A Practical Guide to 'Free-Energy' Devices

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permanent dipole rotor magnet having a reference pole facing axially toward the first reciprocating magnet and an opposite pole facing away from the first reciprocating magnet, and a fourth permanent dipole rotor magnet spaced angularly about the axis in an opposite radial direction from the third rotor magnet, the fourth permanent dipole rotor magnet having a reference pole facing axially away from the first reciprocating magnet and an opposite pole facing toward the first reciprocating magnet; and wherein the first reciprocating magnet disposed in said first space is still further located axially between the first and second rotor magnet pairs, and the actuator cyclically moves the first reciprocating magnet toward and away from the first and second pairs of rotor magnets without passing through a centre of rotation of the second pair of rotor magnets. 8. The motor of claim 1 wherein: the first and second rotor magnets are permanent dipole magnets, each rotor magnet having a reference pole facing in a first lateral direction relative to the reference pole of the first reciprocating magnet and an opposite pole facing in a second lateral direction opposite the first lateral direction of the respective rotor magnet. 9. The motor of claim 1 wherein: the first and second rotor magnets are permanent dipole magnets, each rotor magnet having a reference pole facing in a first lateral direction relative to the reference pole of the first reciprocating magnet and an opposite pole facing in a second lateral direction opposite the first lateral direction of the respective rotor magnet; and the motor further comprising: a second pair of rotor magnets supported for rotation on the rotor about the axis, the second pair of rotor magnets being spaced axially from the first pair of rotor magnets, the second pair including a third permanent dipole rotor magnet and a fourth permanent dipole rotor magnet, the third and fourth rotor magnets each having a reference pole facing in the second lateral direction and an opposite pole facing in the first lateral direction, and wherein the first reciprocating magnet disposed in the first space is still further located axially between the first and second rotor magnet pairs, and the actuator cyclically moves the first reciprocating magnet toward and away from the first and second pairs of rotor magnets without passing through a centre of rotation of the second pair of rotor magnets. 10. The motor of claim 3 further comprising: a third pair of rotor magnets supported on the rotor, spaced axially from the first and second pairs of rotor magnets, the third pair including a fifth rotor magnet and a sixth rotor magnet spaced angularly about the axis in an opposite radial direction from the fifth rotor magnet; a second reciprocating magnet located in a second space within the boundary defined by longitudinally extending the outermost circumferential perimeter of the first pair of rotor magnets and axially between the second and third rotor magnet pairs, and the second reciprocating magnet being supported for movement toward and away from the second and third pairs of rotor magnet; a first arm supported for pivotal oscillation substantially parallel to the axis, the first reciprocating magnet being supported on the arm adjacent the first and second pairs of rotor magnets; and a second arm supported for pivotal oscillation substantially parallel to the axis, the second reciprocating magnet being supported on the arm adjacent the second and third pairs of rotor magnets; and wherein the actuator is driveably connected to the first and second arms. 11. A motor comprising: a rotor supported for rotation about an axis; a first pair of rotor magnets supported on the rotor, including a first rotor magnet and a second rotor magnet spaced angularly about the axis from the first rotor magnet such that the first pair of rotor magnets rotate about the axis along a circumferential path having an outermost perimeter; a first arm supported for pivotal oscillation along the axis, located adjacent the first and second rotor magnets; a first reciprocating magnet, supported on the first arm for movement toward and away from the first and second rotor magnets, the first reciprocating magnet being disposed axially within a first space within a boundary defined by longitudinally extending the outermost perimeter of the first circumferential path of the first pair of rotor magnets; a second pair of rotor magnets supported on the rotor, spaced axially from the first pair of rotor magnets, the second pair including a third rotor magnet, and a fourth rotor magnet spaced angularly about the axis from the third rotor magnet; a third pair of rotor magnets supported on the rotor, spaced axially from the first and second pairs of rotor magnets, the third pair including a fifth rotor magnet, and a sixth rotor magnet spaced angularly about the axis from the fifth rotor magnet; a second arm supported for pivotal oscillation along the axis between the second and third pairs of rotor magnets; a second reciprocating magnet located axially between the second and third rotor magnet pairs and supported on the second arm for movement toward and away from the second and third pairs of rotor magnet; and an actuator for moving the first reciprocating magnet cyclically toward and away from the first pair of rotor magnets without passing through a centre of rotation of the first pair of rotor magnets so as to simultaneously create repulsion and attraction forces with the first pair of rotor magnets to cyclically rotate the first pair of rotor magnets relative to the first reciprocating magnet in one rotational direction; and wherein the first reciprocating magnet disposed in the first space is still further located axially between the first and second rotor magnet pairs, and the actuator cyclically moves the first arm and first reciprocating magnet toward and away from the first and second pairs of rotor magnets without passing the first reciprocator magnet through a centre of rotation of the second pair of rotor magnets, and moves the second arm and second reciprocating magnet toward and away from the second and third pairs of rotor magnets without passing the second reciprocator magnet through the centre of rotation of the second pair of rotor magnets and through a centre of rotation of the third pair of rotor magnets. A - 990
