Should ice take longer to melt when used to run a heat engine?

In summary: From what I've seen of Stirling engine models, they are just demonstrators of the concept without any real energy production.So to better test the issue you should run the experiment with a load applied to the engine.
  • #71
sophiecentaur said:
You problem is that you are trying (hoping) to show something surprising about regular Science. That puts the onus totally on you to make your experimental method way above reproach and you risk ending up amongst all those other Youtube posters. You have set your bar very high indeed.
I'm not sure that is his true intent. I think the OP is more likely to show off a peculiarity of a stirling engine (or indeed this particular design of stirling engine) than anything else. I have never had such a device in my hands and so I feel a bit in the weeds. Seems he is being very careful about making general claims.
Heat experiments are always time consuming and finicky and then there is always some reason they need to be repeated (endlessly). Good luck!
 
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  • #72
sophiecentaur said:
These engines out in the desert don't have any water cooling system, not much of any real "sink" to take away all that heat of a thousand suns being driven directly into them.
Why do you think that? Here is a document describing one such system, and here is another one eg. describing five systems. In each case there is a description of the cooling system e.g. SAIC Arizona "Heat rejection from the engine is provided by a water/glycol cooling system that uses standard radiators and a cooling fan."

Edit: and some data
  • Thermal power into engine 31.63 kW
  • Stirling shaft power 12.25 kW
  • Thermal power out 18.53 kW
So for every 2 W of useful work we get out of this system we have to dump 3 W of useless heat energy in the desert.
 
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  • #73
sophiecentaur said:
10/10 for effort there - respect!
I have no argument with you or what you're doing - as long as you are looking for valid results and valid explanations. I think the whole thing would be resolved if you do a truly comprehensive and well controlled experiments. Where there appears to be some contradiction of the laws of thermodynamics, it has to be somewhere in the experimental details and, indeed in what you are actually measuring.
There are so many ways in which heat can transfer from hot to cold sink and, slowing down that rate can be due to what I could call 'active insulation' - for instance, where natural convection is resisted with a fan.
One suggestion I could make would be to measure the Heat Input as well as the Output into the ice. Measuring the electrical power needed in a very well insulated hot sink, to keep it at a chosen temperature could take care of the huge unknown about the contribution of the surrounding air in the room. That would supply the other half of the required information in the heat flow equation.

Controlling/measuring the heat input and output would certainly be interesting.

Insulating the hot side of the engine with a thermostatically controlled heat source would be largely meaningless, though, without also controlling the outside ambient temperature, or room temperature. Even a vacuum insulation is not perfect.

Right now, I don't even have air conditioning in the house, so I'd need the heat source insulated within a climate controlled room. As the engine, when running cold "sweats" rather profusely, humidity would need to be controlled and recorded, possibly barometric pressure, sun spots, moon phases, astrological influences?

I'm doing this because it is fun and interesting. These engines are inexpensive and there really isn't any other way I would rather be spending my time.

Personally, I consider there to be nothing sacred in this endeavor. Carnot thought heat was literally a fluid. Carnot was wrong. I'm not out to disprove established science, but I have no investment in the second law of thermodynamics either.
 
  • #74
For serious examples of practical engines; built and tested to handle hundreds of HP; at over 1000 RPM; using compressed H2 or He as the expansion gas; with water cooling; see;
NASA Technical Reports Server (NTRS) 19830022057: Stirling engine design manual, 2nd edn
https://archive.org/details/NASA_NTRS_Archive_19830022057
 
  • #75
Tom Booth said:
Carnot was wrong.
Maybe. Maybe not.
To the extent that relativity tells us hot thing are more massive than cold ones Carnot was in fact correct. It is the caloric.
It serves us ill to criticize thinkers of great thoughts for not being perfect.
 
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  • #76
pbuk said:
Why do you think that? Here is a document describing one such system, and here is another one eg. describing five systems. In each case there is a description of the cooling system e.g. SAIC Arizona "Heat rejection from the engine is provided by a water/glycol cooling system that uses standard radiators and a cooling fan."

Edit: and some data
  • Thermal power into engine 31.63 kW
  • Stirling shaft power 12.25 kW
  • Thermal power out 18.53 kW
So for every 2 W of useful work we get out of this system we have to dump 3 W of useless heat energy in the desert.

