Abstract: Aspects and techniques of the present disclosure relate to enclosures, such as, electrical enclosures, for example, explosion-proof enclosures, and including advantageous features and methods usable with such enclosures. Disclosed features and techniques relate to: an enclosure fastening device; a visual indicator; an enclosure handling assist arrangement; a control handle; and a reset controller.

Abstract: An adapter plate may be used to secure a wall mountable connector to a junction box by engaging mounting features of the wall mountable connector. In some cases, the wall mountable connector may be directly secured to a wall via fasteners that extend through the same mounting features of the wall mountable connector. In some cases, the adapter plate may be configured such that the wall mountable connector can be secured to the adapter plate simply by pressing the wall mountable connector into position on the adapter plate, where mounting latches of the adapter plate engage the mounting apertures of the wall mountable connector. The wall mountable connector may be an HVAC wall mountable connector that provides an electrical connection between a plurality of field wires of an HVAC system and corresponding terminals of a removably mounted thermostat.

Abstract: A door chime assembly with a transformer assembly mounted within an electrical box and proximately to a chime. The transformer assembly including a transformer operably coupled to a bracket. The transformer being insertable into the electrical box such that the bracket and electrical box cooperate to electrically isolate the transformer from the chime. The electrical box having mounting features for securing the door chime assembly in existing and/or new construction.

Abstract: The present disclosure is directed to a cable securement assembly for protecting cables and/or cable bundles within a wind turbine. The cable securement assembly includes a cable spacer having an inner surface and an outer surface separated by a thickness and one or more fastening components. The inner surface defines an open center configured to receive the plurality of cables therein. The inner surface defines a plurality of cable locations defined by one or more through holes configured through the thickness. The one or more fastening components are configured to secure one or more of the plurality of cables at each cable location via the through holes.

Abstract: A communication distribution unit, containing at least one power switch, said communication distribution unit comprising for an at least one consumer a power switch (4) based on a semiconductor design to switch on and off output lines (3) for the at least one consumer and the power switch (4) comprises at least one switching module (5).

Abstract: An electronic circuit for single-event latch-up (SEL) detection and protection of a target integrated circuit (IC) is disclosed. The circuit comprises: a first detector configured for detecting an absolute load current (i) and comparing the absolute load current (i) with a threshold current (ith); a second detector configured for detecting a rate of change of load current (di/dt) and comparing the rate of change of load current (di/dt) with a threshold current change rate (di/dt)th; and a determination module for triggering a power shut-down to the target IC if the absolute load current (i) exceeds the threshold current (ith) and/or the rate of change of load current (di/dt) exceeds the threshold current change rate (di/dt)th.

Abstract: A power pedestal including a receptacle, a circuit breaker electrically connected between a power source and the receptacle and including separable contacts structured to trip open and electrically disconnect the receptacle from the power source, a current sensor structured to detect current flowing to the receptacle, and a ground fault detection device structured to sense a ground fault based on an output of the current sensor and to control the circuit breaker to trip open the separable contacts in response to detecting the ground fault. The ground fault detection device has an adjustable range of ground fault protection.

Abstract: A current limiter arrangement limiting an electric current between a first and a second terminal includes a first current limiting device and a second current limiting device arranged between the first and the second terminal. The first and the second current limiting device each include a substrate having a substrate surface area and a substrate thickness, and include a superconducting section arranged on the substrate and thermally coupled to the substrate thereby covering a coupling surface area on the substrate. Each of the superconducting sections has a critical current value and the substrate surface areas, the substrate thicknesses and or the coupling surface areas are implemented as a function of the critical current values.

Abstract: A data interface with overvoltage protection circuitry includes a bus interface and power rectification stage configured to provide supply and return voltages for the data interface and overvoltage protection circuitry, a first power level overvoltage protection circuit, a second power level overvoltage protection circuit, a DALI endpoint power output port, a power supply for a DALI endpoint device drawing current from the power output port, a receiver configured to receive signals on the DALI bus, and, a transmitter configured to send signals on the DALI bus.

Abstract: Systems and methods for model-based demand response are disclosed. An analytics server is communicatively connected to a data acquisition component and a virtual system model database. The data acquisition component is operable to acquire and transmit real-time data from a demand response (DR) power network to the analytic server. The virtual system model database is operable to provide a virtual system model of the DR power network. The analytics server is operable to generate predicted data based on the virtual system model of the DR power network and update the virtual system model in real time based on a difference between the predicted data and the real-time data. The analytics server is further operable to optimize DR output of the DR power network to a power grid.

