Difference between revisions of "Energy storage cell"
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[Todo: discuss (known) potential losses of cryogenic storage in an AP product]. <br> | [Todo: discuss (known) potential losses of cryogenic storage in an AP product]. <br> | ||
Advanced AP systems can easily produce cryogenic temperatures via [[diamondoid heat pump system]]s. | Advanced AP systems can easily produce cryogenic temperatures via [[diamondoid heat pump system]]s. | ||
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+ | [[Category:Technology level III]] |
Revision as of 10:11, 20 May 2014
In advanced AP systems energy storage and conversion is more clearly distinct than in e.g. todays bulk electric accumulators.
Energy storage cells need chemomechanical converters or elektromechanical converters
and often some form of mechanical macroscopification to form a complete system.
AP systems can often avoid high energy densities which always are potentially dangerous since energy can be transmitted quite fast and efficiently (e.g. with energy transport cables)
Cells may be have various sizes sub equal or super microcomponent size.
Contents
Forms
for chemomechanical converters
- radicals zip cells
- micro to nano sized high pressure hydrogen capsules
- nitrogen based compounds cells (avoiding explosiveness)
- many more ...
for entropomechanical converters
- chainmolecule stretcher cells
- more dense systems (working with gasses?)
for elektromechanical converters
capacitor cells: Todays capacitors already do a good job.
no conversion
flywheels cells: Like in all other cases an additional gear transmission (mechanomechanical conversion) is possible. Scaringly high power-spikes are possible.
energy elastic springs cells: lower energy density than chemomechanical converter cells but faster and more efficient.
Notes
Cryogenic hydrogen storage is inherently macroscopic.
Nano-sized capsules have a huge surface to mass ratio making individual thermal isolation effectively infeasible.
[Todo: discuss (known) potential losses of cryogenic storage in an AP product].
Advanced AP systems can easily produce cryogenic temperatures via diamondoid heat pump systems.