So, there are systems in some locations that have water cooled engines. I don't claim to know everything about every system. All I know is about 20 years ago my friend, a military government contractor familiar with solar Stirlings at that time said those dish Stirlings they were testing out in the desert were cooled with air conditioners.

It isn't the type of cooling, but when and why the cooling was needed, or when the need for air conditioned cooling was greatest, when the load was reduced.

With a load, the engines ran cooler. That is the only point I was trying to make.

The guy wanted air conditioning on his back yard Stirling dish generators he was planning on building. Or thought it would be necessary, so I looked into it.

The engines run cooler and need less cooling when under a load. If the load is reduced, the engines can overheat.

So I spent several months on the project doing research into all this and stayed up late nights designing Stirling engines, then my friend had a change of plans, so after that it became my own hobby of sorts.
 
  • #77
hutchphd said:
Maybe. Maybe not.
To the extent that relativity tells us hot thing are more massive than cold ones Carnot was in fact correct. It is the caloric.
It serves us ill to criticize thinkers of great thoughts for not being perfect.

Wow, so, are you saying you still adhere to the caloric theory of heat?

I don't think it serves us well to cling tenaciously to outmoded conceptions. It makes people refuse to look and observe when there might be something new to learn, or discover a different way of perceiving things.
 
  • #78
hutchphd said:
I'm not sure that is his true intent. I think the OP is more likely to show off a peculiarity of a stirling engine (or indeed this particular design of stirling engine) than anything else. I have never had such a device in my hands and so I feel a bit in the weeds. Seems he is being very careful about making general claims.
Heat experiments are always time consuming and finicky and then there is always some reason they need to be repeated (endlessly). Good luck!

Since my motives seem to be in question here, I may as well spell it out in detail, (trying to keep it as brief as possible).

I mentioned my government contractor friend. Well I did complete a tentative engine design.

One of the design goals was reduction in the size of the parabolic dish. ( It had to fit in a back yard and be unobtrusive.) The long and short of it was, I ran hundreds of designs in my head, making modifications and improvements until I had this final version that virtually eliminated the dish entirely. It even worked at night, as it did not run directly on concentrated sunlight that had to strike the engine directly. What I came up with was a kind of open cycle refrigeration system that used air as the refrigerant. I'll skip trying to explain how it worked. I can just say that my friend ran it by his associates in the DOA and next time I spoke with him he told me the verdict. They told him it was impossible. After that he became discouraged and dropped the whole idea.

I continued work on this theoretical engine anyway, for years, and years. Then in the course of my research I happened across an article by Nicola Tesla, published in 1900 that described my engine and the working principles behind it, and why he believed it would work. He even worked on building such an engine, up until his workshop burned down.

One of Tesla's assertions was that an engine running on an artificial cold "sink" would not necessarily quickly dissolve the sink by delivering heat to it, because heat is not a fluid but a form of energy and a heat engine converts heat into other forms of energy. In essence he posited that a heat engine running on an artificial "cold hole" , if very efficient, would take longer than might be expected to fill the hole with heat, and in the process destroy the sink, because heat did not pass directly through the engine, as was, at the time the generally established wisdom. Rather, heat was energy that the engine converted to other forms of energy, so that some percentage of the heat did not end up at the sink.

Naturally, the more efficient the engine at converting heat into some other form of energy, the longer the sink would last and the longer the engine would run.

Of course, Tesla's paper was presumably ignored for the most part. It was a conscious direct assault on the postulates of established science of the time.

Low temperature Stirling engines did not exist back then, but in this experiment, such a little engine serves quite well as a means of testing Tesla's mostly long forgotten ramblings. And also might lessen the sting of having all my hard work designing an IDEAL Stirling heat engine rejected. Perhaps my engine design was not so "impossible" after all.

Anyway, though I have some personal interest in the outcome of these experiments, I've tried very hard to avoid the temptation to put my thumb on the scale, but I can't be absolutely certain I'm not doing something, even unconsciously to skew the results.

Personally, when I did the first experiment, taping insulation over the "sink", I fully expected that the engine would come to a halt almost immediately. Instead it ran like 90 minutes longer than the same engine without insulation over the sink.