Abstract: A system architecture and method for enabling hierarchical intelligent control with appropriate-speed communication and coordination of control using intelligent distributed impedance/voltage injection modules, local intelligence centers, other actuator devices and miscellaneous FACTS coupled actuator devices is disclosed. Information transfer to a supervisory utility control is enabled for responding to integral power system disturbances, system modelling and optimization. By extending the control and communication capability to the edge of the HV power grid, control of the distribution network through FACTS based Demand response units is also enabled.

Abstract: A method performed in an electrical microgrid for facilitating connection of a first and second AC power networks. The method includes, when the power networks are disconnected, from the second power network, controlling the AC frequency of the first power network based on the AC frequency of the second power network for ensuring that when the first and second networks are connected power will flow from the power network of the first and second power networks having a higher frequency to the power network of the first and second power networks having a lower frequency. The method also includes, after the controlling, connecting the first power network to the second power network, whereby power, at the instant of connecting, flows from the power network of the first and second power networks having a higher frequency to the power network of the first and second power networks having a lower frequency.

Abstract: An energy management capsule is disclosed, being a mains-powered device with multiple sensors or electrical output controllers connected to the Internet. Web services analyse sensor data for controlling electrical outputs and providing information about significant changes to predicted sensor values. Several Energy Management Capsules may be interconnected via mains powerlines, wireless communications or wired digital networks. It reports failure of mains power supply.

Abstract: Systems and methods for coordinating selective activation of at least one power generation equipment component and/or at least one power storage device over a predetermined geographic area for distribution and/or storage, and/or for sale and distribution in a utility grid.

Abstract: A method for managing power of an energy storage system (ESS) connected to renewable energy, the ESS including an energy storage device connected to a power grid, a battery management system (BMS), a power conditioning system (PCS), and one or more renewable energy generation facilities producing electric energy from renewable energy, the steps including of determining a predicted power consumption amount of a power load and a predicted power production amount of the renewable energy generation facility, predicting power production of the renewable energy generation facility based on the stored type and characteristics information of the renewable energy generation facilities, determining whether the energy storage device is fully charged with the power production from the renewable energy generation facility, and controlling charging/discharging operation of the energy storage device according to a charge/discharge schedule.

Abstract: An energy storage system includes one or more new and renewable energy power stations generating power with a new or renewable energy source, and an energy storage facility including a plurality of energy storage apparatuses to be charged by one of an external power grid supplying power to a power load and the one or more new and renewable energy power stations, and to be discharged to supply the power to the power load, wherein the plurality of energy storage apparatuses have different charging and/or discharging periods.

Abstract: A direct current power system. The direct current power system includes a direct current bus system, a solar power system, an energy storage system, a wind power system, a rectifier system and an inverter system. The solar power system includes a plurality of solar panels, is electrically coupled to the energy storage system and is configured to supply a first direct current power at 48 volts. The energy storage system includes a plurality of battery stacks and is configured to supply a second direct current power at 380 volts to the direct current bus system. The wind power system includes at least one wind turbine assembly and is configured to supply a third direct current power at 380 volts to the direct current bus system. The rectifier system is configured to supply a fourth direct current power at 380 volts to the direct current bus system.

Abstract: Provided is a grid-connected inverter safety detection device applied in a photovoltaic inverter system and including voltage detection circuit, a filter circuit, a comparison circuit and a controller. The voltage detection circuit is configured to detect a voltage between the point N and the ground, or a voltage between the first terminal for any phase of the three-phase power grid and the ground. The filter circuit is configured to filter out an alternating current component of the voltage detected by the voltage detection circuit and to retain an direct current component of the voltage. The comparison circuit is configured to compare the direct current component of the voltage with a preset voltage value and transmit a comparison result to the controller. The controller is configured to determine, according to the comparison result, whether an alternating current side at the output terminal of the inverter has normal insulation.

Abstract: A method and associated control device for synchronizing a turbine with an alternating current network having a network frequency, having the following steps: A) accelerating the turbine up to a frequency in the range of the network frequency; B) sensing an angle difference between the turbine and the alternating current network; C) sensing a speed difference between the turbine and the alternating current network; D) accelerating or decelerating the turbine such that the turbine follows a desired trajectory, wherein the desired trajectory is a trajectory calculated in advance that indicates, in dependence on the angle difference, a desired speed difference that should be present such that a target angular position between the turbine and the alternating current network suitable for synchronous feed-in is achieved when the speed of the turbine and the speed of the alternating current network correspond.

