On 5/2/2013 12:32 AM, Morris Dovey wrote:
> On 5/1/13 10:44 PM, mike wrote:
>
>> Oh, Morris...say it isn't so!!!
>> You've gone over to the dark side.
>> You had a wonderful, easily reproduced solar dwelling heater.
>
> It’s still there. It’s being reproduced. The goals I set for myself have
> been achieved, and people are welcome to use (or not use) what I
> learned. Additional improvements are possible, but the project I
> undertook is completed. :-)
>
>> I tried to read your links, but couldn't get the videos to play.
>> I did skim the MHD book. I'm not the slightest bit interested
>> in reliving math experiences from 50 years ago...but there were
>> some interesting statements glossed over.
>
> Agreed - some even intentionally. :-)
>
>> MHD seems to work with a uni-directional flow of ionized material.
>> If you're sloshing it back and forth, there are all kinds of
>> issues with reversing the flow of massive ions. And there's the
>> tiny detail of superconducting magnets. And the 0.2Volt output.
>
> “Sloshing” isn’t strictly inaccurate, but in order not to lead anyone
> astray, let’s be clear that what’s oscillating is an ionized gas with a
> substantial push at one end and a (synchronized) substantial pull at the
> other end.
Would be interesting to see the theory.
I'm concerned that the operation might be extremely sensitive to the
temperatures at each end and the middle. You need physical dimensions
and masses to be well tuned to maintain the oscillation. Solar input
is not known for stability.
I think you're talking about a LOT more than a pipe with hot water in it.
If you table the MHD issues and just build the pipe, does it oscillate?
You should be able to calculate the mechanical energy available from the
mass of the supercritical water. Put some lossy compressible
material in the end caps to simulate taking energy out and see how that
affects the system.
Sounds like an evening project.
>
> I’m interested in using supercritical water for a number of reasons
> which include cost and availability, its super-solvent characteristics,
> and its R-constant (from PV = nRT). Especially I’m interested in the
> dP/dT behavior (the change in pressure relative to a change in
> temperature) in the operational temperature range.
>
> Some of this stuff seriously offends my intuition. Just the idea of
> completely dissolving a substantial quantity of (for example) common
> table salt into a gas is a bit ‘creepy’ - and that’s not the worst of
> the creepyness. :-)
>
> Superconductivity isn’t part of the design.
>
> Yes, an oscillating flow does require design consideration - but an
> oscillating flow is still a flow in one direction followed by a flow in
> the opposite direction. If the magnetic field remains constant, then the
> result will be AC, and if the magnetic field is reversed at the end of
> each “stroke” the result will be pulsed DC (as if AC had been fully
> rectified) - yes?
I'm trained as an electrical engineer. I know just enough about physics
to be dangerous. I don't have the answers, but I do know enough to ask
questions ;-)
Here's my concern about that...
If you have a plasma flow in one direction, the charges are "bent"
in response to the magnetic field. Given enough distance, you can make
all of them hit the collection plates...EXCEPT...
If you let charge/voltage accumulate on the plates, they also repel the
incoming charges. That's why the paper discussed 1000AMPS at 0.2V.
Sounds like big numbers, but it's only 200W.
You have to hold the voltage down, or increase the magnetic field.
Getting that 0.2V converted to 12V or 120V efficiently is a non-trivial
task.
Consider the sloshing. I have no idea the waveform, so I'll just talk
about it as a sine wave. For a significant portion of the time, the
rate of flow is small and producing almost no power. If you look at the
amount of power you can get out of a sinewave with peak value of 0.2V,
I think you're talking about something like 40%. Strike one.
The ions have mass. Consider an ion in the middle of the stream.
With a DC field, you can get the ion to the collection plate...eventually.
If the direction is changing, the ion gets sloshed around in the center
of the plasma and never makes it to the collector. Depending on the
frequency of oscillation and the mass of the ion and the distances, it
may or may not make a huge difference in how many ions can be collected.
Strike two?
Reversing the magnetic field each cycle sounds easy, until you do the math.
The magnet is an inductor. If it's not a superconductor, it has lots
of resistance. And the magnetic field represents substantial stored energy.