I had surmised that IF Tesla's assertions were right, that a heat engine mostly converted heat into motion rather than delivering all the heat to the sink, the engine might actually continue running for a little while. But if my own idea, that these engines actually can not only not deliver heat to the sink, but actually produce some cooling, well then maybe it would run a little better if ambient heat were prevented from reaching the sink.

The video recorded the results.

Does anyone else viewing that video clip see what I see? With insulation covering the sink, did the engine continue running, and at that, did it run just a wee bit faster than it was running without the insulation?

As I said in the beginning, I'd love it if anyone else would repeat these simple experiments, with better controls and unbiased objectivity. More stringent controls, whatever. These engines are pretty inexpensive, I'll even foot the bill and have the engines sent to your door.

So does anyone want to take a stab at explaining why a little Stirling engine running on a cup of hot water appears to run a little better with the sink insulated?
 
  • #79
One reason I have not been able to run concurrent experiments as yet is the last time I got supplies at the hardware store, they were limited in their supply of nylon bolts.

Today, when I went there again, they had restocked the supply.

The reason for modifying the engines by using nylon bolts, if it isn't already clear, is to reduce heat loss. Since one engine has them, I think the "control(s)" should also have them, as, I'm not testing anything directly related to the bolts, it is just an obvious improvement to the efficiency of these engines.

The nylon bolts are thicker than the steel bolts that came with the engines, so it does involve some drilling out holes, aside from normal assembly.

I can't promise that I won't get carried away and end up making more modifications while I'm at it.

Maybe with some modifications the next engine will run 60 days on the same cup of ice, until the bearings wear out or something. Not likely.
 
  • #80
Tom Booth said:
It was in trying to understand the thermodynamics involved in such engines that got me to wondering how the load on a Stirling engines managed to keep it running cool.
Tom Booth said:
The engines run cooler and need less cooling when under a load. If the load is reduced, the engines can overheat.

Stirling Engines are not different in they respect; it applies to all systems in which the Power Input is not regulated in the way IC engines work. Your truck gets hot under load because you are putting more fuel in. Solar heating and Nuclear Power stations suffer from the same problem when the load is removed. Over heating can occur in IC engines when the timing is wrong and the efficiency has been compromised; for the same power output, you have to put your foot down further and the radiator has more waste heat to deal with.

I have always been surprised that Solar Energy systems don't just use shutters to control the Power input when it becomes an embarrassment. However, with a low efficiency engine, there is always the problem of dumping the waste Power - even when operating at maximum load.
 
  • #81
Tom Booth said:
Of course, Tesla's paper was presumably ignored for the most part. It was a conscious direct assault on the postulates of established science of the time.
Oh dear. I just read this. Can you really think that, in the last 120 years, no one would have utilised all of Tesla's ideas if they actually had legs? (AC has legs of course. ) What you have written comes under the heading 'Conspiracy Theory' and is consequently of no interest to me, unfortunately. I'm out if this conversation.
 
  • #82
sophiecentaur said:
Oh dear. I just read this. Can you really think that, in the last 120 years, no one would have utilised all of Tesla's ideas if they actually had legs? (AC has legs of course. ) What you have written comes under the heading 'Conspiracy Theory' and is consequently of no interest to me, unfortunately. I'm out if this conversation.

Wow.

I guess your gone, but I'll ask anyway: what do you consider "conspiracy theory" in that statement you quoted?

In his own words, from Tesla's paper:

I was vainly endeavoring to form an idea
of how this might be accomplished, when I
read some statements from Carnot and Lord
Kelvin (then Sir Wilham Thomson) which
meant virtually that it is impossible for an
inanimate mechanism or self-acting machine
to cool a portion of the medium below the
temperature of the surrounding, and operate
by the heat abstracted. These statements
interested me intensely. Evidently a living
being could do this very thing, and since the
experiences of my early life which I have
related had convinced me that a living
being is only an automaton, or, otherwise
stated, a " self-acting engine," I came to
the conclusion that it was possible to con-
struct a machine which would do the same.
As the first step toward this realization I con-
ceived the following mechanism...

I think it is quite plain and obvious to anyone with any background or reading on thermodynamics that Tesla is diving headlong into a refutation of what is known today as The second law of thermodynamics.

