CPU Convective Water Cooling 267
biso writes "The possibility of cooling a CPU with gravitational convective flow of water is here analyzed and experimented with positive results.
Many liquid cooling systems have been experimented by overclockers to better dissipate the heat from CPUs. The major part of these coolers is characterized by a relatively complex system requiring pumps or other active devices. Sometimes even liquid nitrogen is used. I built a simpler cooler, able to dissipate the same heat flux of a normal heatsink."
/. effect (Score:5, Funny)
Re:/. effect (Score:5, Funny)
I'm just impressed with a big bowl of water balanced on top of a open tower case. Now THAT takes balls.
The guy obviously doesn't have cats or any other pets.
liquid and open cases (Score:4, Funny)
Since my case has to sit on top of my desk, this also gives me a little more space to put stuff (inside the case, out of the way of boards / wires etc).
What do I keep in there? First is the reciever for my wireless keyboard / mouse [gyration.com], the syncing cradle for my handspring visor edge, and a few important papers. Those are the things that don't really move.
The fun things in there are the mountain dew beer glass, the caffeine shot glass, and usually 2 - 3 open cans of dew. All have soda / caffeine in them and are actively used.
No, nothing has spilled yet, and yes, I do have cats. 3 of them. They know that if they go near the sacred tower, they get stuff thrown at them (usually a slipper, but on occasion a t-shirt if I find that first).
On a side note: I in no way have the balls to water-cool my case, other than replacing the cold soda every 30 minutes.
Re:/. effect (Score:2, Informative)
Re:/. effect (Score:2)
Re:/. effect (Score:5, Funny)
<offtopic>That reminds me -- a few years ago, I went out of town for a few days, and when I got back my old P200 refused to boot. I yanked out cables and cards in an attempt to get the old beast up and going again, and when I yanked out the sound card, it booted. Well, I put everything back together, and then looked closer at the sound card.
It had a nice, dried puddle of mouse piss on it, so I put it aside and waited for the next opportunity to grab another one.
I thought (after I'd gotten another one) that I should have called Dell tech support and discussed the problem with them:
(them) "Hello, <speil>"
(me) "Yeah, I've got a mouse problem."
(them) "What seems to be the problem?"
(me) "Oh, it sort of pissed on my sound card."
</offtopic>
Transformer Oil - Electrical & Thermal Propert (Score:5, Informative)
Nah... I'd use transformer oil, and I don't think a Lipton Cup-a-Soup would taste quite the same.
Transformer oil, however, is probably quite suitable for use in a CPU cooling system.
It has a higher breakdown voltage than air and is almost infinitely less conductive than real-world (ie. impure) water. Transformer oils are specifically designed for use as an insulating material in large power distribution transformers. Electric utility transformers at power substations, operating in the range of hundreds of thousands of volts, would arc between windings if the oil leaked out of them and air - with its lower breakdown voltage - seeped in. (Air breaks down at about 3kV per millimeter.) You can feel pretty confident that leaked oil won't short out IC pins on your motherboard. Hell, you could also ditch your power supply fan and fill that full of oil, too - just beware of relays and other mechanical components.
Heat transfer is a big reason for oil, too. In a car engine, much of the heat is generated by friction in the bearings, and motor oil pumped through the bearings takes that heat away. Transformer oil doesn't have to lubricate, nor does it have to carry away huge amounts of impurities or combustion by-products as in a car engine - the biggest requirements are heat carrying capability and high breakdown voltage. Large pole pigs (pole-mounted power transformers) are usually oil-filled and often have pipes coming from the bottom and going to the top - they serve as radiators. Oil flow is not by pump, the reliability would be too low - they're convective, too.
Finally, viscosity. Yes, this might be difficult, but transformer oils are available in a variety of thicknesses. You want a viscosity corresponding to SAE 0, which is the same as water. Even less might be available, though I've personally never seen it.
