I am not sarcastic at all, anyone can check themselves what I said, everything is open, full specification and links for each component for less than £40 total budget if everything is bought from shops.
When mainstream science and all “experts” in field keep saying it is complicated and expensive to justify billions spent for nothing … people can’t believe this works, but ignoring a simple ram pump works without external energy input if is built correct, they don’t think the same can apply for electricity, or anything else.
In LCR oscillator circuit we need to calculate energy input for induction and energy stored in capacitance. When you spend a lot of input for storing in magnetic field (inductance), than capacitors do not match energy to store it in electric field you only obtain driven resonance at huge expense of input especially when it work against self inductance and self capacitance … there would not be self oscillations or it will be nullified before producing beneficial effects.
We need to drive all potential (voltage) in circuit and only in final stage amperage to let the load to dictate by its resistance the rate of power delivered … this will put under strain switching mechanism and available continuous level of power depend on it.
This is why is possible to power kw of load with few watts input. The circuit I used in the video (zvs) is able to switch up to 35 khz, after this will just be unable to deliver power without draining the input massive and start to heat up. To scale up more powerful zvs must be used, even using the same wires for coils.
Many had said that the gain mechanism is energy input/pulse remain the same then is delivered 100k times more often to the load. Just to be clear: input in my case is max 64 w/hour limited by laptop charger, which in fact is divided in each pulse equivalent of 50w/hour per time on (few fractions of a second) + loses. Each pulse deliver FULL power multiplicate in same amount of time by switching on/off.
Transformer action rise the voltage which is delivered to the load. Resistance of the load will reduce the voltage. When no current can flow zvs switch to second wire of bifilar to deliver current at same amplitude (volatge). So, power taken from input is always the same up to the limit imposed by laptop charger. The action can be seen like a hammer hitting the nail with thousands of times per second. Now, what is happening in a bifilar ? When electric flow in wire 1 will induce a current of opposite direction in wire 2 (this is full magnetic circuit, a circle) when electric flow collapse in wire 1 electric flow change direction flowing back to fulfil complete circuit of 2 wires, but with zvs switching an electric flow is released in wire 2 and this will be in the same direction of reversing flow from collapse, the same occur in both wires in the same time.
In simple words: dc input of 64 watts is considered as 1 pulse on for 1 hour, pulsed ac/dc output is 50 watts + loses multiplied by frequency of switching. Tesla had used rotary commutators for this but we can employ much more advanced methods which in this case do not require additional power source to drive the switch and all is based on resistive feedback.
When mainstream science and all “experts” in field keep saying it is complicated and expensive to justify billions spent for nothing … people can’t believe this works, but ignoring a simple ram pump works without external energy input if is built correct, they don’t think the same can apply for electricity, or anything else.
In LCR oscillator circuit we need to calculate energy input for induction and energy stored in capacitance. When you spend a lot of input for storing in magnetic field (inductance), than capacitors do not match energy to store it in electric field you only obtain driven resonance at huge expense of input especially when it work against self inductance and self capacitance … there would not be self oscillations or it will be nullified before producing beneficial effects.
We need to drive all potential (voltage) in circuit and only in final stage amperage to let the load to dictate by its resistance the rate of power delivered … this will put under strain switching mechanism and available continuous level of power depend on it.
This is why is possible to power kw of load with few watts input. The circuit I used in the video (zvs) is able to switch up to 35 khz, after this will just be unable to deliver power without draining the input massive and start to heat up. To scale up more powerful zvs must be used, even using the same wires for coils.
Many had said that the gain mechanism is energy input/pulse remain the same then is delivered 100k times more often to the load. Just to be clear: input in my case is max 64 w/hour limited by laptop charger, which in fact is divided in each pulse equivalent of 50w/hour per time on (few fractions of a second) + loses. Each pulse deliver FULL power multiplicate in same amount of time by switching on/off.
Transformer action rise the voltage which is delivered to the load. Resistance of the load will reduce the voltage. When no current can flow zvs switch to second wire of bifilar to deliver current at same amplitude (volatge). So, power taken from input is always the same up to the limit imposed by laptop charger. The action can be seen like a hammer hitting the nail with thousands of times per second. Now, what is happening in a bifilar ? When electric flow in wire 1 will induce a current of opposite direction in wire 2 (this is full magnetic circuit, a circle) when electric flow collapse in wire 1 electric flow change direction flowing back to fulfil complete circuit of 2 wires, but with zvs switching an electric flow is released in wire 2 and this will be in the same direction of reversing flow from collapse, the same occur in both wires in the same time.
In simple words: dc input of 64 watts is considered as 1 pulse on for 1 hour, pulsed ac/dc output is 50 watts + loses multiplied by frequency of switching. Tesla had used rotary commutators for this but we can employ much more advanced methods which in this case do not require additional power source to drive the switch and all is based on resistive feedback.