초록 ▼

Inductrack III configurations are suited for use in transporting heavy freight loads. Inductrack III addresses a problem associated with the cantilevered track of the Inductrack II configuration. The use of a cantilevered track could present mechanical design problems in attempting to achieve a stro

Inductrack III configurations are suited for use in transporting heavy freight loads. Inductrack III addresses a problem associated with the cantilevered track of the Inductrack II configuration. The use of a cantilevered track could present mechanical design problems in attempting to achieve a strong enough track system such that it would be capable of supporting very heavy loads. In Inductrack III, the levitating portion of the track can be supported uniformly from below, as the levitating Halbach array used on the moving vehicle is a single-sided one, thus does not require the cantilevered track as employed in Inductrack II.

대표청구항 ▼

1. A system, comprising: a movable object;a first levitating Halbach array attached to said object;a second levitating Halbach array attached to said object;a first track comprising a first levitation portion in operative proximity to said first levitating Halbach array such that upon movement of sa

1. A system, comprising: a movable object;a first levitating Halbach array attached to said object;a second levitating Halbach array attached to said object;a first track comprising a first levitation portion in operative proximity to said first levitating Halbach array such that upon movement of said object, a first levitation force with be generated between said first levitating Halbach array and said first levitation portion;a second track comprising a second levitation portion in operative proximity to said second levitating Halbach array such that upon said movement of said object, a second levitation force with be generated between said second levitating Halbach array and said second levitation portion;a substantially uniform non-cantilevered support structure supporting said first levitation portion and said second levitation portion such that they are substantially uniformly supported; andmeans for adjusting said first levitation force and said second levitation force. 2. The system of claim 1, wherein said first track further comprises a first current portion electrically connected to said first levitation portion, wherein said second track further comprises a second current portion electrically connected to said second levitation portion. 3. The system of claim 2, wherein said means comprises a third Halbach array and a fourth Ha'bath array, wherein said third Halbach array and said fourth Halbach array are in a parallel spaced orientation and are each attached to said object and configured such that said first current portion of said first track and said second current portion of said second track are located between said third Halbach array and said fourth Halbach array. 4. The system of claim 3, wherein said means can vary a parameter at least one of said third Halbach array and said fourth Halbach array to optimize levitation efficiency. 5. The system of claim 3, wherein said means can change the relative magnetic field polarization directions of said third Halbach array and said fourth Halbach array either to reduce, or to increase, the current induced in at least one of said first track and said second track relative to that which would be induced by at least one of said first Halbach array and said second Halbach array acting alone. 6. The system of claim 2, wherein said means comprises a third Halbach array, a fourth Halbacti array, a fifth Halbach array and a sixth Halbach array, wherein said third Halbach array and said fourth Halbach array are in a parallel spaced orientation and are each attached to said object and configured such that said first current portion of said first track is located between said third Halbach array and said fourth Halbach array, wherein said fifth Halbach array and said sixth Halbach array are in a parallel spaced orientation and are each attached to said object and configured such that said second current portion of said second track is located between said fifth Halbach array and said sixth Halbach array. 7. The system of claim 6, wherein said uniform support structure comprises a first uniform support structure and a second uniform support structure, wherein said first uniform structure supports said first levitation portion, wherein said second uniform support structure supports said second levitation portion, wherein said first current portion overhangs said first uniform support structure and said second current portion overhangs said second uniform support structure, wherein there is substantially no angle between said first levitation portion and said first current portion and wherein there is substantially no angle between said second levitation portion and said second current portion. 8. The system of claim 7, wherein said LSM comprises LSM windings and said first track and said second track comprises track windings, wherein said LSM winding are collocated with said track windings. 9. The system of claim 8, wherein said LSM windings are spaced far enough from said track windings to limit inductive coupling between said LSM windings and said track windings. 10. The system of claim 6, wherein said means can vary a parameter at least one of said third Halbach array, said fourth Halbach array, said fifth Halbach array and said sixth Halbach to optimize levitation efficiency. 11. The system of claim 6, wherein said means can change the relative magnetic field polarization directions of said third HalbaCh array and said fourth Halbach array either to reduce, or to increase, the current induced in said first track relative to that which would be induced by said first Halbach array acting alone, and wherein said means can change the relative magnetic field polarization directions of said fifth Halbach array and said sixth Halbach array either to reduce, or to increase, the current induced in said second track relative to that which would be induced by said second Halbach array acting alone. 12. The system of claim 1, wherein said means comprises a first biasing magnet and a second biasing magnet, wherein said first biasing magnet and said second biasing magnet are attached to said movable object, wherein said means further comprises a first iron piece and a second iron piece both fixedly attached relative to said support structure and respectively are proximately and operatively positioned near said first biasing magnet and said second biasing magnet. 13. The system of claim 12, wherein said first biasing magnet and said second biasing magnet are mechanically adjustable to move toward or away from said first iron piece and said second iron piece respectively as a load on said movable object increases or decreases to add to or subtract from said first levitation force and said second levitation force respectively. 14. The system of claim 12, wherein said first biasing magnet together with said first iron piece and said second biasing magnet together with said second iron piece are configured to provide lateral centering forces, wherein said first iron piece comprises a dimension sized to insure that edge effects between said first biasing magnet and said first iron piece give rise to, a centering force and wherein said second iron piece comprises a dimension sized to insure that edge effects between said second biasing magnet and said second iron piece give rise to a centering force. 15. The system of claim 1, wherein said first levitation portion and said second levitation portion are oriented at a dihedral angle with respect to each other to provide a centering force when said object is in motion. 16. The system of claim 1, wherein said first track is laminated and wherein said second track is laminated. 17. The system of claim 1, further comprising a linear synchronous motor (LSM) drive system attached to at least one of said first track or said second track. 18. The system of claim 1, wherein said movable object comprises a vehicle. 19. The system of claim 1, wherein said means can produce a current upon said movement, wherein said means can reduce said drive current relative to at least one of said first levitating force and said second levitation force in order to optimize levitation efficiency. 20. A method for operating a system, wherein said system comprises: a movable object;a first levitating Halbach array attached to said object;a second levitating Halbach array attached to said object;a first track comprising a first levitation portion in operative proximity to said first levitating Halbach array such that upon movement of said object, a first levitation force with be generated between said first levitating Halbach array and said first levitation portion;a second track comprising a second levitation portion in operative proximity to said second levitating Halbach array such that upon said movement of said object, a second levitation force with be generated between said second levitating Halbach array and said second levitation portion;a substantially uniform non-cantilevered support structure supporting said first levitation portion and said second levitation portion such that they are substantially uniformly supported; andmeans for adjusting said first levitation force and said second levitation force,wherein said method comprises adjusting said first levitation force and said second levitation force by operating said means for adjusting said first levitation force and said second levitation force.