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<conspiracyFile>HOMOPOLAR "FREE-ENERGY" GENERATOR TEST
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Robert Kincheloe
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Professor of Electrical Engineering (Emeritus)
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Stanford University
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Paper presented at the 1986 meeting
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of the
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Society for Scientific Exploration
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San Francisco
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June 21, 1986
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Revised February 1, 1987
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<div>
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HOMOPOLAR "FREE-ENERGY" GENERATOR TEST
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Robert Kincheloe
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ABSTRACT
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Known for over 150 years, the Faraday homopolar generator has
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been claimed to provide a basis for so-called "free-energy"
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generation, in that under certain conditions the extraction of
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electrical output energy is not reflected as a corresponding
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mechanical load to the driving source.
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During 1985 I was invited to test such a machine. While it did
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not perform as claimed, repeatable data showed anomalous
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results that did not seem to conform to traditional theory.
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In particular, under certain assumptions about internally
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generated output voltage, the increase in input power when power
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was extracted from the generator over that measured due to
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frictional losses with the generator unexcited seemed to be
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either about 13% or 20% of the maximum computed generated power,
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depending on interpretation.
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The paper briefly reviews the homopolar generator, describes the
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tests on this particular machine, summarizes and presents
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tentative conclusions from the resulting data.
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THE SUNBURST HOMOPOLAR GENERATOR
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In July, 1985, I became aware of and was invited to examine and
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test a so-called free-energy generator known as the Sunburst N
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Machine.
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This device, shown in Figs 1a and 1b, was proposed by Bruce
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DePalma and constructed by Charya Bernard of the Sunburst
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Community in Santa Barbara, CA, about 1979.
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The term "free-energy" refers to the claim by DePalma [1]
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(and others [2]) that it was capable of producing electrical
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output power that was not reflected as a mechanical load to the
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driving mechanism but derived from presumed latent spatial
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energy.
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Apart from mechanical frictional and electrical losses inherent
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in the particular construction, the technique employed was
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claimed to provide a basis for constructing a generator which
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could supply the energy to provide not only its own motive power
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but also additional energy for external use. From August 1985
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to April 1986 I made a series of measurements on this particular
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machine to test these claims.
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GENERATOR DESCRIPTION
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Details of the generator construction are shown in Figs. 2 and 3.
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It consists essentially of an electromagnet formed by a coil of
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3605 turns of #10 copper wire around a soft iron core which
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can be rotated with the magnetic field parallel to and
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symmetrical around the axis of rotation.
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At each end of the magnet are conducting bronze cylindrical
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plates, on one of which are arranged (as shown in Fig. 3)
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one set of graphite brushes for extracting output current
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between the shaft and the outer circumference and a second
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set of metering brushes for independently measuring the induced
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voltage between these locations.
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A third pair of brushes and slip rings supply the current for
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the electromagnet. A thick sheath of epoxy-impregnated
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fiberglass windings allow the magnet to be rotated at high speed.
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The generator may be recognized as a so-called homopolar, or
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acyclic machine, a device first investigated and described
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by Michael Faraday [3] in 1831 (Figs. 4,5) and shown
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schematically in Fig. 6.
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It consists of a cylindrical conducting disk immersed in an
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axial magnetic field, and can be operated as a generator with
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sliding brushes extracting current from the voltage induced
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between the inner and outer regions of the disk when the
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rotational energy is supplied by an external driving source.
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The magnitude of the incremental radial generated voltage
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is proportional to both the strength of the magnetic field
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and the tangential velocity, so that in a uniform magnetic
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field the total voltage is proportional to the product of speed
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times the difference between the squares of the inner and outer
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brush radii.
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The device may also be used as a motor when an external
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voltage produces an radial current between the sliding brushes.
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There have been a number of commercial applications of
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homopolar motors and generators, particularly early in this
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century [4], and their operating principles are described in a
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number of texts [5].
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The usual technique is to use a stationary magnet to produce
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the magnetic field in which the conducting disk (or
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cylinder) is rotated.
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Faraday found, however, (Fig 7) that it does not matter whether
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the magnet itself is stationary or rotating with the disk as long
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as the conductor is moving in the field, but that rotating the
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magnet with the conducting disk stationary did not produce an
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induced voltage.
