That last comment really seems like a promotion of perpetual motion. And at that, the engine would produce zero work output. You have yet to demonstrate any work output, not even half the power supplied. Do not confuse power supplied with power actually entering the engine.
Tom Booth wrote:A proof in experimental science is an experimental result that validates the hypothesis.
https://en.m.wikipedia.org/wiki/Scienti ... 0community.
Wikipedia wrote:While the phrase "scientific proof" is often used in the popular media,[22] many scientists and philosophers have argued that there is really no such thing as infallible proof. For example, Karl Popper once wrote that "In the empirical sciences, which alone can furnish us with information about the world we live in, proofs do not occur, if we mean by 'proof' an argument which establishes once and for ever the truth of a theory."[23][24] Albert Einstein said:
The scientific theorist is not to be envied. For Nature, or more precisely experiment, is an inexorable and not very friendly judge of his work. It never says "Yes" to a theory. In the most favorable cases it says "Maybe", and in the great majority of cases simply "No". If an experiment agrees with a theory it means for the latter "Maybe", and if it does not agree it means "No". Probably every theory will someday experience its "No"—most theories, soon after conception.[25]
However, in contrast to the ideal of infallible proof, in practice theories may be said to be proved according to some standard of proof used in a given inquiry.[26][27] In this limited sense, proof is the high degree of acceptance of a theory following a process of inquiry and critical evaluation according to the standards of a scientific community.[26][27]
I would say there is no such thing as "no" . Contradiction intended. There is such a thing as probably not, which appears stronger than maybe not.
There is no high degree of acceptance of your experiments, nor your theories. What you have so far is interesting anecdotal evidence, that you are hoping to get people to look at. Leaving your work for others to say, maybe not.
https://en.m.wikipedia.org/wiki/Anecdotal_evidence
It's a very meticulous process to do good science. It's very easy to confuse data taking with good science. Case in point: Cold fusion, Pons and Fleischmann. They took lots of data with a thermometer poorly enough to get erroneous conclusions. Conclusion: Thermometer used wrong, as it was for professor Waxman and his time machine. Probably wrong.
https://en.m.wikipedia.org/wiki/Cold_fusion
Wikipedia wrote:Criticism of cold fusion claims generally take one of two forms: either pointing out the theoretical implausibility that fusion reactions have occurred in electrolysis setups or criticizing the excess heat measurements as being spurious, erroneous, or due to poor methodology or controls.
Cold fusion appears to go against some current theories. Both maybe wrong.
You are battling both. If you go against current theory/mathematics, and practice, you'd better have stellar methods. I and others, have tried to suggest improvements to your practices, the reasons you are using, for not accepting those suggestions are, disarming your maybe wrong maybe right statements. You are going against current theory. No matter how much you think it's ludicrous, it is the currently backed up maybe right theory.
Tom Booth wrote:2. After reaching BDC and having used up 100% of the supplied heat the piston is now in a new position. The "internal energy" of the gas, however, has already returned to the condition it was in originally at TDC before heat was added.
The volume is larger and compressing it to V1 will cause the temperature to increase back up to Th and require Pin to equal Pout in doing so, unless of course DQc is rejected. In other words, the gas will get hotter during compression.
Let us look at a heat pump:
Total work input 25 Joules. Tc=300, Th=400. Qcz=MCbTc.
A: Starting at the same point as above engine Tc=T1, P1, V1, internal energy is Qcz, Tc is the cold plate. Powered expansion, Work input from electric motor, or such. The volume increases to V4, Pressure P4 is lower than P1/atmospheric. T4 would be much lower than T1 but isn't because of heat conduction. This allows DQc to be picked up keeping the temperature close to Tc, in an ideal case it would stay at Tc.* The internal gas does positive work but it is way less than the work input from the atmosphere. So requires electrical input, or such.
B: Heat is added to bring the Temperature of the gas to Th. Two ways to do this are, adding work energy Carnot compression, and, regenerator/displacer Stirling. T3=Th, P3, V3.
C: Compression stroke from V3 to V1. The gas is in conduction with the hot plate. T2 stays close to Th and T3, ideally they are the same. Compressing the gas allows DQh to be rejected by work input to the hot plate.* The atmosphere does positive work but is much smaller than the negative work the gas does. This requires work input from an electrical motor, or such.
D: Heat is removed to return to the starting point T1, V1, P1. Two ways to do this are:
1: Work output Carnot from expansion. This is where the Carnot work added is cancelled.
2: Heat is stored in the regenerator/displacer, Stirling.
Using the Carnot Theorem to calculate the maximum amount of heat transfered for temperatures of 300 K and 400 K, gives:
25 J work in, 75 J picked up from the cold plate, 100 J deposited into the hot plate. This is a COP of 4 Or 400%. Ideally.
* Real pumps will be worse, because the gas needs to be much colder than Tc to pick up heat, and much hotter than Th to deposit heat.