chronology and vibration levels (ips). note: vibration was rapidly and steadily increasing 0.19 ips...
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Chronology and Vibration levels (ips).Note: vibration was rapidly and steadily increasing 0.19 ips to 0.45 ips in 2 days
Orientation: Horiz Vert. Horiz Vert Axial
Date2003
5/10/2010 0.04 0.04 0.04 0.02 0.05
1/23/20111/24/2011 0.11 0.04 0.1 0.06 0.08
3/1/2011
3/1/2011 0.19 0.14 0.17 0.09 0.2
3/2/11 AM 0.24 0.14 0.3 0.14 0.24
3/2/11 Noon 0.29 0.17 0.33 0.14 0.28
3/2/11 1600 0.34 0.19 0.35 0.16 0.24
3/3/11 0615 0.39 0.22 0.44 0.19 0.31
3/3/11 1200 0.42 0.27 0.47 0.21 0.35
3/3/11 1600 0.45 0.27 0.46 0.21 0.38
3/4/2011
Inboard Bearing
Removed the motor and sent to shop
Noise reported getting louder. In addition to rattling noise outboard end of motor, pulsating growling noise coming
from center of motor
Abnormal noise reported. Rattling outboard end of motor
Motor Bearings replaced. Fits not checked.
Outboard Bearing
Hi-Res Spectrum of
Zoom in around 1x
TWF
Overview of observations on the two bearings (more later)
Inboard Bearing Outboard Bearing
Bearing Bore fit measurements Normal.
Shaft 8.5 mils undersized, bearing bore 2.5 mils oversized. * Shows that bearing spun on shaft.
Bearing bore inspection Normal.
1 - Pitting pattern2 - Mirror-like surface, apparenlty polished by movement3 - Slight discoloration, indicate some heat
Shaft seat inspection
Ridge on each side of bearing suggests shaft was machined by the relative movement
Grease cavity Full Full
Bearing outer ring seat appearance Circumferential stripes No marks
Discoloration on races, indicating overheating
Mild discoloration. Probably due to unfavorable cooling of inboard bearing on TEFC motor. No discoloration
Indication of thrust load based on ball track on races
Slightly offset indicating light thrust load. Thrust load is not expected, but more likely on inboard/fixed bearing than outboard/floating No offset, no indication of thrust loading
Bearing seating surface measurements (average of 3 per measurement)Outboard bearing shaft is 8 mils small and bearing bore is 3 mils big
ABFMA Number Min Max Min Max Min Max Min Max
65BC03 2.5592 2.5597 2.5585 2.5591 5.5118 5.5128 5.5111 5.5118
Inboard Inboard deivation 0.0003 too big 0.0007 too bigOutboard Outboard deviation 0.0084 too small 0.0026 too big 0.0002 too big
Shaft (k5) Housing (H6)Bearing ID Bearing od
2.5593
2.5508
2.5594
2.5617 5.5125 5.5120
5.5125 5.5125
Left photo - Outboard bearing remained in endbell when removed, since bearing was loose on shaft (Later bearing was easily removed from endbell by hand). (This is single shielded bearing with shield toward winding)Right photo – View of grease cavity after bearing removed from housing – cavity is FULL. (grease is otherwise in good condition, no discoloration)
Shield
Cavity fullOf grease
Photo showing general as-found condition of grease in bearing on winding side = non-shield side.Fairly good condition.
IB
OB
Seating surface of bearing on shaft (outboard). Ridges on both sides of bearing that can be felt with fingernail (red arrows) No evidence of axial movement… distance from shoulder appears correct.
Outboard bearing inner ring bore:1 – OB Darker color than IB. Indicating perhaps higher temperature at this location when OB was spinning.2 - OB Pitted appearance across axial center (see next slide)3 - OB has a smoother, more mirror-like finish than inboard. (see slide after next)
IB OB
Closer view of bearing OB brg ID shows pitting.
Outboard bearing has smoother more mirror-like finish than inboard. Presumably polished by relative motion
IB OB
1 - After cleaning, Inboard bearing has more permanent staining (presumably from baking on lubricant during high temps). Higher inboard temp makes sense since inboard is cooled better in TEFC…. Presumably spinning
outboard bearing did not yet create overheating (certainly would have after more time)2 - Inboard shows more thrust loading. It is not typical to see sign of thrust loading, however more likely on
inboard which is fixed than outboard.
IB OB
Inboard bearing has distinct circumferential tracks on OD after cleaned, outboard does not. I am used to seeing some signs of movement/fretting, but inboard looks strange.
IB OB
Photo of bearing cavity after grease removed. Estimate cavity volume next slide
Grease cavity volume estimation ~ 13 cubic inch.
Brg
0.25”
0.375”
2.56”
5.51”
1.30” 1.75”
GreaseCavity
Shaft
0.5” 1.25”
A1 A2
A1=0.5*Pi*(2.38^2-1.28^2) = 6.3 in^3
A2 ~1.25*Pi*(2.1^2 – 1.65^2) = 6.6” in^3Total cavity volume ~ 13 in^3. (6.5 free after pack half full).Lube schedule: 1.2 ounce = 2.1 cubic inches every 18 months. (in-line with EPRI, not as often as recommended by SKF etc)
After 4.5 – 6 years will be full IF no shrinkage (*)This had been installed 8 years -> perhaps we should not be surprised that cavity is full?(*) I have heard that grease can shrink substantially, but can we count on that?
2.38”
1.28”
2.1”
1.65”
General Greasing discussion
• We never have any luck with grease coming out of the drain or relief, even though we let it run for 2 hours after greasing with plug removed.
• Why do OEM’s even bother to put a grease plug in? I think grease may expel if bearing is lubricated very frequently (like monthly or continuous… such that it never hardens). But not when following EPRI schedule like once per 18 months
How close to failure was this motor?
• Pretty close.• Rapidly increasing vibration levels suggested rapidly degrading condition (see slide 1)• Fits are specified to be clearance at outer-ring/housing interface and interference at inner-ring/shaft interface.• Clearance at inner-ring/shaft interface tends to degrade much faster than looseness at outer-ring/housing
interface due to the fact that the machine weight load always acts down… the inner-ring/shaft interface is moving with respect to this load and therefore the load tends to force relative motion at the interface.
• This action is illustrated below (worst case scenario assuming weight load completely overcomes friction to maintain contact at 6:00 loaded position.
w w w w w
Inner Ring
shaft
Rotate90 CW
Rotate90 CW
Rotate90 CW
Rotate90 CW
Slip distance in 1 rev
We assumed that the weight load forced the contact to be maintained at 6:00 position. Therefore surface velocity of inner ring is same as shaft.
=> During one revolution of the shaft, the dot on the shaft and inner ring both traveled the same circumferential distance = *D_shaft.
However the circumference of the inner ring is *D_innerRing, which is greater than *D_shaft, so the inner ring did not complete a full revolution.
Slip distance in 1 rev = *(D_inner_ring – D_shaft)
For our measured 10 mil diametrical clearance, slip distance in one rev is *0.010 = 0.0314” per revolution.In one minute at 3600rpm, slip distance could be up to 3600*0.0314” = 113”… almost 10 feet.In one hour, slip distance could be 565 feet.In one day, slip distance could be 2.5 miles. This relative motion tends to enlarge the clearance, which can lead to accelerating failure. The scenario is much more concern on inner ring than outer ring due to the fact that inner-ring/shaft mating surface rotates with respeect to the load as shown above (outer ring/housing does not)