He goes on to elaborate in detail, why Carnot's and Lord Kelvin's postulates do not hold under all circumstances.

One of those circumstances he elaborates on at length is when a heat engine runs on a manufactured "cold hole".

Reading his paper, I realized Tesla's assertion could be easily disproven experimentally. What he was basically talking about, in modern terms, would be a Stirling engine running on ice. Anyone should be able to easily find half a dozen or more examples on YouTube of Stirling engines doing just that.

But does a Stirling engine running on ice actually have the ramifications Tesla elaborated on? Would it bring down Lord Kelvin's and Carnot's postulate like a house of cards?

Not likely. But that certainly was his intent wasn't it?

So, has Tesla's logical demolition of the second law been universally embraced by all?

I don't see that it has, or I certainly would not be wasting time and money on these experiments.
 
  • #83
Another consequence of Tesla's rambling, or, let's call it a factor or element of his proposition would be that a heat engine would have to be able to run without passing much if any heat from source to sink.

Again, that Tesla's idea is demonstrably impossible and rediculus on its face can easily be proven by simply insulating the cold side of the engine or "sink" and watch the engine immediately grind to a halt.

I did the experiment and posted here the video of the result.

Well,...?

I assumed the engine with the sink insulated would quickly run down and stop without an outlet for the heat to pass through.

Annoyingly, that did not happen. What did I do wrong? Why did the engine continue running? I poured scalding hot water from the tea kettle into a $5 Dewar flask (of sorts) and put a less than $30 model Stirling engine on top, (insulated so the heat could not leave the engine through the "sink". Or presumably not much) This TOY is not any 100% efficient engine, I thought it should have stopped running, easily demonstrating the fallasy of Tesla's plan.

Before placing the insulation on top the top plate of the engine it felt relatively cool considering there was scalding hot water under it. It felt,.. about room temperature.

With the insulation on top? How hot (or cold?) Did it get?

I don't know. I neglected to put a temperature probe in there, but from the response of the engine, it seemed to run slightly faster. I do know it ran about an hour longer than it ran on hot water previously, without the insulation on top.

I'm not claiming any violation of thermodynamics. I just ran the experiment,
in a mostly skeptical frame of mind as I could not find any record anywhere of any such experiment ever having been conducted before.

If there were some such record of any such previous experiment I certainly would not have bothered with it.
 
  • #84
Just to be clear what experiment I'm referring to:



This engine is running on hot water poured from a boiling tea kettle. The cup is vacuum insulated.

I had a friend with a stop watch (phone app) help me time the RPM of the engine at the beginning of the experiment, (before the "sink" was covered with insulation) Vs. the RPM towards the end of the video, (after the sink was insulated, with the insulation taped tightly down, with no apparent leaks that I could see)

RPM without sink insulation: 162
RPM with the sink insulated: 180

That is an increase in RPM of about 18 revolutions per minute, give or take a revolution or two, but I think that is a fairly accurate count.

Anyone, please feel free to check that
 
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  • #85
A machine that violates the second law of thermodynamics is a perpetual motion machine. I understand why you don't want to use those words, but that doesn't change what it is.
  1. The number of backyard inventors who think they have built such a thing is large.
  2. The number who have actually done so is zero,
  3. The fraction who invoke Tesla is also large. But that does not invalidate point 2.
 
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  • #86
Vanadium 50 said:
A machine that violates the second law of thermodynamics is a perpetual motion machine. I understand why you don't want to use those words, but that doesn't change what it is.
  1. The number of backyard inventors who think they have built such a thing is large.
  2. The number who have actually done so is zero,
  3. The fraction who invoke Tesla is also large. But that does not invalidate point 2.

Well it clearly wasn't a perpetual motion machine. It stopped when the water cooled down after about three hours.

I never claimed it violated any laws of thermodynamics. I honestly don't think it does.

As I said, I just ran the experiment.

Other than replacing the metal bolts holding the engine together it is a stock engine. Assembled according to the directions.