Abstract: A system for generating electrical power includes engine generators positioned on a pad and housed within an enclosure. The pad may have a first side having an associated long axis and a shorter second side having an associated short axis. The short axis is transverse to the long axis. The engine generators are electrically coupled to one another in a parallel fashion. Each engine generator includes a prime mover and an alternator that are serially aligned with the short axis of the pad. The enclosure encloses the engine generators and has a plurality of side walls, a roof, and a floor. The enclosure includes at least one intake opening formed in the floor to provide airflow into an interior of the enclosure.

Abstract: A power supply apparatus links to a grid, converts DC power from a distributed power source to AC power, and includes a controller that controls input voltage of the DC power in accordance with current flowing between the power supply apparatus and the grid. Based on communication with another power supply apparatus connected to the power supply apparatus, the controller also sets a standard value of controlling the input voltage.

Abstract: A power supply system includes a power control device and a power supply device. The power control device includes a first controller, a power measurement circuit, and a first communication circuit. The power measurement circuit measures power being supplied to the power supply device. The first controller calculates additionally suppliable power based on the power being supplied and selects one operation mode based on the additionally suppliable power. The first communication circuit transmits the operation mode selected to the power supply device. The power supply device includes a second controller, a power converter circuit, and a second communication circuit. The second communication circuit receives the operation mode selected. The second controller outputs a condition of supply power indicating electric power supplied, to the power converter circuit.

Abstract: A wireless power receiving element with capacitive coupling is described herein. The design allows for a wireless power receiving element that extends all the way around the band of a wearable electronic device. In an area where one end of the band clasps to the other, a capacitive coupling is provided, allowing the element to extend around the entire band without requiring a direct physical connection to complete this circuit.

Abstract: A charge rebalancing integration circuit can help keep an output node of a front-end integration circuit within a specified range, e.g., without requiring resetting of the integration capacitor. The process of monitoring and rebalancing the integration circuit can operate on a much shorter time base than the integration time period, which can allow for multiple charge balancing charge transfer events during the integration time period, and sampling of the integration capacitor once per integration time period, such as at the end of that integration time period. Information about the charge rebalancing can be used to adjust subsequent discrete-time signal processing, such as digitized values of the samples. Improved dynamic range and noise performance is possible. Computed tomography (CT) imaging and other use cases are described, including those with variable integration periods.

Abstract: A battery charge-discharge balancing circuit assembly used in a battery pack consisting of multiple secondary battery cells is disclosed to include a switch device installed in each of the positive and negative terminals of each secondary battery cell and a balancing resistor connected with all the secondary battery cells in a parallel manner and the balancing resistor device having two opposite ends thereof connected the switch devices in series. All the secondary battery cells or multiple secondary battery cells of the battery pack can share one balancing resistor. By means of discharging the secondary battery cells in rotation, every secondary battery cell gets balanced to achieve efficient charging, eliminating the problem of overheat of the prior art technique.

Abstract: The invention relates to a process for making sodium-ion cells, particularly sodium-ion cells which are capable of safe storage and/or transportation, comprising the steps: a) constructing a sodium-ion cell comprising a positive electrode, a negative electrode and an electrolyte, optionally performing one more charge/discharge operations on the sodium- ion cell; and b) treating the sodium-ion cell to ensure that it is in a state of charge of from 0% to 20%.

Abstract: The present disclosure provides an energy storage cell comprising at least one capacitive energy storage device and a DC-voltage conversion device. The capacitive energy storage device comprises at least one meta-capacitor. The output voltage of the capacitive energy storage device is the input voltage of the DC-voltage conversion device. The present disclosure also provides a capacitive energy storage module and a capacitive energy storage system.

Abstract: Described is the portable, charging travel pillow having a removable portable power bank for providing the user with a comfortable place for resting the neck and head and charging the user's handheld portable mobile device. The portable, charging travel pillow provides a portable pillow body with the removable fabric cover and a removable portable power bank. The portable, charging travel pillow is a fully-functional portable pillow body with portable charging capability via the portable power bank. device for texting or viewing handheld mobile devices while charging said handheld mobile device portably and comfortably.

Abstract: The present disclosure provides a communication method, a power adaptor, and a terminal. The method includes: receiving, by a terminal, handshake information from a power adaptor before the terminal receives a charging current from the power adaptor; determining, by the terminal, an initial charging parameter according to the handshake information; and sending, by the terminal, the initial charging parameter to the power adaptor to instruct the power adaptor to charge the terminal according to the initial charging parameter. In the embodiments of the present disclosure, before the power adaptor charges the terminal, the terminal receives the handshake information from the power adaptor, and determines the initial charging parameter according to the handshake information.

