VincentG wrote: ↑Sat Jun 03, 2023 8:35 am
The heat going into and powering a heat engine does not due so as a result of the heat "trying to get to" the cold.
The idea that heat will be "compelled" to "flow" from a "hot reservoir" to a "cold reservoir" is way overblown.
I have to disagree here and state that the temperature difference between melting ice and room temperature may not be large enough to really demonstrate the flow. The higher the delta T the more entropy we can observe.
Take a look at this video again, which I think clearly demonstrates the direct flow of heat energy into the cold sink.
...
I'm not sure if maybe I misunderstood or jumped to conclusions about what you were trying to say here, but to maybe clarify my point about Tesla's Ambient heat engine ambition.
Tesla stated in his article, or implied that all that would be required is to carve out a "cold hole" in the midst of the ambient environment and the heat would "be compelled" to flow into that cold space in the same way water would flow into a tank submerged in a lake.
I suppose what I'm overlooking here is getting the water to flow from the lake into the tank would require some kind of conduit for the water to flow through.
A pipe.
I had my engine surrounded by insulation, but overlooked the fact that the air above the engine is also an excellent insulator.
My disappointment in the performance of the engine stemmed from my expectation that the top of the engine completely exposed to "ambient heat" would result in a virtual "waterfall" of heat into the engine causing it to run quite vigorously. Instead it ran, barely, as if submerged in molasses.
Compared with an engine running on hot water, the video of the engine running on ice looks like it was filmed in slow motion.
I experimented with putting a big aluminum box on top of the engine and even putting an electric fan nearby to keep the air circulating which helped a little. The speed of the engine could be increased by hitting the top of the engine with a hair dryer but, I did not get the impression that there was any real
pressure, so to speak "compelling" the heat in the room to flow down into my artificial "cold hole" passing through and powering the engine in the process. The engine just sat in a pool of cold and could barely be coaxed into running at all.
Maybe what was needed is a better "pipe" an effective heat pipe that could transfer the heat to the engine, or perhaps putting the ice
ON TOP of the engine would work better.
Actually, at one time I did try this. I insulated the engine on top, leaving a compartment for an ice cube so the ice could be placed under the insulation on top of the engine. The bottom of the engine was left exposed to the ambient heat. This actually worked so well I got rather excited about it and carried the engine upstairs to show my wife.
As I tried to explain what was going on the engine which had been running rather vigorously very suddenly seized.
My wife, looking on as I muttered WTF said "maybe it froze up again".
I carried the engine back downstairs to investigate but can't really confirm what caused the piston to suddenly jam up but it was somewhat reminiscent of an earlier apparent freeze up.
This engine in the below video apparently froze up just sitting on the ice as a control not running at all.
https://youtu.be/fnxC8hymFLU
The engine I was showing my wife with the insulation and ice on top seemed to be "stuck" in the same way but unfortunately I was just fooling around at the time and did not get it on film.
By the time I got downstairs and removed the insulation the engine had come unstuck and the ice was starting to melt. The engine did not seem to want to run until I dried it off and let it warm up for a while, I did eventually get it running again, (on hot water).
I can't be sure if this is actual freezing or just the aluminum cylinder contracting from the cold and locking up the piston. Either way, not enough heat going in through the bottom of the engine remained to prevent the piston from "freezing up" from the cold at the cylinder which is rather surprising as the ice was a distance away, separated from the cylinder by about 1/2 inch of insulation. Also the ice WAS melting. The (apparently extreme) cold seemed to be confined to the area of the power piston. Or maybe it had to do with contraction of the aluminum cylinder, contracting more than the graphite piston. Anyway I thought further experiment was pointless, unless I could figure out what was causing this "freez-up" and devised some means to prevent it.
Anyway, I think heat dispersal is random in all directions. As a result the hot space or object is cooled down as much as the cold space is warmed as a gradual equalization takes place.
In a way you could just as well say that the cold "flows" towards the heat.
That heat actually makes a beeline for the cold creating a direct "flow" that can be intercepted to extract energy from like a paddlewheel in a river is I think, generally false. The heat disperses like billiard balls in a break, randomly in all directions.
In a "fluid" (gas or liquid) cooled air molecules travel back towards the heat source just as readily as hot molecules travel towards the cold. There is no directional, one sided "flow" of heat towards cold.
Maybe if the heat were confined to traveling through a heat conductor in some way but like a copper electric wire, the conductor would need to be insulated.
Controlling and directing the heat flow is not just a matter of letting it happen because the heat is in some way "compelled" to move towards cold.
It is more like the hot and the cold mutually dilute or flow into each other to become warm, unless, of course, one or the other is really overwhelmingly hot or cold, or the quantity of one is much greater than the other, but then the cold could just as well "overpower" the heat as the other way around.
In your video, what it looks like to me is that there isn't much movement of heat (or cold) one way or the other unless you
make it move by lifting or lowering the displacer.