Difference between revisions of "Energy conversion"
From apm
m (→Related: added link to Global scale energy management) |
(added the diagram from the page Global scale energy management here too) |
||
| Line 2: | Line 2: | ||
---- | ---- | ||
{{template:site specific definition}} | {{template:site specific definition}} | ||
| + | [[File:energy-management-complete.png|512px|thumb|right|'''todo''' upload scalable svg version & add split-off version]] | ||
Atomically precise technology for energy conversion can: | Atomically precise technology for energy conversion can: | ||
Revision as of 15:33, 24 May 2021
Atomically precise technology for energy conversion can:
- solve the enegry storage problem making renewable energy storable and fossile or nuclear fission baseload power plants unnecessary
- circumvent burning processes that unnecessarily devaluates energy
[Todo: add infographic]
Different power converters have heterogeneity residing on different size scales.
Contents
Nanoscale: molecular power converters
AP technology provides several possibilities for energy conversion that work in a mill/zip/conveyor belt like style:
- chemomechanical converters
- electromechanical converters - the link for massive and efficient energy storage that is missing today
- entropomechanical converters
- optoelectric / solarelectric
Mesoscale
thermomechanical:
diamondoid heat pump system
Used base technologies can be: microcapsules, infinitesimal bearings and thermal switching cells
Note that although the efficiency is limited by the Carnough-cycle the conversion can be near reversible.
Makroscale
thermonuclear
Complex macroscopic systems made from advanced diamondoid metamaterials may lead to significant improvements here.
Related
- Global scale energy management
- wikipedia: transducer, actuators, ...
- energy transmission