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He concluded that a magnetic field is a property of space
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itself, not attached to the magnet which serves to induce the
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field [6].
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DePalma stated [7] that when the conducting disk is attached
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to a rotating magnet, the interaction of the primary magnetic
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field with that produced by the radial output current results in
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torque between the disk and the magnet structure which is not
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reflected back to the mechanical driving source.
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Lenz's law therefore does not apply, and the extraction of
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output energy does not require additional driving power.
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This is the claimed basis for extracting "free" energy.
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Discussions of the torque experienced by a rotating magnet are also
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discussed in the literature [8].
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Because the simple form shown in Fig. 6 has essentially
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one conducting path, such a homopolar device is characterized
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by low voltage and high current requiring a large magnetic field
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for useful operation.
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Various homopolar devices have been used for specialized
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applications [9] (such as generators for developing large
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currents for welding, ship degaussing, liquid metal
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magnetohydrodynamic pumps for nuclear reactor cooling,
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torquemotors for propulsion, etc.), some involving quite high
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power.
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These have been extensively discussed in the literature,
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dealing with such problems as developing the high magnetic
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fields required (sometimes using superconducting magnets in
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air to avoid iron saturation effects), the development of
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brushes that can handle the very high currents and have low
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voltage drop because of the low output voltage generated,
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and with counteracting armature reaction which otherwise would
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reduce the output voltage because of the magnetic field
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distortion resulting from the high currents.
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From the standpoint of prior art, the design of the
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Sunburst generator is inefficient and not suitable for power
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generation:
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1. The magnetic field is concentrated near the axis where
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the tangential velocity is low, reducing the generated
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voltage.
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2. Approximately 4 kilowatts of power are required to
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energize the magnet, developing enough heat so that the
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device can only be operated for limited periods of time.
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3. The graphite brushes used have a voltage drop almost
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equal to the total induced voltage, so that almost all of
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the generated power is consumed in heating the brushes.
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4. The large contacting area (over 30 square inches) of
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the brushes needed for the high output current creates
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considerable friction loss.
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Since this machine was not intended as a practical generator but
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as a means for testing the free energy principle, however,
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from this point of view efficiency in producing external
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power was not required or relevant.
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DEPALMA'S RESULTS WITH THE SUNBURST HOMOPOLAR GENERATOR
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In 1980 DePalma conducted tests with the Sunburst
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generator, describing his measurement technique and results in an
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unpublished report [10].
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The generator was driven by a 3 phase a-c 40 horsepower motor
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by a belt coupling sufficiently long that magnetic fields of
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the motor and generator would not interact. A table from this
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report giving his data and results is shown in Fig. 8.
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For a rotational speed of 6000 rpm an output power of 7560 watts
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was claimed to require an increase of 268 watts of drive power
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over that required to supply losses due to friction, windage,
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etc. as measured with the output switch open.
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If valid, this would mean that the output power was 28.2 times
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the incremental input power needed to produce it. Several
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assumptions were made in this analysis:
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1. The drive motor input power was assumed to be the product
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of the line voltage and current times the appropriate factor
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for a three-phase machine and an assumed constant 70% power
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factor.
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There was apparently no consideration of phase angle
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change as the motor load increased. This gives optimistic
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results, since consideration of phase angle is necessary
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for calculating power in an a-c circuit, particularly with
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induction motors.
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It might also be noted that the measured incremental line
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current increase of 0.5 ampere (3.3%) as obtained with the
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analog clamp-on a-c ammeter that was used was of limited
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accuracy.
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2. The output power of the generator was taken to be the
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product of the measured output current and the internally
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generated voltage in the disk less the voltage drop due only
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to internal disk resistance. Armature reaction was thus
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neglected or assumed not to be significant.
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3. The generated voltage which produced the current in the main
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output brushes was assumed to be the same as that measured
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at the metering brushes, and the decrease in metered voltage
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from 1.5 to 1.05 volts when the output switch is closed was
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assumed to be due to the internal voltage drop resulting
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from the output current flowing through the internal disk
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resistance that is common to both sets of brushes and
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calculated to 62.5 microohms.
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Of these, the first assumption seems the most serious, and it is my
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opinion that the results of this particular test were inaccurate.