Abstract: A capacitor based energy storage system (CBESS) and methods of using it are disclosed. The CBESS uses meta-capacitors in its capacitive energy storage devices (CESD) to configure capacitive energy storage cells (CESC), which are used to configure capacitive energy storage modules (CESM) to achieve the CBESS's function as an uninterruptible power supply. The CBESS is connected to a power generation system (PGS), a load, and a power grid. When the grid is in an abnormal state, the CESM is simultaneously charged with power from the PGS and used to supply power to the load. If a remaining amount of power of a CESM is less than a predetermined level, the CESM is charged with power from PGS or grid. The CBESS interfaces with a computer system or network to buy or sell electricity to the grid depending on grid electricity cost and CESD charging states.

Abstract: An electricity storage device includes a battery, a discharge device, and a controller for controlling charging and discharging of the battery. The discharge device includes a swelling member, a movable switch, and a discharge switch. When the swelling member swells, the movable switch is moved. When the movable switch is moved, the discharge switch is turned on. A signal indicating that the discharge switch is turned on is transmitted to the controller to cause the battery to start discharging of electricity.

Abstract: A circuit device includes a power supply portion that supplies power from a battery to a power supply target, and a control portion that controls the power supply portion. The power supply portion includes a charge pump circuit that steps down a battery voltage VBAT of the battery to a voltage that is m/n times the battery voltage VBAT, and supplies the stepped down voltage to the power supply target from a terminal (n is an integer of one or more, m is an integer of one or more and (n?1) or less). The control portion stops a charge pump operation of the charge pump circuit when a voltage VOUT? of the terminal satisfies the expression VOUT?>VBAT×m/n.

Abstract: In the case where it is detected that a power receiving device has been removed from a power transmitting device, a control device turns on a power supply operation of a power supply portion when an operation mode is set to a first mode, and turns off the power supply operation of the power supply portion when the operation mode is set to a second mode.

Abstract: Provided are an electronic device and a wireless charging method and apparatus for an electronic device. In the wireless charging method, an environmental parameter transmitted by a wireless charging device is detected (S102); and a receiving antenna board within an electronic device is moved to a designated position according to the environmental parameter, wherein charging efficiency for charging the electronic device at the designated position is higher than charging efficiency for charging the electronic device at other positions (S104). The problems of wasting time and poor user experience caused by adjusting back and forth the electronic device in the process of wireless charging are solved. Free positioning of the antenna can be implemented, and time required by matching the electronic device and a wireless power supply device in the process of wireless charging can be greatly reduced.

Abstract: A wireless power transmission apparatus for high efficiency energy charging, includes a resonator configured to transmit power, and a power supply unit configured to supply power to the resonator. The apparatus further includes a first switching unit configured to connect the resonator to the power supply unit, and disconnect the resonator from the power supply unit, and a controller configured to control the first switching unit based on an amount of current flowing into the resonator.

Abstract: In one aspect, the present invention provides a universal power supply for wired and wireless electronic devices. In a second aspect, the present invention provides a universal power supply that is reconfigurable to provide a wide range of power supply options.

Abstract: A portable device is provided. The portable device includes a power receiving unit configured to receive a first energy or a second energy from a wireless power transmitter, the first energy being used to perform a communication function and a control function, the second energy being used to charge a battery, and the wireless power transmitter being configured to wirelessly transmit a power, a voltage generator configured to generate a wake-up voltage from the first energy, or to generate a voltage for charging the battery from the second energy, a controller configured to perform the communication function and the control function, the controller being activated by the wake-up voltage, and a communication unit configured to perform a communication with the wireless power transmitter based on a control of the controller.

Abstract: A power distribution method is applied to control an energy harvesting system that includes an ambient energy source, an energy storage, a power converting circuit and a control unit. With the power distribution method, the excess power generated by the ambient energy source is transmitted to charge the energy storage through an indirect power flowing path, or the load side is powered by the energy storage through another indirect power flowing path. Therefore, the number of inductor switches of the power converting circuit can be reduced to mitigate switching loss and ensure higher power conversion efficiency.

Abstract: Systems and methods for controlling a solar panel or solar panel array to power one or more appliances are disclosed. The systems include at least a solar panel or solar panel array, an appliance or electrical load, and a power controller connected between the solar panel or solar panel array and the electrical load. The controller performs a maximum power point tracking (MPPT) algorithm on the solar panel or array. The controller also takes into account contextual information, including location and time information, and allows the battery to be discharged beyond a defined threshold only if the contextual information indicates that sufficient solar power will be available to recharge it.

Abstract: A solar charging apparatus is disclosed that includes an article of apparel that is capable of conformably fitting to a body part of a wearer, the article of apparel having a longitudinal dimension and a transversal dimension. The apparatus includes a power source that is coupleable to an interior portion of the article of apparel. The power source is connected to an output connector that is configured to charge a portable electronic device that is separate from the article of apparel. The apparatus includes a plurality of crystalline solar cells for recharging the power source, wherein the plurality of crystalline solar cells curves to conform to the article of apparel.

