An Introduction to Vibration Analysis Theory and Practice
An overview of Various Maintenance Methods Breakdown Preventive Predictive Reliability centered (Proactive) Vibration analysis What is machine vibration Measuring and analyzing vibration The BIG 4
Why do machines stop running? Component failures: Failed bearings Broken fan blades Seized couplings And the list goes on
Minimize failures: Why Question Existing Maintenance Practices? Balance and align machines Improved maintenance practices Clean lubricants Reduce the impact: Avoid unscheduled repairs Stop secondary damage Save $$$$$
Just let it fail Breakdown Maintenance Also known as run to failure Remains common practice in many places Budgeted and accepted cost of operation Disadvantages: Secondary costs of failure (10X$) High downtime Large spare parts inventory Worker safety issues
Preventive Maintenance Fix it before it breaks Also known as planned maintenance, Historical maintenance Periodic Maintenance Calendar-based maintenance Most common maintenance practice today Assumes that all machines will fail in time You perform maintenance before it fails But WHEN will it fail? WHY will it fail?
Preventive Maintenance Disadvantages Machines fail before planned shutdown Perfectly good machines are over-repaired Overhauls often introduce problems due to defects Unnecessary costly downtime Excessive spare parts Inventory
Predictive Maintenance If it ain t broke, don t t fix it! Also known as condition based maintenance Predict when a machine will fail Repair it when most convenient Repair/replace ONLY the components that are required Intelligently assess the risk
Predictive Maintenance Perform condition monitoring Determine health status Predict failure mode Act accordingly Advantages: No surprise downtime No unexpected failures No secondary damage All maintenance is planned Sounds great!
Fix it once, fix it right! Proactive Maintenance Also known as reliability centered maintenance and precision maintenance Change machine design, purchasing and maintenance procedures to reduce failures and increase machine reliability Precision balancing, laser alignment, etc.
What technology is available Condition monitoring: Vibration analysis Oil analysis Wear particle analysis Thermography Ultrasound Steam Trap
Infrared Thermography Which Technology to use? 15% Ultrasonic 10% Motor Current 5% 10% 45% Vibration Analysis Steam Trap 15% % Oil Percent of total PAYBACK when adopting a predictive maintenance program plant wide
Vibration Analysis All machines vibrate The vibration signature changes as the condition changes. What you can hear is only part of the story. Vibration analysis can help you detect a wide variety of fault conditions.
What Causes Vibration? As the shaft turns, there are frictional and rotational forces. That vibration created by those forces is transferred via the bearings to the machine housing.
The BASIC Vibration Signal The fan rotates five times every second. Add weight which creates an unbalance force. One second of time
The Frequency? Frequency? Hertz = Hz = Cycles per second RPM = Revolutions per minute CPM = Cycles per minute CPM = RPM = Hz x 60 Fan speed = 5 Hz or 300 RPM Period = 1/Frequency Fan speed = 5 Hz or 300 RPM
Increase the Frequency The fan is now going twice as fast. Cycles of the waveform are closer together. Fan speed = 10 Hz or 600 RPM
The Amplitude The height of the wave is the amplitude. Because of the weight on one blade, the vibration level increases as the fan speeds up. Displacement: mils or microns Velocity: in/sec or mm/sec Acceleration: g
Add a second source of vibration The rub introduces a new source of vibration. Rub Imbalance New vibration = 10 x 8 = 80 Hz 8 blades x 10 revolutions/second
The Spectrum
Spectrum - Examples 5 Hz = 300 RPM 5 Hz FFT 10 Hz = 600 RPM 10 Hz FFT
A More Complex Spectrum Rub Imbalance 10 Hz FFT 80 Hz 600 CPM 4,800 CPM
Data collector samples the electrical signal from the sensor. The sampling rate, number of samples, and the length of the time record determine resolution and Fmax. Resolution High resolution Low resolution
