Theoretical question about pulsing motors
Kogs had pointed out a place that prints PCBs. I see Don H. has been successful in making them. And the evolution of the circuits in this thread has been used demonstrate and instruct us on how to generate Radiant Energy. I am in the process of dissecting the multiple circuits and may try the demo with the neon bulb using a motor coil posted on Ufo's My Asymmetric Electrodynamic Machines, and want to do the Monster Driver with arduino for bigger motors I plan to build, but want to also use it to experiment on the Happy motor and finding Radiant energy tests. So I think you can do it all with the arduino and monster driver combo.
But I am wondering what would happen if we look at pulsing in sync with rpms and moreover in sync with commutator elements. It goes to the heart of whether Radiant Energy is fast, or needs to be coaxed out by slowing down, or whether it is best tapped by a Back EMF decay time, taught by conventional electronics training to be 5/SqRt(LC) or whether RE is just being obtained due to action within a given coil, or whether there is cross-inductance going on. Lots of possibilities. I have not gotten around to trying to figure out the inductance and self-capacitance of an asymmetric motor coil yet to even know if we are ball park in frequency range of 30Hz, as Dana (prochiro) suggests. However, an extra pulsing duty cycle added to the current design, probably easy with arduino could be used to find this out experimentally.
I would propose that the basic frequency of pulsing be linked to rpm X number of commutator elements. For an Imperial this would mean pulsing around 90KHZ. The primary duty cycle would be applied to each pulse. A secondary duty cycle would be to then match the say the 30HZ signal. In a 25% duty cycle at 30HZ with a motor at 3000 rpm, means that the motor brush set that the signal is applied to, the motor just did a full 25 revolutions with power on and 75 rpm coasting. All I can say is wow if the brush set is loafing 75% of the time and it still out puts the power AT reduced amperage. But if the same effect can be obtained by supplying pulses within pulses, at the commutator level, imagine what that might do to power consumption
Kogs had pointed out a place that prints PCBs. I see Don H. has been successful in making them. And the evolution of the circuits in this thread has been used demonstrate and instruct us on how to generate Radiant Energy. I am in the process of dissecting the multiple circuits and may try the demo with the neon bulb using a motor coil posted on Ufo's My Asymmetric Electrodynamic Machines, and want to do the Monster Driver with arduino for bigger motors I plan to build, but want to also use it to experiment on the Happy motor and finding Radiant energy tests. So I think you can do it all with the arduino and monster driver combo.
But I am wondering what would happen if we look at pulsing in sync with rpms and moreover in sync with commutator elements. It goes to the heart of whether Radiant Energy is fast, or needs to be coaxed out by slowing down, or whether it is best tapped by a Back EMF decay time, taught by conventional electronics training to be 5/SqRt(LC) or whether RE is just being obtained due to action within a given coil, or whether there is cross-inductance going on. Lots of possibilities. I have not gotten around to trying to figure out the inductance and self-capacitance of an asymmetric motor coil yet to even know if we are ball park in frequency range of 30Hz, as Dana (prochiro) suggests. However, an extra pulsing duty cycle added to the current design, probably easy with arduino could be used to find this out experimentally.
I would propose that the basic frequency of pulsing be linked to rpm X number of commutator elements. For an Imperial this would mean pulsing around 90KHZ. The primary duty cycle would be applied to each pulse. A secondary duty cycle would be to then match the say the 30HZ signal. In a 25% duty cycle at 30HZ with a motor at 3000 rpm, means that the motor brush set that the signal is applied to, the motor just did a full 25 revolutions with power on and 75 rpm coasting. All I can say is wow if the brush set is loafing 75% of the time and it still out puts the power AT reduced amperage. But if the same effect can be obtained by supplying pulses within pulses, at the commutator level, imagine what that might do to power consumption
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