Abstract: Systems and methods for achieving controlled load transition between power supplies and battery units are described. A method may include determining that a Power Supply Unit (PSU) coupled to an IHS via a power transmission interface is turned off; allowing a Backup Battery Unit (BBU) coupled to the IHS via the power transmission interface and in parallel with the PSU via a current sharing bus to supply all current consumed by the IHS via the power transmission interface while the PSU is turned off, where the PSU and the BBU are each configured to output a current sharing signal onto the current sharing bus that is indicative of the PSU's or BBU's current being supplied to the IHS via the power transmission interface; reducing a current sharing scaling factor of the BBU; determining that the PSU is turned back on; and increasing the current sharing scaling factor of the BBU.

Abstract: A power supply system which connects a DC consumer to an AC supply includes an AC-DC converter and a UPS. The AC-DC converter has an input to which alternating current from the AC supply is applied and an output at which DC current is developed. The UPS has an input to which direct current from the AC-DC converter is applied and an output at which DC current is developed. The DC current developed at the output of the AC-DC converter and DC current developed at the output of the UPS are applied to the DC consumer selectively in parallel with each other or exclusively to each other.

Abstract: An automatic autonomous redundant switch configured for providing energy from either a first power source or a second power source to a load is provided. The automatic switch includes a first automatic transfer switch (ATS) and a second ATS. The automatic switch further includes an interconnecting bus configured to connect the first ATS and the second ATS, and at least one controller configured to control the operation of the first ATS and the second ATS. Still further, the first ATS and the second ATS each include a respective transfer-switch mechanism, a respective bus attachment configured to connect to the interconnecting bus, and a respective motorized rack-out mechanism having a powered actuator.

Abstract: The methods and apparatus described enable automatic configuration, or commissioning, of controller devices and load control devices through a low voltage communication network controlled by one or more controller devices. These methods and apparatus further enable expansion of the load control system by connection of additional loads and or load control devices and or controller devices which will reinitialize the low voltage communication network and automatically reconfigure the controller devices and load control devices connected to the network.

Abstract: A computerized method allowing automated building energy management is provided, including specifically automated electric load shed in response to load shed programs and the like. The method also provides for automated electric load increases in response to certain conditions. The system allows for remote and automated managing, coordinating, and implementing of electrical load changes or modifications at a facility having electric equipment.

Abstract: A system, a circuit, and a method of wireless power transfer using a transmitter and a controller coupled to the transmitter. The controller is configured to perform operations including causing the transmitter to scan a frequency range that includes a maximum frequency and a minimum frequency. The operations further include determining one or more detections based at least on the scan of the frequency range. The detection may include a presence of one or more receivers, an absence of one or more receivers, and/or a presence of a foreign object. The operations include determining one or more further operations based on the one or more detections.

Abstract: Provided is a first coil device that faces a second coil device in a facing direction, and wirelessly transmits or receives power, the first coil device including a first coil portion, and a first auxiliary magnetic member provided adjacent to the first coil portion in a first direction orthogonal to the facing direction. The first auxiliary magnetic member is configured to be closer to the second coil device with increasing distance in the first direction from the first coil portion.

Abstract: A reconfigurable wireless power transmit antenna includes an antenna coil configured in a first configuration having a first number of turns configured to operate at a first frequency, the antenna coil configurable in a second configuration having a second number of turns configured to operate at a second frequency, and a switching mechanism configured to switch between the first configuration and the second configuration.

Abstract: A system and method for wireless power transfer. The system includes a transmit coil having a first magnetic field having a first magnitude. The system also includes a receive coil, magnetically coupled to the transmit coil, having a second magnetic field having a second magnitude. The system also includes an electronic processor electrically coupled to the transmit coil and communicatively coupled to the receive coil. The electronic processor is configured to determine the first magnitude of the first magnetic field. The electronic processor is further configured to receive the second magnitude of the second magnetic field. The electronic processor is further configured to determine an efficiency based on the first magnitude and the second magnitude, and determine a power level for the transmit coil based on the efficiency.

Abstract: Aspects of the present disclosure involve a system and method for charging a device. The current disclosure also presents a cradle which can be used as an interface for communicating with external computing systems and power charging systems. In one embodiment, the cradle is used to down convert a high powered signal from a power charging system for use to charge a device such as a wearable. In another embodiment, the cradle is used to communicate with and external computing system for device upgrades and maintenance.