Determining Accurate Alignment Targets
VibrAlign,
Inc.
Posted 9-5-03
The previous article in this series, "Understanding
Shaft Alignment: Thermal Growth" (MT 1/03, pg. 19), explained
thermal growth and its affect on proper equipment alignment.
A practical example involves a recent project at a wastewater
treatment plant in Cleveland that needed realistic cold alignment
targets for a 3600 rpm compressor.
This machine had a long history of coupling and bearing failures.
Over a two-year period several attempts were made to calculate
the thermal growth on the motor and compressor supports. The
original equipment manufacturer’s (OEM) technical manual gave
a vertical thermal offset value of +0.04 in. (+40 mils). There
were no recommendations for a target vertical angularity. Horizontal
alignment changes were not mentioned.
Confusing data
There was some confusion with the OEM targets as provided.
Maintenance personnel did not know if this value represented
what the rim dial indicator should read when the cold alignment
was completed (with a dial indicator mounted on the stationary
shaft and indicating the motor coupling). Dial indicators indicate
the total indicated runout (TIR) each time the shaft is rotated
180 deg. Half of the TIR represents the actual centerline offset;
therefore the target should actually be +20 mils vertical offset.
The technician averaged temperature changes measured from
the bottom of the support to the split line of the machine.
This data was compared with hot alignment readings taken with
a modern laser shaft alignment system. The result of all the
data was a calculated vertical offset target of +19 mils and
a target vertical angularity of +0.65 mil/1 in. No targets
were calculated to compensate for horizontal alignment changes.
Laser-based system used
A laser-based monitoring system was installed on the machine
and the shaft alignment was monitored as the machine was placed
online and allowed to operate until it reached normal operating
conditions. There were some interesting changes in the machine’s
operating characteristics. A set of machine vibration data
was collected at 30 min intervals during the machine’s warm-up
period.
The graphs show data collected from
the laser-based monitoring system.
The shaft alignment was set with a vertical offset value
of +19 mils and a vertical angularity value of –0.65 mil/1
in. The vibration data collected on the machine bearings continued
to improve, reaching a low of 0.13 in./sec (peak overall) until
the change in the alignment reached the calculated targets.
Unfortunately, the alignment continued to change past the calculated
values; as the alignment moved farther away from zero, the
vibration data trended back up to fairly high levels, 0.30
in./sec (peak overall). Spectral data indicated misalignment.
The farther the alignment moved away from tolerance, the more
clearly the signs of shaft misalignment became.
The laser-based monitoring system’s data indicated changes
in the horizontal alignment that would take the alignment out
of tolerance in the horizontal plane as well. The total change
in the shaft alignment was:
| Vertical offset: |
–22.2 mils |
| Vertical angularity: |
–0.88 mil/1 in. |
| Horizontal offset: |
+4.42 mils |
| Horizontal angularity: |
+0.55 mil/1 in. |
Based on the changes in the alignment as measured by the
laser-based monitoring system, the cold alignment targets for
this machine were:
| Vertical offset: |
+22.2 mils |
| Vertical angularity: |
+0.88 mil/1 in. |
| Horizontal offset: |
-4.42 mils |
| Horizontal angularity: |
-0.55 mil/1 in. |
Data was obtained from a startup; therefore, targets are
opposite of the recorded change.
Lessons learned
So, what was learned from this example of thermal growth
documentation? The first lesson learned is that no matter how
many statistical calculations go into a thermal growth estimate,
the best way to get thermal growth information is to measure
it directly.
Another lesson is OEM-recommended cold alignment targets,
while sometimes close, cannot accurately predict the actual
operating conditions of a machine in its final installed state.
A third lesson can be learned from the changes in the horizontal
alignment data. The dynamics of machines during operation force
changes in the shaft alignment that cannot be measured during
a hot alignment check. The machine examined in this example
had a horizontal offset of +4.4 mils during operation. When
the machine was shut down, the horizontal offset immediately
changed by –3 mils, leaving a net horizontal change of +1.4
mils. The +1.4 mils is most likely due to temperature changes
in the piping; however, 3 mils of the total change were most
likely due to rotor torque and discharge pressure of the compressor.
Knowing the initial alignment condition of the machine and
the measured changes in the alignment allows us to estimate
the current operating misalignment of this machine:
| Vertical offset: |
–3.2 mils |
| Vertical angularity: |
–0.23 mil/1 in. |
| Horizontal offset: |
+4.42 mils |
| Horizontal angularity: |
+0.55 mil/1 in. |
For a 3600 rpm machine, the offset values would be considered
outside the acceptable tolerance, and the angularity values
are also higher than would normally be considered acceptable.
This also relates to shaft alignment tolerances based on shaft
rpm rather than on maximum coupling alignment values. Many
coupling manufacturers would consider the alignment data acceptable;
however, the vibration data shows that considerable force can
be applied to the machine bearings due to small amounts of
shaft misalignment.
Next month this series will conclude with another case study
discussing how identical machines may have different alignment
targets.
Contributors to this article include Rich Henry, Ron
Sullivan, John Walden, and Dave Zdrojewski, all of VibrAlign,
Inc., 530G Southlake Blvd., Richmond, VA 23236; (804)
379-2250; e-mail info@vibralign.com.
Change in vertical offset when vibration was at its lowest
recorded value: –18.61 mils
Change in vertical angularity when vibration was at its lowest
recorded value: –0.55 mil/1 in.
Change in horizontal offset when vibration was at its lowest
recorded value: +4.658 mils/1 in.
Change in horizontal angularity when vibration was at its lowest
recorded value: +0.252 mil/1 in
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