12. The motor of claim 11 wherein the actuator further comprises: a rotor shaft driveably connected to the rotor for rotation therewith; first and second bridge plates, mutually angularly aligned about the axis, extending over a first angular range about the axis; third and fourth bridge plates, offset axially from the first and second bridge plates, mutually angularly aligned about the axis, extending over a second angular range about the axis; an electric power supply including first and second terminals; a first contact connecting the first power supply terminal alternately to the first bridge plate and the third bridge plate as the rotor rotates; a second contact connecting the second power supply terminal alternately to the second bridge plate and the fourth bridge plate as the rotor rotates; a toroidal permanent magnet; a solenoid supported above a pole of the toroidal permanent magnet, including first and second terminals; a third contact connecting the first solenoid terminal alternately to the first and second power supply terminals through the first and fourth bridge plates and first contact as the rotor rotates; a fourth contact alternately connecting and disconnecting the second power supply terminal and the second solenoid terminal as the rotor rotates; and a fifth contact alternately connecting and disconnecting the first power supply terminal and the second solenoid terminal as the rotor rotates. 13. The motor of claim 11 wherein the actuator further comprises: a toroidal permanent magnet; an A.C. power source; and a solenoid supported for displacement adjacent a pole of the toroidal permanent magnet, including first and second terminals electrically connected to the power source. 14. A motor comprising: a rotor supported for rotation about an axis; a first rotor magnet supported for rotation about the axis along a first circumferential path having an outermost perimeter and a centre at the axis, the first rotor magnet having a first permanent reference pole facing laterally toward the axis and a first permanent opposite pole facing in an opposite lateral direction toward the first reference pole; a pair of reciprocating magnets supported for movement toward and away from the rotor magnet, including a first reciprocating magnet and a second reciprocating magnet spaced axially from the first rotor magnet, each reciprocating magnet being at least partially disposed within a first axial space having a boundary defined by longitudinally extending the outermost perimeter of the first circumferential path of the first rotor magnet, wherein the rotor magnet is located axially between the first and second reciprocating magnets; and an actuator for moving the pair of reciprocating magnets cyclically toward and away from the rotor magnet without passing through the centre of the first circumferential path so as to simultaneously create repulsion and attraction forces with the first rotor magnet to cyclically rotate the rotor magnet relative to the pair of reciprocating magnets in one rotational direction. 15. The motor of claim 14 wherein the first and second reciprocating magnets are permanent dipole magnets with each having a reference pole facing laterally from the axis and an opposite pole facing in an opposite lateral direction from its corresponding reference pole. 16. The motor of claim 15 further comprising: a second rotor magnet spaced axially from the first rotor magnet, the second rotor magnet being supported for rotation about the axis along a second circumferential path having an outermost perimeter about the centre, the second rotor magnet including a second permanent reference pole facing laterally toward the axis and a second permanent opposite pole facing in an opposite lateral direction toward the second reference pole; and wherein the second reciprocating magnet is located axially between the first and second rotor magnets and at least partially within a second axial space having a boundary defined by longitudinally extending the outermost perimeter of the second circumferential path of the second rotor magnet, and the actuator cyclically moves the second reciprocating magnet away from and towards the second rotor magnet. A - 991
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JUAN AGUERO Patent Application EP04
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the exhaust manifold. This heats so
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combustion chambers. The hydrogen i
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21. The system of claim 20, charact
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electrolysis of water at such a rat
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Fig.4 is an elevation view of the h
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Fig.10 is a cross-section on the li
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Fig.16 is a cross-section on the li
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Fig.23 is an enlargement of part of
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Fig.33 is a perspective view of a v
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A - 843
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through a resistor R4 to provide tr
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The installation of the above circu
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cathode in the upper region of the
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transformer and, assuming an input
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valve apparatus to control engine s
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. a first hollow cylindrical electr
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CHRISTOPHER ECCLES UK Patent App. 2
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Fig.1 is a circuit diagram of fract
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If a large electric field is applie
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The pulses R1 and S1 are of the sam
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DISCLOSURE OF THE INVENTION The inv
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A - 867
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Fig.5B shows a stylised representat
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Fig.6 shows a gas collection system
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Fig.8A and Fig.8B are views of a se
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A - 875
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Figs.16-30 are graphs supporting th
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A - 887
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If it is the case that the hydrogen
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plate shown in Fig.1A and Fig.1B an
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is in equilibrium where the 10 watt
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The previously mentioned prior art
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The stores of high pressure gases c