Density changes with temperature rise will have to be considered, since the lower density of hot liquids causes them to rise in the system (and is also the physics behind lava lamps). The system that guy designed is based on the density changes of water. Transformer oil won't behave the same way; accordingly, you'll have to whip out the old slide-rule and do some math. Calculus is your friend. Fortunately, the data on transformer oil should be readily available, it's an important design criteria.
Voltesso and Diala are good trade names which I've personally used in transformers loaded to hundreds of kilowatts at over 250,000V, at RF frequencies. (FAA obstruction lights on large VLF radio transmitting towers.) They're ALL PCB-free, and while you don't want to drink it, they're no more toxic than motor oil. And it takes a hell of a lot of work to make them catch fire.
In short, transformer oils are available in a variety of viscosities, are specifically engineered for their thermal transfer capabilities, are not electrically conductive, not dangerous, and are suitable for almost all of your electronic cooling needs.
The only problem I forsee is that you're gonna have a hard time buying them in quantities less than 45-gallon drums... though the drum would make a great passive radiator. Seriously, talk to a couple of linesmen with your local power utility, maybe you'll be able to talk your way into a couple of gallons of it.
And once that's done across all the machines in your compile farm, you can get to work tackling the big problems of why Linux isn't ready for the desktop yet [glowingplate.com].
Re:Transformer Oil - Electrical & Thermal Prop (Score:2, Interesting)
What I found funny was that I don't think a single person had ever thought about shooting a transformer until he mentioned it, and the fact that they could explode might be something that would encourage young boys to shoot one with their pellet gun.
Re:Transformer Oil - Electrical & Thermal Prop (Score:2)
So the best way is to check it yourself - stick a multimeter and measure the resistance. Given that most stuff on a motherboard is low voltage I wouldn't be overbothered by resistance-voltage properties of the oil.
Re:Transformer Oil - Electrical & Thermal Prop (Score:4, Insightful)
water would make a fine insulator unless the 'hit through'(amount of voltage differential needed for the electricity to jump/hit like lighting through something) was small(and no, i'm not an electricity-engineer).
anyways, this kind of cooling has been done(submerging the whole mobo in something), couple of times. one guy used some biograde mineral oil succesfully.
theres at least one no-pump commercial solution too for liquid cooling, but it has a fan on the radiator.
though, in my opinion, getting rid of the pump doesn't bring you anything 'extra' since the pump makes next to zero noise, and noise damping the pump from environment is easy too. the real problem lies in how to get the water to keep cool without having extra fans(heatload on it gets quite big if you have cpu, gfx-card, chipset, psu, hd's and etc watercooled for silence). the bowl of that size that's in the article won't cut it.
and really, k6-2 could be cooled enough with just about any lump of metal compared to the 76w+ modern cpu's.
Re:Transformer Oil - Electrical & Thermal Prop (Score:3, Informative)
True, but water is about a zillion times more evaporative than oil, so if you get any water on you, especially if it's warmer than body temp, it's already evaporating and thus feels cooler than warm oil would.
If you have ever got your hands wet in the winter time, you'll notice that it literally sucks the heat right out of your hand because the relative humidity in winter is usually very low and it doesn't take much to make the water on your hands start evaporating. If you got cold oil on your hands (at the same temperature as the cold water) it won't feel nearly as cold as it's not evaporating. It will pull enough heat out of your hands to reach thermal equilibrium and then stop.
If you have ever splashed hot water on yourself, you'll notice that even if you get burned, the inital 'hot' part of it is over with almost immediately. Hot oil on the other continues to feel hot and will continue to burn you much longer.
In an enclosed system where there is no evaporation, the difference won't be nearly as great.
Has anyone ever built a water-cooled PC that uses an external fountain as a radiator? Obviously you would want it far enough away from the PC so as to prevent splashing, but I think one of those little zen rock fountains would make an interesting and relaxing radiator, as long as you remembered to keep adding water...
