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SKF Condition Monitoring ® Vibration Diagnostic Guide CM5003 Vibration Diagnost

SKF Condition Monitoring ® Vibration Diagnostic Guide CM5003 Vibration Diagnostic Guide Table of Contents Part 1 Overview …………………………………………………...1 How To Use This Guide ……………………………………1 Detection vs. Analysis ……………………………………...1 Vibration (Amplitude vs. Frequency) ……………………... 1 “Overall” Vibration ………………………………………... 2 Time Waveform Analysis …………………………………..5 FFT Spectrum Analysis …………………………………….5 Envelope Detection ………………………………………...6 SEE Technology …………………………………………...7 Phase Measurement ………………………………………...7 High Frequency Detection (HFD) ……………………….....7 Other Sensor Resonant Technologies ……………………....7 Part 2 Spectrum Analysis Techniques …………………………... 13 Misalignment …………………………………………….. 14 Imbalance …………………………………………………16 Looseness …………………………………………………18 Bent Shaft …………………………………………………19 Bearing Cocked on a Shaft ………………………………. 19 Bearing Defect …………………………………………… 20 Multi-Parameter Monitoring ……………………………...24 Appendix A Understanding Phase ……………………………………...25 Glossary Glossary ………………………………………………….. 27 i Vibration Diagnostic Guide Vibration Diagnostic Guide Part 1 This guide is designed to introduce machinery maintenance workers to condition monitoring analysis methods used for detecting and analyzing machine component failures. This document was created by field experienced SKF application engineers using measurements obtained with SKF Condition Monitoring equipment. This guide is a “Living Document” and will continuously grow as application and experience information becomes available. It is important to note that this guide is not intended to make the reader an analysis expert. It merely informs the reader about “typical” methods of analysis and how machinery problems “typically” show themselves when using these methods of analysis. It is intended to lay the foundation for understanding machinery analysis concepts and to show the reader what is needed to perform an actual analysis on specific machinery. Rule 1 Know what you know and don’t pretend to know what you don’t know! Often, a situation arises where the answer is not obvious or not contained within the analysis data. At this point “I don’t know” is the best answer. A wrong diagnosis can cost greatly and can rapidly diminish the credibility of the machinery maintenance worker. Analysis of the problem by a vibration specialist is required. This guide is divided into two sections. • The first section introduces concepts and methods used to detect and analyze machinery problems. • The second section examples “typical” ways in which various machinery problems show themselves and how these problems are “typically” analyzed. A glossary is provided at the end of this document. Reference this glossary for any unfamiliar terms. 1 OVERVIEW HOW TO USE THIS GUIDE CAUSE AND EFFECT There is a big difference between detecting a machinery problem and analyzing the cause of a machinery problem. Swapping out a bearing that is showing wear by vibrating heavily may or may not solve your problem. Usually, some other machinery problem is causing the bearing to wear prematurely. To solve the bearing problem you must solve the cause of the bearing problem (i.e. misalignment, looseness, imbalance). If not, you are not running a condition monitoring program, you’re running a bearing exchange program. It is essential that machinery problems be detected early enough to plan repair actions and to minimize machine downtime. Once detected, a cause and effect approach must be used to take further steps toward analyzing what caused the detected problem. Only then will you keep the problem from becoming a repeat problem. Vibration is the behavior of a machine’s mechanical components as they react to internal or external forces. Since most rotating machinery problems show themselves as excessive vibration, we use vibration signals as an indication of a machine’s mechanical condition. Also, each mechanical problem or defect generates vibration in its own unique way. We therefore analyze the “type” of vibration to identify its cause and take appropriate repair action. When analyzing vibration we look at two components of the vibration signal, its amplitude and its frequency. • Frequency is the number of times an event occurs in a given time period (the event being one vibration cycle). The frequency at which the vibration occurs indicates the type of fault. That is, certain types of faults “typically” occur at certain frequencies. By establishing the frequency at which the vibration occurs, we get a clearer picture of what could be causing it. • Amplitude is the size of the vibration signal. The amplitude of the vibration signal determines the severity of the fault. The higher the amplitude, the higher the vibration, the bigger the problem. Amplitude depends on the type of machine and is always relative to the vibration level of a “good”; “new” machine! DETECTION VS. ANALYSIS VIBRATION (AMPLITUDE VS. FREQUENCY) Overview / How To Use