A permanent magnet motor is provided with a housing, a rotating shaft supported within the housing, and magnetic coils arranged within the housing. A hydrostatic bearing is disposed on the rotating shaft, the hydrostatic bearing having a permanent magnet incorporated therewith that restricts movement of the rotating shaft in a radial direction.
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0. 17. A permanent magnet motor or generator comprising:
a housing;
a rotating shaft supported within the housing; and
a hydrostatic bearing disposed on the rotating shaft and within the housing, the hydrostatic bearing comprising a first face that is a porous permanent magnet and a second face,
wherein the hydrostatic bearing is configured to distribute a pressurized fluid across a back surface of the porous permanent magnet,
the porous permanent magnet is configured to issue the pressurized fluid through the back surface to the first face, and the first face and the second face arranged such that movement of the rotating shaft is restricted in an axial direction, whereby the first face and the second face are configured to generate electricity or create force.
1. A permanent magnet motor/generator comprising:
a housing;
a rotating shaft supported within the housing; and
a hydrostatic bearing disposed on the rotating shaft and within the housing, the hydrostatic bearing comprising a first face that is a porous permanent magnet and a second face that is coils,
wherein the hydrostatic bearing is configured to distribute a pressurized fluid across a back surface of the porous permanent magnet,
the porous permanent magnet is configured to issue the pressurized fluid through the back surface to the first face, and
the first face and the second face arranged such that movement of the rotating shaft is restricted in a radial direction, whereby the permanent magnet and the coils are configured to generate electricity or create force.
8. A method for making a permanent magnet motor or generator, the method comprising:
providing a housing with a rotating shaft supported therein; and
disposing a hydrostatic bearing on the rotating shaft and within the housing, the hydrostatic bearing comprising a first face that is a porous permanent magnet and a second face that is coils,
wherein the hydrostatic bearing is configured to distribute a pressurized fluid across a back surface of the porous permanent magnet,
the porous permanent magnet is configured to issue the pressurized fluid through the back surface to the first face, and
the first face and the second face arranged such that movement of the rotating shaft is restricted in a radial direction, whereby the porous permanent magnet and the coils are configured to generate electricity or create force.
0. 22. A hydrostatic bearing comprising:
a housing;
a rotating shaft supported within the housing; and
a hydrostatic bearing disposed on the rotating shaft and within the housing, the hydrostatic bearing comprising a first face and a second face,
wherein the hydrostatic bearing is configured to distribute a pressurized fluid across a back surface of the porous permanent magnet,
the first face is a porous permanent magnet configured to issue the pressurized fluid through the back surface to the first face,
the first face and the second face arranged such that movement of the rotating shaft is restricted in either a radial or axial direction, and
the first face and the second face are separated by a hydrostatic gap created by the pressurized fluid that issues from the first face, wherein the pressurized fluid removes heat the first face and the second face.
0. 2. The permanent magnet motor of
3. The permanent magnet motor of claim 2 1, wherein the first face and second face are separated by a hydrostatic gap.
4. The permanent magnet motor of
5. The permanent magnet motor of
6. The permanent magnet motor of
7. The permanent magnet motor of
9. The method of
10. The method of
11. The method of
0. 12. A permanent magnet motor or generator comprising:
a permanent magnet used as a restrictive element of a hydrostatic bearing;
coils, wherein the hydrostatic bearing works directly between the permanent magnet and the coils and the permanent magnet and coils are configured to generate electricity or create force.
0. 13. A permanent magnet motor or generator according to
0. 14. A permanent magnet motor or generator according to
0. 15. A permanent magnet motor or generator according to
0. 16. A permanent magnet motor or generator according to
0. 18. The permanent magnet motor or generator of claim 17, wherein the first face and second face are separated by a hydrostatic gap.
0. 19. The permanent magnet motor or generator of claim 18, wherein the hydrostatic gap has a thickness of a pressurized film created by the pressurized fluid.
0. 20. The permanent magnet motor or generator of claim 19, wherein the pressurized fluid removes heat from bearing surfaces of the hydrostatic bearing and from the hydrostatic gap.
0. 21. The permanent magnet motor or generator of claim 17, wherein the second face is coils.
0. 23. The hydrostatic bearing of claim 22 wherein the second face is coils.
0. 24. The hydrostatic bearing of claim 23 wherein the first face and the second face arranged such that movement of the rotating shaft is restricted in a radial direction, whereby the permanent magnet and the coils are configured to generate electricity or create force.
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This application claims the benefit of U.S. Provisional Patent Application No. 61/149,794, filed Feb. 4, 2009, which is incorporated by reference as if fully set forth.
This application is generally related to motors or generators having magnetic elements, and more particularly related to hydrostatic bearings constructed with a permanent magnet that can be used as the permanent magnetic element of motors or generators.