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Tim Wilhelm of Stelle, Illinois, who witnessed tests of the Sunburst
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generator in 1981, had a similar opinion [11].
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RECENT TESTS OF THE SUNBURST GENERATOR
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Being intrigued by DePalma's hypothesis, I accepted the offer by
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Mr. Norman Paulsen, founder of the Sunburst Community, to
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conduct tests on the generator which apparently had not been
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used since the tests by DePalma and Bernard in 1979.
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Experimental Setup
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A schematic diagram of the test arrangement is shown in Fig. 9,
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with the physical equipment shown in Fig. 10. The generator
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is shown coupled by a long belt to the drive motor behind it,
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together with the power supplies and metering both contained
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within and external to the Sunburst power and metering cabinet.
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Figure 10b shows the panel of the test cabinet which provided
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power for the generator magnet and motor field. The 4-1/2 digit
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meters on the panel were not functional and were not used;
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external meters were supplied.
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I decided to use an avaiable shunt-field d-c drive motor
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to facilitate load tests at different speeds and to simplify
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accurate motor input power measurements.
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Page 5
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Referring to Figure 9, variacs and full-wave bridge
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rectifiers provided variable d-c supplies for the motor armature
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and field and the homopolar generator magnet.
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Voltages and currents were measured with Micronta model 11-191
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3-1/2 digit meters calibrated to better than 0.1% against a
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Hewlett Packard 740B Voltage Standard that by itself was
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accurate to better than .005%.
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Standard meter shunts together with the digital voltmeters were
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used to measure the various currents. With this
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arrangement the generator speed could be varied smoothly from 0
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to over 7000 rpm, with accurate measurement of motor input
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power, metered generator output voltage Vg and generator output
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current Ig.
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Speed was measured with a General Radio model 1531 Strobotac
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which had a calibration accuracy of better than 2% (as verified
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with a frequency counter) and which allowed determination of
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relative speed changes of a few rpm of less.
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Small changes in either load or input power were clearly
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evident because of the sensitivity of the Strobotac speed
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measurement, allowing the motor input power to be adjusted
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with the armature voltage variac to obtain the desired
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constant speed with no acceleration or deceleration before
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taking readings from the various meters.
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Generator Tests
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Various tests were conducted with the output switch open to
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confirm that generated voltage at both the output brushes (Vbr)
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and metering brushes (Vg) were proportional to speed and magnetic
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field, with the polarity reversing when magnetic field or
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direction of rotation were reversed.
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Tracking of Vbr and Vg with variation of magnetic field is shown
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in Fig. 11, in which it is seen that the output voltages are not
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quite linearly related to magnet current, probably due to core
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saturation.
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The more rapid departure of Vg from linearity may be due to
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the different brush locations as seen on Fig 3, differences
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in the magnetic field at the different brush locations, or other
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causes not evident. An expanded plot of this voltage
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difference is shown in Fig. 12, and is seen to considerably
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exceed meter error tolerances.
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Figure 11 also shows an approximate 300 watt increase in drive
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motor armature power as the magnet field was increased from
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0 to 19 amperes.
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(The scatter of input power measurements shown in the upper curve
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of Fig. 11 resulted from the great sensitivity of the motor
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armature current to small fluctuations in power line voltage,
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since the large rotary inertia of the 400 pound generator did
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not allow speed to rapidly follow line voltage changes).
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At first it was thought that this power loss might be due to
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the fact that the outer output brushes were arranged in a
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rectangular array as shown in Fig. 3.
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Since they were connected in parallel but not equidistant from
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the axis the different generated voltages would presumably
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result in circulating currents and additional power dissipation.
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Measurement of the generated voltage as a function of
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radial distance from the axis as shown in Fig. 13, however,
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showed that almost all of the voltage differential occurred
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between 5 and 12 cm, presumably because this was the region of
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greatest magnetic field due to the centralized iron core.
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The voltage in the region of the outer brushes was almost
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constant, with a measured variation of only 3.7% between the
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extremes, so that this did not seem to explain the increase in
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input power. The other likely explanation seems to be that there
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are internal losses in the core and other parts of the metal
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structure due to eddy currents, since these are also moving
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conductors in the field.
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In any event, the increase in drive power was only about 10% for
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the maximum magnet current of 19 amperes.