Re:Transformer Oil - Electrical & Thermal Prop (Score:3, Funny)
odd (Score:5, Insightful)
Re:odd (Score:5, Funny)
not that complex... (Score:5, Insightful)
Re:not that complex... (Score:4, Informative)
Re:not that complex... (Score:5, Insightful)
Re:not that complex... (Score:2)
The pump, on the other hand, is going to involve either a motor and a turbine and something like it (dramatically more complex, perhaps 10-20 parts there alone if you break them down) or something similar. At the very least you'll have an impeller driven by magnetic induction which implies a certain parts count on its own.
A water jacket is just one flat piece (a lid) and one channeled piece, and a couple of fittings.
Re:not that complex... (Score:2)
Re:not that complex... (Score:2)
I've never understood why... (Score:3, Interesting)
Think about it. If the processor and other heat generating chips were on the reverse side you could mount the motherboard in such a way as to press against the large metal backside of your case cabinet. The case cabinet could be designed in such a way as to have indentations that force the processor flat against the case with heat sink gel. In fact the entire case back could be a water-cooled heat sink. This would keep the inside of the case "water-free".
Sure, this would take a radical new case design and motherboard (another industry standard), but that seems to be where we are headed right? I mean processors are getting hotter and Intel and AMD are trying to figure out what to do.
Why not?
BTW, I think it has something to do with the fact that the motherboard components are all wave soldered on one side. This would melt most plastic components on that side. I'm not sure about this.
Re:I've never understood why... (Score:3, Interesting)
A nice idea in principle, but cases are there to protect the components inside. If you go physically attaching the components to the case, all you have to do is knock the case and end up stressing the CPU die.
That said however, I agree some sort of more "holistic" approach could be wise.
Re:I've never understood why... (Score:3, Informative)
Typicially medium temperature plastics can easily handle the 300-500 F temperatures needed for soldering. The problem with mounting the socket on the backside is that you'd have to solder the opposite side of the board, and the socket would have to be covered so the wave soldering process wouldn't force solder into the socket holes.
Since the chipset is often BGA (Ball Grid Array), and many components are surface mount and require a seperate process anyway (usually infrared heating, sometimes oven heating) then the extra soldering isn't that much of an issue, nor is the protective cover over the socket. Rerouting the board backwards would be a pain though, and since it'd essentially require new case designs and could cause burns if not properly vented...
Well, there really isn't a *good* reason to go to that amount of trouble for what appears to be a very small market of people who would trade $200 - $300 for a passive heatsink on the outside case. (define very small as < 5 million units sold worldwide)
-Adam
Nitrogen is a GREAT coolant! (Score:5, Funny)
Re:Nitrogen is a GREAT coolant! (Score:2, Informative)
for those of you who evidently didnt get this, 78% nitrogen mixture at approx 14.7 psi is AIR!!!
too hot (Score:5, Insightful)
I saw a presentation by Intel last year in which it pointed out that modern CPU's emit more heat per area than molten lava, and they expect that within a few years they will emit more heat per area than the sun.
With these considerations passive water cooling is only a good first step and bound to be insufficient, even over the short term.
Re:too hot (Score:5, Funny)
Re:too hot (Score:4, Insightful)
Not quite true. I saw the same graph, and it was an extrapolation of current trends.
Obviously we aren't going to emit more heat/area than a nuclear reaction, something is going to have to change in the design of Intel CPUs.
Re:too hot (Score:2)
Nuclear reaction? (Score:3, Interesting)
Molten lava temperature is ~1000C so only 5000C to go
Re:too hot (Score:2)
Hrmm...I was going to buy a space heater, but I guess I'll just wait for the P5's to come out instead.
All kidding aside, I suspect that we're running into some physical barriers with respect to clock synchronized computing. Seems to me that we really need a paradigm shift such as asynchronous computing [sciam.com] to take us to the next level.
Re:too hot (Score:2)
Without the heatsink, a silicon CPU wouldn't be solid for very long.
(As for your hypothetical silicone CPU, it probably wouldn't be considered fully solid even at room temperature.)
