This disclosure describes a miniaturized energy-monitoring device that can be powered through an Internet port, which also facilitates the programming the device and transmitting energy consumption data to a remote device for recording and analyzing.

This disclosure describes a miniaturized energy-monitoring device that can be powered through an Internet port, which also facilitates the programming the device and transmitting energy consumption data to a remote device for recording and analyzing.

A plug in power strip that prevents electricity from traveling to an appliance when not in use is disclosed. The power strip may use either sensor technology or a manually operated switch that when an appliance is unused will be alerted and will prevent electricity from traveling to the appliance, thus not wasting energy. The resulting shut off will save energy, save money and be safer for homeowners. When the user deems it useful to begin using the appliance once again, the plug in power strip will re-open the channel to let electricity back into that specific appliance. Therefore, the plug in power strip of the present invention keeps optimally keeps appliances running, but does not waste electricity.

A plug in power strip that prevents electricity from traveling to an appliance when not in use is disclosed. The power strip may use either sensor technology or a manually operated switch that when an appliance is unused will be alerted and will prevent electricity from traveling to the appliance, thus not wasting energy. The resulting shut off will save energy, save money and be safer for homeowners. When the user deems it useful to begin using the appliance once again, the plug in power strip will re-open the channel to let electricity back into that specific appliance. Therefore, the plug in power strip of the present invention keeps optimally keeps appliances running, but does not waste electricity.

Isolation circuit system and a signal isolation method thereof. The system includes: a power management unit, configured to output a first signal to a digital logic circuit when power down is detected in a first circuit area, and output a second signal to the digital logic circuit when no power down is detected in the first circuit area; the digital logic circuit, configured to perform logical processing on the first signal received from the power management unit before outputting an isolation signal to the isolation circuit, and perform logical processing on the second signal received from the power management unit before outputting a connection signal to the isolation circuit; and the isolation circuit, configured to block the interactive signal, or to output the interactive signal to a second circuit area after the interactive signal is processed through voltage stabilization.

Isolation circuit system and a signal isolation method thereof. The system includes: a power management unit, configured to output a first signal to a digital logic circuit when power down is detected in a first circuit area, and output a second signal to the digital logic circuit when no power down is detected in the first circuit area; the digital logic circuit, configured to perform logical processing on the first signal received from the power management unit before outputting an isolation signal to the isolation circuit, and perform logical processing on the second signal received from the power management unit before outputting a connection signal to the isolation circuit; and the isolation circuit, configured to block the interactive signal, or to output the interactive signal to a second circuit area after the interactive signal is processed through voltage stabilization.

A digital power distribution system includes a source sensor configured to provide feedback that includes a signal indicative of voltage across the source terminals; a source controller configured to receive the feedback from the source sensor and to generate a control signal that opens a source disconnect switch between the power source and the source terminals; a non-linear load configured such that the electrical current it draws from the load terminals drops by at least an order of magnitude below a non-zero voltage threshold; reduced capacitance for storing charge and discharging that charge during the sample period, wherein the reduced capacitance is at a level for providing this low level of electrical current drawn by the non-linear load. The system can be configured without a disconnect switch between the load terminals and the non-linear load to thereby maintain the non-linear load in electrical contact with the load terminals.

A digital power distribution system includes a source sensor configured to provide feedback that includes a signal indicative of voltage across the source terminals; a source controller configured to receive the feedback from the source sensor and to generate a control signal that opens a source disconnect switch between the power source and the source terminals; a non-linear load configured such that the electrical current it draws from the load terminals drops by at least an order of magnitude below a non-zero voltage threshold; reduced capacitance for storing charge and discharging that charge during the sample period, wherein the reduced capacitance is at a level for providing this low level of electrical current drawn by the non-linear load. The system can be configured without a disconnect switch between the load terminals and the non-linear load to thereby maintain the non-linear load in electrical contact with the load terminals.

A superconducting magnet device including a superconducting coil formed of a high-temperature superconducting wire, a power supply which supplies current to the superconducting coil, and a protector capable of forming a short-circuit path which short-circuits both ends of the superconducting coil to each other is installed. Current is made to flow from the power supply to the superconducting coil in a superconducting state, and the superconducting coil thereby generates a magnetic field. After the magnetic field is generated, when an abnormality of the superconducting magnet device is detected, or when the power supply and the superconducting coil are disconnected from each other, the short-circuit path is formed by the protector.

A superconducting magnet device including a superconducting coil formed of a high-temperature superconducting wire, a power supply which supplies current to the superconducting coil, and a protector capable of forming a short-circuit path which short-circuits both ends of the superconducting coil to each other is installed. Current is made to flow from the power supply to the superconducting coil in a superconducting state, and the superconducting coil thereby generates a magnetic field. After the magnetic field is generated, when an abnormality of the superconducting magnet device is detected, or when the power supply and the superconducting coil are disconnected from each other, the short-circuit path is formed by the protector.