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Figure 14 typifies a number of measurements of input power
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and generator performance as a function of speed and various
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generator conditions.
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Since the generator output knife switch procedure was very stiff
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and difficult to operate the procedure used was to make a
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complete speed run from zero to the maximum speed and descending
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again to zero with the switch open, taking readings at each
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speed increment with the magnet power both off and on.
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The procedure was then repeated with the switch closed. (It
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was noted that during the descending speed run the input power
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was a few percent lower than for the same speed during the
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earlier ascending speed run; this was presumably due to
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reduced friction as the brushes and/or bearings became
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heated. In plotting the data the losses for both runs were
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averaged which gave a conservative result since the losses
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shown in the figures exceed the minimum values measured).
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The upper curve (a) shows the motor armature input power
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with a constant motor field current of 6 amperes as the speed
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is varied with no generator magnet excitation and is seen to
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reach a maximum of 4782 watts as the speed is increased to 6500
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rpm.
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This presumably represents the power required to overcome
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friction and windage losses in the motor, generator, and drive
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belt, and are assumed to remain essentially constant whether
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the generator is producing power or not [12].
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Curve 14b shows the increase of motor armature power over that
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of curve (a) that results from energizing the generator magnet
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with a current of 16 amperes but with the generator output
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switch open so that there is no output current (and hence
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no output power dissippation).
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This component of power (which is related to the increase of
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drive motor power with increased magnet current as shown in Fig.
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11 as discussed above) might also be present whether or not the
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generator is producing output current and power, although this is
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not so evident since the output current may affect the
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magnetic field distribution.
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Curve 14c shows the further increase of motor armature input
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power over that of curves (a) plus (b) that results when the
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output switch is closed, the generator magnet is energized and
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output current is produced.
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It is certainly not zero or negligible but rises to a maximum of
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802 watts at 6500 rpm. The total motor armature input power
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under these conditions is thus the sum of (a), (b), and
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(c) and reaches a maximum of 6028 watts at 6500 rpm.
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The big question has to do with the generated output power.
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The measured output current at 6500 rpm was 4776 amperes; the
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voltage at the metering brushes was 1.07 volts.
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Using a correction factor derived from Fig. 12 and assuming a
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common internal voltage drop due to a calculated disk
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resistance of 38 microohms, a computed internal generated
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potential of 1.28 volts is obtained which if multiplied by
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the measured output current indicates a generated power of
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6113 watts.
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All of this power is presumably dissipated in the internal
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and external circuit resistances, the brush loss due both to
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the brush resistance and the voltage drops at the contact
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surfaces between the brushes and the disk (essentially an arc
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discharge), and the power dissipated in the 31.25 microohm meter
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shunt.
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It still represents power generated by the machine, however,
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and exceeds the 802 watts of increased motor drive power due
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solely to closing the generator output switch and causing
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output current to flow by a factor of 7.6 to 1.
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If the 444 watts of increased input power that resulted
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from energizing the magnet with the output switch open is assumed
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to have been converted to generated output power and hence
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should be included as part of the total increased drive motor
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power required to produce generated output, the computed 6113
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watts of generated power still exceeds the total input power of
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444 watts plus 802 watts by a factor of 4.9 to 1.
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The computed output power even slightly exceeds the total
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motor armature input power including all frictional and windage
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losses of 6028 watts under these conditions (although the
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total system effeciency is still less than 100% because of the
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generator magnet power of approximately 2300 watts and motor
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field power of about 144 watts which must be added to the
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motor armature power to obtain total system input power).
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It would thus seem that if the above assumptions are valid
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that DePalma correctly predicted that much of the generated
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power with this kind of machine is not reflected back to the
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motive source. Figure 15 summarizes the data discussed above.
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To further examine the question of the equivalence between
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the internally generated voltage at the main output brushes and
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that measured at the metering brushes, a test was made of the
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metered voltage as a function of speed with the generator magnet
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energized with a current of 20 amperes both with the output
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switch open and closed. The resulting data is shown in Fig. 16.
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The voltage rises to about 1.32 volts at 6000 rpm with the
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switch open (which is close to that obtained by DePalma) and
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drops 0.14 volts when the switch is closed and the measured
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output current is 3755 amperes, corresponding to an effective
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internal resistance of 37 microohms.
