Difference between revisions of "Atomically precise slide bearing"

From apm
Jump to: navigation, search
(Related: added link to wikipedia page about "Plain bearing")
(Related)
Line 35: Line 35:
 
* [[Absence of wear in atomically precise bearings]]
 
* [[Absence of wear in atomically precise bearings]]
 
* Deliberate inclusion of [[snapback]] elements can make an intentional high friction [[damper element]]
 
* Deliberate inclusion of [[snapback]] elements can make an intentional high friction [[damper element]]
 +
----
 +
* [[Snapback]]
 +
* [[Negative pressure bearings]]
  
 
== External links ==
 
== External links ==

Revision as of 08:53, 29 August 2022

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

Up: Atomically precise bearings

A simulation of a superlubricatinvg strained shell sleeve bearing. Author Eric K. Drexler
Graphic by Eric K. Drexler -- Citation: "Symmetric molecular bearings can exhibit low energy barriers that are insensitive to details of the potential energy function" [1]

Atomically precise slide bearings are bearings with:

  • all surfaces being atomically precise and sufficiently nonreactive (See: nanoscale passivation)
  • atomic bumpiness tuned for incommensurability – See: superlubricity
  • dry running – no lubricants – (atoms in lubricants would be like gravel at these scales)
  • no hollow spaces where dirt could get caught in & (redundantly) typically operating in a sealed PPV environment

Pros & Cons

PROs / Advantages:

CONs / Disadvantages:

  • significant friction for moderate speeds ~1m/s
  • very high friction for high speeds
    Dynamic friction scales quadratically with speed. 10x speed 100x friction.
    And vice-versa as the flip side of the coin.

2 Strategies for reducing friction for higher speeds – in bigger bearings

The design principle of Infinitesimal bearings can help for higher speeds
but going for atomically precise roller gearbearings too in the case of larger scale bearings
(assembly level 2 and above in productive nanosystems) may be advisable.

Related


External links

References

  1. Drag mechanisms in symmetrical sleeve bearings: Drexler, K. E. (1992) Nanosystems: Molecular Machinery, Manufacturing, and Computation. Wiley/Interscience, pp.290–293.