Disclosed is a power wiring device which comprises: at least one elongated wiring member which includes a plurality of first connectors and allows the first connectors to be mutually electrically conducted; and a plurality of circuit modules each including a second connector which is mechanically and electrically attachable to and detachable from any of the first connectors, wherein the plurality of circuit modules include: at least one energy harvesting module as a circuit module capable of outputting power generated by energy harvesting from the second connector; and at least one load module as a circuit module capable of consuming power input from the second connector.

A system is disclosed which eliminates problems caused by surges of electric energy which is generated on a utility customer's property and which is fed back onto a utility-owned service line by maintaining a minimum utility provided percentage (MUPP) of power being provided onto a customer-owned dead-end service line. Where the electric energy generated by a utility customer is incrementally excluded from the customer-owned dead-end service line through a plurality of contactors which are controlled by a 120 volt command line.

A microgrid system for water pumps is provided herein and includes a solar array comprising three independent branches and a first pair of photovoltaic modules and a second pair of photovoltaic modules on each of the three independent branches, each of the first pair photovoltaic modules and the second pair of photovoltaic modules connected by a corresponding single-phase inverter connected in series with each other and connected to a common controller configured to connect the first pair photovoltaic modules and the second pair of photovoltaic modules to a grid during a first mode of operation and connect the first pair photovoltaic modules and the second pair of photovoltaic modules to a water pump during a second mode of operation, different from the first mode of operation.

Apparatus, methods, and computer program products for managing power sharing in electronic devices are disclosed. One apparatus includes a processor and a memory that stores code executable by the processor to determine, in real-time, whether one or more first electronic devices that are compatible with a second electronic device that is low on power are within a predetermined geographic distance of the second electronic device and, in response to determining that one or more first electronic devices that are compatible with the second electronic device are within the predetermined geographic distance of the second electronic device, transmit a request to the one or more first electronic devices inquiring whether any of the one or more first electronic devices are willing to share power with the second electronic device. Methods and computer program products that include and/or perform the operations of the apparatus are also disclosed.

There is provided a method of determining and utilizing predicted available power resources from one or more renewable power sources for one or more industrial gas plants comprising one or more storage resources. The method is executed by at least one hardware processor and comprises: obtaining historical time-dependent environmental data associated with the one or more renewable power sources; obtaining historical time-dependent operational characteristic data associated with the one or more renewable power sources; training a machine learning model based on the historical time-dependent environmental data and the historical time-dependent operational characteristic data; executing the trained machine learning model to predict available power resources for the one or more industrial gas plants for a pre-determined future time period; and controlling the one or more industrial gas plants in response to the predicted available power resources for the pre-determined future time period.

An AC power sharing system for connecting an AC power source to at least two loads, the system comprising: power distribution board, the power distribution board having at least one input for receiving AC power from the AC power source; and, the power distribution board further comprising at least two relays, each relay for connecting the distribution board to a load, each switch having an OPEN/CLOSED configuration, wherein in the CLOSED configuration the relay is configured to connect the AC power source to a load to provide power from the AC power source to the load; wherein the relays comprise two IGBTs or MOSFETs arranged with their load side terminals connected in anti-series.

A power distribution system configured as a radial network includes buses having respective voltages, and distribution lines having respective currents. The radial network interconnects the buses with the distribution lines in a tree-like manner. A bus has a link to at least two distribution lines. The bus voltages and distribution line currents are determined by a processing circuitry configured to receive a Branch Matrix (BM), iteratively determine currents for the distribution lines and voltages for each of the buses until a difference is below a predetermined tolerance, and output final bus voltages and final distribution line currents. The circuitry iteratively determines the currents by determining a current matrix (CM) using the BM, and by determining the currents for the plurality of distribution lines in a zig zag manner over the matrix elements in the CM. The system finds a solution using fewer iterations than the backward forward sweep method.

A system and a control method of a mobile micro-grid are provided. The mobile micro-grid system includes a renewable energy source and a non-renewable energy source which are in a container. The control method includes supplying the renewable energy source as a primary power supply to an external load; and determining whether the electricity of the renewable energy source is sufficient. If the electricity of the renewable energy source is sufficient, then the renewable energy source provides electricity to the external load; if the electricity of the renewable energy source is not sufficient, then the renewable energy source and non-renewable energy source provide electricity to the external load. If an external power source, which is a renewable-energy-type power source, is connected to the mobile micro-grid system, then the renewable energy source and external power source work as the primary power supply.

A device for electrically connecting a direct current (DC) microgrid to a DC bus of an electrical power network, which is operating at a higher voltage than the microgrid, comprises a pair of electrical port each configured for connection with either the DC bus or the microgrid; a DC-DC power converter operatively interconnecting the electrical ports for power transmission therebetween from a first voltage at the port connected to the DC bus to a lower second voltage at the port connected to the DC microgrid; a DC circuit breaker connected between the DC-DC power converter and one of the electrical ports for selectively conducting current therebetween; and a controller which is configured to communicate with constituent devices in the DC microgrid as well as a control center representative of the electrical power network in order to exchange information about electrical energy consumption in the DC microgrid and the larger network.

Various embodiments provide methods and systems for the deployment of distributed energy systems. In an embodiment, a method, performed by a microgrid controller of a microgrid, includes receiving information indicating that a failure has occurred in at least one external grid connected to the microgrid. In response to receiving the information, the method further includes transmitting operational parameters to one or more energy resources to regulate power injected into the microgrid when the microgrid is importing power from the at least one external grid.