Abstract: The present system relates to a power topology mapping system for identifying which one of one or more equipment components are being powered from a specific phase of a multi-phase AC power source. The system makes use of a plurality of power receiving subsystems which each receive an AC power signal from at least one phase of the multi-phase AC power source. Each power receiving subsystem has a communications card, an identification designation unique to it, and a controller. One of the power receiving subsystems is designated as a reference power domain component. The controllers each carry out phase angle measurements associated with the AC power signal being received by its power receiving subsystem. A topology mapping subsystem is included which analyzes phase angle measurement data reported by the power receiving subsystems and determines which subsystem is being powered by which phase of the multi-phase AC signal.

Abstract: The present disclosure relates to a system for controlling power walk-in for an uninterruptible power supply (UPS) being switched to receive AC power from an AC generator. The system may have a control system and a power walk-in (PWI) subsystem. The PWI subsystem may be controlled in part by the control system. The PWI subsystem may be configured to control at least one of an input current or an input power of an AC signal being provided by an AC generator during a power walk-in operation to attempt to maintain a minimum frequency of the AC signal from the AC generator during the power walk-in operation.

Abstract: The present disclosure relates to a shared hybrid transfer switch for transferring power received by a Load from a preferred AC power source to an alternate AC power source, or transferring power being received by the Load from the alternate AC power source to the preferred AC power source. The transfer switch makes use of a solid-state switch configured in communication with first and second pluralities of relay contacts, and also being coupled to the Load, and which receives control signals from a controller. The solid-state switch is controlled such that it is turned on to be in communication with select ones of the first and second pluralities of relay contacts, to provide a path for current flow to the Load from one of the preferred or alternate AC power sources being transitioned to, to carry out a switching transition from one of the preferred or alternate AC power sources to the other.

Abstract: The present disclosure is a method and apparatus to retrieve data from a power distribution unit. Apparatus to retrieve data from a power distribution unit may include a processor, memory and display which may be coupled to tracking circuitry of the power distribution unit in order to allow viewing of current operating conditions of the power distribution unit. In an embodiment of the disclosure, the processor may be configured to convert data from the tracking circuitry of the power distribution unit into a stream of character sets presented on the display which may be interpreted by a mobile device and translated by the mobile device into human readable information.

Abstract: A DC-DC power converter includes an input, an output, a power circuit coupled between the input and the output to convert a voltage of a DC power received at the input to a different voltage of a DC power supplied at the output, and a control circuit. The DC-DC power converter also includes a resistor coupled in an input current path to receive an inrush current from the input, a switch coupled in parallel with the resistor to selectively bypass the resistor, and a transistor coupled to control the switch in response to a voltage across the resistor. The transistor is coupled to open the switch when the voltage across the resistor is above a specified inrush threshold to permit current flow through the resistor, and to close the switch when the voltage across the resistor is below the specified inrush threshold to bypass the resistor.

Abstract: An electrolyte monitoring system is disclosed which has an interface module and a sensor assembly. The sensor assembly is attachable to an exterior wall surface of a battery cell for monitoring a level of an electrolyte within the battery cell. The sensor assembly may include an infrared (IR) sensor and a cradle. The IR sensor may be configured to communicate with the interface module and to detect when the electrolyte level within the battery cell drops below a predetermined level. The cradle is configured to be affixed to the exterior wall surface of the battery cell at a desired elevational position in relation to the electrolyte level in the cell. The cradle enables mounting and removal of the IR sensor from the cradle without an external tool.

Abstract: An electrical power supply includes a power circuit for providing power to a load via a conductor, and a control circuit. The control circuit is configured to set an output voltage of the power circuit at different values to cause the load voltage at the load to change, sense an output current of the power circuit corresponding to each different value of the output voltage, determine an electrical resistance of the conductor based on the different output voltage values and their corresponding output current values, and set the output voltage of the power circuit at a defined value based on the determined resistance to compensate for a voltage drop of the conductor when the power circuit provides power to the load and to regulate the load voltage at the load at a desired value. Other example power supplies, control circuits and/or methods of regulating load voltages are also disclosed.

