A Practical Guide to 'Free-Energy' Devices
A Practical Guide to 'Free-Energy' Devices
A Practical Guide to 'Free-Energy' Devices
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constructed otherwise than as specifically illustrated and described without departing from its spirit or scope. It is<br />
intended that all such modifications and alterations be included insofar as they come within the scope of the<br />
appended claims or the equivalents thereof.<br />
CLAIMS<br />
1. A mo<strong>to</strong>r comprising: a ro<strong>to</strong>r supported for rotation about an axis; a first pair of ro<strong>to</strong>r magnets supported on the<br />
ro<strong>to</strong>r, including a first ro<strong>to</strong>r magnet and a second ro<strong>to</strong>r magnet spaced angularly about the axis in an opposite<br />
radial direction from the first ro<strong>to</strong>r magnet such that the first pair of ro<strong>to</strong>r magnets rotate about the axis along a<br />
path having an outermost circumferential perimeter; a first reciprocating magnet supported for movement<br />
<strong>to</strong>ward and away from the first and second ro<strong>to</strong>r magnets, the first reciprocating magnet being axially disposed<br />
in a first space within a boundary defined by longitudinally extending the outermost circumferential perimeter of<br />
the first pair of ro<strong>to</strong>r magnets, and the first reciprocating magnet is a permanent dipole magnet having a<br />
reference pole facing laterally from the axis and an opposite pole facing in an opposite lateral direction from<br />
the reference pole; and an actua<strong>to</strong>r for moving the first reciprocating magnet cyclically <strong>to</strong>ward and away from<br />
the first pair of ro<strong>to</strong>r magnets without passing through a centre of rotation of the first pair of ro<strong>to</strong>r magnets so<br />
as <strong>to</strong> simultaneously create repulsion and attraction forces with the first pair of ro<strong>to</strong>r magnets <strong>to</strong> cyclically<br />
rotate the first pair of ro<strong>to</strong>r magnets relative <strong>to</strong> the first reciprocating magnet in one rotational direction.<br />
2. The mo<strong>to</strong>r of claim 1 further comprising: a second reciprocating magnet axially disposed in a second space<br />
within the boundary defined by longitudinally extending the outermost circumferential perimeter of the first pair<br />
of ro<strong>to</strong>r magnets at an axial opposite side of the first pair of ro<strong>to</strong>r magnets, and supported for movement<br />
<strong>to</strong>ward and away from the first and second ro<strong>to</strong>r magnets without passing through the centre of rotation of the<br />
first pair of ro<strong>to</strong>r magnets.<br />
3. The mo<strong>to</strong>r of claim 1 further comprising: a second pair of ro<strong>to</strong>r magnets supported on the ro<strong>to</strong>r, spaced axially<br />
from the first pair of ro<strong>to</strong>r magnets, the second pair including a third ro<strong>to</strong>r magnet and a fourth ro<strong>to</strong>r magnet<br />
spaced angularly about the axis in an opposite radial direction from the third ro<strong>to</strong>r magnet; and wherein the first<br />
reciprocating magnet is located in said first space disposed axially between the first and second ro<strong>to</strong>r magnet<br />
pairs, and the actua<strong>to</strong>r cyclically moves the first reciprocating magnet <strong>to</strong>ward and away from the first and<br />
second pairs of ro<strong>to</strong>r magnets without passing through a centre of rotation of the second pair of ro<strong>to</strong>r magnets.<br />
4. The mo<strong>to</strong>r of claim 1 further comprising: a second pair of ro<strong>to</strong>r magnets supported on the ro<strong>to</strong>r, spaced axially<br />
from the first pair of ro<strong>to</strong>r magnets, the second pair including a third ro<strong>to</strong>r magnet and a fourth ro<strong>to</strong>r magnet<br />
spaced angularly about the axis in an opposite radial direction from the third ro<strong>to</strong>r magnet; a third pair of ro<strong>to</strong>r<br />
magnets supported on the ro<strong>to</strong>r, spaced axially from the first and second pairs of ro<strong>to</strong>r magnets, the third pair<br />
including a fifth ro<strong>to</strong>r magnet and a sixth ro<strong>to</strong>r magnet spaced angularly about the axis in an opposite radial<br />
direction from the fifth ro<strong>to</strong>r magnet; and a second reciprocating magnet disposed in a second space located<br />
axially between the second and third ro<strong>to</strong>r magnet pairs and within the boundary defined by longitudinally<br />
extending the outermost circumferential perimeter of the first pair of ro<strong>to</strong>r magnets, and the second<br />
reciprocating magnet being supported for movement <strong>to</strong>ward and away from the second and third pairs of ro<strong>to</strong>r<br />
magnet; and wherein the first reciprocating magnet disposed in the first space is still further located axially<br />
between the first and second ro<strong>to</strong>r magnet pairs, and the actua<strong>to</strong>r cyclically moves the first reciprocating<br />
magnet <strong>to</strong>ward and away from the first and second pairs of ro<strong>to</strong>r magnets without passing through a centre of<br />
rotation of the second pair of ro<strong>to</strong>r magnets, and the second reciprocating magnet <strong>to</strong>ward and away from the<br />
second and third pairs of ro<strong>to</strong>r magnets without passing through the centre of rotation of the second pair of<br />
ro<strong>to</strong>r magnets and through a centre of rotation of a third pair of ro<strong>to</strong>r magnets.<br />
5. The mo<strong>to</strong>r of claim 1 further comprising: an arm supported for pivotal oscillation substantially parallel <strong>to</strong> the<br />
axis, the first reciprocating magnet being supported on the arm adjacent the first and second ro<strong>to</strong>r magnets;<br />
and wherein the actua<strong>to</strong>r is driveably connected <strong>to</strong> the arm.<br />
6. The mo<strong>to</strong>r of claim 1 wherein: the first and second ro<strong>to</strong>r magnets are permanent dipole magnets, the first ro<strong>to</strong>r<br />
magnet having a reference pole facing axially away from the first reciprocating magnet and an opposite pole<br />
facing axially <strong>to</strong>ward the first reciprocating magnet, the second ro<strong>to</strong>r magnet having a reference pole facing<br />
axially <strong>to</strong>ward the first reciprocating magnet and an opposite pole facing axially away from the first<br />
reciprocating magnet.<br />
7. The mo<strong>to</strong>r of claim 1 wherein: the first and second ro<strong>to</strong>r magnets are magnet is a permanent dipole magnets<br />
magnet, the first ro<strong>to</strong>r magnet having a reference pole facing axially away from the first reciprocating magnet<br />
and an opposite pole facing axially <strong>to</strong>ward the first reciprocating magnet, the second ro<strong>to</strong>r magnet having a<br />
reference pole facing axially <strong>to</strong>ward the first reciprocating magnet and an opposite pole facing axially away<br />
from the first reciprocating magnet; and the mo<strong>to</strong>r further comprising: a second pair of ro<strong>to</strong>r magnets<br />
supported on the ro<strong>to</strong>r, spaced axially from the first pair of ro<strong>to</strong>r magnets, the second pair including a third<br />
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