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Even if this were due to other causes, such as armature reaction,
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it does not seem likely that there would be a large potential
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drop between the output and metering brushes because of
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the small distance, low magnetic field (and radial differential
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voltage), and large mass of conducting disk material.
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Internal currents many times the measured output current of
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almost 4000 amperes would be required for the voltage
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difference between the outer metering and output brushes to
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be significant and invalidate the conclusions reached above.
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A further method of testing the validity of the assumed
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generated output potential involved an examination of the
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voltage drop across the graphite brushes themselves.
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Many texts on electrical machinery discuss the brush drop
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in machines with commutators or slip rings.
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All of those examined agree that graphite brushes typically have
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a voltage drop that is essentially constant at approximately one
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volt per brush contact when the current density rises above 10-15
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amperes per square centimeter.
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To compare this with the Sunburst machine the total brush
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voltage was calculated by subtracting the IR drop due to the
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output current in the known (meter shunt) and calculated (disk,
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shaft, and brush lead) resistances from the assumed
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internally generated output voltage. The result in Fig. 17
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shows that the brush drop obtained in this way is even less than
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that usually assumed, as typified by the superimposed curve
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taken from one text.
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It thus seems probable that the generated voltage is
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not significantly less than that obtained from the metering
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brushes, and hence the appropriateness of the computed output
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power is supported.
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CONCLUSIONS
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We are therefore faced with the apparent result that the
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output power obtained when the generator magnet is
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energized greatly exceeds the increase in drive power over
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that needed to supply losses with the magnet not energized.
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This is certainly anomalous in terms of convential theory.
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Possible explanations?
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1. There could be a large error in the measurements resulting
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from some factor such as noise which caused the digital
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meters to read incorrectly or grossly inaccurate current
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shunt resistances.
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If the measured results had shown that the computed generated
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output power exceeded the input drive power by only a few percent
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this explanation would be reasonable and would suggest that more
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careful calibration and measurements might show that the results
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described above were due to measurement error.
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With the data showing such a large ratio of generated power to
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input power increase, however, in my opinion this
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explanation of the results seems unlikely.
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(A later test showed that the digital meters are insensitive
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to a large a-c ripple superimposed on the measured d-c, but
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within their rated accuracy of 0.1% give a true average value).
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2. There could be a large difference between the measured
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voltage at the metering brushes and the actual generated
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voltage in the output brush circuit due to armature
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reaction, differences in the external metering and output
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circuit geometry, or other unexplained causes.
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As discussed above the various data do not seem to support this
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possibility.
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3. DePalma may have been right in that there is indeed a
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situation here whereby energy is being obtained from a
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previously unknown and unexplained source.
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This is a conclusion that most scientists and engineers would
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reject out of hand as being a violation of accepted laws of
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physics, and if true has incredible implications.
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4. Perhaps other possibilities will occur to the reader.
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The data obtained so far seems to have shown that while DePalma's
|
|
numbers were high, his basic premise has not been disproved.
|
|
While the Sunburst generator does not produce useful output power
|
|
because of the internal losses inherent in the design, a
|
|
number of techniques could be used to reduce the friction
|
|
losses, increase the total generated voltage and the
|
|
fraction of generated power delivered to an external load.
|
|
DePalma's claim of free energy generation could perhaps then
|
|
be examined.
|
|
I should mention, however, that the obvious application of using
|
|
the output of a "free-energy" generator to provide its own motive
|
|
power, and thus truly produce a source of free energy, has
|
|
occured to a number of people and several such machines have
|
|
been built.
|
|
At least one of these known to me [13], using what seemed to
|
|
be a good design techniques, was unsuccessful.
|
|
<div>
|
|
FOOTNOTES
|
|
1. DePalma, 1979a,b,c, 1981, 1983, 1984, etc.
|
|
2. For example, Satelite News, 1981, Marinov, 1984, etc.
|
|
3. Martin, 1932, vol. 1, p.381.
|
|
4. Das Gupta, 1961, 1962; Lamme, 1912, etc.
|
|
5. See, for example, Bumby, 1983; Bewley, 1952; Kosow, 1964; Nasar,
|
|
1970.
