Difference between revisions of "Drive subsystem of a gem-gum factory"
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The energy conversion inefficiencies in this subsystem are a major source of waste heat (beside [[friction]]) so one ought to minimize them. <br> | The energy conversion inefficiencies in this subsystem are a major source of waste heat (beside [[friction]]) so one ought to minimize them. <br> | ||
Waste heat from energy conversion can be more difficult to estimate in an more accurate way beyond just very crude conservative estimations. | Waste heat from energy conversion can be more difficult to estimate in an more accurate way beyond just very crude conservative estimations. | ||
+ | |||
+ | == Systems of interest == | ||
+ | |||
+ | Tips on a molecular mill wheel doing [[mechanochemistry]] provide only intermittent torque and sometimes even the wrong polarity. <br> | ||
+ | Connecting wheels directly via mechanical differential would drive back other wheels in the longer frewheeling pauses <br> | ||
+ | or even cancel out opposite with drive in the opposite direction. <br> | ||
+ | The obvious thing to do is to couple a number of wheels as stiffly together as possible with slight phase shifts such that one overall gets a continuous positive torque in the desired direction. Only then one couples various grouped sources together to larger transmission line(s) via [[mechanical differentials]]. | ||
+ | |||
+ | The design needs to be such that if one group mill-wheels attempts to back-drive an other group, <br> | ||
+ | then this other group needs to increase resistance to that. <br> | ||
+ | What is desired here is a negative feedback self-regulation. | ||
+ | |||
+ | This is related to the reason why LEDs need resistors in series before putting them in parallel. <br> | ||
+ | Otherwise their slight differences in threshold voltage leads to huge differences in current, leaving some dark and some burning through. | ||
+ | |||
+ | Though we want to avoid resistive dissipation elements as much as possible to stay energy efficient. <br> | ||
+ | Especially at the nanoscale transmitting powers of single chemical reactions with small margins. <br> | ||
+ | So other solutions than friction are preferable | ||
+ | |||
+ | == Signal amplification == | ||
+ | |||
+ | TODO | ||
== Related == | == Related == | ||
+ | * '''[[Lagrangian mechanics for nanomechanical circuits]]''' | ||
+ | * '''[[Subsystems of gem-gum factories]]''' | ||
+ | * [[Mechanical-electrical analogies]] | ||
+ | ---- | ||
* [[Chemomechanical converter]] – [[chemospring]] | * [[Chemomechanical converter]] – [[chemospring]] | ||
* [[Electromechanical converter]] | * [[Electromechanical converter]] | ||
* [[Entropomechanical converter]] | * [[Entropomechanical converter]] | ||
+ | ---- | ||
+ | * [[Mechanical pulse width modulation]] | ||
+ | * [[Mechanical circuit element]] | ||
---- | ---- | ||
* [[How to make a gem-gum factory run forward]] | * [[How to make a gem-gum factory run forward]] | ||
Line 21: | Line 50: | ||
---- | ---- | ||
* Slightly off topic: [[Mechanical energy transmission]] | * Slightly off topic: [[Mechanical energy transmission]] | ||
+ | |||
+ | == External links == | ||
+ | |||
+ | Simulate mechanical circuits (educational toy construction kit context there)<br> | ||
+ | https://simulator.spintronics.com/ | ||
+ | Some constraints. | ||
+ | * Even supposedly ideal elements are simulated with quite high losses matching the actual kit made from plastic | ||
+ | * It seems values are not fine-tunable so slightly de-tuned coupled oscillators can't be simulated. | ||
+ | * Modeling mechanical pulse with modulation for buck conversion is far beyond the capacity of this toy siulator | ||
+ | |||
+ | ---- | ||
+ | |||
+ | * LEDs must not be put directly in parallel. Same holds for mechanochemical power sources. <br>[https://en.wikipedia.org/wiki/Threshold_voltage Threshold voltage] |
Latest revision as of 14:53, 10 June 2023
The drive system (or energy management subsystem) is an essential subsystem of gemstone metamaterial nanofactories.
Like other non-primary subsystems it would be located in the housing and the internal walls of a device.
The energy conversion inefficiencies in this subsystem are a major source of waste heat (beside friction) so one ought to minimize them.
Waste heat from energy conversion can be more difficult to estimate in an more accurate way beyond just very crude conservative estimations.
Systems of interest
Tips on a molecular mill wheel doing mechanochemistry provide only intermittent torque and sometimes even the wrong polarity.
Connecting wheels directly via mechanical differential would drive back other wheels in the longer frewheeling pauses
or even cancel out opposite with drive in the opposite direction.
The obvious thing to do is to couple a number of wheels as stiffly together as possible with slight phase shifts such that one overall gets a continuous positive torque in the desired direction. Only then one couples various grouped sources together to larger transmission line(s) via mechanical differentials.
The design needs to be such that if one group mill-wheels attempts to back-drive an other group,
then this other group needs to increase resistance to that.
What is desired here is a negative feedback self-regulation.
This is related to the reason why LEDs need resistors in series before putting them in parallel.
Otherwise their slight differences in threshold voltage leads to huge differences in current, leaving some dark and some burning through.
Though we want to avoid resistive dissipation elements as much as possible to stay energy efficient.
Especially at the nanoscale transmitting powers of single chemical reactions with small margins.
So other solutions than friction are preferable
Signal amplification
TODO
Related
- Lagrangian mechanics for nanomechanical circuits
- Subsystems of gem-gum factories
- Mechanical-electrical analogies
- How to make a gem-gum factory run forward
- Reversible actuation
- Dissipation sharing – Exothermy offloading
- Energy recuperation
- balance masses? – flywheels?
- Slightly off topic: Mechanical energy transmission
External links
Simulate mechanical circuits (educational toy construction kit context there)
https://simulator.spintronics.com/
Some constraints.
- Even supposedly ideal elements are simulated with quite high losses matching the actual kit made from plastic
- It seems values are not fine-tunable so slightly de-tuned coupled oscillators can't be simulated.
- Modeling mechanical pulse with modulation for buck conversion is far beyond the capacity of this toy siulator
- LEDs must not be put directly in parallel. Same holds for mechanochemical power sources.
Threshold voltage