Difference between revisions of "Motor-muscle"

From apm
Jump to: navigation, search
(added link to yet unwritten page Nanoscale actuators)
 
(29 intermediate revisions by the same user not shown)
Line 1: Line 1:
APM in T.Level III may finally enable us to create an active '''muscle '''[[Metamaterial|'''metamaterial''']] that can reach and exceed the performance of human muscle tissue. A long cherished dream of robotic engineers.
+
{{Template:Site specific definition}}
 +
[[file:Crystal molecule - redundant fractal design - 342x640.png |thumb|250px|Fractal structuring of metamaterials can avoid linear increase of actuation range loss due to e.g. [[radiation damage|radiation induced damage]]. [http://apm.bplaced.net/w/images/a/a1/Crystal_muscle_-_redundant_fractal_design.svg SVG] ]]
  
The material consits out of many minimal sized active units. Each of them contains one or more [[Elektromechanical|elektromechanical]] or [[Chemomechanical|chemomechanical]] motors that extend or shrink the units length. For fault tolerancy a the units must be connected parrallel and seriell in a hirachical fractal fashion [TODO add infographic. Instead of constant volume shear deformation in [[infinitesimal bearings|interfacial drives]] a volume changing extension or shrinkage takes place here.  
+
'''Artificial motor-muscles''' (suggestion: '''Mokels''') are actuators out of an active [[diamondoid metamaterial]] that '''can perform pull but also push action''' with '''high energy densities''' beyond the ones seen in biological muscles tissue and even beyond combustion engines [[power density|like it's typical '''[add ref]''' for all AP technologies]] of [[technology level III|technology level III]].
 +
On the small scale they resemble some form of motors but on the large scale they seem sort of like a crystalline muscle thus the term ''motor-muscle''.
  
Since on the nano level the muscle turns out to consist out of lots of motors a crossword might be fitting. '''Suggestion: Mokel.'''  
+
The material consists out of many minimal sized active units. Each of them contains one or more [[electromechanical converter|electromechanical]] or [[Chemomechanical converters|chemomechanical]] motors that extend or shrink the units length. For fault tolerance a the units must be connected parallel and serial in a hierarchical fractal fashion '''[TODO add [http://www.thingiverse.com/thing:404286 info-graphic]]'''.
  
All the powersupply infrastructure for the motors must be incorporatred making the design quite complex.
+
When a mokel metamaterial is actuated a volume changing extension or shrinkage takes place.
 +
This is in contrast to '''[[interfacial drive]]s''' (which are essentially [[infinitesimal bearing]]s with motor/generator cells included)
 +
where only a shear deformation is present which does not change the actuators volume.
 +
 +
With motor-muscles built out of modular [[microcomponents]] beside [[electromechanical converters]] or [[chemomechanical converter]]s other microcomponents like [[energy storage cells]] could directly be incorporated (possibly in a choosable ratio) instead of feeding the energy in from an external source. This way one can trade efficiency (through lowering of power transport distance) for maximal force and power density.
 +
 
 +
All the power-supply infrastructure for the motors must be incorporated making the design quite complex.
 +
Combining mokel with [[metamaterial]] [[emulated elasticity|elasticity]] in the directions normal to the pulling action (transversal directions) and making the mokel long and thin one gains some kind of '''active rope'''.
 +
 
 +
Mokel would undoubtedly provide a boost for robotic engineering.
 +
 
 +
Due to their high power density mokel can be distributed sparsely into active materials.
 +
Chemical energy storage in contrast has high volume but can be located far off sight since with AP technology [[energy transmission]] is easy.
 +
 
 +
== Related ==
 +
 
 +
* [[Resilience boost by fractal design]]
 +
* [[Fractals in gem-gum nanomachinery]]
 +
* [[Nanoscale actuators]]
 +
 
 +
[[Category:Technology level III]]
 +
[[Category:Site specific definitions]]

Latest revision as of 09:55, 24 February 2022

This article defines a novel term (that is hopefully sensibly chosen). The term is introduced to make a concept more concrete and understand its interrelationship with other topics related to atomically precise manufacturing. For details go to the page: Neologism.
Fractal structuring of metamaterials can avoid linear increase of actuation range loss due to e.g. radiation induced damage. SVG

Artificial motor-muscles (suggestion: Mokels) are actuators out of an active diamondoid metamaterial that can perform pull but also push action with high energy densities beyond the ones seen in biological muscles tissue and even beyond combustion engines like it's typical [add ref] for all AP technologies of technology level III. On the small scale they resemble some form of motors but on the large scale they seem sort of like a crystalline muscle thus the term motor-muscle.

The material consists out of many minimal sized active units. Each of them contains one or more electromechanical or chemomechanical motors that extend or shrink the units length. For fault tolerance a the units must be connected parallel and serial in a hierarchical fractal fashion [TODO add info-graphic].

When a mokel metamaterial is actuated a volume changing extension or shrinkage takes place. This is in contrast to interfacial drives (which are essentially infinitesimal bearings with motor/generator cells included) where only a shear deformation is present which does not change the actuators volume.

With motor-muscles built out of modular microcomponents beside electromechanical converters or chemomechanical converters other microcomponents like energy storage cells could directly be incorporated (possibly in a choosable ratio) instead of feeding the energy in from an external source. This way one can trade efficiency (through lowering of power transport distance) for maximal force and power density.

All the power-supply infrastructure for the motors must be incorporated making the design quite complex. Combining mokel with metamaterial elasticity in the directions normal to the pulling action (transversal directions) and making the mokel long and thin one gains some kind of active rope.

Mokel would undoubtedly provide a boost for robotic engineering.

Due to their high power density mokel can be distributed sparsely into active materials. Chemical energy storage in contrast has high volume but can be located far off sight since with AP technology energy transmission is easy.

Related