Content of the page (Score:3, Informative)
The possibility of cooling a CPU with gravitational convective flow of water is analyzed and experimented with positive results.
Introduction
Many liquid cooling systems have been experimented by overclockers to better dissipate the heat from CPUs. The major part of these coolers is characterized by a relatively complex system requiring pumps or other active devices. Sometimes even liquid nitrogen is used.
My intent was instead to build a cooler able to dissipate the same heat flux of a normal heatsink, but without the annoying noise of the fan.
A first prototype was built out of a regular heatsink. Holes were drilled in the aluminium finning, and copper tubes passed through them. An aquarium pump provided the necessary pressure for circulation.
Figure 1. First Prototype--Front View
(picture)
Figure 2. First Prototype--Side View
(picture)
The system was silent and reliable. But with bigger pipes and a lower pressure drop would it have been possible to take away the pump? Simple calculations showed that it would have been perhaps feasible and a prototype was built.
Temperature on Heatsink Surface
Roughly:
Power to be dissipated: powd = 80 W
If the heatsink is a little copper box to put over the CPU, a reasonable value for the surface available at copper-water interface can be: surfc = 0.01 m2
The heat transfer coefficient on the water-copper boundary layer can vary from a few watt per square meter per kelvin if the flow is slow and laminar to more than 1 kW K-1m-2 when the flow is very fast and turbulent. If the coefficient is supposed to be: texc = 100 W K-1m -2
The difference of temperature on surface will be: delt = powd / (texc surfc) = 80 K
It appears that the water should boil on the surface of such a little heatsink, but radiation wasn't taken into account and the geometry of the box is complex, so it's not clear if there could be turbulence and with which effect. If necessary the surface could be enhanced with fins or by increasing the dimension of the equipment.
Convection
Supposing that the heatsink could be able to exchange the heat between the CPU and the water, would it flow through the pipes?
Power to convey: powd = 80 W
Length of the circuit branches between the CPU and the radiator on the top of the computer case: heigh = 0.8 m
Equivalent length of the circuit (we take into account the bends too): len = 2 m
Radius of the pipe: rdp = 9 10-3 m
Rate of change of water density against temperature: dct = 0.55 kg m-3 K -1
Water density: rho = 103 kg m-3
Water viscosity: eta = 10-3 decapoise
Specific heat of water: wsh = 4180 J kg-1 K -1
Gravitational acceleration: grav = 9.8 m s-2
Pi: pi = 3.14
Difference of temperature between ascending and descending branch: deltat
Difference of density of the water in the two branches: deltarho = deltat dct
Difference of pressure due to the difference of density: deltap = deltarho grav heigh
Volume of water conveyed per unit time: vot
Pressure drop in the pipe: deltap = vot 8 eta len / (pi rdp 4)
Power conveyed: powd = wsh rho deltat vot
Putting it all together: deltat2 = 8 powd eta len / (wsh rho pi rdp 4 dct grav heigh) = 3.4 K2
Everything should work with a temperature difference of less than 2 kelvin. Consequently the radiator isn't required to be very efficient.
SIRPAL-1 Prototype
The SIRPAL-1 prototype was made using a 5 mm thick copper sheet for the base, and 2 mm thick copper sheets for the walls. The edge of the square base is 55 mm long. Inside there are two plates 25 mm wide. One is vertically aligned, soldered to the base, to increase the exchange surface near the CPU, the other is horizontal, soldered between the input-output pipe fittings, to guide the fluid in the right direction.
A test was performed on a K6-2 450MHz which dissipates a power of about 25 watt. The ambient temperature was 18 celsius degrees. After a few hours the CPU temperature, measured by the PC board sensor, was at least 1 kelvin lower than when the fan is used. External surface temperatures: 19 celsius degrees on the pipes; 24 celsius degrees on the copper box.
A drop of ink in the water revealed a slow flow as expected. It worked so well that I think a more powerful CPU would be efficiently cooled too.
