Course Details
Vibration Analysis & Condition Monitoring
Location
Date
Duration
Language
Discipline
Mechanical & Utility EngineeringIntroduction
COURSE INTRODUCTION
This course provides a detailed examination of the detection, location and diagnosis of faults in rotating and reciprocating machinery using vibration analysis. The basics and underlying physics of vibration signals are first examined. The acquisition and processing of signals is then reviewed followed by a discussion of machinery fault diagnosis using vibration analysis. The course is concluded by a review of the other techniques of predictive maintenance such as oil and particle analysis, ultrasound and infrared thermography with an introduction to automated machine condition monitoring
Objective
COURSE OBJECTIVE
Upon completing this course, participants will be able to:
• Understand the basics of vibration measurement
• Demonstrate the basics of signal analysis
• Understand measurement and the characteristics of vibration signals
• Understand how to use Data Acquisition Equipment for vibration signals
• Apply vibration analysis for different machinery faults
• Apply specific techniques for pumps, compressors, engines, turbines and motors
• Apply vibration based fault detection and diagnostic techniques
• Diagnose machinery related problems with vibration analysis techniques
• Apply advanced signal processing techniques and tools to Vibration analysis
• Detect, locate and diagnose faults in rotating and reciprocating machinery using vibration analysis techniques
• Identify conditions of resonance and be able to rectify these problems
• Understand the basic advantages of allied predictive techniques such as oil analysis, thermography, ultrasonics and performance evaluation
Audience
COURSE AUDIENCE
Engineers, engineering supervisors and managers responsible for designing or qualifying mechanical components, equipment, piping and structures subjected to dynamic forces; those responsible for auditing, reviewing, or approving shock and vibration analysis tasks. Those with a few years of experience in vibration analysis as well as those who are new to the area will benefit
Content
COURSE CONTENT
Introduction
- Definition of Machinery Monitoring, Fault Diagnostics and Failure
- Maintenance Strategies and their application (pros and cons)
- Principles of Predictive Maintenance (including specific tasks)
- Periodic Monitoring versus Continuous Monitoring
- Various Techniques of Predictive Maintenance
- Vibration Analysis as a Key Technique
Part 1 THEORY: INTRODUCTION TO VIBRATION ANALYSIS
Chapter 1 introduction
Chapter 2 vibration analysis applications
Chapter 3 vibration analysis overview
Theoretical vibration profiles
Actual vibration profiles
Time domain
Vibration measuring equipment
Transducer
Portable vibration analyzer
Chapter 4
Vibration sources
Rotating machinery
Rotor imbalance
Flow instability and operating conditions
Mechanical motion and forces
Reciprocating and/or linear-motion machinery
Sources of vibration
Chapter 5
Vibration theory
Periodic motion
Harmonic motion
Measurable parameters
Frequency
Amplitude
Maximum Vibration Measurement
Displacement
Velocity
Acceleration
Measurement Classifications
Broadband or Overall
Narrowband
Component
Common Elements of Curves
Peak-to- Peak
Zero-to-Peak
Root-Mean-Square
VIBRATION DATA TYPES AND FORMATS
ANALYSIS TECHNIQUES
TRENDING
Broadband
Narrowband
Industrial Reference Data
Vibration monitoring overview
MACHINE-TRAIN MONITORING PARAMETERS
TRENDING ANALYSIS
Part 2 Machine vibration
Machine history
Machine characteristics
Data acquisition
Vibration amplitude versus frequency analysis
Importance of tri-axial reading
The machine sketch
Machinery vibration signature
Supporting information
Obtaining amplitude versus frequency data
Waterfall diagram
Amplitude/phase versus machine rpm
Data interpretation
Identifying the type of rotor unbalance
Determining machinery condition
Controlling normal vibration
Controlling radiated noise
Special techniques for monitoring bearing condition
Vibration due to plane (journal) bearings
Oil whirl
Dry whirl
Vibration due to resonance
Turbomachinery problems
Friction induced (hysteresis) whirl
Aerodynamic cross coupling
Surging
Choking (stone-walling)
Vibration problems with specific machinery types
Centrifugal pumps
Hydraulic forces
Cavitation
Re-circulation
Vibration of reciprocating machines
Part 3 Non-Vibration Based Techniques
- Costs versus Benefits
- Visual Monitoring
- Performance Monitoring
- Oil Quality Analysis
- Wear Particle Analysis
- Acoustic Emission
- Thermography (thermal imaging)
Certificate
COURSE CERTIFICATE
TRAINIT ACADEMY will award an internationally recognized certificate(s) for each delegate on completion of training.
Methodology
COURSE METHODOLOGY
The training course will be highly participatory and the course leader will present, guide and facilitate learning, using a range of methods including formal presentation, discussions, sector-specific case studies and exercises. Above all, the course leader will make extensive use of real-life case examples in which he has been personally involved. You will also be encouraged to raise your own questions and to share in the development of the right answers using your own analysis and experiences. Tests of multiple-choice type will be made available on daily basis to examine the effectiveness of delivering the course.
- 30% Lectures
- 30% Workshops and work presentation
- 20% Case studies & Practical Exercises
- 10% Role Play
- 10% Videos, Software or Simulators (as applicable) & General Discussions