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This circuit is capable of delivering any amount of power with a locked input power.
Introduction:
In a typical bedini circuit setup as shown (figure 1), the collapsing magnetic field is directed to recharge the battery. I found that it is superior to omit the recharging process and left the circuit as shown in figure 2. The logic behind this is that the magnetic field does not collapse uniformly but rather in ripples waves distributed through out the coil. This is extremely useful in the application of rapid switching as soon describe in my circuit.
Circuit description:
A power source is connected to the master coil going through the switch. It is then connects to loading elements in a series fashion. As many elements as desire can be connected in series to draw power. Typical loading element design and switching circuit are shown.
Theory of operation:
As the switch shut, a current flows through the master coil and all loading elements. When the switch open, the magnetic fields collapse within the coil inducing rippling magnetic waves. These waves propagate at the speed base on the total induction of the circuit, which mainly resides in the master coil. The energy within the coil remains until all the waves dampens out. The switch is shut again to prevent the dampening effect, thus keeping the waves alive. Notice that no extra current will flow if the switch is operate at high frequency. This is due to induction property of coil which resist the change in current. As more load is added, the induction within the circuit increase, thus much more energy is store within the circuit. The energy, intransient, gives the power output. This does not effect the input power since the purpose of input is to maintain the oscillation. It is desire to have the loading element made out of a few turns and identical since differnt induction can cause differnt frequency at specific section. It also be desire, but not neccessary, to have the circuit operate at resonance and that the length of the circuit is a half wavelength multiple. This will give the nodal ends of the circuit 0 potential to prolong the source life.
Introduction:
In a typical bedini circuit setup as shown (figure 1), the collapsing magnetic field is directed to recharge the battery. I found that it is superior to omit the recharging process and left the circuit as shown in figure 2. The logic behind this is that the magnetic field does not collapse uniformly but rather in ripples waves distributed through out the coil. This is extremely useful in the application of rapid switching as soon describe in my circuit.
Circuit description:
A power source is connected to the master coil going through the switch. It is then connects to loading elements in a series fashion. As many elements as desire can be connected in series to draw power. Typical loading element design and switching circuit are shown.
Theory of operation:
As the switch shut, a current flows through the master coil and all loading elements. When the switch open, the magnetic fields collapse within the coil inducing rippling magnetic waves. These waves propagate at the speed base on the total induction of the circuit, which mainly resides in the master coil. The energy within the coil remains until all the waves dampens out. The switch is shut again to prevent the dampening effect, thus keeping the waves alive. Notice that no extra current will flow if the switch is operate at high frequency. This is due to induction property of coil which resist the change in current. As more load is added, the induction within the circuit increase, thus much more energy is store within the circuit. The energy, intransient, gives the power output. This does not effect the input power since the purpose of input is to maintain the oscillation. It is desire to have the loading element made out of a few turns and identical since differnt induction can cause differnt frequency at specific section. It also be desire, but not neccessary, to have the circuit operate at resonance and that the length of the circuit is a half wavelength multiple. This will give the nodal ends of the circuit 0 potential to prolong the source life.
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