Difference between revisions of "Chemical energy transmission"
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| − | + | The idea here is to [[energy transmission|transmit energy]] by [[capsule transport]] of chemical [[energy storage cell]] | |
| + | through special chemical energy transmission cables. | ||
| − | {{wikitodo| | + | Transport inside the cables happens at potentially high speeds in solid state inside a sheath of |
| + | [[stratified shear bearings]] ([[superluricating]]) that acts as a ultra low friction rail system. | ||
| + | |||
| + | The cables are tightly packed with [[energy storage cell|energy storage capsules]]. | ||
| + | There is no air in the small voids that are left. Instead there is a very good vacuum. | ||
| + | |||
| + | Similar transport systems to this one include: | ||
| + | * [[Mechanical energy transmission cables]] | ||
| + | * [[Global microcomponent redistribution system]] | ||
| + | * [[Diamondoid heat pipe system]] | ||
| + | |||
| + | For higher safety this could be combined with [[entropical energy transmission]]. | ||
| + | This way a ripping cable won't lead to fires and maybe even explosions but instead freeze over. | ||
| + | |||
| + | Chemical energy transmission like this has several advantages over (not superconducting) electrivcal energy transport. <br> | ||
| + | See: ... <br> | ||
| + | Thus chemical energy transmission like this could eventually some day replace most of the high power electrical energy transmission of today (2021) | ||
| + | |||
| + | {{wikitodo|add crossed out electrical power lines as illustrative image}} | ||
== Related == | == Related == | ||
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* [[Mechanical energy transmission cables]] | * [[Mechanical energy transmission cables]] | ||
* [[Power density]] | * [[Power density]] | ||
| + | * [[Energy storage cell]] | ||
* [[Capsule transport]] | * [[Capsule transport]] | ||
* [[Global microcomponent redistribution system]] | * [[Global microcomponent redistribution system]] | ||
* [[Thermal energy transport]] – slightly off-topic | * [[Thermal energy transport]] – slightly off-topic | ||
| + | * [[Transport and transmission]] | ||
| + | * [[Superlube tubes]] | ||
----- | ----- | ||
Storage: | Storage: | ||
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----- | ----- | ||
* [[Global scale energy management]] | * [[Global scale energy management]] | ||
| + | * [[Upgraded street infrastructure]] | ||
Revision as of 22:34, 25 May 2021
The idea here is to transmit energy by capsule transport of chemical energy storage cell through special chemical energy transmission cables.
Transport inside the cables happens at potentially high speeds in solid state inside a sheath of stratified shear bearings (superluricating) that acts as a ultra low friction rail system.
The cables are tightly packed with energy storage capsules. There is no air in the small voids that are left. Instead there is a very good vacuum.
Similar transport systems to this one include:
- Mechanical energy transmission cables
- Global microcomponent redistribution system
- Diamondoid heat pipe system
For higher safety this could be combined with entropical energy transmission. This way a ripping cable won't lead to fires and maybe even explosions but instead freeze over.
Chemical energy transmission like this has several advantages over (not superconducting) electrivcal energy transport.
See: ...
Thus chemical energy transmission like this could eventually some day replace most of the high power electrical energy transmission of today (2021)
(wiki-TODO: add crossed out electrical power lines as illustrative image)
Related
Transport:
- Energy transmission
- Mechanical energy transmission cables
- Power density
- Energy storage cell
- Capsule transport
- Global microcomponent redistribution system
- Thermal energy transport – slightly off-topic
- Transport and transmission
- Superlube tubes
Storage:
Conversion:
- Energy conversion
- Chemomechanical converter
- Entropomechanical converters
- Mechanosynthetic water splitting