Abstract: Disclosed in embodiments of the present invention are a control method, apparatus, device, and medium for a power factor correction (PFC) circuit, used for solving the problems of high implementation costs and relatively severe THD that exist in existing PFC circuit control methods. The control method for a power factor correction (PFC) circuit, comprising: acquiring circuit parameter information of the PFC circuit; when determining that the circuit parameter information meets a preset switching condition, switching a control mode of the PFC circuit to be a continuous conduction mode (CCM).

Abstract: Example DC-DC power distribution systems include electronic communication device(s), a circuit breaker DIN rail adapted to receive a circuit breaker for providing electrical protection to the one or more electronic communication devices, and a DC-DC converter including a housing having a DIN rail mount, a voltage input and a voltage output. The DC-DC converter includes a DC-DC voltage converter circuit coupled between the voltage input and the voltage output, and a controller electrically coupled with the DC-DC voltage converter circuit. The DC-DC converter is mounted on the circuit breaker DIN rail via the DIN rail mount of the DC-DC converter housing, and the controller is configured to control the DC-DC voltage converter circuit to convert a DC voltage at the voltage input to a different DC voltage at the voltage output to supply power to the one or more electronic communication devices.

Abstract: The present disclosure relates to a roof mounted modular cooling unit (“RMC unit”) which is adapted for use above a unit IT structure being used to help form a data center. The RMC unit has a housing configured to be secured perpendicularly relative to a longitudinal axis of a frame of a modular unit IT structure. The housing has a cold air discharge compartment at one end thereof, overlaying a cold aisle formed within the unit IT structure, from which cold air from the modular cooling unit is discharged into the cold aisle, and a hot air intake compartment selectively located to overlay the hot aisle, into which hot air from the hot aisle is drawn. A width of the RMC unit is sufficient to substantially span a full width of the one of the equipment racks.

Abstract: A system and method is disclosed for detecting a specific voltage phase, from a multiphase voltage source, and a specific outlet of an intelligent power strip, that is associated with a residual current flow. The method accomplishes this by using a system that employs a statistical time series analysis using a Pearson's correlation coefficient calculation to measure the linear dependence between the discretely sampled residual current waveform and each phase and outlet's discretely sampled current waveforms, in turn. A residual current as low as 1 mA can be accurately measured and its associated voltage phase source, as well as which outlet of an intelligent power strip it flows out of, can be reliably determined.

Abstract: The present disclosure relates to a power distribution unit (PDU) having at least one power receptacle for enabling attachment of an AC power cord of an external device thereto. A branch receptacle controller (BRC) has at least one bistable relay and is associated with the one power receptacle for supplying AC power thereto from an AC power source. The BRC monitors a voltage of an external power source and uses it to detect when AC power is lost, and then toggles the bistable relay, if the relay is in a closed position, to an open position.

Abstract: Example DC-DC converters include a housing having at least two bullet terminals. The at least two bullet terminals are configured to mate with corresponding terminals in a DC bullet breaker panel. The converter also includes a DC-DC voltage converter circuit coupled between the at least two bullet terminals, and a controller coupled with the DC-DC voltage converter circuit. The controller is configured to control the DC-DC converter circuit to convert a DC input voltage at a first one of the at least two bullet terminals to a different DC output voltage at another one of the at least two bullet terminals. Methods of converting DC voltages using DC-DC converters having bullet terminals are also disclosed.

Abstract: A cooling system including a primary cooling module supplying refrigerant to a circuit including a thermal load. A secondary cooling module provides a supplemental flow of refrigerant to the circuit upon detection of a deficiency of the primary cooling module. A valve is disposed between the primary: module and the circuit to prevent refrigerant flow between the primary cooling module in the circuit. The secondary cooling module transactions from a standby mode of operation to an online mode of operation and the primary cooling module is deactivated in response to detection of the deficiency of the primary cooling module.

