[invest_in_politics]

I forgot to address SolarDave's assertion

$this->bbcode_second_pass_quote('', 'A')NY work done is done at the efficiency of the engine, including "powering" the contraption that "relieves" the engine of it's compression dutues.

[invest_in_politics]

Sorry for the intervening post!

Your assertion that

$this->bbcode_second_pass_quote('', 'C')ompression work does not consume the level of energy the inventor claims to recover from it, even if 100% of it was recovered (impossible). The inventor is claiming to recover more energy than is actually used.

[SolarDave]

$this->bbcode_second_pass_quote('invest_in_politics', '
')$this->bbcode_second_pass_quote('', 'Y')ou can't "eliminate the compression work." It's nonsense.

[Caoimhan]

The counterweight analogy is the best yet.

You see, in the paper by Tinker, he starts by pointing out that there are 2 sides to a piston... 1) The compression chamber side and 2) the crank-case side. The crankcase side in a regular engine operates at how much pressure? You guessed it... 1 atm. But the compression chamber side works best at high compression... ideally at 17:1.

Right now, engines are designed so that some of the work on a previous cycle must be retained (such as in a flywheel), to help provide compression for the next cycle. Every cycle, the engine has to work from a "baseline" pressure of 1 atm to achieve whatever compression is desired in the compression chamber.

What if the baseline pressure were 10 atm instead of 1? What if you had 10 atmospheres of pressure "pushing" on the crankcase side of the piston? With the higher baseline, less energy needs to be retained from cycle to cycle to achieve the target compression on the compression side.

That's what his "conservative force" is doing. It's a force that's completely unrelated to the engine power. It exists whether the engine is running or not. It's just a force that raises the baseline... just like a counterweight.

[SolarDave]

$this->bbcode_second_pass_quote('Caoimhan', 'T')he counterweight analogy is the best yet.

What if the baseline pressure were 10 atm instead of 1? What if you had 10 atmospheres of pressure "pushing" on the crankcase side of the piston? With the higher baseline, less energy needs to be retained from cycle to cycle to achieve the target compression on the compression side.

[invest_in_politics]

$this->bbcode_second_pass_quote('', 'C')ompression of the air fuel mixture requires work ON TOP of the work to move the piston.

[Caoimhan]

Oh, and by the way... once the starter motor has overcome the inertia to achieve a certain RPM in the engine, it only needs to have enough juice to overcome friction... because in a multi-cylinder engine, the energy needed to reverse the momentum of a single piston at either end of its stroke is provided by the inertia of other pistons in the middle of their strokes.

If you attached a hand crank to the crankshaft on an engine without the cylinder heads bolted down, you have equal pressure on both sides of the pistons. Turning the engine with that hand crank would be easy, once you got it going. Getting it moving in the first place would be the hard part.

By having a "conservative force" counterbalancing the compression in the cylinder, we achieve the same thing. Pressures are balanced on either side of the cylinder... and once again, with a hand crank, we should have a smooth, easy rotation through the complete cycle. It should feel exactly the same as with the engine head removed.

One nice side effect of using Tinker's suggested method in an engine would likely be greatly reduced vibration and noise.

I understand that this is all a bit tough to understand at first... but reading the full article and discussion on greencarcongress.com as well as Tinker's whitepaper (even if you don't follow all the math) should give just about anyone enough to go on.

[SolarDave]

Engines are air pumps.

What you say is nonsense. Take the cylinder heads off and they are no longer air pumps. Of course they spin easier! Taking out the spark plugs accomplishes the same thing.

Go grab a socket wrench, go out to your car, and turn the engine. It will not "get up to speed" and it will not subsequently need less effort. Stop arguing theoretically. Go try it.

Your idea of a counterbalancing force would resist downward motion of a piston, reducing engine power.

Here is an experiment a 6 year old can understand.

Get a tire pump. Don't have one? Go buy one, it's worth it for the education.

Hook it to a tire. Start pumping. Hard work, eh? Here's an idea! Put a brick on the handle at the top of the stroke. Genius! It's a "conservative force" - look how much easier it was to push that handle down. But wait!?!?!!? WTF?? It's HARDER to lift it back up again! Nothing has been gained at all.

You guys are dreaming - the piston, rods and crankshaft are like the brick. In the absence of friction and compression, they would spin forever once set in motion. OK, pretend there is no friction. Now - where is the work going to come from to compress the air - it actually is moving THROUGH the engine, you know, not just sitting there like an air spring. Think a bigger brick will make filling the tire any easier? Try it and report back.

