A flexible growcenter includes a mobile container, a behind-the-meter power input system, a power distribution system, a growcenter control system, a climate control system, a lighting system, and an irrigation system. The growcenter control system modulates power delivery to one or more components of the climate control system, the lighting system, and the irrigation system based on unutilized behind-the-meter power availability or an operational directive. A method of dynamic power delivery to a flexible growcenter using unutilized behind-the-meter power includes monitoring unutilized behind-the-meter power availability, determining when a growcenter ramp-up condition is met, and enabling behind-the-meter power delivery to one or more computing systems when the growcenter ramp-up condition is met.

Apparatus and associated methods related to providing safe electrical control and/or communication between a remote controller located in a safe location and interface system for a machine located in a hazardous location. The control and/or communication is provided via industrial-voltage power lines that traverse a barrier separating the safe location from the hazardous location. Control and/or communication is provided by reactively coupling to industrial power lines, which traverse the barrier, so as to superimpose a control and/or communication signal upon AC operating power provided to the machine. Each of the interface system located at the hazardous location and the remote control module located at a safe location provides such reactive coupling to the industrial-voltage power lines so as to communicate therebetween.

A variable speed genset system is provided. The variable speed genset system may include a plurality of gensets, a switch assembly coupling one or more of the gensets to a common bus, a power electronics circuit selectively coupling the switch assembly to the common bus, and a controller in electrical communication with the gensets, the switch assembly and the power electronics circuit. The controller may be configured to designate any one or more of the gensets to operate as variable speed gensets and one or more of the remaining gensets to operate as constant speed gensets, engage the switch assembly to couple the variable speed genset to the power electronics circuit, and engage the switch assembly to couple the constant speed gensets to the common bus.

Method and system are provided for power path identification in a power distribution system. The method transmits a data signal through a power line infrastructure including adding an identifier value at multiple points of the infrastructure to the data signal to form a concatenated path identifier formed of the identifier values. The method reads the path identifier at a reading point of the infrastructure to obtain power path information to or from the reading point in the power line infrastructure. A system may include a plurality of path identification devices each provided at a connection point of the power distribution system to transmit connection point identifiers to form a concatenated path identifier with identifier values of other connection points.

A power line communication system (200) comprising a first node (202) and a second node (204). The first node (202) comprises a second-node-connection-terminal (206); a first-node-transmission-module (208) that provides a first-node-output-signal (210) to the second-node-connection-terminal (206); and modulates the voltage level of the first-node-output-signal based on first-node-transmission-data. The second node (204) comprises a second-node-input-voltage-terminal (214) that is connected to the second-node-connection-terminal (206) of the first node (202) in order to receive the first-node-output-voltage-signal (210). The second node (204) is configured to use the first-node-output-voltage-signal (218) as a supply voltage. The second node (204) also includes a second-node-transmission-module (216) that: provides a second-node-current-signal (218) to the second-node-input-voltage-terminal (214) for transmission to the second-node-connection-terminal (206) of the first node (202); and modulates the current level of the second-node-current-signal (218) based on second-node-transmission-data. The second node (204) also includes a second-node-reception-module (222) that is configured to process the voltage level of the received first-node-output-signal (210) in order to demodulate the first-node-transmission-data. The first node (202) further comprises a first-node-reception-module (226) that processes the current level of the second-node-current-signal (218) received from the second node (204) at the second-node-connection-terminal (206) in order to demodulate the second-node-transmission-data.

A power management system comprises a plurality of HEMSs 10 and CEMSs 40. The CEMS 40 receives, from each HEMS 10, power information including the amount of power consumed by a load connected to each HEMS 10. The CEMS 40 transmits, to each HEMS 10, reduction information including the amount of power that should be reduced in each consumer, in response to a curtailment signal and the power information.

A power control device for an electrically powered appliance may selectively switch off one 110 volt input (of two separate 110 volt input lines) of a 220 volt power supply to the appliance during certain periods of operation, in response to a demand-response request. This may adjust operation of one or more components of the appliance, thus adjusting an amount of power consumed by the appliance. A determination of which one, of the two, 110 volt input lines to be switched off may be made based on an analysis of the amount of power consumed by each of the two 110 volt input lines during operation of the appliance. The power control device may be provided at any point between the electrically powered appliance and a power distribution panel distributing power from an external source.

The invention relates to a method of cancelling noise present in a data signal received on an electrical bifilar line (L), implemented by a sender-receiver device (M) comprising a first transformer (TD), termed the differential mode circuit, comprising a primary side (TDp) and a secondary side (TDs), the primary side being connected by two wires to the bifilar line, a second transformer (TC), termed the common mode circuit, comprising a primary side (TCp) and a secondary side (TCs), the primary side being connected by a wire (c) to the primary side (TDp) of the differential mode circuit, and to an earth by another wire, the method comprising the following steps during an adjustment phase: obtaining a first value of voltage on the bifilar line, termed the differential mode voltage; obtaining a second value of voltage corresponding to a voltage at the level of the two wires of the secondary side of the common mode circuit, termed the image voltage of the common mode, resulting from said differential mode voltage; calculating the ratio between the second value and the first value, termed the noise conversion ratio; and the method comprising the following steps during a cancellation phase, subsequent to the adjustment phase; receiving the data signal originating from the bifilar line; simultaneously with the receiving step, obtaining a third value corresponding to the voltage at the level of the two wires of the secondary side of the common mode circuit; cancelling the noise in the data signal, by subtracting an estimation of the noise, the estimation being calculated by dividing the third value by said conversion ratio.

A charging/discharging control system of an energy storage apparatus includes a weather information collection module, a load information collection module, a load grouping module which classifies a plurality of loads into at least one load group based on a load correlation according to a predetermined condition, and an energy storage apparatus charging/discharging control module which determines a battery charging or discharging level per time slot of each of a plurality of energy storage apparatuses by using at least one of an estimated load amount of each load per time slot, a battery charging amount of the energy storage apparatus per time slot via solar generation, and a battery charging amount per time slot via system power, wherein a particular load corresponding to a lowest rate for a unit load is determined by using battery charging/discharging information and power rate information per time slot.

Examples are disclosed that relate to computing systems having a common conductive pathway. One example provides a computing system comprising a power supply configured to output electrical power for delivery to one or more power nodes, and one or more power monitors configured to identify a power overload condition based on the power output by the power supply. The computing system further comprises a parent controller configured to, based at least on receiving an indication of the power overload condition, transmit an instruction to one or more child controllers that causes each child controller to effect a change in an operational state of a corresponding power node. The computing system also comprises a conductive pathway along which electrical power output from the power supply is transmitted for delivery to the one or more power nodes, and along which the instruction is transmitted to the one or more child controllers.