Bearings for 200,000 rpm and up

  • Thread starter Sunfire
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In summary, the author suggests that high-speed dental bearings are not suitable for use at speeds above 200,000 rpm due to the destructive forces and friction on balls or rollers. He also suggests that magnetic or fluid bearings may be a better option.
  • #1
Sunfire
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Hello,

we are interested in high-speed bearings -- 200,000 rpm and up
bearing size:
inner diameter: 0.5cm - 1cm
outer diameter: up to 3cm
thickness: up to 1cm

Many sites offer high-speed dental bearings, but they are quite small in size...

Would anyone have an idea about a site/catalog for such bearings.
Thanks!
 
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  • #2
The forces and friction on balls or rollers in larger bearings at those speeds will be destructive.
You should consider magnetic or fluid bearings.
What are you spinning, how big is it, what drives it and how long must it operate?
 
  • #3
At 200,000 rpm for a device requiring a 1cm inner diameter, the material constraints are stiff.
Magnetic bearings in a vacuum seem the most plausible, but data will be hard to come by, because this is enrichment centrifuge territory.
 
  • #4
"In this study, we presented the design procedure and experimental results of the rotor and bearings for 500 W class MTG with the rated speed of 400,000 rpm. The rotordynamic analysis model for MTG rotor is reliably constructed by using impact test for the test rotors. The motoring test rig to evaluate the radial air foil bearings is fabricated, and the motoring test was performed up to 280,000rpm."

http://cap.ee.ic.ac.uk/~pdm97/powermems/2011/Poster/P-64.pdf
 
  • #5
My thinking is, since dental bearings are good for up to 500,000 rpm, there must be larger ones with the same speed rating...
 
  • #6
Bobbywhy said:
The rotordynamic analysis model for MTG rotor is reliably constructed by using impact test for the test rotors. The motoring test rig to evaluate the radial air foil bearings is fabricated, and the motoring test was performed up to 280,000rpm."

http://cap.ee.ic.ac.uk/~pdm97/powermems/2011/Poster/P-64.pdf

I think there is less to that than meets the eye. This is a poster presentation at a conference, not a peer reviewed published paper (not even a paper presented at the conference), and the research has nothing to do with Imperial College London, except one of the conference organizers happens to work there. http://cap.ee.ic.ac.uk/~pdm97/powermems/2011/

The way I read it, they tested three designs of rotor by measuring one vibration mode at zero RPM, and then tweaked the rotor model to give exactly the same frequency (table 1). That doesn't give you any real validation of how the dynamic behavior changes with RPM, especially considering they estimate that the accelerometer perturbed the vibration frequency by about 10% (table 2). Why didn't they use a non-contact method to (e.g. an LDV or even a capacitor proximity probe) to measure the unperturbed frequency?

They tested the rotating structure, but they could only run up to 70% of the design speed (or 60% of their calculated critical rotor speed) because of high vibration levels. On the basis of that result, they claim the bearings worked OK.

That's a bit like saying "we designed a table to carry a load of 1000 pounds. We could only test it up to 500 pounds because the table top started bending, but the legs worked OK."

Nice try, but no cigar :smile:
 
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  • #7
Turbochargers have shaft speeds on that order. Don't know much in terms of specifics, but it may be worth a look.
 
  • #8
If it was load that you were carrying you could simply stack dental bearings along the shaft. So I assume that you need bigger bearings because you are transmitting torque along the supported shaft through the centre of the bearing. Power = torque * RPM, so by using higher speed you can reduce torque for the same power, which reduces bearing size. Ball bearing RPM is inversely proportional to diameter. At 200k RPM with a 10 mm diameter, bearing surface speeds will be around 360 km/hr. You are getting too close to the edge of the envelope for reliable cool intermittent operation of ball bearings.

The bearing operational envelope decides what is available. Bigger dental bearings will not need to be made if there is a better bearing technology for those dimensions. Each technology develops it's niche, there are so many dental bearings made that they have finally optimised the design. Dental bearings are not rated for continuous operation at those speeds. Outside the dental sized ball bearing there will be very little experience and so they will be unreliable. It will depend on the duty cycle and longevity you require. I suspect you may be looking at speeds and powers that will require either magnetic bearings or bearings separated and cooled by hydrogen gas pressure.

There is also the problem of balancing the rotor and of rotor vibration. Magnetic and fluid bearings have a much greater tolerance for rotor asymmetry than do ball bearings.

Without a better idea of the application, power and geometry, it is hard to narrow down the search or invert the design.
 
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  • #9
xxChrisxx said:
Turbochargers have shaft speeds on that order. Don't know much in terms of specifics, but it may be worth a look.

We got one some time ago, it was rated for up to 220,000 rpm, but never ran past 100,000 rpm :smile: It didn't have bearings, but one lubricated bushing, which is some sort of a solution at these speeds :)
 
  • #11
We could manage to find a way to decrease the rpms into a range where plenty of bearings are available (say, below 20,000)
Sorry haven't been able to keep up with all questions
Thanks to all who contributed
 

1. What are bearings used for in high-speed applications?

Bearings are used to reduce friction and support rotating parts in high-speed applications such as turbines, engines, and motors. They help to maintain the stability and precision of the rotating components.

2. What factors are important in choosing bearings for speeds over 200,000 rpm?

The factors that are important in choosing bearings for high speeds include the material of the bearings, lubrication, design, and precision of the bearings. These factors play a crucial role in ensuring the bearings can withstand the high speeds and loads without failing.

3. What materials are commonly used for bearings in high-speed applications?

Some common materials used for bearings in high-speed applications include ceramic, stainless steel, and hybrid bearings. These materials have high strength, low friction, and good wear resistance, making them suitable for high-speed operation.

4. How is lubrication important for bearings in high-speed applications?

Lubrication is essential for bearings in high-speed applications as it reduces friction and prevents metal-to-metal contact, which can cause wear and premature failure. Proper lubrication also helps to dissipate heat and improve the overall performance of the bearings.

5. What are some common failure modes for bearings in high-speed applications?

Some common failure modes for bearings in high-speed applications include fatigue failure, overheating, and lubrication issues. These failures can be caused by factors such as high speeds, excessive loads, inadequate lubrication, and improper installation or maintenance.

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