A Practical Guide to 'Free-Energy' Devices

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no motional e.m.f. Thus, dφ/dt in equation (11) is zero, even though the flux is changing with time. Note that dφ/dt was defined as representing the right hand part of the expression in equation (10) and dφ/dt must not be interpreted more broadly than that. In the application of the present equations, it is required that all flux densities and movements are referred to a single, specified co-ordinate system. In particular, the velocities will all be with respect to this system alone and not interpreted as relative velocities between conductors or moving lines of flux. The co-ordinate system is selected arbitrarily and the magnitudes of variational and motional fields depend upon the selection. Example 1: A fundamental electric generator is shown in Figure 2: The parallel, stationary conductors, separated by distance "l", have a stationary voltmeter connected across them. The circuit is completed by a moving conductor connected to the parallel conductors by means of two sliding contacts. This conductor is connected at y = 0 at time t = 0, and it moves to the right at a constant velocity V = Vay. The applied flux B is represented by dots on Fig.2 and has a magnitude of B = BO CosBy Coswt ax. The unit vectors in the direction of the co-ordinate axes are ax, ay and az respectively. Solution: Let S denote the plane rectangular surface bounded by the closed electric circuit, with a positive side selected as the side facing you. The counter-clockwise e.m.f. around the circuit is dφ/dt with φ signifying the magnetic flux out of the positive side of S (As ds = 1 dy ax). The scalar product B x ds is BO l CosBy, Coswt dy; integrating from y = 0 to y = y gives: With y1 denoting the instantaneous y position of the moving wire. The counter-clockwise e.m.f. is found by replacing y with vt and evaluating dφ/dt. The result is: The variational (transformer) component is determined with the aid of equation (12) and is wBBOl/BsinBy sinwt where y = vt. This is the first component on the right hand side of equation (13). Note: y1 was treated as a constant when evaluating the partial time derivative of φ. The motional E-field is the line integral of V x B along the path of the moving conductor. As V x B is -BO vcosBy1 coswt ax and As dl is dz ax, evaluation of the integral -BO vcosBy1 coswt dz from Z = 0 to Z = 1 results in a motional E-field of -BO lvcosBv1 coswt. This component results from modulation of the lines of flux by the moving conductor. If the voltmeter draws no current, there can be no electromagnetic force on the free electrons of the wire. Therefore, the e.m.f. along the path of the metal conductors including the moving conductor, is zero. A - 1208
Example 2: Suppose the conductor with the sliding taps is stationary (V = 0) and it is located at y = y1. Also, suppose that the magnetic field B is produced by a system of moving conductors which are not shown in Fig.2 and those conductors are travelling with a constant velocity V = Vay. At time t = 0, the magnetic field B is BO sinBy ax. Determine the voltage across the voltmeter. Solution: There is no motional E-field because the conductors in Fig.2 are at rest (stationary) with respect to our selected co-ordinate system. However, the magnetic field at points fixed with respect to the co-ordinate system is changing with time and as a result, there is a variational e.m.f. Since the B-field at time t = 0 is BO sinBy ax and has a velocity of V = Vay, it can be calculated that the B-field as a function of time is BOsin[B(y-vt)] ax. This is verified by noting that an observer located at time t = 0 who is travelling at the constant velocity (V = Vay) of the moving current, would have a y co-ordinate of y = y + Vt and an accordingly different expression for B. He would observe a constant field where the magnetic current density is: The counter-clockwise e.m.f. can be arrived at by taking the negative of an integral of the above expression for the rectangular surface bounded by the electric circuit with the positive side facing you, with the limits of zero and y. The resulting e.m.f. equals: which is the voltage across the meter. Induced Motional Field - Negative Energy: Conventional theory says that electric fields and magnetic fields are different things. Consider for a moment, a charge with an electric field around it. If the charge is moved, then a magnetic field develops and the moving charge constitutes a current. If an observer were to move along with the charge, then he would see no relative motion, no current and no magnetic field. A stationary observer would see motion, current and a magnetic field. It would appear that a magnetic field is an electric field observed from a motional reference frame. Similarly, if we take a mass with a gravity field around it, and we move the mass and create a mass current, a new field is also created. It is a different kind of gravity field with no source and no sink. It is called the "Protational field" and is also known as the "Lense-Thirring Effect". This field and it's governing principles will form the basis for future anti-gravitational devices (see figures 1 to 4). Within the confined are of the Vacuum Triode box, the space-time continuum is reversed by the fields which are produced in the presence of excited coherent space flux quanta. These quanta have been attracted form, and ultimately extracted from the virtual vacuum, the infinitely non-exhaustible Diac Sea. For a more detailed mathematical format see Tom Bearden's paper "The Phase Conjugate Vacuum Triode" (23rd April 1987). Much of the theory which likely applies to the vacuum triode has been developed in the field of phase-conjugate optics. A - 1209
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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 - 879
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A - 881
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A - 883
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A - 885
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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
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From the foregoing description it w
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Fig.2 is an enlarged view of the de
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Fig.6 is a section taken along line
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ROBERT SHELTON US Patent 2,982,528
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Fig.4 is a transverse sectional vie
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HAROLD SCHWARTZ US Patent 3,294,381
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182,420 now abandoned. The present
