A system for load balancing on a multi-phase power line connected to a single phase lateral power line, includes a contactor configured to selectively connect each phase of the multi-phase power line to the single phase lateral power line. There is a phase change device connected in parallel with the contactor and a controller. During the phase change state, the controller connects the input of the phase change device to the multi-phase power line and connects the output of the phase change device the single phase lateral power line. The controller causes the phase change device to output a voltage to the single phase lateral line initially aligned with the first phase and then rotated to align with the second phase and causes the contactor changes connection to the second phase of the multi-phase power line and disconnect the phase change device from the power lines.

A system for load balancing on a multi-phase power line connected to a single phase lateral power line, includes a contactor configured to selectively connect each phase of the multi-phase power line to the single phase lateral power line. There is a phase change device connected in parallel with the contactor and a controller. During the phase change state, the controller connects the input of the phase change device to the multi-phase power line and connects the output of the phase change device the single phase lateral power line. The controller causes the phase change device to output a voltage to the single phase lateral line initially aligned with the first phase and then rotated to align with the second phase and causes the contactor changes connection to the second phase of the multi-phase power line and disconnect the phase change device from the power lines.

An energy-saving brushless motor-kinetic generator is provided in the present invention, especially a combination structure by adjusting the rotors and the stators in the electric generator. The energy-saving brushless motor-kinetic generator with the new combination structure can be simply cascaded to assemble an energy-saving system with the energy-saving brushless motor-kinetic generator included with magnetic energy motor electric power. The energy-saving brushless motor-kinetic generator can specifically perform transformation of magnetic energy and mechanical energy by magnetic energy of permanent magnet of the rotors and design of turns of the stator windings, so to enhance output of electrical energy.

A system for power conservation in a residential building that includes: a motor; a generator, where the generator is powered by the motor; a power inverter, where the power inverter receives current from the generator; and a circuit breaker for the residential building, where the circuit breaker receives power from the power inverter based on pre-selected conditions. The motor is preferably a 110-volt motor, where the generator generates a current of about 350 amps to 450 amps directed to the power inverter. The power inverter generates 4000 to 500 watts of power. The system further includes an electric meter connected to the circuit breaker, where the power inverter transmits power to the circuit breaker for distribution in the residential building during peak power consumption periods and transmits power to the circuit breaker for distribution to the power grid during low power consumption periods.

A self-powered generator disclosed here includes a stator member, a rotor member, a direct current motor, and an alternating current motor. The rotor member is configured to rotate within the stator member, and the direct current motor is coupled to a rotor shaft of the rotor member, where the direct current motor is configured to rotate the rotor member within the stator member via the rotor shaft to generate electricity. However, the direct current motor is shut off when a predetermined amount of electricity is generated, where a portion of the electricity generated is fed to an alternating current motor coupled to the rotor shaft, where the alternating current motor continuously drives the rotor member within the stator member in a closed loop arrangement to generate a continuous supply of electricity.

A self-powered generator disclosed here includes a stator member, a rotor member, a direct current motor, and an alternating current motor. The rotor member is configured to rotate within the stator member, and the direct current motor is coupled to a rotor shaft of the rotor member, where the direct current motor is configured to rotate the rotor member within the stator member via the rotor shaft to generate electricity. However, the direct current motor is shut off when a predetermined amount of electricity is generated, where a portion of the electricity generated is fed to an alternating current motor coupled to the rotor shaft, where the alternating current motor continuously drives the rotor member within the stator member in a closed loop arrangement to generate a continuous supply of electricity.

The invention provides a topsides drive for electric centrifugal pumps or compressors, distinctive in that the drive comprises an electric motor, an electric generator, a variable stepless coupling connecting the motor to the generator, at least one housing, and penetrators through a wall of the at least one housing.

The invention provides a topsides drive for electric centrifugal pumps or compressors, distinctive in that the drive comprises an electric motor, an electric generator, a variable stepless coupling connecting the motor to the generator, at least one housing, and penetrators through a wall of the at least one housing.

A power generating system. The system generates enough energy to allow the processes needed to operate while also generating enough energy for an outside product to operate at capacity to the machine limits by the use of electric motor control(s) and mechanical advantage by utilizing proper gearing with the use of sprockets, pulleys, gears or any combination to create the necessary ratio. The invention utilizes increased electrical motor torque, horsepower and motor control to rotate a power generating unit, causing the power generating unit to produce electricity. A transmission device is coupled between the motor and the power generating unit to increase the torque and horsepower of the motor so as to power the generating unit by gearing, torque, force, and lever force by way of the use of simple machines such as levers and pulleys.

A system for providing electrical power to a facility includes a generator configured to generate electrical power for the facility when a drive-shaft of the generator is rotated. A motor is configured to provide torque to rotate the generator drive-shaft and to be driven by a first power supply. A mechanical energy provider is configured to provide torque to the drive-shaft using mechanical energy generated from an intermittent local power source. The system is configured to defer to the mechanical energy provider to rotate the drive-shaft such that, when the intermittent local power source is active, less power is needed from the first power supply to power the motor than when the intermittent local power source is inactive.