You have to dissipate that energy and put it back in the other direction
every cycle. I can't think of a way to do that other than resonance.
So, you have a sinusoidal magnetic field that drops the efficiency more.
Although, that may mitigate the issues with having to change the direction
of the ion flow. The devil is in the details.
It may be more efficient to generate AC and use a transformer to get
higher voltage to rectify by conventional synchronous rectifier technology.
Strike three?
My guess is that, by the time you get it working, you'll find
that all the little details have reduced the efficiency too far to be
useful.
And simplicity and ease of maintenance will be far in the rear-veiw mirror.
I'm not blind to the fact that, if everybody thought like me,
there would be no technological advances at all.
Who, in their right mind, would even consider making explosions
that push things up and down making things go round and round
fueled by stuff not yet invented...with chains and levers and rods
and unimaginable complexity? ;-)
If you have a novel idea that's never before been considered, your
chances of success are very small. If your "idea" has been
worked on for a century by the best minds available, success seems
remote indeed.
Probably the reason I got fired from my last job...
I stood up in the executive staff meeting and drew a tiny circle
and a huge circle on the whiteboard.
The market wants features we can't produce, despite years of
concentrated development. We don't even have a theory that
predicts success. Best I'd done was show them a "trick"
to double the output. And it had nothing to do with technology.
We're the number one investor in our technology.
We're the small circle.
Investment in the competing technology is the big circle.
Who do you think will win?
Nobody had a rebuttal, but they really, REALLY didn't want to hear it
or quit banging their heads against the development wall.
Stock was at $20 when I was shown the door.
Last I looked, it was creeping back up toward $2.
Technological breakthrough is very different from wishful thinking.
Funding for technological breakthrough has to jump through feasibility
hoops.
Wishful thinking just requires some hype and greed.
I'm not convinced. We're talking about producing energy that's WAY, WAY
in excess of what's available by conventional chemical reactions.
It takes zero technical skill to know that it's working. A bucket of
water, a stopwatch, a thermometer and a bathroom scale is plenty accurate.
Rossi could have put one in a suitcase and taken it to my garage.
You pour water in the top.
By the time it produced 10X the amount of energy you could get
from an equivalent mass of gasoline, I'd have declared it a success.
Would never have had to look inside.
And I wouldn't have to care how it worked.
I'd just buy 'em.
Rossi is a master of obfuscation and misdirection.
Just like Stan Meyer's water car.
If stuff works, it should be easy to demo and reproduce.
>
>> LENR is a fool's errand. Don't let your wonderfully practical
>> side succumb to the fantasy side.
>
> It could be, but until I convince myself that I’m not able to make it
> practical, I’d rather explore this than play golf, shoot pool, and/or
> watch reality TV - and if it turns out that I can’t produce a practical
> LENR, I’d like to know (and share) why not.
I think you'd be better off playing golf with someone in the business
of funding Rossi and collecting commission. ;-)
>
>> Work on stuff that obeys the currently known laws of physics
>> and buy magic stuff at Home Depot after Rossi gets it working.
>
> I spend most of my working life at the bleeding edge - doing stuff that
> had never been done before - and I’ve enjoyed it so much that I’ll
> continue doing that for as long as I can.
Bleeding edge is incremental advance based on sound theory.
Bleeding edge good!
Wishful thinking based on wishful thinking bad!
Wishful thinking easily debunked is LENR.
>
> In spite of his very real contribution, I don’t think Rossi has what it
> takes to produce a practical device. I think I can build on what he’s
> done and at least add enough to move it closer.
I don't play golf, but I'll use a golf analogy anyway.
Stand at the tee taking your usual stance.
Then rotate 90 degrees around the ball and take a swing.
People who have spent decades studying physics and golf
would suggest that you can't get to the hole with that
strategy. But maybe you read that some guy named Rossi
consistently achieved a hole in one that way...but nobody
had ever seen it or reproduced it.
How many times are you gonna bang the ball into the trees?
I'm all for optimism. But when the idea instantly runs smack
into currently known theory, I start looking for something
else to be optimistic about.
LENR is a game-changer for the Earth. I hope he succeeds.
But I'm not investing in it just yet.