the anode terminal or the cathode terminal of a direct current power source; a bypass circuit for connecting the input terminal and the output terminal of the semiconductor rectifying element so as to bypass the semiconductor rectifying element; a breaker for opening or closing the bypass circuit; and a switch including a control unit, which controls the semiconductor rectifying element so as to conduct current when a preset conduction signal is received, controls the breaker so as to close the bypass circuit, and, when the bypass circuit is closed by the breaker, controls the semiconductor rectifying element so as to stop the conduction of current.

A storage device includes a secondary power source, a charging circuit, a protection circuit and a main system. The secondary power source includes a plurality of capacitors, is charged based on a charging voltage, and generates an internal power supply voltage. The charging circuit generates the charging voltage based on an external power supply voltage. The protection circuit monitors whether at least one of the plurality of capacitors is defective, and blocks at least one defective capacitor. The main system operates based on the external or internal power supply voltage. The protection circuit includes a plurality of resistors, a plurality of transistors and a control circuit. The control circuit monitors whether the at least one of the plurality of capacitors is defective using the plurality of resistors and a plurality of currents associated with the plurality of capacitors, and blocks the at least one defective capacitor using the plurality of transistors and a plurality of control signals.

A system of controlling backup power of a lithium iron phosphate battery for a vehicle contains: the lithium iron phosphate (LiFePO.sub.4) battery module, a boost module, and a supercapacitor module which are parallelly connected with an electric control device of the vehicle. A first switch electrically is connected with a negative electrode of the electric control device and a negative electrode of the supercapacitor module of the vehicle, a second switch is electrically connected with a negative input electrode and a negative output electrode of the boost module, and a third switch is electrically connected with a positive electrode of the LiFePO.sub.4 battery module and a positive input electrode of the boost module. The system further contains a backup control module including a microprocessor configured to direct, control, order, and manage a detection unit, a controlling unit, and a Bluetooth module.

A reliable and redundant hybrid VTOL UAV power architecture includes two or more channels of high voltage AC power generated from at least one generator, the generator coupled to one or more liquid fueled turbine engines. Two or more high voltage domain modules, one for each channel, receive the high voltage AC power and, using a rectifier change it to high voltage DC power. A power distribution unit accepts the newly converted channel of high voltage DC power and thereafter bidirectionally provides it to a domain battery and to a primary set of motors. Two or more high voltage busses, each coupled separately to one of the two or more high voltage domain modules, each redundantly transport converted channel of high voltage DC power to, in one embodiment, primary sets of motors forming a primary high power domain bus for these select motors.

According to one embodiment, an Information Technology (IT) power system for a data center. The system includes a utility power source, an IT cluster that includes a several pieces of IT equipment. The cluster is coupled to the source and is configured to draw power from the source and provide the drawn power to the pieces of IT equipment. The system also includes a photovoltaic (PV) system that includes a PV panel that is arranged to convert solar radiation into direct current (DC) power. It also may include a voltage sensor and a controller that are configured to decouple the cluster from the source and to couple the cluster to the PV system such that the cluster draws the DC power directly from the PV panel when the output voltage of the PV panel sensed by the voltage sensor exceeds a threshold value.