|
|
6. There has been much discussion on this point in the
|
|
literature, and about interpretation of flux lines. Bewley,
|
|
1949; Cohn, 1949a,b; Crooks, 1978; Cullwick, 1957; Savage,
|
|
1949.
|
|
7. DePalma, op. cit.
|
|
. Kimball, 1926; Zeleny, 1924.
|
|
9. Bumby, Das Gupta, op. cit.
|
|
10. DePalma, 1980.
|
|
11. Wilhelm, 1980, and personal communication.
|
|
12. The increase in motor losses with increased load are
|
|
neglected in this discussion because of a lack of accurate
|
|
values for armature and brush resistances, magnetic field
|
|
distortion resulting from armature reaction, etc. Such
|
|
losses, while small, would be appreciable, however; their
|
|
inclusion would further increase the ratio of generated to
|
|
drive power so that the results described are conservative.
|
|
13. Wilhelm, 1981, and personal communication.
|
|
<div>
|
|
REFERENCES
|
|
[Bewley, 1949] - L. V. Bewley, letter re [Cohn, 1949a]; ELECTRICAL
|
|
ENGINEERING, Dec. 1949, p.1113-4. (Claims error in Cohn's paper)
|
|
[Bewley, 1952] - L. V. Bewley, FLUX LINKAGES & ELECTROMAGNETIC
|
|
INDUCTION, Macmillan, NY, 1952. (Explanation of induction
|
|
phenomena and the Faraday generator)
|
|
[Bumby, 1983] - J. R. Bumby, SUPERCONDUCTING ROTATING ELECTRICAL
|
|
MACHINES, Claredon Press, 1983. (Homopolar designs, high current
|
|
brushes including liquid metal)
|
|
[Cohn, 1949a] - George I. Cohn, "Electromagnetic Induction",
|
|
ELECTRICAL ENGINEERING, May 1949, p441-7. (Unipolar generator as
|
|
paradox)
|
|
[Cohn, 1949b] - George Cohn, letter re [Savage, 1949]; ELECTRICAL
|
|
ENGINEERING, Nov 1949, p1018. (Responds to criticism by Savage)
|
|
[Crooks, 1978] - M. J. Crooks et al, "One-piece Faraday generator:
|
|
A paradoxical experiment from 1851", Am. J. Phys. 46(7), July
|
|
1978, p729-31. (Derives Faraday generator performance using
|
|
Maxwell's equations)
|
|
[Cullwick, 1957] - E. G. Cullwick, ELECTROMAGNETISM AND RELATIVITY,
|
|
Longmans & Green, London, 1957. (Chapter 10, "A Rotating
|
|
Conducting Magnet", pp.141-60, discusses question of flux rotation
|
|
with magnet)
|
|
[Das Gupta, 1961] - A. K. Das Gupta, "Design of self-compensated
|
|
high current comparatively higher voltage homopolar generators",
|
|
AIEE Trans. Oct 1961, p567-73. (Discusses very high current
|
|
homopolar generator design)
|
|
[Das Gupta, 1962] - A. K. Das Gupta, "Commutatorless D-C generators
|
|
capable to supply currents more than one million amperes, etc"
|
|
AIEE Trans. Oct 1962, p399-402. (Discusses very high current low
|
|
voltage Faraday generators)
|
|
[DePalma, 1979a] - Bruce DePalma, EXTRACTION OF ELECTRICAL ENERGY
|
|
DIRECTLY FROM SPACE: THE N-NACHINE, Simularity Institute, Santa
|
|
Barbara CA, 6 Mar 1979. (Discusses homopolar generator or N-
|
|
Machine as free-energy source)
|
|
[DePalma, 1979b] - Bruce DePalma, "The N-Machine", Paper given at
|
|
the World Symposium on Humanity, Pasadena, CA, 12 April 1979.
|
|
(Describes background, development of "free-energy" theories)
|
|
[DePalma, 1979c] - Bruce DePalma, ROTATION OF A MAGNETIZED
|
|
GYROSCOPE, Simularity Institute Report #33, 16 July 1979.
|
|
(Describes design of Sunburst homopolar generator)
|
|
[DePalma, 1980] - Bruce DePalma, "Performance of the Sunburst N
|
|
Machine", Simularity Institute, Santa Barbara, CA, 17 December
|
|
1980. (Description of tests and results)
|
|
[DePalma, 1981] - Bruce DePalma, "Studies on rotation leading to the
|
|
N-Machine", DePalma Institute, 1981 (transcript of talk?)