Figure 3. SIRPAL-1
(picture)
Figure 4. SIRPAL-1--Testing
(picture)
Allow me to suggest... (Score:5, Funny)
Welcome to the party, PAL! (Score:3, Funny)
Re:Welcome to the party, PAL! (Score:2)
Why not use transformer oil? (Score:3, Interesting)
Re:Why not use transformer oil? (Score:2)
Re:Why not use transformer oil? (Score:2, Insightful)
Re:Why not use transformer oil? (Score:2, Interesting)
Re:Why not use transformer oil? (Score:2, Informative)
Re:Why not use transformer oil? (Score:2)
Re:Why not use transformer oil? (Score:2, Interesting)
Polychlorinated Biphenyls (D 4059) Regulations prohibiting the commercial distribution of polychlorinated biphenyls (PCBs) mandate that insulating oils be examined for PCB contamination levels to assure that new products do not contain detectable amounts.
Viscosity (D 445) Viscosity is the resistance of oil to flow under specified conditions. The viscosity of oil used as a coolant influences heat transfer rates and consequently the temperature rise of an apparatus. The viscosity of an oil also influences the speed of moving parts in tap changers and circuit breakers. High viscosity oils are less desirable, especially in cold climates. Standard viscosity curves can be generated using Method D 341 by measuring two or three data points and plotting the data on special chart paper. The resulting curve can be used to interpolate or extrapolate values at temperatures where the viscosity is not measured directly.
tesla turbine... (Score:2, Interesting)
Re:tesla turbine... (Score:2)
In the end you might be able to utilize excellent design to get enough power to light a small bulb. I think you could get more power more cheaply by using a sizable heat pipe system which ran into a stirling engine made out of soda pop cans :P
PC or 400psi TCM? (Score:4, Interesting)
Hey I had a 9021-721 MVS/ESA mainframe that used TCM's cooled by a 400psi cooling system. The great thing about the next gen CMOS mainframes was that even though one TCM was now replaced with 3-6 CMOS units, we didn't need a massive chiller system.
Oh well, guess everything will have huge ass chiller pumps now.
Simpler, Cheaper Method... (Score:5, Interesting)
Re:Simpler, Cheaper Method... (Score:2)
The reason that generally only dedicated individuals go to the trouble of using a water-cooling system in their case is because water conducts electricity, right? And air doesn't, which is why air is much safer -- well, risk free. Spilling water on the innards of one's computer would short it out, or cause a surge, or some electrical-type thing; but no amount of air flowing through a case is going to cause any damage, unless we're talking hurricane-force winds.
So why don't liquid water-cooling systems use some liquid with the useful thermal properties of water, but without its ability to conduct electricity? In other l33t cooling stories on /. I've read about liquid nitrogen being used, but I imagine it's so cold that the damage from a leak there would be largely from temperature. Surely there is some easily-obtainable liquid, oil or something, that wouldn't cause damage to computer components if it came into contact with them, but would be effective at cooling the system.
Re:Simpler, Cheaper Method... (Score:2)
They do. It's known as 'distilled water'. Water is non-conductive (or close enough for most purposes) when it is free of salts.
Some people have tried using Flourinert for cooling but it's very expensive and I don't know what the minimum quantity is but I think it's multiple gallons.
In the end distilled water is probably your best bet. Putting filters on any intake fans or vents on your case will prevent distilled water mixing with conductive dust and shorting things out. If your case has multiple intake paths, either it's poorly designed, or you just need multiple filters. Most cases should have only one intake point, and air should more or less move throughout the entire machine before exiting, whether because you have multiple exhausts, or because air is forced to flow in such a manner.
People have also used mineral oil but with any cooling medium other than distilled water (which also does not corrode things for obvious reasons) you have to ask yourself if the seals in your pump can handle it and so on. Water is the most commonly pumped fluid, so we're quite good with it these days.