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DESCRIPTION OF THE INVENTION The ca
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THOMAS OGLE US Patent 4,177,779 11t
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In accordance with other aspects of
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Fig.3 is a sectional view of the va
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Fig.7 is a partial side, partial se
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The cooling system of the vehicle c
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Upon initial starting of the engine
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(f) A filter positioned in the vapo
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with the magnitude of the current a
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Fig.1B is a perspective view of the
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Fig.3 is a top view of the motor of
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Fig.7 is an isometric view showing
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Fig.10 is a top view showing the ro
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Fig.13 is a top view of a pair of r
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Extending in opposite diametric dir
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Fig.5 shows the state of the switch
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otor magnets 42 - 49 when in the ho
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Fig.9 and Fig.10 show a second arra
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constructed otherwise than as speci
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12. The motor of claim 11 wherein t
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timer or a control mechanism mounte
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Fig.4 is a view similar to Fig.3 bu
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Fig.10 is a view similar to Fig.3 f
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Fig.13 is a schematic circuit diagr
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Fig.16 is a simplified embodiment o
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Fig.22 to Fig.25 are similar to Fig
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Referring to Fig.2, the permanent m
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Fig.7 shows a modified embodiment w
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them, will depend upon the order in
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Fig.14, shows another embodiment 14
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Fig.18 shows the air coil 210 posit
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Figs. 22-25 show four different pos
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movement with the first permanent m
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a shaft and means journaling the sh
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CLAUDE MEAD and WILLIAM HOLMES US P
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Fig.2 is a front elevation of the w
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impactors and drills. The turbine d
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(a) fourth rotating means responsiv
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path to the other side of the perma
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Fig.3 is an oscilloscope waveform t
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DETAILED DESCRIPTION OF THE PREFERR
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although it is by no means obvious
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second diode connected at its posit
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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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Fig.8 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
Page 335 and 336: Fig.5 is a cross-sectional view of
Page 337 and 338: Fig.12 is a cross-sectional view si
Page 339 and 340: Fig.14 is a schematic diagram of an
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Page 345 and 346: Figs.20A-20F are schematic diagrams
Page 347 and 348: Note: Corresponding reference chara
Page 349 and 350: Integral with the piston bodies are
Page 351 and 352: The piston has a generally semi-tor
Page 353 and 354: Referring back to Fig.13A, for engi
Page 355 and 356: As piston 39A reaches BDC, distribu
Page 357 and 358: mixture and do not combine because
Page 359 and 360: These wires are about twelve gauge,
Page 361 and 362: cold-cathode tube 391, and an x-ray
Page 363 and 364: Fig.17D), polariser 289, branch B17
Page 365 and 366: Robert Britt US Patent 3,977,191 31
Page 367 and 368: Fig.3 is an elevational view of the
Page 369 and 370: Fig.7 is an electrical schematic of
Page 371 and 372: Referring now to Fig.3 of the drawi
Page 373 and 374: and drives Q1 into conduction. The
Page 375 and 376: Floyd Sweet Recently, some addition
Page 377 and 378: The day when we witnessed the VTA d
Page 379 and 380: up to see Floyd. Floyd was with the
Page 381 and 382: Energy cannot enter a space of zero
Page 383 and 384: electromagnetic and gravitational f
Page 385: or in another form: So, the e.m.f.
Page 389 and 390: Meguer Kalfaian There is a patent a
Page 391 and 392: Fig.2 illustrates a controlled top
Page 393 and 394: Fig.9 is a modification of Fig.6; a
Page 395 and 396: the outer periphery of the magnet,
Page 397 and 398: wobbling top is sufficient, as proo
Page 399 and 400: Theodore Annis & Patrick Eberly US
Page 401 and 402: BRIEF DESCRIPTION OF THE DRAWINGS F
Page 403 and 404: Fig.6 is a schematic diagram of a s
Page 405 and 406: DETAILED DESCRIPTION OF THE PREFERR
Page 407 and 408: Fig.5 is a detail drawing of an alt
Page 409 and 410: In the preferred implementation of
Page 411 and 412: William McDavid junior US Patent 6,
Page 413 and 414: This sloping floor causes the drive
Page 415 and 416: FIG.3 is a side elevational view of
Page 417 and 418: FIG.9 is a horizontal cross-section
Page 419 and 420: otational downstream annular chambe
Page 421 and 422: In Fig.5 is shown a perspective vie
Page 423 and 424: small hydro-electric version of the
Page 425 and 426: Fig.10 is a perspective view of a s
Page 427 and 428: longitudinally mounted in the upstr
Page 429 and 430: shaft in the central aperture, said
Page 431 and 432: Scientific Papers The following lin
Page 433 and 434: http://www.free-energy-info.co.uk/M
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A Practical Guide to 'Free-Energy' Devices

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