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unit to retain operational gas pres
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HENRY PAINE This is a very interest
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Henry Paine’s apparatus would the
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some form of distortion of space. I
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superconductive disk is made part o
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Fig.2A and Fig.2B are diagrams, pre
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Fig.4A and Fig.4B are diagrams, pre
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#1 hollow superconductive shield #2
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Fig.2B shows the counter-clockwise
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In this example, the difference bet
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CHARLES POGUE US Patent 642,434 12t
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Fig.3 is a horizontal sectional vie
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Fig.9 and Fig.10 are detail section
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having a valve 52 in it. Chamber 50
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CHARLES POGUE US Patent 1,997,497 9
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Fig.4 is a detail sectional view of
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A low-speed or idling jet 25 has it
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DESCRIPTION OF THE DRAWINGS Fig.1 i
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Fig.5 is a detail sectional view on
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Vapour formed by air bubbling throu
Page 117 and 118: From the foregoing description it w
Page 119 and 120: Fig.2 is an enlarged view of the de
Page 121 and 122: Fig.6 is a section taken along line
Page 123 and 124: ROBERT SHELTON US Patent 2,982,528
Page 125 and 126: Fig.4 is a transverse sectional vie
Page 127 and 128: HAROLD SCHWARTZ US Patent 3,294,381
Page 129 and 130: 182,420 now abandoned. The present
Page 131 and 132: DESCRIPTION OF THE INVENTION The ca
Page 133 and 134: THOMAS OGLE US Patent 4,177,779 11t
Page 135 and 136: In accordance with other aspects of
Page 137 and 138: Fig.3 is a sectional view of the va
Page 139 and 140: Fig.7 is a partial side, partial se
Page 141 and 142: The cooling system of the vehicle c
Page 143 and 144: Upon initial starting of the engine
Page 145 and 146: (f) A filter positioned in the vapo
Page 147 and 148: with the magnitude of the current a
Page 149 and 150: Fig.1B is a perspective view of the
Page 151 and 152: Fig.3 is a top view of the motor of
Page 153 and 154: Fig.7 is an isometric view showing
Page 155 and 156: Fig.10 is a top view showing the ro
Page 157 and 158: Fig.13 is a top view of a pair of r
Page 159 and 160: Extending in opposite diametric dir
Page 161 and 162: Fig.5 shows the state of the switch
Page 163 and 164: otor magnets 42 - 49 when in the ho
Page 165 and 166: Fig.9 and Fig.10 show a second arra
Page 167: constructed otherwise than as speci
Page 171 and 172: timer or a control mechanism mounte
Page 173 and 174: Fig.4 is a view similar to Fig.3 bu
Page 175 and 176: Fig.10 is a view similar to Fig.3 f
Page 177 and 178: Fig.13 is a schematic circuit diagr
Page 179 and 180: Fig.16 is a simplified embodiment o
Page 181 and 182: Fig.22 to Fig.25 are similar to Fig
Page 183 and 184: Referring to Fig.2, the permanent m
Page 185 and 186: Fig.7 shows a modified embodiment w
Page 187 and 188: them, will depend upon the order in
Page 189 and 190: Fig.14, shows another embodiment 14
Page 191 and 192: Fig.18 shows the air coil 210 posit
Page 193 and 194: Figs. 22-25 show four different pos
Page 195 and 196: movement with the first permanent m
Page 197 and 198: a shaft and means journaling the sh
Page 199 and 200: CLAUDE MEAD and WILLIAM HOLMES US P
Page 201 and 202: Fig.2 is a front elevation of the w
Page 203 and 204: impactors and drills. The turbine d
Page 205 and 206: (a) fourth rotating means responsiv
Page 207 and 208: path to the other side of the perma
Page 209 and 210: Fig.3 is an oscilloscope waveform t
Page 211 and 212: DETAILED DESCRIPTION OF THE PREFERR
Page 213 and 214: although it is by no means obvious
Page 215 and 216: second diode connected at its posit
Page 217 and 218: In the present invention, a permane
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Fig.4 is a circuit diagram, illustr
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and Fig.3. In practice, this coil m
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y a simultaneous magnetic accelerat
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Mr. P.G. Mallory started out in 191
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All models have a 30 Watt power rat
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In the auto racing circles it has a
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BATTERY + _ SIMPLIFIED MULTIVIBRATO
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Schematic Wiring Diagrams for two P
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motor. What is not generally known,
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Mark McKay's investigation of Edwin
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Investor Photo #012D Popping a coil
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capacitors connected in series, wit
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PULSE WIDTH TIME IN mS went to the
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TOP DEAD CENTER 0° REFERENCE Accor
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The recovery and simple analysis of
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FILTER CAPACITOR + 2 OHM 200 WATT R
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Subject: CSET design Date: Sun Feb
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Date: Fri Feb 28, 2003 8:25 pm (Tim
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(Tad Johnson) I'm being as careful
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SANGAMO ENERGY DISCHARGE CAPACITOR
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(Alan Francoeur) But I also measure
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Subject: Progress Date: Sun Mar 30,
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● all electrical connections were
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Mark Gray claims that the heart and
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Mark Gray claims that some potentia
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Radio Frequency (RF) Generator Gene
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Some time during 1987 - 1988, Gray