I didn't build anything, I just assembled a $37 kit, like anyone could. And ran a simple experiment.

https://www.stirlinghobbyshop.com/e...irling-engine-ja-828/#cc-m-product-9759217783
 
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  • #87
Tom Booth said:
Of course, Tesla's paper was presumably ignored for the most part. It was a conscious direct assault on the postulates of established science of the time.
Nikola Tesla got some things right and much very wrong. Since then he has been misrepresented by conspiracy theorists who don't understand science. Avoid mention of Tesla unless it is essential, or you will be associated with conspiracy theorists.
https://en.wikipedia.org/wiki/Nikola_Tesla#On_experimental_and_theoretical_physics
 
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  • #88
Tom Booth said:
Well it clearly wasn't a perpetual motion machine. It stopped when the water cooled down after about three hours.

I never claimed it violated any laws of thermodynamics. I honestly don't think it does.

As I said, I just ran the experiment.
What you believe isn't very clear to me because several of your posts do seem to be advocating Tesla's view that it is possible to create a cold sink while extracting work at the same time. But PF does not discuss perpetual motion machines even for the purpose of debunking them, so either way, unfortunately this thread will need to be closed. It's a shame because I'm a big fan of people doing their own experiments and I commend you for the effort you put into it.

Postscript/summary; I think the group basically reached a consensus that the outcome of the experiment is more based on "flaws" in the machine than general thermodynamic principles. E.G., it can't be said that in general a stopped turbine/engine will pass energy slower or faster than a running unloaded one or a running loaded one. Different machines and setups can produce different results. But those results will always be consistent with the laws of thermodynamics, so one should never conclude that what they are seeing contradicts the laws of thermodynamics, but instead should interpret the results from within that existing framework.
 
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<h2>1. Why would ice take longer to melt when used to run a heat engine?</h2><p>This is because the heat engine is using the ice as a source of cold temperature, which means the ice is absorbing heat from the surroundings to maintain its low temperature. As a result, the ice will take longer to melt as it needs to absorb more heat to maintain its temperature.</p><h2>2. How does a heat engine use ice to produce work?</h2><p>A heat engine uses ice as a source of cold temperature to create a temperature difference between the hot and cold reservoirs. This temperature difference is then used to produce work through the expansion and contraction of a working fluid, such as steam or gas.</p><h2>3. Can any type of ice be used to run a heat engine?</h2><p>Yes, any type of ice can be used as long as it is able to maintain a low temperature. However, different types of ice may have different melting points, which can affect the efficiency of the heat engine.</p><h2>4. Is using ice as a source of cold temperature more efficient than using other substances?</h2><p>It depends on the specific application and the efficiency of the heat engine. In some cases, using ice may be more efficient as it is readily available and does not require additional energy to create a cold temperature. However, in other cases, using other substances such as liquid nitrogen may be more efficient.</p><h2>5. What are the potential limitations of using ice to run a heat engine?</h2><p>One potential limitation is the availability of ice, especially in warmer climates. Another limitation is the melting point of ice, which can limit the temperature difference that can be achieved in the heat engine. Additionally, the efficiency of the heat engine may be affected by the type and quality of the ice used.</p>

1. Why would ice take longer to melt when used to run a heat engine?

This is because the heat engine is using the ice as a source of cold temperature, which means the ice is absorbing heat from the surroundings to maintain its low temperature. As a result, the ice will take longer to melt as it needs to absorb more heat to maintain its temperature.

2. How does a heat engine use ice to produce work?

A heat engine uses ice as a source of cold temperature to create a temperature difference between the hot and cold reservoirs. This temperature difference is then used to produce work through the expansion and contraction of a working fluid, such as steam or gas.

3. Can any type of ice be used to run a heat engine?

Yes, any type of ice can be used as long as it is able to maintain a low temperature. However, different types of ice may have different melting points, which can affect the efficiency of the heat engine.

4. Is using ice as a source of cold temperature more efficient than using other substances?

It depends on the specific application and the efficiency of the heat engine. In some cases, using ice may be more efficient as it is readily available and does not require additional energy to create a cold temperature. However, in other cases, using other substances such as liquid nitrogen may be more efficient.

5. What are the potential limitations of using ice to run a heat engine?

One potential limitation is the availability of ice, especially in warmer climates. Another limitation is the melting point of ice, which can limit the temperature difference that can be achieved in the heat engine. Additionally, the efficiency of the heat engine may be affected by the type and quality of the ice used.

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