Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
David Joseph
GENERATING LOADS IN PULSES
Technical Field
[0001] The present invention relates to generating electricity by division of
electricity to a
motor and a load in a continuous cycle by a unique manipulation of the
magnetic fields.
Background
[0002] An electric generator converts mechanical energy obtained from an
external source
into electricity. The mechanical energy supplied to magnets housed inside a
generator causes
the movement of electric charges in the wire of its windings through an
external electric circuit.
This flow of electric charges creates the output electric current and voltage
of the generator.
[0003] Today's generator works on the principle of electromagnetic induction
discovered by
Michael Faraday in 1831. Faraday discovered that the flow of electric charges
could be induced
by moving a wire, in a magnetic field. This movement creates a voltage
difference between the
two ends of the wire, which causes the electric charges to flow, when the
circuit is closed:
thereby generating electric current.
[0004] The induced magnetic field inside any loop of wire always acts to
keep the
magnetic flux in the loop constant. If the flux is increasing, the induced
field acts in opposition
to it. If it is decreasing, the induced field acts in the direction of the
applied field to oppose the
change. In accordance with Lens Law, the result is that when a generator must
increase energy
to supply a load, the external mechanical force on the generator's rotor must
increase in
torque.
[0005] The laws of thermodynamics prohibit a device from acting perpetually in
the
generating of energy as the first law of thermodynamics states is simply 'the
law of
conservation of energy' which states, 'that energy can neither be created nor
destroyed,
although it can be converted from one form to another.' The embodiments of the
present
invention do not contravene the law of conservation of energy, as the extra
energy which is
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CA 3141901 2021-12-06
David Joseph
GENERATING LOADS IN PULSES
usable for the load and motor can be measured and is well known.
Summary of Invention
[0006] The embodiment of the present invention uses a zero electromotive
repulsion
generator US Patent Application 16/706,744. This type of generator allows for
increased
current through a stator coil without increasing torque on the rotor magnet
and does not
contravene lens law but uses lens law to manipulate the stators magnetic
fields.
[0007] The preferred embodiment of the present invention includes a magnetic
electric
impulse motor US Patent No. 15/832,773. The magnetic electric impulse motor is
linked to the
'Zero Electromotive Repulsion Generator. The 'Magnetic Electric Impulse Motor'
needs only
electricity in its one phase of its rotation, while using the natural magnetic
fields from magnets
to propel its rotor in the second phase of rotation. This means that the motor
via way of
receiving energy from the generator only needs that energy 50% of each turn
cycle. This
invention uses that 50% of generated power not used in the motor to power a
load.
[0008] In the alternate embodiment of the present invention uses an electric
motor linked to
the 'Zero Electromotive Repulsion Generator'. Due to the 'Zero Electromotive
Repulsion
Generator' having no back EMF the invention uses access energy normally
required to offset
the back EMF caused by the effects of Lens Law, to power a load.
Brief Description of Drawings
[0009]
FIG. 1 illustrates the preferred configuration of this present invention
showing a side
view of the invention's commutator unit 316, an magnetic electric impulse
motor 300, a zero
electromotive repulsion generator 215, linked together by a linkage 2316.
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CA 3141901 2021-12-06
David Joseph
GENERATING LOADS IN PULSES
[00101 FIG. 2 illustrates the preferred configuration of this present
invention showing the
wiring layout which includes a commutator unit 316, sending power from a zero
electromotive
repulsion generator 215 to a magnetic electric impulse motor 300 in one phase,
and a storage
device in the second phase which is linked to a load.
[0011] FIG. 3 illustrates the preferred configuration of this present
invention showing the
wiring layout which includes a commutator unit 316, sending power from a zero
electromotive
repulsion generator 215 to a magnetic electric impulse motor 300 in one phase,
and a load in
the second phase.
[0012] FIG. 4 illustrates the preferred configuration of this present
invention showing a side
view of the invention's commutator unit 316, an electric motor 400, a zero
electromotive
repulsion generator 215, linked together by a linkage 2316.
[0013] FIG. 5 illustrates the preferred configuration of this present
invention showing the
wiring layout which includes a commutator unit 316, sending power from a zero
electromotive
repulsion generator 215 to an electric motor 400 in one phase, and a storage
device in the
second phase which is linked to a load.
[0014] FIG. 6 illustrates the preferred configuration of this present
invention showing the
wiring layout which includes a commutator unit 316, sending power from a zero
electromotive
repulsion generator 215 to an electric motor 400 in one phase, and a load in
the second phase.
[0015] FIG. 7 illustrates an alternate configuration of this present
invention showing the
wiring layout which wiring sends power from a zero electromotive repulsion
generator 215 to a
magnetic electric impulse motor 300 and a load at the same time.
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CA 3141901 2021-12-06
David Joseph
GENERATING LOADS IN PULSES
[0016] FIG. 8 illustrates an alternate configuration of this present
invention showing the
wiring layout which wiring sends power from a zero electromotive repulsion
generator 215 to a
electric motor 400 and a load at the same time.
Description of Embodiments
[0017] As shown in illustration FIG. 1 an electric motor 300 with a commutator
316 is linked
up by a linkage 2316 to a zero electromotive repulsion generator 215.
[0018] As shown in illustration FIG.1 and FIG. 2 a wiring configuration with
an electric motor
300 with a commutator 316 linked up by a linkage 2316 to a zero electromotive
repulsion
generator 215. The commutator 2316 sends power to the motor in one phase and
sends power
to a storage device, which is linked electrically to a load.
[0019] As shown in illustration FIG.1 and FIG. 3 a wiring configuration with
an electric motor
300 with a commutator 316 linked up by a linkage 2316 to a zero electromotive
repulsion
generator 215. The commutator 2316 sends power to the motor in one phase and
sends power
to a load.
[0020] As shown in illustration FIG. 4 a magnetic electric impulse motor 400
with a
commutator 316 is linked up by a linkage 2316 to a zero electromotive
repulsion generator 215.
[0021] As shown in illustration FIG.4 and FIG. 5 a wiring configuration with
magnetic electric
impulse motor 400 with a commutator 316 linked up by a linkage 2316 to a zero
electromotive
repulsion generator 215. The commutator 2316 sends power to the motor in one
phase and
sends power to a storage device, which is linked electrically to a load.
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CA 3141901 2021-12-06
David Joseph
GENERATING LOADS IN PULSES
[0022] As shown in illustration FIG.4 and FIG. 6 a wiring configuration with a
magnetic electric
impulse motor 400 with a commutator 316 linked up by a linkage 2316 to a zero
electromotive
repulsion generator 215. The commutator 2316 sends power to the motor in one
phase and
sends power to a load.
[0023] As shown in illustration FIG. 7 a wiring configuration with a magnetic
electric impulse
motor 400 wired to a zero electromotive repulsion generator 215 sending power
to the
magnetic electric impulse motor 400 and to a load at the same time.
[0024.] As shown in illustration FIG. 8 a wiring configuration with an
electric motor 300 wired
to a zero electromotive repulsion generator 215 sending power to the electric
motor 300 and
to a load at the same time.
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CA 3141901 2021-12-06
