Hey guys, I work here in Brazil with the Keppe Motor team, and I'm
gonna show you here how to add a light to your Keppe Motor.
You will need:
> 1 neon light bulb, 90 volts
> 2 alligator clips
First Step:
Take the two alligator clips and the neon light bulb and your
Keppe Motor.
Second Step:
Connect the terminals of the light bulb to the terminals of the reed switch
as shown in the sequence of pictures below. Your Keppe Motor is ready
for demonstration.
(See the 3 pictures bellow)
https://2img.net/r/ihimizer/img183/7920/foto3colocandoagarrinha.jpg
https://2img.net/r/ihimizer/img183/9094/foto4garrinhascolocadas.jpg
https://2img.net/r/ihimizer/img183/2130/foto5garrinhascolocadas.jpg
Demonstration of the Working Principle Behind the Keppe Motor
The Keppe Motor works with the back energy derived from the switching
off of the magnetic reed switch and corresponds to the complementation
force predicted by Keppe in his works on the disinversion of
the Metaphysics of Physics.
To find out experimentally about this back energy, we can connect a
small 90V neon lamp to the ends of the reed switch. The rated voltage
of this lamp indicates that it only lights on when the voltage between its
ends reaches 90V.
When the switch is on, the battery supplies energy to the circuit and the
voltage between the terminals of the coil is 9V. This tension is not enough to
light on the lamp. However, at the precise moment when the magnetic switch
is turned off, there is a reverse voltage peak caused by the collapse of
the magnetic field built in the coil. Some of these back peaks exceed twenty
times the voltage of the battery, i.e., they can get to about 200V. Although
the time intervals of these peaks last only a few microseconds, this voltage
is enough to light on the lamp without burning it.
The two following pictures show this sequence of closing and opening
of the battery circuit and the response of the lamp to these actions.
The following picture shows the Demonstrative Keppe Motor functioning
while the magnetic switch is on and the 9V battery is feeding the
Keppe Motor circuit. Note that the lamp remains off with this voltage.
The next picture shows the precise moment when the magnetic switch
is turned off and the collapse of the magnetic field inside the coil takes
place. Curiously, this back energy, which is completely undesirable for the
conventional technology of motors, constitutes the working principle of the
Keppe Motor.
https://2img.net/r/ihimizer/img183/1057/foto7luzinhaacopladalig.jpg
Thank you!
gonna show you here how to add a light to your Keppe Motor.
You will need:
> 1 neon light bulb, 90 volts
> 2 alligator clips
First Step:
Take the two alligator clips and the neon light bulb and your
Keppe Motor.
Second Step:
Connect the terminals of the light bulb to the terminals of the reed switch
as shown in the sequence of pictures below. Your Keppe Motor is ready
for demonstration.
(See the 3 pictures bellow)
https://2img.net/r/ihimizer/img183/7920/foto3colocandoagarrinha.jpg
https://2img.net/r/ihimizer/img183/9094/foto4garrinhascolocadas.jpg
https://2img.net/r/ihimizer/img183/2130/foto5garrinhascolocadas.jpg
Demonstration of the Working Principle Behind the Keppe Motor
The Keppe Motor works with the back energy derived from the switching
off of the magnetic reed switch and corresponds to the complementation
force predicted by Keppe in his works on the disinversion of
the Metaphysics of Physics.
To find out experimentally about this back energy, we can connect a
small 90V neon lamp to the ends of the reed switch. The rated voltage
of this lamp indicates that it only lights on when the voltage between its
ends reaches 90V.
When the switch is on, the battery supplies energy to the circuit and the
voltage between the terminals of the coil is 9V. This tension is not enough to
light on the lamp. However, at the precise moment when the magnetic switch
is turned off, there is a reverse voltage peak caused by the collapse of
the magnetic field built in the coil. Some of these back peaks exceed twenty
times the voltage of the battery, i.e., they can get to about 200V. Although
the time intervals of these peaks last only a few microseconds, this voltage
is enough to light on the lamp without burning it.
The two following pictures show this sequence of closing and opening
of the battery circuit and the response of the lamp to these actions.
The following picture shows the Demonstrative Keppe Motor functioning
while the magnetic switch is on and the 9V battery is feeding the
Keppe Motor circuit. Note that the lamp remains off with this voltage.
The next picture shows the precise moment when the magnetic switch
is turned off and the collapse of the magnetic field inside the coil takes
place. Curiously, this back energy, which is completely undesirable for the
conventional technology of motors, constitutes the working principle of the
Keppe Motor.
https://2img.net/r/ihimizer/img183/1057/foto7luzinhaacopladalig.jpg
Thank you!