A power tool is provided. The power tool includes an internal combustion engine and an integrated device coupled to the internal combustion engine. The internal combustion engine includes a flywheel or another rotating component. The integrated device is enclosed in a housing and is coupled adjacent to either the flywheel or a rotating component. The integrated device includes a printed circuit board with a wireless communications module and a power generation portion which receives power wirelessly from the internal combustion engine.

A power tool is provided. The power tool includes an internal combustion engine and an integrated device coupled to the internal combustion engine. The internal combustion engine includes a flywheel or another rotating component. The integrated device is enclosed in a housing and is coupled adjacent to either the flywheel or a rotating component. The integrated device includes a printed circuit board with a wireless communications module and a power generation portion which receives power wirelessly from the internal combustion engine.

A portable and/or stationary device that continuously delivers geomagnetically induced current to a 0-380 volts inverter for a usable electricity. The design invention once started runs perpetual geomagnetic induced current to a spinning 11 kilowatt motor shaft attached t a reversible generator's shaft by a coupling which feeds a 0-380 volt variable inverter until switched off, blows a switch circuit or requires new parts, (increment of parts and part voltage can vary up and down to support a bigger or small load.)

A portable and/or stationary device that continuously delivers geomagnetically induced current to a 0-380 volts inverter for a usable electricity. The design invention once started runs perpetual geomagnetic induced current to a spinning 11 kilowatt motor shaft attached t a reversible generator's shaft by a coupling which feeds a 0-380 volt variable inverter until switched off, blows a switch circuit or requires new parts, (increment of parts and part voltage can vary up and down to support a bigger or small load.)

A flux machine has plural coil assemblies and plural magnet sets arranged in mutual close proximity and circularly about a central axis. Either one of the coil assemblies and the magnet sets are supported by at least one axle which is aligned with the central axis, and either one of the coil assemblies and magnet sets executes rotary motion about the central axis when electrical current is present in the coil assemblies. Magnetic flux of the magnet sets is directed axially and radially while machine rotation is orthogonal to the direction of flux. A plurality of magnets in each magnet set are supported by one or another of a plurality of coaxially aligned axles so that the flux machine may operate as an electrical motor, as an electrical generator, or both at the same time.

A flux machine has plural coil assemblies and plural magnet sets arranged in mutual close proximity and circularly about a central axis. Either one of the coil assemblies and the magnet sets are supported by at least one axle which is aligned with the central axis, and either one of the coil assemblies and magnet sets executes rotary motion about the central axis when electrical current is present in the coil assemblies. Magnetic flux of the magnet sets is directed axially and radially while machine rotation is orthogonal to the direction of flux. A plurality of magnets in each magnet set are supported by one or another of a plurality of coaxially aligned axles so that the flux machine may operate as an electrical motor, as an electrical generator, or both at the same time.

A brushless dual rotor electromagnetic induction motor with an inner exciter rotor having a rotatable drive/input shaft, the inner exciter rotor generating a rotating magnetic field when the drive/input shaft is rotated, an outer carrier rotor surrounding the inner exciter rotor and being co-axial and concentric therewith, the outer carrier rotor having a rotatable carrier frame and a plurality of conductive elements, an electrical current being induced to flow through each of the conductive elements in response to the rotating magnetic field generated by the inner exciter rotor, a rotatable driven/output shaft which rotates in response to rotation of the rotatable carrier frame, and an outer stator surrounding the outer carrier rotor which interacts with the induced electrical current flowing through the conductive elements of the outer carrier rotor to thereby cause the rotatable carrier frame of the outer carrier rotor to rotate.

A winding type permanent magnet coupling transmission device includes a permanent magnet rotor and a winding rotor that is coaxial with the permanent magnet rotor and capable of rotating relative to the permanent magnet rotor. An air gap exists between the permanent magnet rotor and the winding rotor. The winding rotor is connected to a control structure capable of regulating the current/voltage of the winding rotor. The control structure is capable of controlling the current or voltage of the winding rotor, so as to regulate the output torque of the transmission device, with no need to configure any corresponding mechanical execution mechanism. Therefore, the transmission device has a simple structure and small energy loss.

A winding type permanent magnet coupling transmission device includes a permanent magnet rotor and a winding rotor that is coaxial with the permanent magnet rotor and capable of rotating relative to the permanent magnet rotor. An air gap exists between the permanent magnet rotor and the winding rotor. The winding rotor is connected to a control structure capable of regulating the current/voltage of the winding rotor. The control structure is capable of controlling the current or voltage of the winding rotor, so as to regulate the output torque of the transmission device, with no need to configure any corresponding mechanical execution mechanism. Therefore, the transmission device has a simple structure and small energy loss.

A flux machine has plural coil assemblies and plural magnet sets arranged in mutual close proximity and circularly about a central axis. Either one of the coil assemblies and the magnet sets are supported by at least one axle which is aligned with the central axis, and either one of the coil assemblies and magnet sets executes rotary motion about the central axis when electrical current is present in the coil assemblies. Magnetic flux of the magnet sets is directed axially and radially while machine rotation is orthogonal to the direction of flux. A plurality of magnets in each magnet set are supported by one or another of a plurality of coaxially aligned axles so that the flux machine may operate as an electrical motor, as an electrical generator, or both at the same time.