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Hildenbrand, Flynn, Magnacoaster... all seem to use the same type of magnetic current control to leverage flux paths. I posted a device, which I'm in the process of constructing, in the Flynn thread which takes advantage of this technology. I'll repost it at the end of this message so anyone interested doesn't have to hunt it down.
Another iteration of this Idea can be used with a rotor and some magnets, to convert rotational power into electrical power, as in a windmill. Here is a diagram of my idea:
As seen in the diagram (pretend the rotor and stator magnets are of equal value), flux would flow through the core of coil 2 and coil 3. Coil 1 would see little if any flow.
When the polarity of the rotor magnet is reversed, flux would cease to flow through coil 2 and 3, since like poles would face each other, and all the flux from the stator magnets would flow through the core of coil 1.
Of course, this is an ideal scenario and reality would probably find leakage flows in all three cores.
Nevertheless, the force of passing one magnet past the stator is controlling the flux of two (or more) magnets.
I haven't built or tested any of these concepts yet, but they seem promising so I thought you guys might be interested. If a couple of us can build working models we may have something.
Anyway, here's the other post I mentioned earlier:
I'm just about to build and test a generator concept based on the Flynn and Hildenbrand technologies.
As you can see in the drawings, the magnets are encased in a steel jacket, around which is wound a coil, just like the Hildenbrand electromagnet. This coil would be a bifiler wind with an energizing coil and a collection coil.
Normally the magnetic current will travel from the magnets and through the jacket from one pole to the other, as in #3. However, when the inner coil is energized, it reverses the domains in the jacket, cutting off that return path for the magnet's current (#2). The current is then forced into the outer coils where it is used for power. This current (flux) is twice the current of the magnets alone since the inner energizing coil is adding at least as much as the magnets to be able to reverse the current flow through the jacket.
For one unit of magnetic force I get two units traveling through the outer coils. This is where we pick up extra energy. We also pick up some energy from the inner collection coil since any change in current direction produces power.
The next pulse is in the opposite direction through the inner coil. This is necessary since the domains in the jacket won't switch all by themselves (won't switch quickly anyway). This "reset"pulse only needs to be a very short duration in order to realign the domains. Once the current flows from the magnets, the inner collection coil again produces power.
The pulse frequency, voltage, and power would all have to be figured out. The engineering of this unit will take a while to get dialed in. However, there is undeniable gain every time the magnets get "switched". Increasing the efficiency will only produce more power.
I'm going to start construction this weekend. I need to design the outer cores to handle the increased current and efficiently transform that into power. Lots of parameters to consider but I think the basic Idea is workable.
I need to figure out a switching circuit to control the coil, but I have to do some tests first to determine the amount of power needed to switch and reset.
If you or anyone else wants to build one of these things that would be great.
Sharing ideas and solutions is always more productive.
Here are a few basic drawings I made. I put them in a public photo folder if they don't appear for you below: Picasa Web Albums - Ted - Hildenbrand F...
Cheers,
Ted
Another iteration of this Idea can be used with a rotor and some magnets, to convert rotational power into electrical power, as in a windmill. Here is a diagram of my idea:
As seen in the diagram (pretend the rotor and stator magnets are of equal value), flux would flow through the core of coil 2 and coil 3. Coil 1 would see little if any flow.
When the polarity of the rotor magnet is reversed, flux would cease to flow through coil 2 and 3, since like poles would face each other, and all the flux from the stator magnets would flow through the core of coil 1.
Of course, this is an ideal scenario and reality would probably find leakage flows in all three cores.
Nevertheless, the force of passing one magnet past the stator is controlling the flux of two (or more) magnets.
I haven't built or tested any of these concepts yet, but they seem promising so I thought you guys might be interested. If a couple of us can build working models we may have something.
Anyway, here's the other post I mentioned earlier:
I'm just about to build and test a generator concept based on the Flynn and Hildenbrand technologies.
As you can see in the drawings, the magnets are encased in a steel jacket, around which is wound a coil, just like the Hildenbrand electromagnet. This coil would be a bifiler wind with an energizing coil and a collection coil.
Normally the magnetic current will travel from the magnets and through the jacket from one pole to the other, as in #3. However, when the inner coil is energized, it reverses the domains in the jacket, cutting off that return path for the magnet's current (#2). The current is then forced into the outer coils where it is used for power. This current (flux) is twice the current of the magnets alone since the inner energizing coil is adding at least as much as the magnets to be able to reverse the current flow through the jacket.
For one unit of magnetic force I get two units traveling through the outer coils. This is where we pick up extra energy. We also pick up some energy from the inner collection coil since any change in current direction produces power.
The next pulse is in the opposite direction through the inner coil. This is necessary since the domains in the jacket won't switch all by themselves (won't switch quickly anyway). This "reset"pulse only needs to be a very short duration in order to realign the domains. Once the current flows from the magnets, the inner collection coil again produces power.
The pulse frequency, voltage, and power would all have to be figured out. The engineering of this unit will take a while to get dialed in. However, there is undeniable gain every time the magnets get "switched". Increasing the efficiency will only produce more power.
I'm going to start construction this weekend. I need to design the outer cores to handle the increased current and efficiently transform that into power. Lots of parameters to consider but I think the basic Idea is workable.
I need to figure out a switching circuit to control the coil, but I have to do some tests first to determine the amount of power needed to switch and reset.
If you or anyone else wants to build one of these things that would be great.
Sharing ideas and solutions is always more productive.
Here are a few basic drawings I made. I put them in a public photo folder if they don't appear for you below: Picasa Web Albums - Ted - Hildenbrand F...
Cheers,
Ted
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