Re:Simpler, Cheaper Method... (Score:3, Insightful)
Re:Simpler, Cheaper Method... (Score:2)
I should think it would be instructive to have some way to measure the water level in your cooling system. I would probably use an old-school water glass such as those used on steam locomotives, and of course thermal monitoring with automated shutdown, and/or cpu idling. You DO want to know if you have sprung a leak.
Re:Simpler, Cheaper Method... (Score:2)
Re:Simpler, Cheaper Method... (Score:2)
Re:Simpler, Cheaper Method... (Score:5, Interesting)
This guy is trying to be creative and show us a unique way of cooling a computer. Obviously this type of water cooling is somewhat of a new idea, and has yet to be perfected. I mean, he even says that he tested it on a K6-2 computer (relatively low power dissipation).
Give the guy some credit here! Instead of saying why fans are better and that water (or any liquid) spells disaster, why not try and understand why this is better than the old system?
First - liquid cooled without a pump = no mechanical parts to fail. Those heat-pipe heatsinks that are becoming popular have liquid inside them, and you probably aren't worried about having them leak. It's possible that there might be a commercial product that does the same thing with gravitational convection of liquids.
Secondly - eliminating (or reducing) fans not only eliminates noise, it also improves reliability. How many of us have had fans get noisier over time and eventually die on us?
Anyway, I say more power to this guy. someday we might have the CPU mounted at the bottom of our case, and have a cool lava-lamp looking effect running up the side wall. Let's not be quick to fear new technologies - look at the possibilities first!
"Sometimes even liquid nitrogen is used. " (Score:4, Informative)
Re:"Sometimes even liquid nitrogen is used. " (Score:2)
I like my fan (Score:2, Funny)
I'm sure others have had this idea (Score:2, Interesting)
Something idiot proof and self contained with no mechanical parts, save perhaps a slower turning large fan to exhaust air.
So far existing heat pipes are not much more than a novelty. The wick style ones with alcohol as a fluid (mentioned here awhile back) look promising.
The giant skivved aluminum/copper blocks with the big ass fans aren't going to cut it, not just because of noise, but practicality.
Top 5 reasons to water cool your PC (Score:3, Funny)
5 -- You just inherited $700 from your great-grandfather that's just waiting to be thrown out the proverbial case window
4 -- A loud smelly watercooling kit is the perfect complement to your neon light tubes
3 -- Why spend $200 for a brand new P4 when you can pay $500 for supplies and crank your P2 up 30 MHz?
2 -- That rock fountain you got for Christmas can be put to a much geekier use
1 -- To impress your classmates at Chubb Institute
Free blogging for geeks at *nix.org [starnix.org]
Re:Top 5 reasons to water cool your PC (Score:2)
Re:Top 5 reasons to water cool your PC (Score:2)
Newer processor would be more interesting (Score:3, Insightful)
I'd be much more interested to see him cooling an overclocked Athlon XP 2100+ with 1.9 vcore running at 2400 MHz - or something of the like - with the method in the article.
Ah well, I'm happy with my good 'ol pumps and radiator, myself.
Re:Newer processor would be more interesting (Score:2, Interesting)
Re:Newer processor would be more interesting (Score:2)
If you were doing this as an experiment to see if it's workable or not, wouldn't you try it out on old equipment before risking the expensive new stuff?
Re:Newer processor would be more interesting (Score:2, Insightful)
You know...for the cost of a cooling system... (Score:4, Funny)
You wanna build a quieter computer? (Score:3, Interesting)
Without the need to implement that bulky bowl of water.
recycling? (Score:2)
Seriously, the steam can condensate in pipes outside of PC and come back as a liquid. Just add a compressor and we've got a refrigerator. Can I keep my soda cool inside my PC?
Re:recycling? (Score:2)
Re:recycling? (Score:2)
Re:recycling? (Score:2)
Re:recycling? (Score:2)
R11, for example boiled at about 20 degrees C, but you can't get that anymore, due to nasty ozone-depletion. However, one of the other commonly-available R's (R123 perhaps?) boils at around 30 degrees. Sounds like what's needed here, as long as room temp doesn't get above 30 so you can condense it again without too much hassle.
Re:recycling? (Score:2)
I found it! (Score:3, Funny)
Re:I found it! (Score:3, Funny)
Re:I found it! (Score:2)
damn cpu makers (Score:2)
Re:damn cpu makers (Score:2)
The x86 market is still pushing for speed, but I suspect that the next generation of the cheap PC will run cool instead of being faster.
And will this (Score:2)
Oh well. The chip was probably a DOritos..
Wait a second... (Score:2)
Obsolete? (Score:2)
I was going to agree, but... (Score:2)
Re:I was going to agree, but... (Score:2)
Re:I was going to agree, but... (Score:2)
Only more reliable if the pump doesn't fail. This method has no pump to fail, making it more reliable.
Forced circulation for geeks (Score:2)
Water is a very bad conductor of heat without good convection - you can boil water in the top half of a test tube while ice is happily sitting at the bottom - wrapped in gauze to make it sink, obviously.
Excellent (Score:3, Funny)
same heat as normal heatsink (Score:2)
So it works as well as a regular heatsink? whats the purpose then?
So? (Score:2)
When do we see the first Lava Lamp mod?
This is how liquid cooling should be done (Score:3, Insightful)
Now on a side note, if you like the idea of passive cooling loops Shuttle XPC cases now come with them. They use very similar ideas. You have liquid in a tube, when it vaporizes it rises to the upper radiator where it condenses and a fan carries the heat away and the water returns to the cpu side of the loop. Not sure if it vaporizes or just gets hot to move up the tube, really just a matter of effectiveness. It does a good job in lowering cpu fan noise. Unfortenly the noise of the PSU is very high in these things, or at least my SN41g2, though i belive the P4's have same PSU. The need the same thing on the PSU as the cpu. Also the "heat pipe" is a work of art.
Re:This is how liquid cooling should be done (Score:2)
Re:This is how liquid cooling should be done (Score:2)
Re:This is how liquid cooling should be done-Two. (Score:2)
efficiency (Score:3, Insightful)
Sure, heat convection flows, but your efficiency goes way up if you have an active flow. Same principle with hot water heating. They used to not have pumps to circulate the water - because it worked - but it's more efficient to have a pump.
I live in wisconsin (Score:3, Funny)
cool! (Score:2)
Very old technology (Score:2)
I saw one guy once using one of these to cook his lunch, using a pan in the water tank as a water bath to heat soup, and they can also get water to the boiling point to make tea. However, and computer system which gets water to the boiling point is not likely to be terribly effective (unless we go back to tube technology, of course)
Apples and ... oranges? (Score:2)
No, that's not what you did. The cooler you built was substantially more complex than a normal heatsink+fan. It was more expensive in materials, took more time for you to make, and required you to make more mods to your case.
It might have been quieter, though :-)
Re:a few concerns.. (Score:5, Funny)
Bowels of water on his PC, this is something I definitely DON'T want to see!
Re:a few concerns.. (Score:2, Funny)
You make your roommates happier when you enclose your bowel, too.
Re:No moving parts (Score:2)
Specifications:
Height: 9.7" (24.6 cm.)
Diameter: 6.5" (16.5 cm.)
Weight: 1 lb. 3.3 oz. (547 g.)
Temperature differential required: 18 degrees F (10 degrees C).
Precision Ball Bearings: 4.
Piston Material: Graphite.
Power Cylinder Material: Borosilicate Glass.
Flywheel Material: Acrylic.
Metal Parts: Anodized Aluminum and Steel.
Rotational Speed: Approximately 150 rpm (speed depends on temperature differential, barometric pressure, and other factors) When running on your warm hand, the engine will run faster in cold rooms, slower in warm room, and not at all in very hot rooms.
I just don't get the 150 RPM and ball bearing portions of the specification if there are no moving parts.
On a serious note, the sterling engine requires a larger temprature diffrential than most people want to have with their cooling solution.