Forcing Frequencies Special calculations are used to indicate where to look in the spectrum called forcing frequencies
Vibration tells an interesting story Detailed vibration analysis can reveal far more information. Imbalance Misalignment We can detect different fault conditions, and assess the severity. Bearing faults Looseness
The Big 4 Imbalance Misalignment Looseness Faulty Bearings
Imbalance What causes Imbalance? A heavy spot along the shaft Causes high vibration and premature bearing failure Your vbseries data collector can correct imbalance
Misalignment What is Misalignment? Definition: The shaft center-lines are not collinear Can be detected in vibration signature Corrected with dial indicators and lasers Also cause of high vibration, and thus bearing damage
Looseness Rotating looseness - excessive clearance between rotation & stationary parts Non Rotating looseness - between two normally stationary parts. ie between foot & foundation
Bearing Faults Monitor the vibration at the bearings Amplitude levels indicate severity of the problem Frequency patterns indicate nature of the problem Many different ways to analyze the data
Demodulation Ball/roller strikes defect and creates a shock wave. Demodulated spectrum Aux Comp C7 - Mntg Base #1 - Vertical - Acc Time 800 ms 17/08/1999 14:02:15 6204 BPFO O/All 2.235 m/s/s rms 1.6 Bearing then rings like a bell or resonates. 1.4 1.2 1 m/s/s rms 0.8 0.6 6204 BPFO 0.4 0.2 6204 BPFO 6204 BPFO 6204 BPFO 0 0 5,000 10,000 15,000 20,000 25,000 30,000 CPM
BASIC Vibration Analysis
How do we Monitor Vibration? February 25 In practice, we watch how the patterns and levels change over time. We relate the changes to what we know about the machine. March 17 April 26
Where do I mount the Sensor? The sensor converts the vibration into an electronic signal. The most common sensor is an accelerometer. The sensor is commonly attached using a magnet.
Mounting the sensor Proper mounting is very important. Repeatability is essential. Good mechanical transmission path from the bearing.
Repeatability Vibration changes when the speed and load change. The machine must operate in the same state during every test. Check the speed and load with each measurement.
Tests are typically performed every 30 days. Test a machine at 2 or 3 bearings. Collect vertical, horizontal and axial data. Repeatability Cannery Motor - OE (left) - Horizontal - Acc Freq 120000 CPM 18/02/2000 8:43:18 O/All 3.169 m/s/s rms 1.2 1 0.8 m/s/s rms 0.6 0.4 0.2 0 0 20,000 40,000 60,000 80,000 100,000 120,0 CPM
-10-15 15 10-5 5 0 Cannery Motor - DE (right) - Vertical - Acc Time 100 ms 0 10 20 30 40 6/03/2000 12:27:05 O/All 5.982 m/s/s rms 6/03/2000 12:27:05 40 50 60 70 80 90 100 ms <set RPM> <add note> 0.005-0.005-0.015 0.01-0.01 0 O/All 5.982 m/s/s rms 0 20 40 60 80 100 120 140 160 180 200 6/03/2000 12:26:29 O/All 0.008 mm rms <set RPM> ms <add note> O/All 0.008 mm rms Look for patterns and changes m/s/s rms The vibration pattern is important. How the pattern changes is equally important. Cannery Motor - DE (right) - Vertical - Dis Time 200 ms 6/03/2000 12:26:29 mm peak-peak
Trend vibration levels An Overall RMS trend can provide useful information 4.5 Aux Comp C7 - Mntg Base #1 - Vertical - Overall Trend Velocity 4 3.5 3 2.5 mm/s rms 2 1.5 1 0.5 0 12/06/1998 1:28:20 10/07/1998 1:32:32 14/08/1998 1:23:53 11/09/1998 1:25:20 Velocity
What does it mean..? How do you know when to take action? Standards are available. ASCENT removes the guesswork.
Reality Check! Predictive maintenance: Monitoring machines regularly with repeatable results requires discipline Not all machines can be monitored Some machines cannot be monitored frequently enough Technologies are not perfect Recommendations are not always followed Some machines will still fail until analysis experience grows
Probability of Failure Infant Mortality Normal Service Life Fatigue & Failure Time The result is an increase in machine availability with a decrease in total costs