The discussion centers on estimating the voltage produced by a small turbine powered by human breath, specifically a turbine with a diameter of 2 inches and a 1-inch axle. Participants conclude that the power output would likely be a few watts, influenced by factors such as the moment of inertia of the turbine and the efficiency of the alternator design. Suggestions include using a capacitor to store energy for lighting an LED and exploring alternative designs like Tesla turbines or piezoelectric strips for better efficiency. The conversation also touches on the challenges of using human power for electrolysis and the practicality of artificial gills.
PREREQUISITESEngineers, hobbyists, and inventors interested in renewable energy solutions, particularly those exploring human-powered devices and electrolysis applications.
rootone said:Sure, I did a parachute - only one time but jumping out of the plane was scary.
Anyway I survived, and it turned out not to be that difficult,.
Jeff Rosenbury said:Try not to keep any extra oxygen around. The stuff is flamable-ish. Things that don't normally burn might spontaneously ignite/explode under pure oxygen.
Nidum said:If you are doing your electrolysis on sea water you could just end up with hydrogen and chlorine gasses and a residue of toxic chemical soup .
Efficiency of modern hydrogen generators is measured by power consumed per standard volume of hydrogen (MJ/m3), assuming standard temperature and pressure of the H2. The lower the power used by a generator, the higher would be its efficiency; a 100%-efficient electrolyser would consume 39.4 kilowatt-hours per kilogram (141,840 J/g) of hydrogen,[17] 12,749 joules per litre (12.75 MJ/m3). Practical electrolysis (using a rotating electrolyser at 15 bar pressure) may consume 50kWh/kg, and a further 15kWh if the hydrogen is compressed for use in hydrogen cars
Minute ventilation during moderate exercise may be between 40 and 60 litres per minute.
anorlunda said:Let's do a little back of the envelope calculations.
https://en.wikipedia.org/wiki/Electrolysis_of_waterhttps://en.wikipedia.org/wiki/Respiratory_minute_volumeSo 50 liters of air per minute is 3000 liters per hour, of which 3000*0.21 or 630 liters is oxygen. That is 0.9 kg oxygen/hour, that means you need 50*0.9=45 kw of electric power to supply your own oxygen. And that makes no correction for the pressures needed at scuba depth, nor any correction to capture and recirculate the other 79% of the breathing mixture.
Compare 45,000 watts for a rebreather with 10 watts for cell phone charger, and you see that the energy needs for an electrolysis rebreather are about 4500 times more than what your lungs can produce.
twiz_ said:Now I'm curious about making the bike alternator, which I'm hoping will produce a much closer wattage to the one you decribed
twiz_ said:I just read that a bike generator typically produces about 100 watts depending on the rider,
anorlunda said:You must have misread. I said it needed 45000 watts, or 450 bike generators.
Edit: someone please double check my calcs in #36. It sounds like I dropped a decimal.
I don't see any missed decimals, but didn't you use the energy per mass of hydrogen produced instead of the mass of oxygen? So I think you need to divide your answer by 4.anorlunda said:You must have misread. I said it needed 45000 watts, or 450 bike generators.
Edit: someone please double check my calcs in #36. It sounds like I dropped a decimal.
russ_watters said:I don't see any missed decimals, but didn't you use the energy per mass of hydrogen produced instead of the mass of oxygen? So I think you need to divide your answer by 4.
Does that Respiratory_minute_volume thing take into account that the lungs only extract about 25% of the oxygen in the air?anorlunda said:Thanks Russ, you're right. 11250 watts, or 15 hp sounds more in the ball park.
Sorry twiz, that's still more than 112 bike generators.
Even at a rough estimate of 25%, that's still 2800 watts.Oxygen Absorption Rate in Lungs | Lung Efficency at Capturing Oxygen
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During normal breathing, oxygen content in the inhaled air is 20.9%, while in the expired air is 15.3% (see above). Hence, 5.6% of air is extracted or captured as oxygen. This oxygen remains in the lungs and is used by the human body.
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that translates to 7 bicyclists, 28 good fitness adults, or 37 laborers, just to supply enough power for 1 person to breath.Human Power [wiki]
Available power
A trained cyclist can produce about 400 watts of mechanical power for an hour or more, but adults of good average fitness average between 50 and 150 watts for an hour of vigorous exercise. A healthy well-fed laborer over the course of an 8-hour work shift can sustain an average output of about 75 watts.