Difference between revisions of "Suitable mechanisms"

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can cope without any metal screws whatsoever. A few big 3D printable screws suffice.
 
can cope without any metal screws whatsoever. A few big 3D printable screws suffice.
  
== Whole classes of mechanisms ==
+
= Whole classes of mechanisms =
  
 
* Rolling with static friction being absent and surfaces not being flat (atomic bumps) calls for gear-bearings. <br>Peculiarly the '''[[periodic table of gearbearings]]'''
 
* Rolling with static friction being absent and surfaces not being flat (atomic bumps) calls for gear-bearings. <br>Peculiarly the '''[[periodic table of gearbearings]]'''
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Related: [[Atomically precise bearings]]
 
Related: [[Atomically precise bearings]]
  
== Related ==
+
= Related =
  
 
More generally: '''Principles that can help avoid the need for very many small screws:'''
 
More generally: '''Principles that can help avoid the need for very many small screws:'''
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----
 
----
  
== External links ==
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= External links =
  
=== Bearings and Gearings ===
+
== Bearings and Gearings ==
  
 
* '''conical/tapered gearbeaings''' (with applied pre-tension)
 
* '''conical/tapered gearbeaings''' (with applied pre-tension)
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* '''rotative to reciprocative conversion''' via a straight-line-hypocycloid rather than a classical crankshaft mechanism <br> Like this: https://digital.library.cornell.edu/catalog/ss:29272012 <br>Or like this: https://commons.wikimedia.org/wiki/File:Inversion_of_Hypocycloid_Gear_Train_Ellipse_and_Straight-line_Mechanism.gif or [https://www.researchgate.net/publication/328249305_Concept_of_a_pump_for_diesel_engines_fuel_supply_using_hypocycloid_drive]<br> The essence: http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/Hypo2_1.html<br>vice versa needs multi-phase drive for defined direction
 
* '''rotative to reciprocative conversion''' via a straight-line-hypocycloid rather than a classical crankshaft mechanism <br> Like this: https://digital.library.cornell.edu/catalog/ss:29272012 <br>Or like this: https://commons.wikimedia.org/wiki/File:Inversion_of_Hypocycloid_Gear_Train_Ellipse_and_Straight-line_Mechanism.gif or [https://www.researchgate.net/publication/328249305_Concept_of_a_pump_for_diesel_engines_fuel_supply_using_hypocycloid_drive]<br> The essence: http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/Hypo2_1.html<br>vice versa needs multi-phase drive for defined direction
  
=== Couplings ===
+
== Couplings ==
  
 
* https://en.wikipedia.org/wiki/Coupling#Oldham
 
* https://en.wikipedia.org/wiki/Coupling#Oldham
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* (Rzeppa & Thompson down in the likely unsuitable section)
 
* (Rzeppa & Thompson down in the likely unsuitable section)
  
=== Joints ===
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== Joints ==
  
 
* Hirth joints: https://en.wikipedia.org/wiki/Hirth_joint <<< '''these are extremely useful'''
 
* Hirth joints: https://en.wikipedia.org/wiki/Hirth_joint <<< '''these are extremely useful'''
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* Snap shackle: https://en.wikipedia.org/wiki/Shackle
 
* Snap shackle: https://en.wikipedia.org/wiki/Shackle
  
=== Chains ===
+
== Chains ==
  
 
* Sprockets: https://en.wikipedia.org/wiki/Sprocket
 
* Sprockets: https://en.wikipedia.org/wiki/Sprocket
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* Rigid chains: https://en.wikipedia.org/wiki/Rigid_chain_actuator
 
* Rigid chains: https://en.wikipedia.org/wiki/Rigid_chain_actuator
  
=== For end-effectors and preceding ===
+
== For end-effectors and preceding ==
  
 
* Chucks https://en.wikipedia.org/wiki/Chuck_(engineering)
 
* Chucks https://en.wikipedia.org/wiki/Chuck_(engineering)
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See [[ReChain frame systems]].
 
See [[ReChain frame systems]].
  
=== Likely useful for tensioning and other things ===
+
== Likely useful for tensioning and other things ==
  
 
* Turnbuckle: (but rather for length adjustment when load is displaced) https://en.wikipedia.org/wiki/Turnbuckle
 
* Turnbuckle: (but rather for length adjustment when load is displaced) https://en.wikipedia.org/wiki/Turnbuckle
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* Rolamite (but modified to gearbearings): https://en.m.wikipedia.org/wiki/Rolamite
 
* Rolamite (but modified to gearbearings): https://en.m.wikipedia.org/wiki/Rolamite
  
=== Positive displacement pumps ===
+
== Positive displacement pumps ==
  
 
* PCP pumps: https://en.wikipedia.org/wiki/Progressing_cavity_pump <br> Good resources for modeling here: http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/HypoEpi4_3.html <br> and here various configs: http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/
 
