A vertical magnetic transmission assembly includes a shelf, a transmission shaft, multiple magnetic modules and a weight. The shelf has multiple boards disposed along a longitudinal direction of the shelf. The magnetic modules are respectively mounted in multiple through holes formed in the boards. The transmission shaft with the weight rotates along the longitudinal direction of the shelf without friction by magnetic force between the magnetic modules and the magnets of transmission shaft. Therefore, the rotation speed or the torsion of the transmission shaft will be increased in use. An energy-saving generator is further combined with the vertical magnetic transmission assembly to reduce the energy loss in the energy transfer process and to save energy.

A new non-contacting magnetic “snubber” bearing is provided for application to rotating systems such as vehicular electromechanical battery systems subject to frequent accelerations. The design is such that in the equilibrium position the drag force of the snubber is very small (milliwatts). However in a typical case, if the rotor is displaced by as little as 2 millimeters a large restoring force is generated without any physical contact between the stationary and rotating parts of the snubber bearing.

An improved passive magnetic bearing (PMB) for rotating machineries and rotating machineries integrating the bearing are configured to counteract the three states dimensional forces applied on them when put in an operating environment having external forces. The improved PMB includes a first ring element having a Halbach array. A second ring element has first and second Halbach arrays extending angularly over respective regions of the second ring. Magnetic interaction from the Halbach array of the first ring with the first and second Halbach arrays of the second ring when the rings are positioned relative each other within an axial operating range defines a combined force curve. This curve can have an axial component matching a predetermined target axial force curve and a radial component matching a predetermined target radial force. In one application, one or more passive magnetic bearings can be integrated in energy producing turbines, whereby the axial component of the force counteracts flow force in a torque generating direction and the radial component counteracts gravitational forces.

An improved passive magnetic bearing (PMB) for rotating machineries and rotating machineries integrating the bearing are configured to counteract the three states dimensional forces applied on them when put in an operating environment having external forces. The improved PMB includes a first ring element having a Halbach array.

A second ring element has first and second Halbach arrays extending angularly over respective regions of the second ring. Magnetic interaction from the Halbach array of the first ring with the first and second Halbach arrays of the second ring when the rings are positioned relative each other within an axial operating range defines a combined force curve. This curve can have an axial component matching a predetermined target axial force curve and a radial component matching a predetermined target radial force. In one application, one or more passive magnetic bearings can be integrated in energy producing turbines, whereby the axial component of the force counteracts flow force in a torque generating direction and the radial component counteracts gravitational forces.

A vertical magnetic transmission assembly includes a shelf, a transmission shaft, multiple magnetic modules and a weight. The shelf has multiple boards disposed along a longitudinal direction of the shelf. The magnetic modules are respectively mounted in multiple through holes formed in the boards. The transmission shaft with the weight rotates along the longitudinal direction of the shelf without friction by magnetic force between the magnetic modules and the magnets of transmission shaft. Therefore, the rotation speed or the torsion of the transmission shaft will be increased in use. An energy-saving generator is further combined with the vertical magnetic transmission assembly to reduce the energy loss in the energy transfer process and to save energy.

A machine (101) including a vertical rotatable shaft (4b) levitated by magnets (5) so as to minimize frictional losses. Magnets (5) are arranged on the machine body (7) and/or the shaft (4b) of the machine (101) to thereby exert a repelling force so that the rotating shaft (4b) is uplifted against gravitational forces. The machine (101) may additionally or alternatively incorporate a magnetic bearing (6), a variable inertia flywheel (24), a magnetic gear (29), and/or a magnetic clutch (19). The magnetic gear (29) may incorporate arrow shaped magnets (28).

A ferromagnetic shield in contact with a magnet bar at the opposite end from the working surfaces of the bar eliminates the field canceling effects that arise from the Amperian currents at that end. The optimum polarization direction for such bars is one that is parallel to the azimuthal coordinate of the bar. The field at the working surface of the bar approaches that of a bar of infinite length because the shield, located on the side opposite to that of the working surface, completely eliminates, or at least substantially reduces, the field cancellation effect that normally would occur. The magnet bars with shields can be assembled on rotors and stators in flywheel storage systems and other rotating machinery.

A power generation apparatus may include a rotating body including a first part, a second part, placed at one side of the first part, having a first dent portion, and a third part, placed at the other side of the first part, having a second dent portion; a supporting body opposite the first part; a first non-rotating body, opposite the second part, having a first portion protruding toward the first dent portion; a second non-rotating body, opposite the third part, having a second portion protruding toward the second dent portion; magnet units, having a first polarity, installed on the first protruding portion, the first dent portion, and the supporting body; magnet units, having a second polarity, installed on the second dent portion, the second protruding portion, and the first part; and conductor units, between the first part and the supporting body, in which induced current is generated.

A ferromagnetic shield in contact with a magnet bar at the opposite end from the working surfaces of the bar eliminates the field canceling effects that arise from the Amperian currents at that end. The optimum polarization direction for such bars is one that is parallel to the azimuthal coordinate of the bar. The field at the working surface of the bar approaches that of a bar of infinite length because the shield, located on the side opposite to that of the working surface, completely eliminates, or at least substantially reduces, the field cancellation effect that normally would occur. The magnet bars with shields can be assembled on rotors and stators in flywheel storage systems and other rotating machinery.