This Guide / Detection vs. Analysis / Vibration (Amplitude vs. Frequency) Vibration Diagnostic Guide 2 When measuring vibration we use certain standard measurement methods: • Overall Vibration • Phase • Acceleration Enveloping • SEE Technology (Acoustic Emissions) • High Frequency Detection (HFD) • Other Sensor Resonant Technologies Overall vibration is the total vibration energy measured within a frequency range. Measuring the “overall” vibration of a machine or component, a rotor in relation to a machine, or the structure of a machine, and comparing the overall measurement to its normal value (norm) indicates the current health of the machine. A higher than normal overall vibration reading indicates that “something” is causing the machine or component to vibrate more. Vibration is considered the best operating parameter to judge low frequency dynamic conditions such as imbalance, misalignment, mechanical looseness, structural resonance, soft foundation, shaft bow, excessive bearing wear, or lost rotor vanes. FREQUENCY RANGE The frequency range for which the overall vibration reading is performed is determined by the monitoring equipment. Some data collectors have their own predefined frequency range for performing overall vibration measurements. Other data collectors allow the user to select the overall measurement’s frequency range. Unfortunately there is an ongoing debate on which frequency range best measures to measure overall vibration (even though the International Organization for Standardization (ISO) has set a standard definition). For this reason, when comparing overall values, it is important that both overall values be obtained from the same frequency range. SCALE FACTORS When comparing overall values, the scale factors that determine how the measurement is measured must be consistent. Scale factors used in overall vibration measurements are Peak, Peak- to-Peak, Average, and RMS. These scale factors have direct relationships to each other when working with sinusoidal waveforms. The figure below shows the relationship of Average vs. RMS vs. Peak vs. Peak-to-Peak for a sinusoidal waveform. “OVERALL” VIBRATION Scale Factors on a Sinusoidal Vibration Waveform. Peak = 1.0 RMS = 0.707 × Peak Average = 0.637 × Peak Peak-to-Peak = 2 × Peak The Peak value represents the distance to the top of the waveform measured from a zero reference. For discussion purposes we’ll assign a Peak value of 1.0. The Peak-to-Peak value is the amplitude measured from the top most part of the waveform to the bottom most part of the waveform. The Average value is the average amplitude value for the waveform. The average of a pure sine waveform is zero (it is as much positive as it is negative). However, most waveforms are not pure sinusoidal waveforms. Also, waveforms that are not centered around zero volts produce nonzero average values. Visualizing how the RMS value is derived is a bit more difficult. Generally speaking, the RMS value is derived from a mathematical conversion that relates DC energy to AC energy. Technically, on a time waveform, it’s the root mean squared (RMS). On a FFT spectrum, it’s the square root of the sum of a set of squared instantaneous values. If you measured a pure sine wave, the RMS value is 0.707 times the peak value. NOTE: Peak and Peak-to-Peak values can be either true or scaled. Scaled values are calculated from the RMS value. Don’t be concerned about the math, the condition monitoring instrument calculates the value. What’s important to remember is when comparing overall vibration signals, it is imperative that both signals be measured on the same frequency range and with the same scale factors. Vibration (Amplitude vs. Frequency) / “Overall” Vibration Vibration Diagnostic Guide 3 NOTE: As discussed in future sections, for comparison purposes, measurement types and locations must also be identical. MEASUREMENT SENSOR POSITION Select the best measurement point on the machine. Avoid painted surfaces, unloaded bearing zones, housing splits, and structural gaps. When measuring vibration with a hand-held sensor, it is imperative that you perform consistent readings, paying close attention to the sensor’s position on the machinery, the sensor’s angle to the machinery, and the contact pressure with which the sensor is held on the machinery. Position - When possible, vibration should be measured in three directions: • the axial direction (A) • the horizontal direction (H), and • the vertical direction (V). • Horizontal measurements typically show the most vibration due to the machine being more flexible in the horizontal plane. Also, imbalance is one of the most common machinery problems and imbalance produces a radial vibration, that is, part vertical and part horizontal. Because the machine is usually more flexible in the horizontal plane, excessive horizontal vibration is a good indicator of imbalance. • Vertical measurements typically show less vibration than horizontal because of stiffness due to mounting and gravity. uploads/Industriel/ cm5003-vibration-guide.pdf