Some motors are designed to use coils in order to generate a magnetic field. These motors include two sets of coils, one located in the stator and one located in the rotor. One set of coils is energized using conductive contacts or brushes that may touch on the shaft or the moving body. The current fed to these coils creates an electromagnetic field. Other motors and generators employ permanent magnets to provide motion. Electricity is produced when coils of copper windings are moved relative to the flux fields generated by the magnets. Alternatively, electricity may be fed into the coils to produce motion. In both of these scenarios, separate bearings are used to define the relative motion between the coils and magnets, which may be linear or rotary in nature. In either case, the flux field creates an attractive force that must be resisted by the bearings. This force is mitigated in some degree when there is an opposing force applied at 180° from other magnets. Although the opposing force mitigates the flux field's attractive force, it is not a stabilizing force. For example, as the coils get closer to the magnets on one side, the attractive force from those magnets increase, which moves the coils further away from the magnets that are arranged at 180° and decreases the applied opposing force. In the absence of separate bearings, the coils and magnets would come into contact and disable the motor or generator's function.
Permanent magnet motors employ magnets made of, for example and without limitation, neodymium NdFeB or ferrite. There are multiple methods for manufacturing these magnets, such as through casting in a mold, pressing, injection molding, or bonding. In most cases, these magnets are porous, which is especially true for magnets that are sintered. These magnets may be magnetized after they have been formed into their desired shape. Motors and generators may employ a wide variety of magnetic circuit designs. Permanent magnets may be used on the outside diameter of a rotating body or on the interior of a housing. They may use switched reluctance or induction and may use AC or DC current.
Motors and generators' efficiency and power can be increased by minimizing the distance between the coils in the magnets. As the distance between the coils decreases, the flux field force increases. However, due to the unstable relationship between the coils and magnets as described above, relatively large gaps between coils must be used in the manufacture of motors and generators. Such an arrangement is shown by U.S. Pat. No. 5,036,235 to Klecker.
Design engineers have been trying to achieve more functionality in less space. The paradigm today in the design of motors and generators is to have separate bearings and motor functions. This results in assemblies that are longer, larger in diameter, and heavier than if the motor and bearing elements can be one in the same. For example, see the assembly shown by U.S. Pat. No. 5,443,413 to Pflager et al.
In U.S. Pat. No. 5,098,203 to Henderson, magnets are inserted into the face of a hydrostatic bearing assembly in order to increase the stiffness of the hydrostatic film with the magnets' preload force. However, there is no disclosure of using such magnets in a motor or generator.
One of ordinary skill in the art of hydrostatic bearings would appreciate that air and other gases are examples of a fluid used in hydrostatic bearings. This means that the broad term of hydrostatic bearings encompasses aerostatic bearings, as discussed in U.S. Pat. No. 5,488,771 to Devitt et al. The terms “hydrostatic bearings” and “hydrodynamic bearings” are both encompassed in the definition of “fluid film bearings.” Hydrostatic bearings are differentiated from hydrodynamic bearings by the use of an external pressure source, which allows hydrostatic bearings to operate even with zero velocity between the relative bearing faces. In contrast, hydrodynamic bearings require relative motion between bearing faces to create fluid film pressure. One of ordinarily skill in the art would also appreciate that hydrostatic bearings exhibit hydrodynamic effects when there is relative motion between the bearing faces. These hydrodynamic effects are an unavoidable result of the shear of the hydrostatic fluid caused by the relative motion of the bearing surfaces, and are included in the operation of hydrostatic bearings.
Accordingly, it is an object of the present application to combine the bearing and motor functionalities, provide economy of space, and improve efficiency by reducing the gap in the flux field to the thickness of the hydrostatic bearing fluid.
A permanent magnet motor is disclosed, the permanent magnet motor having a housing, a rotating shaft supported within the housing, and magnetic coils arranged within the housing. A hydrostatic bearing is disposed on the rotating shaft, the hydrostatic bearing having a permanent magnet incorporated therewith that restricts movement of the rotating shaft in a radial direction.
A method for making a permanent magnet motor is also disclosed. The method includes the steps of providing a housing with a rotating shaft supported therein, arranging magnetic coils within the housing, and disposing a hydrostatic bearing on the rotating shaft. The hydrostatic bearing has a permanent magnet incorporated therewith that restricts movement of the rotating shaft in a radial direction. For sake of brevity, this summary does not list all aspects of the present device, which is described in further detail below.
Certain terminology is used in the following description for convenience only and is not limiting. The words “inner,” “outer,” “top,” and “bottom” designate directions in the drawings to which reference is made. The terminology includes the words specifically noted above, derivatives thereof, and words of similar import.
The prior art motor's motor elements are completely separate from the permanent magnets. Coils 101 are wrapped by 360° around the inner diameter of the housing or stator 105. Magnets 102 are disposed around the outer diameter of the rotatable shaft 100, leaving an air gap 104 between the magnets 102 and coils 101. The air gap 104 must be large enough to accommodate error motions in the bearings 103, out of balance centrifugal forces, and centrifugal force growth of the magnets 102 and rotor.
The embodiment of the hydrostatic bearing shown in
While various methods, configurations, and features of the present invention have been described above and shown in the drawings, one of ordinary skill in the art will appreciate from this disclosure that any combination of the above features can be used without departing from the scope of the present invention. It is also recognized by those skilled in the art that changes may be made to the above described methods and embodiments without departing from the broad inventive concept thereof. For example, the coils 301 shown in
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