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The two-channel trace from the osci
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What “maximum squareness” means
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Zo = 112 Ohms Td of 293 nS. 50 KV 8
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MIKE BRADY’S “PERENDEV” MAGNE
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Fig.3 is a perspective view showing
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Fig.7 is a perspective view showing
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In the rotor assembly 30 of Fig.2,
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Fig.7 shows a typical magnetic sour
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DONALD A. KELLY ABSTRACT Patent US
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This series of magnetic oscillating
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Because there is no natural, lock-i
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Fig.3 is an enlarged top view of on
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An arm 9, is fastened to a flat fac
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Fig.2 is a vertical transverse cros
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Fig.6 is a vertical, longitudinal,
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Working inside the cylinders 12 are
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Leroy K. Rogers Patent US 4,292,804
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Preferred embodiments of a method a
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Fig.6 is a cross-sectional view of
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tapped hole in the cylinder 20 typi
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A second embodiment of a valve actu
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otates faster, the other end 98 of
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In normal operation (as seen in Fig
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Eber Van Valkinburg Patent US 3,744
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Referring to the drawings in detail
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Since the pump depends for its supp
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Briefly, in one aspect the engine o
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Fig.12 is a cross-sectional view si
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Fig.14 is a schematic diagram of an
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A - 1163
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A - 1165
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Figs.20A-20F are schematic diagrams
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Note: Corresponding reference chara
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Integral with the piston bodies are
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The piston has a generally semi-tor
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Referring back to Fig.13A, for engi
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As piston 39A reaches BDC, distribu
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mixture and do not combine because
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These wires are about twelve gauge,
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cold-cathode tube 391, and an x-ray
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Fig.17D), polariser 289, branch B17
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Robert Britt US Patent 3,977,191 31
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Fig.3 is an elevational view of the
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Fig.7 is an electrical schematic of
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Referring now to Fig.3 of the drawi
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and drives Q1 into conduction. The
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Floyd Sweet Recently, some addition
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The day when we witnessed the VTA d
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up to see Floyd. Floyd was with the
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Energy cannot enter a space of zero
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electromagnetic and gravitational f
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or in another form: So, the e.m.f.
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Example 2: Suppose the conductor wi
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Meguer Kalfaian There is a patent a
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Fig.2 illustrates a controlled top
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Fig.9 is a modification of Fig.6; a
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the outer periphery of the magnet,
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wobbling top is sufficient, as proo
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Theodore Annis & Patrick Eberly US
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BRIEF DESCRIPTION OF THE DRAWINGS F
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Fig.6 is a schematic diagram of a s
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DETAILED DESCRIPTION OF THE PREFERR
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Fig.5 is a detail drawing of an alt
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In the preferred implementation of
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William McDavid junior US Patent 6,
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This sloping floor causes the drive
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FIG.3 is a side elevational view of
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FIG.9 is a horizontal cross-section
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otational downstream annular chambe
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In Fig.5 is shown a perspective vie
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small hydro-electric version of the
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Fig.10 is a perspective view of a s
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longitudinally mounted in the upstr
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shaft in the central aperture, said
Page 431 and 432:
Scientific Papers The following lin
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http://www.free-energy-info.co.uk/M
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A Practical Guide to 'Free-Energy' Devices

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