* PCP pumps: https://en.wikipedia.org/wiki/Progressing_cavity_pump <br> Good resources for modeling here: http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/HypoEpi4_3.html <br> and here various configs: http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/
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* ( Roots blower: https://en.wikipedia.org/wiki/Roots-type_supercharger )
 
* ( Roots blower: https://en.wikipedia.org/wiki/Roots-type_supercharger )
  
=== Misc ===
+
== Misc ==
  
 
* "parts for nano-machines" collection on thingiverse: <br>https://www.thingiverse.com/mechadense/collections/51015/things
 
* "parts for nano-machines" collection on thingiverse: <br>https://www.thingiverse.com/mechadense/collections/51015/things
  
=== Probably too many small pins, too low stiffness, and better solutions present ===
+
== Probably too many small pins, too low stiffness, and better solutions present ==
  
 
* Sarrus linkage: https://en.wikipedia.org/wiki/Sarrus_linkage
 
* Sarrus linkage: https://en.wikipedia.org/wiki/Sarrus_linkage
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* Schmidt coupling: https://en.wikipedia.org/wiki/Schmidt_coupling
 
* Schmidt coupling: https://en.wikipedia.org/wiki/Schmidt_coupling
 
* Classical cycloidal drive: https://en.wikipedia.org/wiki/Cycloidal_drive <br> Very many bearings desirable here.
 
* Classical cycloidal drive: https://en.wikipedia.org/wiki/Cycloidal_drive <br> Very many bearings desirable here.
'''CV type joints:'''
+
'''Unsuitable CV type joints:'''
 
* Rzeppa joint: https://en.wikipedia.org/wiki/Constant-velocity_joint#Rzeppa_joints <br> 2-DOF rolling balls not suitable for atomic scale due to atomic bumpiness.
 
* Rzeppa joint: https://en.wikipedia.org/wiki/Constant-velocity_joint#Rzeppa_joints <br> 2-DOF rolling balls not suitable for atomic scale due to atomic bumpiness.
 
* Thompsonjoint: https://en.wikipedia.org/wiki/Constant-velocity_joint#Thompson_joints <br> Too intricate. Many small parts.
 
* Thompsonjoint: https://en.wikipedia.org/wiki/Constant-velocity_joint#Thompson_joints <br> Too intricate. Many small parts.

Revision as of 09:23, 20 May 2023

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

This page is basically just a list of mechanisms that
could be useful for future advanced diamondoid gemstone based nanosystems.

Unlike in macroscale machinery with machine parts at the lowermost possible size limit
there is no space for tiny screws that are much more tiny than the parts (housings like gearboxes and such) to clamp together.
Thus there is a need for designs that differ quite a bit from the conventional.
See the design principles listed on the page: RepRec pick-and-place robots (GemGum).

Under the lens of these constrains a particular set of
mechanisms/machine-elements emerges as especially promising.
This page is a collection of such mechanisms.

These mechanisms also allows for interesting 3D printable mechanics that
can cope without any metal screws whatsoever. A few big 3D printable screws suffice.

Whole classes of mechanisms

  • Rolling with static friction being absent and surfaces not being flat (atomic bumps) calls for gear-bearings.
    Peculiarly the periodic table of gearbearings
  • Enforced equipartitioned distribution of speed differences over several layers.
    See: Infinitesimal bearings

Related: Atomically precise bearings

Related

More generally: Principles that can help avoid the need for very many small screws:


Most generally: The design principles listed on page RepRec pick-and-place robots (GemGum).


External links

Bearings and Gearings


Couplings

  • https://en.wikipedia.org/wiki/Coupling#Oldham
  • Oldham coupling inspired gear coupling:
    Two linear-rack-gearbearings with each two rollers to define a plane. Those two sandwiched atop each other with
    their rolling direction arranged 90° to each other. Thus they have the same exact effect as an Oldham coupling. But with internal rolling rather than sliding.
  • (Schmidt coupling - this needs a lot of pins (ideally gear-bearings) thus listed in the likely unsuitable section further below)

CV type joints

Joints



For quick-release:

Chains

For end-effectors and preceding



Special screwdrivers end-effector mechanisms that:

  • put zero torque on the manipulated structure ("space screwdriver")
  • decouple tensioning from unloaded screwing structure ports (wiki-TODO: explain that principle more clearly with sketch)

These screwdrivers end-effector mechanisms shall operate on "tension-force hydrants".
See ReChain frame systems.

Likely useful for tensioning and other things


Positive displacement pumps

Misc

Probably too many small pins, too low stiffness, and better solutions present

Unsuitable CV type joints: