A system for capture, storage, and usage of electric energy generated by humans during exercise activities, including exercise devices having a modular control-power storage unit that incorporates energy conversion units arranged to transform mechanical energy of the at least one human participant into different storable forms of energy, at least one energy storage module arranged to store energy in at least one storage medium, and at least one control unit arranged to provide digital or analog control for the at least one modular control-power storage unit. The system may also have a communication and networking subsystem structured as a networking device and arranged to connect to and communicate bay exchanging information with at wired and/or wireless network.

Alternator/starters and methods for providing electrical power to a vehicle and rotating an engine are disclosed. In one example, the alternator/starter provides a differential action whereby torque on an input side of the alternator may be maintained while speed of an output side of the alternator may be varied. The alternator/starter includes two armature windings and two field windings.

An apparatus including a stator configured to be stationarily connected to a housing; and a rotor configured to have a robot arm connected thereto. The rotor includes a shaft and an robot arm mount adjustably connected to the shaft. The stator and the rotor include mechanical reference locators to temporarily stationarily locate the robot arm mount to the stator for subsequently stationarily fixing the robot arm mount to the shaft.

A vibration motor is provided in the present disclosure. The vibration motor includes a frame, vibrating assemblies and elastic connectors. The elastic connectors comprise a first elastic connector and a second elastic connector. The vibrating assemblies comprise a first vibration system and a second vibration system disposed at two sides of the frame respectively. A portion of the first elastic connector is connected with the first vibration system and another portion of the first elastic connector is connected with one side of the frame, and a portion of the second elastic connector is connected with the second vibration system and another portion of the second elastic connector is connected with the other side of the frame. The first vibration system comprises a coil, the second vibration system comprises a magnetic circuit system with a magnetic gap, at least part of the coil is disposed in the magnetic gap.

A low resistance generator includes a series of stator plates and rotors. Stator plates include the coils wrapped around coil spools. The stator plates and coil spools are made from non-conductive and non-ferromagnetic material. The coils are exposed to the surrounding air and cooled convectively by airflow caused by a rotation of the rotors in the gaps. Rotors house magnets and are disposed within gaps between the stator plates. The rotors are also made of non-conductive and non-ferromagnetic materials. The magnets may be disposed on the rotors to form columns. Two columns of magnets are joined together to form one or more closed magnetic loops, each column being joined by a gauss bridge disposed at first and second end rotors.

The present invention provides a high-speed motor for supplying high-output power by preparing a power transmission device, which increases rotational power at the front of a motor converting electrical energy into mechanical energy, so as to cause a rotary motion, obtain power, and supply the power, such that the power transmission device generates torque through an interaction of attraction and repulsion between a rotating magnetic field and a magnetic field generated by receiving the rotational power of the electric motor of receiving the rotational power of the electric motor and external electric power, thereby implementing a motor for transferring power with an increased number of revolutions and torque.

The present disclosure is an electrical power generating and storage unit configured to generate electricity using magnetic forces and gravitational forces. The power generator can be scaled for various applications, including mobile and stationary power production. One example of the power generator includes nano-coated coils placed along the walls of a cylindrical housing around a centrally placed sphere containing a gel compound. The gel compound is produced by an electrochemical reaction between metals and a salt contained in a supersolution.

A machine that employs discharge of a first battery to enable rotation of a magnetic tube within a wire coil to generate electricity is disclosed. Discharge of the battery may continue until a sensor signals a second battery to begin discharge to enable the magnetic tube to continue to rotate to generate electricity. A portion of the electricity which may be generated is directed to recharging the first battery. Another portion is directed to an electricity powered device.

The present invention discloses a novel electric motor, which comprises a stator and a rotor. The stator is a permanent magnet. The rotor comprises a rotor coil and a capacitor. The rotor coil and the capacitor are connected in series to form a resonant driving circuit. The resonant driving circuit is used to convert a natural electromagnetic field into a current to drive the rotor to rotate. The motor of the present invention can rotate without any external power, thereby solving the technical problem that the use of the external power makes a restriction to the further development and application of the motor, and solving the problem of motor energy consumption.

The present invention is a machine in which the repulsion and attraction forces of moving electromagnets are utilized to power a series of linkages that ultimately turn a crank. The motor is controlled by an external computer system which distributes an electric current among the electromagnets. In order to reverse the polarities of the electromagnets, the direction of the current will be rapidly changing. This polarity reverse causes electromagnets to repel and attract. The magnets then oscillate along two swing arms that once swung because of both polarity attraction and repulsion, activate the linkages.