|
|
(Discusses experiments with gravity that led to development of
|
|
idea of free-energy machine)
|
|
[DePalma, 1983] - Bruce DePalma, THE ROTATION OF THE UNIVERSE,
|
|
DePalma Institute Report #83, Santa Barbara, CA, 25 July 1983.
|
|
(Uses Faraday disc to discuss universal principles).
|
|
[DePalma, 1984] - Bruce DePalma, THE SECRET OF THE FARADAY DISC,
|
|
DePalma Institute, Santa Barbara, CA, 2 Feb 1984. (Claims
|
|
explanation of Faraday disc as a free-energy device)
|
|
[Kimball, 1926] - A. L. Kimball, Jr., "Torque on revolving
|
|
cylindrical magnet", PHYS. REV. v.28, Dec 1928, p.1302-8.
|
|
(Alternative analysis of torque in a homopolar device to that of
|
|
Zeleny and Page, 1924)
|
|
[Kosow, 1964] - Irving L. Kosow, ELECTRICAL MACHINERY & CONTROL,
|
|
Prentice-Hall, 1964. (Discusses high current homopolar (acyclic)
|
|
generators)
|
|
[Lamme, 1912] - B. G. Lamme, "Development of a successful direct-
|
|
current 2000-kW unipolar generator", AIEE Trans. 28 June 1912,
|
|
p1811-40. (Early discussion of design of high power homopolar
|
|
generator)
|
|
[Marinov, 1984]- Stefan Marinov, THE THORNY WAY OF TRUTH, Part II;
|
|
Graz, Austria, 1984 (Advertisement in NATURE). (Claims free-
|
|
energy generator proved by DePalma, Newman)
|
|
[Martin, 1932] - Thomas Martin (ed), FARADAY'S DIARY, Bell, 1932,
|
|
in 5 vols. (Transcription and publication of Faraday's original
|
|
diaries)
|
|
[Nasar, 1970] - S. Nasar, ELECTROMAGNETIC ENERGY CONVERSION DEVICES
|
|
& SYSTEMS, Prentice-Hall, 1970. (Discusses principles and
|
|
applications of acyclic (homopolar) machines)
|
|
[Satellite News, 1981] - "Researchers see long-life satellite power
|
|
systems in 19th century experiment", Research news, SATELLITE
|
|
NEWS, 15 June 1981. (Reports DePalma's claim for free-energy
|
|
generator)
|
|
[Savage, 1949] - Norton Savage, letter re [Cohn, 1949a]; ELECTRICAL
|
|
ENGINEERING, July 1949, p645. (Claims error in Cohn's paper)
|
|
[Wilhelm, 1980] - Timothy J. Wilhelm, INVESTIGATIONS OF THE N-EFFECT
|
|
ONE-PIECE HOMOPOLAR DYNAMOS, ETC. (Phase I), Stelle, IL, 12 Sept
|
|
1980. (Discusses tests on DePalma's N-Machine)
|
|
[Wilhelm, 1981] - Timothy J. Wilhelm, INVESTIGATIONS OF THE N-EFFECT
|
|
ONE-PIECE HOMOPOLAR DYNAMOS, ETC. (Phase II), Stelle, IL, 10 June
|
|
1981. (Design and tests of improved homopolar generator/motor)
|
|
[Zeleny, 1924] - John Zeleny & Leigh Page, "Torque on a cylindrical
|
|
magnet through which a current is passing", PHYS. REV. v.24, 14
|
|
July 1924, p.544-59. (Theory and experiment on torque in a
|
|
homopolar device)
|
|
<div>
|
|
(Sysop note: The following figure also had an accompanying drawing)
|
|
Figure 5 - Transcription of the first experiment showing generation
|
|
of electrical power in a moving conductor by Michael
|
|
Faraday
|
|
99*. Made many expts. with a copper revolving plate, about 12 inches
|
|
in diameter and about 1/5 of inch thick, mounted on a brass
|
|
axle.
