"efficiency depends only on the temperature of the hot source and the cold sink." Or:
Random source: https://energyeducation.ca/encyclopedia ... efficiency"The maximum efficiency, known as the Carnot efficiency ηmax, is dependent only on the temperatures of the hot source and the cold sink TH and TL, as shown in Figure 1, and is given by the equation below[3]
(1)
ηmax=1−TL/TH"
So, in theory, (more generally, accepted as actual fact), a Stirling engine should run just as well or even more efficiently when the temperature difference is greater, even though lower on the temperature scale.
In other words, the engine should, in theory, run just as well on COLD as it does on heat because efficiency depends "ONLY" on the temperature difference
Now I have done numerous experiments running Stirling engines on ice, (or more accurately, on ambient heat), and felt some satisfaction at my cleverness, however, I cannot say truthfully, that I have ever been particularly impressed by the performance of these engines running on COLD rather than on HEAT.
They always, inevitably, seemed rather slow and sluggish.
I tended to write this off as due to mechanical issues.
Probably the shrinkage of the power piston due to the unusual cold caused a loss in compression. I would think, with a furrowed brow. A tighter fitting piston should remedy the problem
Or, the lubricant used may be to blame. The graphite, oil or whatever simply does not perform well at low temperature. Some other method of lubrication should solve the problem.
Or there is not enough air circulation. Adding some small fan blades or paddles to the flywheel could move more air past the engine, so the engine gets more heat flow and runs better.
The idea that there might be something wrong with "established science", the theory behind thermal efficiency or the basic assumption of the efficiency formula, or the mathematics of the formula itself, tended always to escape blame.
Well thinking more deeply about it recently, I think that maybe a Stirling engine tends to run a little sluggish and slow "on ice", (even in spite of there being a greater temperature difference, in many cases), for another reason, which, now that I think about it, seems pretty obvious, and I'm not really sure why I did not realize this before
Cold gas molecules move more slowly and have less energy than hotter gas molecules.
So a quantity of gas working between, say 300 and 400 Kelvin does not impart the same energy to the engine as a working fluid operating between 200 and 300 K.
Or does it?
Well, logically, if heat is the transfer of "vibration" or motion between molecules, or the transfer of kinetic energy, then naturally a hotter gas contains more kinetic energy than a colder gas Right? Or does it?
Well, a colder gas is more dense so... maybe it averages out or something,...
Nevertheless, I have to admit that experimentally, it has not really appeared to me that a Stirling engine runs just as well on a ∆T lower on the temperature scale. It just doesn't. At least that has been my experience
Same as far as dozens of YouTube videos I've watched of Stirling engines running on ice, dry ice, liquid nitrogen or some other COLD source. The performance is generally not all that impressive.
Admittedly though, I have never done any carefully controlled experiments to address this specific question, but has anyone, ever?
Not that I'm aware of. Mostly it seems to just be taken as established fact. It is NOT heat that powers a Stirling engine, it is the temperature difference.
But is this really true?
Would a heat engine REALLY run better or more efficiently between 0 and 100 K where the gas molecules are nearly motionless, than between 1000 and 1099 K ?
What does the math say ?
Does the math really reflect reality?0 to 100 = 100% efficiency
1000 to 1099 = 9% efficiency