Difference between revisions of "Progressing cavity pump"
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| − | + | '''Progressing cavity pumps (PCPs) also Moineau pumps.''' <br> | |
| − | + | Due to a quite astonishing and surprising geometric miracle despite …<br> | |
| − | + | ||
| − | Due to a quite astonishing and surprising geometric miracle despite <br> | + | |
– the smooth non translatory motion and <br> | – the smooth non translatory motion and <br> | ||
– the continuous non pulsing transport flow <br> | – the continuous non pulsing transport flow <br> | ||
this is a positive displacement pump with closed chambers. <br> | this is a positive displacement pump with closed chambers. <br> | ||
| − | As | + | As such it acts as a pump in the [[mechanical electrical analogy]] <br> |
more like a constant current source rather than a constant voltage source <br> | more like a constant current source rather than a constant voltage source <br> | ||
(given a non compressible liquid as medium). <br> | (given a non compressible liquid as medium). <br> | ||
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clever geometries with interdigitating blades on the inside too likely can completely solve that <br> | clever geometries with interdigitating blades on the inside too likely can completely solve that <br> | ||
| − | + | Viscosity losses at near perfect vacuum are likely negligible. <br> | |
For pumping at higher pressures larrger scale PCPs may be <br> | For pumping at higher pressures larrger scale PCPs may be <br> | ||
| + | |||
| + | Note that (while not totally obvious) there are two exactly equal 90° phase shifted reciprocative motions involved. <br> | ||
| + | Four PCPs need to be paired up to compensate by counter-motions and hugely reduce radiated vibrations. <br> | ||
| + | Higher multipole moment(?) <br> | ||
== Possible disadvantages of piston based positive displacement pumps == | == Possible disadvantages of piston based positive displacement pumps == | ||
Revision as of 18:13, 25 March 2025
Progressing cavity pumps (PCPs) also Moineau pumps.
Due to a quite astonishing and surprising geometric miracle despite …
– the smooth non translatory motion and
– the continuous non pulsing transport flow
this is a positive displacement pump with closed chambers.
As such it acts as a pump in the mechanical electrical analogy
more like a constant current source rather than a constant voltage source
(given a non compressible liquid as medium).
Contents
[hide]Vacuum applications
Due to nanoscale atomically precise diamondois or more gemerally gemstone based
structures being possibly such tight that even high pressure helium can't leak through gaps,
these pumps will be usable to create very good (or even PPV) vacuum.
Due to molecular flow having a hard time to find one small outled from a big chamber.
One will want to cover walls with many nano PCPs
walls similar to the size of the chambers pumped down.
Advantage over trubomolecular pumps
Turbomolecular pumps need to operate near or above the speed of sound.
Atomically precise sliding bearings would cause extreme friction heat at these very high speeds
(see Nanoscale friction) so much so that they could not be operate steady-state in macroscopic quantities,
some sort of active nanoscale electrostatic levitation bearing could still make them practically
at a bit bigger scale.
There's the possible issue of backflow through bearing gaps.
Though ballistic molecular gas flow counteracts and
clever geometries with interdigitating blades on the inside too likely can completely solve that
Viscosity losses at near perfect vacuum are likely negligible.
For pumping at higher pressures larrger scale PCPs may be
Note that (while not totally obvious) there are two exactly equal 90° phase shifted reciprocative motions involved.
Four PCPs need to be paired up to compensate by counter-motions and hugely reduce radiated vibrations.
Higher multipole moment(?)
Possible disadvantages of piston based positive displacement pumps
- More parts and more complex assembly
- Possibly squeezed gas or liquid atoms (though the high thermals speeds compared to pump speeds might make that unlikely)
- Possibly more (complex) vibrations though PCP pumps feature two orthogonal 90° phase shifted reciprocative motions too. The wobbling.
Ideas
The concept could be reversed and used as a motor.
Wobbling the outer stator without rotating is around a fixed axis rotating inner rotor
Using pulling actuators in three or more phases for the wobbling.
The lobe number determines a decent gear-down ration.
If a gas or liquid is present it can act acts as a coolant that is automatically pumped.
Though this works better at larger scales due to falling viscosity issues.
Low pressure hydrogen or helium might work for nanoscale - to analyze.
Related
- Quasi amorphous structure
- Reciprocation – reciprocation does not need to be translatory
- Reciprocative friction in gem-gum technology
External links
- https://en.wikipedia.org/wiki/Progressing_cavity_pump
- http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/ ( nice page explaining the math - on internet archive too )
- http://www2.mat.dtu.dk/people/J.Gravesen/MoineauPump/HypoEpi4_3.html
