초록 ▼

In accordance with an embodiment of the present invention, a permanent magnet, includes a body that has a body axis and that, in turn, has a plurality of discreet components. Each of the components may be radially spaced from the body axis approximately an equal distance and each component may be ci

In accordance with an embodiment of the present invention, a permanent magnet, includes a body that has a body axis and that, in turn, has a plurality of discreet components. Each of the components may be radially spaced from the body axis approximately an equal distance and each component may be circumferentially spaced an approximately equal distance apart. Also, each of the components may include a cavity and a component axis and wherein each of the components may have an inner body, that, in turn, has a magnetic substance and that is rotatable about the component axis and a plurality of inner segments each having an inner segment magnetic field. The components may also include an outer body that, in turn, includes a magnetic substance and that is rotatable about the component axis. The outer body may also have a plurality of outer segments each having an outer segment magnetic field and the outer body being located in proximity to the inner body whereby each of the inner segment magnetic fields and the outer segment magnetic fields interact.

대표청구항 ▼

The invention claimed is: 1. A permanent magnet, comprising: a body having a body axis and comprising a plurality of discreet components, each component being in the shape of a disk and having a generally rectangular shape in cross section and each component being radially spaced from the body axis

The invention claimed is: 1. A permanent magnet, comprising: a body having a body axis and comprising a plurality of discreet components, each component being in the shape of a disk and having a generally rectangular shape in cross section and each component being radially spaced from the body axis and also being disposed approximately an equal distance from the body axis and, further, each component being circumferentially spaced an approximately equal distance such that between at least a portion of each component is a space that is generally trapezoidal in cross section, and wherein each of the components comprise a cavity and a component axis, and wherein each of the components further comprise: an inner ring comprising a magnetic substance and being rotatable about the component axis, the inner ring comprising a plurality of inner segments each having an inner segment magnetic field; and an outer ring also comprising a magnetic substance and being rotatable about the component axis, the outer ring comprising a plurality of outer segments each having an outer segment magnetic field and the outer ring being located in proximity to the inner ring whereby each of the inner segment magnetic fields and the outer segment magnetic fields interact; wherein each of the components are interconnected together via a moldable plastic substance. 2. The permanent magnet of claim 1, wherein each inner segment has a direction of magnetization that varies such that an angle of magnetization γ is twice a local coordinate θ or γ =2θ. 3. The permanent magnet of claim 2, wherein each outer segment has a direction of magnetization that varies such that an angle of magnetization γ is twice a local coordinate θ or γ =2θ. 4. The permanent magnet of claim 1, wherein the body comprises a generally toroidal outer configuration. 5. The permanent magnet of claim 1, wherein an outer radius of the inner ring is substantially equal to an inner radius of the outer ring. 6. The permanent magnet of claim 1, wherein a boundary radius (r) defining a boundary between the inner ring and the outer ring is given by r=(RORI)1/2 , wherein RO=an outer radius of the inner ring and RI =an inner radius of the outer ring. 7. A method of assembling a toroidal magnet, comprising: forming a plurality of discreet components, each being in the shape of a disk and having a generally rectangular shape in cross section, by: providing an inner ring comprising a magnetic substance and being rotatable about an inner ring central axis, the inner ring comprising a plurality of inner segments each having an inner segment magnetic field; providing an outer ring also comprising a magnetic substance and being rotatable about an outer ring central axis, the outer ring comprising a plurality of outer segments each having an outer segment magnetic field and the outer ring being located in proximity to the inner ring whereby each of the inner segment magnetic fields and the outer segment magnetic fields interact; arranging the plurality of discreet components into a toroidal body that has a body central axis wherein each of the discreet components are radially spaced from the body axis and wherein each are circumferentially spaced an approximately equal distance such that between at least a portion of each component is a space that is generally trapezoidal in cross section, and further wherein each of the components comprise a cavity and a component axis; and fixing the toroidal body via interconnecting the discreet components together with a moldable plastic substance. 8. The method of claim 7, wherein each inner segment has a direction of magnetization that varies such that an angle of magnetization γ is twice a local coordinate θ or γ =2θ. 9. The method of claim 8, wherein each outer segment has a direction of magnetization that varies such that an angle of magnetization γ is twice a local coordinate θ or γ =2θ. 10. The method of claim 7, wherein an outer radius of the inner ring is substantially equal to an inner radius of the outer ring. 11. The method of claim 7, wherein a boundary radius (r) defining a boundary between the inner ring and the outer ring is given by r=(RORI)1/2, wherein RO=an outer radius of the inner ring and RI=an inner radius of the outer ring.