US2017030337A1PendingUtilityA1
Magnet configurations for magnetic levitation of wind turbines and other apparatus
Est. expiryApr 20, 2032(~5.8 yrs left)· nominal 20-yr term from priority
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Claims
Abstract
A wind turbine having one or more magnets for reducing friction between the turbine support and a turbine rotor. The reduction of friction between the turbine rotor and the turbine support allows for an increase in energy production and scale of the wind turbines. The magnet configuration employs a ring of cylindrically-shaped magnets at the bottom and opposed by a corresponding number of generally rectangular-shaped magnets. Bearing magnets are also employed for axial stabilization.
Claims
exact text as granted — not AI-modified1 . A wind turbine, comprising:
a turbine rotor; a turbine support; a first magnet set located on a lower surface of said turbine rotor, magnets therein having a generally rectangular shape and disposed in a ring along said lower surface of said turbine rotor; and a second magnet set located on an upper surface of said turbine support, magnets therein having a generally cylindrical shape, each of said generally cylindrically-shaped magnets being disposed in a ring and substantially aligned below at least one of said rectangularly-shaped magnets in said first magnet set, whereby, in operation, said first magnet set on said turbine rotor and said second magnet set on said turbine support separate due to magnetic repulsion, wherein a space is created by the magnet sets in opposition allowing the rotor to rotate with reduced friction.
2 . The wind turbine according to claim 1 , wherein the turbine support further comprises:
a support shaft and a base; and a platform located substantially under a bottom of the base.
3 . The wind turbine according to claim 2 , further comprising:
one or more stabilization magnet sets, wherein the one or more stabilization magnet sets are configured to form a space between the support shaft and the turbine rotor.
4 . The wind turbine according to claim 1 , wherein the generally cylindrically-shaped magnets are about 1.5 inch in diameter.
5 . The wind turbine according to claim 1 , wherein the generally cylindrically-shaped magnets are about 0.75 inches in height.
6 . The wind turbine according to claim 1 , further comprising:
at least one generator configured to generate electric power from the movement of said turbine rotor.
7 . The wind turbine according to claim 6 , wherein at least one generator further comprises:
a generator gear; a turbine gear, wherein the turbine gear is configured to move the generator gear; a magnetic gear connection between the generator gear and the turbine gear, wherein the magnetic gear connection is configured to move the generator gear without friction between the turbine gear and the generator gear.
8 . The wind turbine according to claim 7 , wherein said at least one generator further comprises:
at least one linear synchronous generator.
9 . The wind turbine according to claim 1 , further comprising:
at least one blade coupled to said turbine rotor, said at least one blade configured to move said turbine rotor relative to said turbine support by capturing wind energy.
10 . The wind turbine according to claim 9 , wherein said at least one blade is comprised of a poly-carbon material.
11 . A wind turbine, comprising:
a turbine rotor; a turbine support; a first magnet set located on a lower surface of said turbine rotor, magnets therein having a generally rectangular shape and disposed in a ring along said lower surface of said turbine rotor; and a second magnet set located on an upper surface of said turbine support, magnets therein having a generally cylindrical shape, each of said cylindrically-shaped magnets being disposed in a ring and substantially aligned below at least one of said generally rectangularly-shaped magnets in said first magnet set.
12 . The wind turbine according to claim 11 , wherein the turbine support further comprises:
a base located below the turbine rotor; a support shaft located along a central axis of the turbine rotor and extending therethrough along said central axis; and a top configured to cover a substantial portion of the turbine rotor and one or more blades affixed thereto.
13 . The wind turbine according to claim 12 , wherein the top further comprises:
an observation deck.
14 . The wind turbine according to claim 12 , wherein the support shaft further comprises:
an interior access way configured to allow one or more persons to travel to and from the observation deck, wherein the interior access way further comprises an elevator.
15 . The wind turbine according to claim 11 , further comprising:
a transport device located beneath the turbine support and configured to move the wind turbine to and from remote sites.
16 . The wind turbine according to claim 15 , wherein the transport device is a trailer.
17 . The wind turbine according to claim 11 , wherein at least one of said magnet sets are permanent magnets.
18 . A method for generating electricity, comprising:
lifting, through magnetic repulsion between opposing magnets, a vertical turbine rotor off of a turbine support, thereby reducing the friction between the vertical turbine rotor and the turbine support, wherein a first magnet set being located on a lower surface of said vertical turbine rotor, magnets therein having a generally rectangular shape and disposed in a ring along said lower surface of said vertical turbine rotor, and wherein a second magnet set being located on an upper surface of said turbine support, magnets therein having a generally cylindrical shape, each of said generally cylindrically-shaped magnets being disposed in a ring and substantially aligned below at least one of said generally rectangularly-shaped magnets in said first magnet set; rotating, after said lefting, the vertical turbine rotor relative to the turbine support using the wind, the rotation of said vertical turbine rotor generating energy; and converting the energy of the moving vertical turbine rotor into electric power.
19 . The method according to claim 18 , further comprising:
rotating a turbine gear mechanically coupled to the vertical turbine rotor proximate a generator gear mechanically coupled to the generator; and rotating the generator gear.
20 . The method according to claim 19 , wherein rotating the generator gear further comprises:
engaging the generator gear with a magnetic force between the turbine gear and the generator gear.Cited by (0)
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