Difference between revisions of "Thermal energy transport"

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(Created page with "{Template: Stub} With Diamondoid heat transmission systems of technology level III enormous surface densities of heat flow (heating cooling) can be archived. The factors...")
 
(Related: back from ge.gum to diamondoid - fits better here due to diamonds high heat conductivity)
 
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Up: [[Energy transmission]]
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With Diamondoid heat transmission systems of [[technology level III]]
 
With Diamondoid heat transmission systems of [[technology level III]]
 
enormous surface densities of heat flow (heating cooling) can be archived.
 
enormous surface densities of heat flow (heating cooling) can be archived.
  
The factors that go in are:
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== The factors that go in ==
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* high surface to volume ratio (a thin sheet or dense stripes)
 
* high surface to volume ratio (a thin sheet or dense stripes)
* very good thermal conductiocity of diamond
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* very good thermal conductiocity of [[diamond]] (also for [[moissanite]])
 
* good thermal capacity - the transport meium can be choosen for the operating temperature range
 
* good thermal capacity - the transport meium can be choosen for the operating temperature range
 
* high throughput of thermal mass due to fast [[capsule transport]] - the turning radius poses hard constraints on geometry though
 
* high throughput of thermal mass due to fast [[capsule transport]] - the turning radius poses hard constraints on geometry though
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* thermal conductivity of one dimensional sliding interfaces
  
['''Todo:''' determine bottleneck diagram]
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['''Todo:''' determine bottleneck in different situations - diagram]
  
Some possible applications:
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== Some possible applications ==
* in AP small scale factories of [[technology level III]] this is extended with [[diamondoid heat pump systems]] there the waste heat isn't too high and the situation far from extreme so turning radii do not play a role.
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* in AP small scale factories of [[technology level III]] this is extended with [[diamondoid heat pump system]]s there the waste heat isn't too high and the situation far from extreme so turning radii do not play a role.
 
* high speed Aerial vehicles (See: [[medium movers]])
 
* high speed Aerial vehicles (See: [[medium movers]])
 
* fusion power (figure eight loops for tokamaks?)
 
* fusion power (figure eight loops for tokamaks?)
 
* geothermal stuff?
 
* geothermal stuff?
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* active cooling for [[gemstone based metamaterial]]s that maximize emulated toughness (''speculative!'')
 
* ...
 
* ...
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== Related ==
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* [[Energy transmission]]
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* [[Diamondoid heat pump system]]
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* [[Diamondoid heat pipe system]] (or ''"Gem-gum solid state heat pipe"'')
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* [[Thermal management in gem-gum factories]]
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[[Category:Thermal]]
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[[Category:Thermal]]
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[[Category:Technology level III]]

Latest revision as of 12:32, 25 May 2021

This article is a stub. It needs to be expanded.

Up: Energy transmission


With Diamondoid heat transmission systems of technology level III enormous surface densities of heat flow (heating cooling) can be archived.

The factors that go in

  • high surface to volume ratio (a thin sheet or dense stripes)
  • very good thermal conductiocity of diamond (also for moissanite)
  • good thermal capacity - the transport meium can be choosen for the operating temperature range
  • high throughput of thermal mass due to fast capsule transport - the turning radius poses hard constraints on geometry though
  • thermal conductivity of one dimensional sliding interfaces

[Todo: determine bottleneck in different situations - diagram]

Some possible applications

Related