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I finally got back to working on my Milkovic oscillator again. I married it with my SG rotor and added an aspirin bottle full of lead shot for a 7 lb weight. I use the full revolution instead of the pendulum. It’s much easier to regulate and develops a lot more force. It’s been christened the Milkodini machine.
The coil gets the wheel moving fairly well, enough to go through a few oscillating points during spool up.
The secondary will start to bounce wildly at certain RPMs, even with heavy springs to dampen it, unless I hold on to it. Even grabbing on to the arm and really leaning on it doesn’t completely stop it from oscillating. There is a lot of leverage when the stroke is shortened.
I have been adding a few bicycle sprockets and some chain to get the speed up on the output shaft. I have it up to a 5-1 ratio so far but I may have to go even higher.
I have a few things coming in the mail to complete the power conversion section in the secondary. I’m using a big old Farmall power takeoff pulley I bought on Ebay for a flywheel. It’s got most of it’s weight (20 lbs) in the perimeter and is all steel.
For a generator I might try a DC drill motor. A 14 or 18 volt unit would work. I could run a pulley off the chuck.
This offset wheel has potential. It’s only taking about 600 ma @ 12 volts to put out a considerable amount of force in the lever. And, of course, the current stays the same regardless of the loading.
I think I have figured out an efficient way to convert a short stroke into torque. I’m going to use a couple of gearwrenches, attached to the lever, to turn the shaft. This arrangement will allow a varying range of stroke lengths to still generate torque.
On Milkovic’s web site he explains that the rotation of the pendulum, or wheel in this case, and the power supplied to oscillate the lever are two distinct sources of energy. The motive force applied to the pendulum is converted to angular momentum and is stored as potential energy.
The vertical force, which transfers energy to the lever, is the result of centrifugal force. Modern science maintains that this is a “phantom” force and is really the result of other forces caused by a rotating mass. Apparently this is incorrect.
As Milkovic shows, the rotation of the pendulum is independent of this force and can be maintained regardless of load in the secondary.
This is truly a mechanical force amplifier.
Cheers,
Ted
Here’s a few pics of the machine in it’s initial stage. Sorry about the mess.
The coil gets the wheel moving fairly well, enough to go through a few oscillating points during spool up.
The secondary will start to bounce wildly at certain RPMs, even with heavy springs to dampen it, unless I hold on to it. Even grabbing on to the arm and really leaning on it doesn’t completely stop it from oscillating. There is a lot of leverage when the stroke is shortened.
I have been adding a few bicycle sprockets and some chain to get the speed up on the output shaft. I have it up to a 5-1 ratio so far but I may have to go even higher.
I have a few things coming in the mail to complete the power conversion section in the secondary. I’m using a big old Farmall power takeoff pulley I bought on Ebay for a flywheel. It’s got most of it’s weight (20 lbs) in the perimeter and is all steel.
For a generator I might try a DC drill motor. A 14 or 18 volt unit would work. I could run a pulley off the chuck.
This offset wheel has potential. It’s only taking about 600 ma @ 12 volts to put out a considerable amount of force in the lever. And, of course, the current stays the same regardless of the loading.
I think I have figured out an efficient way to convert a short stroke into torque. I’m going to use a couple of gearwrenches, attached to the lever, to turn the shaft. This arrangement will allow a varying range of stroke lengths to still generate torque.
On Milkovic’s web site he explains that the rotation of the pendulum, or wheel in this case, and the power supplied to oscillate the lever are two distinct sources of energy. The motive force applied to the pendulum is converted to angular momentum and is stored as potential energy.
The vertical force, which transfers energy to the lever, is the result of centrifugal force. Modern science maintains that this is a “phantom” force and is really the result of other forces caused by a rotating mass. Apparently this is incorrect.
As Milkovic shows, the rotation of the pendulum is independent of this force and can be maintained regardless of load in the secondary.
This is truly a mechanical force amplifier.
Cheers,
Ted
Here’s a few pics of the machine in it’s initial stage. Sorry about the mess.
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