The work to move the piston is given by

W(z) = Integral(F(z')dz',z0,z)

Yawn. That is not the whole story. That equation only calculates the work in one direction.

Here is the equation to move it in the other direction ("A" term is negative):

-F(V) = ma + p0*-A*(z0/z)^g

resulting in (surprise!):

W(z) = Integral(F(z')dz',z0,z)

Get it now?

[Caoimhan]

No, I don't get it... YOU don't get it.

Yes, an engine is an air pump in reverse, if you want to put it into those terms. Instead of putting mechanical energy in to compress air, you're using heat to expand the air to get mechanical energy. But this is an air pump that works at its most efficient in a certain range of pressures within the chamber. To get up to the minimum chamber air pressure for optimum operation, you can either use a portion of work from the engine, or you can have that pressure be its natural, at rest state.

Let's go back to the counterweight on the pole with the bucket... from what you're saying, we're better off without a counterweight, and fighting the bucket's weight all day long.

With a counterweight that balances the bucket perfectly, when the bucket is empty, all the work we have to put in is to overcome the inertia as we move it around... not the weight... and when the bucket is full, ALL we're lifting is the weight of the water instead of water+bucket, because bucket weight is still cancelled out.

It doesn't get much simpler than this. In this analogy:
bucket = base chamber pressure
water = work done by the engine during the power stroke
counterweight = "spring" (or other conservative force).

[invest_in_politics]

I believe that what we have here is a phenomenon primarily associated with theory known as an essential disagreement, i.e., a disagreement which cannot be resolved through argument. The reason that such disagreements are usually theory-related is that experiments do not frequently provide fertile ground for debate of their findings (although debate over the explanation of experimental results is another story!). I have learned over time that essential disagreements are simply a waste of time to debate beyond some reasonable cutoff point. That cutoff, for me, is now.

Essential disagreements are not bad, they just are. Fortunately in this case it will be quickly dispelled by experiment. When the author of the theory or someone else configures an engine as the theory dictates, either it will exhibit improved efficiency or it will not and the debate will be academic. Until then, I will be a proponent of the theory and I suspect SolarDave will be equally unswerving in his opposition. Whatever the outcome, I look forward to the results of such an experiment.

IIP

[SolarDave]

$this->bbcode_second_pass_quote('Caoimhan', 'N')o, I don't get it... YOU don't get it.

Yes, an engine is an air pump in reverse,

It doesn't get much simpler than this. In this analogy:
bucket = base chamber pressure
water = work done by the engine during the power stroke
counterweight = "spring" (or other conservative force).

[SolarDave]

Well said, invest_in_politics. And I should lay off the coffee, I know

Proof is in the working model, as you say. Theories are, well, theories.

[SolarDave]

$this->bbcode_second_pass_quote('invest_in_politics', ' ')The Newtonian equation of motion for the piston is

F(V) = ma + p0*A*(z0/z)^g

where m is the mass of the piston, a is its acceleration, p0 is the pressure at bottom dead center (BDC), z0 is the enclosed length of the cylinder at BDC, z is the instantaneous enclosed length of the cylinder, and g is the ratio of specific heats of the fuel-air mixture.

[invest_in_politics]

$this->bbcode_second_pass_quote('', 'T')he remaining terms are:

A - area of the piston
V = velocity of the piston?

[Caoimhan]

$this->bbcode_second_pass_quote('', 'P')lease explain how the spring and the flywheel are storing different energy and doing different things with it.

[invest_in_politics]

$this->bbcode_second_pass_quote('', 'P')lease explain how the spring and the flywheel are storing different energy and doing different things with it.

[Caoimhan]

Thanks.

I knew I was understanding it correctly, but wasn't using the formal language for these concepts quite right.

I'm in the process of making a graphic illustration using the "lever to lift water with a conservative counterweight vs. using lifted water as the counterweight".

[Caoimhan]

Here they are:

http://members.dslextreme.com/users/cao ... stroke.gif

http://members.dslextreme.com/users/cao ... stroke.gif

These are extremely simple illustrations of the principle.

[invest_in_politics]

I thought that there may be people interested in the status of this. Dr. Tinker has just had a paper published in the "International Journal of Energy Research" entitled "Occult Parasitic Energy Loss in Heat Engines". You can find it here: http://dx.doi.org/10.1002/er.1312

IIP

[kmann]

IIP,
Your link doesn't appear to work.