Abstract: A cooling system is provided and includes pump, condenser fan, and control modules. The pump module controls a pump to pump a cooling fluid through a cooling circuit. The condenser fan module controls a condenser fan to transfer air across a condenser of the cooling circuit. The control module, while operating in a pumped refrigerant economizer mode or a mixed mode, determines a requested CFC percentage. The pump module activates the pump if the requested CFC percentage is greater than or equal to a predetermined CFC percentage. The condenser fan module: if the requested CFC percentage is greater than or equal to the predetermined CFC percentage, activates the condenser fan or operates the condenser fan at least at a minimum speed; and based on the requested CFC percentage, adjusts a speed of the condenser fan between the minimum speed and a maximum permitted speed to provide the requested CFC percentage.

Abstract: A system and method is disclosed for analyzing a set of collected raw data point values and determining which one or ones of the values are erroneous data values. In one implementation of the method specific ones of the values are examined to determine if they are outliers, and if so they are removed from the data set. At least two other ones of the values obtained at points in time prior to a given one of the values are examined. Weights may be assigned to the at least two other values, and the weights used to help generate a predicted data point value. The predicted data point value is compared to the given one of the values to determine if the given one of the values is an erroneous value. In this way the integrity of each data point value in the set can be checked.

Abstract: Embodiments of the present invention disclose an inverter circuit, an inverter, and a control method and apparatus of an inverter circuit, which are used to solve the problem of direct connection of bridge arms of an inverter circuit. The inverter circuit comprises an inverter module and a filter module that are sequentially connected, wherein the inverter module comprises: a first bridge arm, comprising a first switch tube, a first inductor, a second inductor and a second switch tube that are sequentially connected in series; a second bridge arm, comprising a third switch tube and a first diode that are connected in series; a third bridge arm, comprising a fourth switch tube and a second diode that are connected in series; a first freewheeling branch; and a second freewheeling branch.

Abstract: Disclosed in the present invention are a control method and device for a power factor correction circuit. The method comprises: obtaining voltage information of the power factor correction circuit; determining whether the voltage information meets a set switching condition; if the set switching condition is met, switching a control mode of the power factor correction circuit to a continuous conduction mode; and if the set switching condition is not met, switching the control mode of the power factor correction circuit to a triangular wave current mode or a critical conduction mode. Compared with the prior art, the control mode of the power factor correction circuit can be different according to the voltage information in the embodiment of the present invention, instead of remaining unchanged at all times, without increasing the withstand voltage level of the bus capacitor, thereby reducing the cost of implementation.

Abstract: Embodiments of the present invention disclose an inverter circuit, an inverter, and a control method and apparatus of an inverter circuit, which are used to solve the problem of direct connection of bridge arms of an inverter circuit. The inverter circuit comprises an inverter module and a filter module that are sequentially connected, wherein the inverter module comprises: a first bridge arm, comprising a first switch tube, a first inductor, a second inductor and a second switch tube that are sequentially connected in series; a second bridge arm, comprising a third switch tube and a first diode that are connected in series; a third bridge arm, comprising a fourth switch tube and a second diode that are connected in series; a first freewheeling branch; and a second freewheeling branch.

Abstract: A system and method is disclosed for detecting a specific voltage phase, from a multiphase voltage source, and a specific outlet of an intelligent power strip, that is associated with a residual current flow. The method accomplishes this by using a system that employs a statistical time series analysis using a Pearson's correlation coefficient calculation to measure the linear dependence between the discretely sampled residual current waveform and each phase and outlet's discretely sampled current waveforms, in turn. A residual current as low as 1 mA can be accurately measured and its associated voltage phase source, as well as which outlet of an intelligent power strip it flows out of, can be reliably determined.