|
|
To concentrate the polar action two small magnets 6 or 7 inches
|
|
long, about 1 inch wide and half an inch thick were put against
|
|
the front of the large poles, transverse to them and with their
|
|
flat sides against them, and the ends pushed forward until
|
|
sufficiently near; the bars were prevented from slipping down
|
|
by jars and shakes by means of string tied round them.
|
|
100. The edge of the plate was inserted more of less between the two
|
|
concentrated poles thus formed. It was also well amalgamated,
|
|
and then contact was made with this edge in different places by
|
|
conductors formed from equally thick copper plate and with the
|
|
extreme end edges grooved and amalgamated so as to fit on to
|
|
and have contact with the edges of the plate. Two of these
|
|
were attached to a piece of card board by thread at such
|
|
*[99]
|
|
(Sysop note: a sketch appeared in this area)
|
|
<div>
|
|
(Sysop note: The following figure also had an accompanying drawing)
|
|
Figure 7 - Test of a rotating magnet by Michael Faraday, December
|
|
26, 1831.
|
|
255. A copper disc was cemented on the top of a cylinder magnet,
|
|
paper intervening, the top being the marked pole; the magnet
|
|
supported so as to rotate by means of string, and the wires of
|
|
the galvanometer connected with the edge and the axis of the
|
|
copper plate. When the magnet and disc together rotated
|
|
unscrew the marked end of the needle went west. When the
|
|
magnet and disc rotated screw the marked end of the needle
|
|
went east.
|
|
256. This direction is the same as that which would have resulted
|
|
if the copper had moved and the magnet been still. Hence
|
|
moving the magnet causes no difference provided the copper
|
|
moves. A rotating and a stationary magnet cause the same
|
|
effect.
|
|
257. The disc was then loosed from the magnet and held still
|
|
whilst the magnet itself was revolved; but now no effect upon
|
|
the galvanometer. Hence it appears that, of the metal circuit
|
|
in which the current is to be formed, different parts must
|
|
move with different angular velocities. If with the same, no
|
|
current is produced, i.e. when both parts are external to the
|
|
magnet.
|
|
<div>
|
|
(Sysop note: The following figure also had an accompanying drawing)
|
|
Figure 8 - Test data from report by Bruce DePalma
|
|
PERFORMANCE OF THE SUNBURST HOMOPOLAR GENERATOR
|
|
machine speed: 6000 r.p.m.
|
|
drive motor current no load 15 amperes
|
|
drive motor current increase
|
|
when N machine is loaded 1/2 ampere max.
|
|
Voltage output of N generator no load 1.5 volts d.c.
|
|
Voltage output of N generator loaded 1.05 v.d.c.
|
|
Current output of N generator 7200 amperes
|
|
(225 m.v. across shunt @ 50 m.v./1600 amp.)
|
|
Power output of N machine 7560 watts = 10.03 H.p.
|
|
Incremental power ratio = 7560/268 28.2 watts out/watts in
|
|
Internal resistance of generator 62.5 micro-phms
|
|
Reduction of the above data gives as the equivalent circuit for the
|
|
machine:
|
|
(Sysop note: a drawing R(internal) = 62.5 micro-ohms
|
|
appeared in this area) R(brush) = 114.25 " "
|
|
R(shunt) = 31.25 " "
|
|
BRUCE DEPALMA
|
|
17 DECEMBER 1980
|
|
<div>
|
|
Page 14
|
|
Figure 15 - Summary of test results at 6500 rpm
|
|
I II III
|
|
MAGNET POWER OFF ON ON
|
|
OUTPUT SWITCH OPEN OPEN CLOSED
|
|
SPEED 6500 6500 6500 RPM
|
|
MAGNET CURRENT 0 16 16
|
|
AMPERES
|
|
MOTOR ARMATURE POWER 4782 5226 6028
|
|
WATTS
|
|
INCREMENT 444 802
|
|
WATTS
|
|
METER BRUSH VOLTAGE .005 1.231 1.070
|
|
VOLTS
|
|
OUTPUT CURRENT 0 0 4776
|
|
AMPERES
|
|
GENERATED VOLTAGE 1.280 (1.280)
|
|
VOLTS
|
|
GENERATED POWER 0 0 (6113)
|
|
WATTS
|
|
HOMOPOLAR GENERATOR TEST - BIG SPRINGS RANCH APRIL 26, 1986
|
|
<div>
|
|
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