Guide to Acoustic Induced Vibration for Piping Systems

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Guide to Acoustic Induced Vibration for Piping Systems
Published 12/2023
Created by Anup Kumar Dey
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz, 2 Ch
Genre: eLearning | Language: English | Duration: 5 Lectures ( 43m ) | Size: 354 MB

Guide to Acoustic Induced Vibration for Piping Systems

What you'll learn
What is Acoustic Induced Vibration or AIV?
Causes and Effects Of Piping Vibration
Acoustic Induced Vibration Analysis Steps
Mitigation of AIV

Requirements
No Knowledge Required

Description
Piping systems are the unsung heroes of industrial operations, silently transporting fluids and gases to keep various processes running smoothly. However, behind the scenes, an often overlooked phenomenon known as Acoustic Induced Vibration (AIV) can create a symphony of challenges for these critical structures. Understanding Acoustic Induced Vibration:Acoustic Induced Vibration, as the name suggests, is the vibration induced in piping systems due to the presence of acoustic waves. These waves are generated by the flow of fluid or gas through the pipes and can lead to mechanical oscillations that may compromise the structural integrity of the system.This course will help you to learn:The Causes and Effects of Piping VibrationsWhat is AIV?Reasons of AIVAIV Analysis following Energy Institute GuidelinesAIV Mitigation OptionsConsequences of AIV:Structural Fatigue: Prolonged exposure to AIV can lead to fatigue failure in piping systems. The constant vibration weakens the material over time, potentially causing cracks and leaks.Increased Maintenance Costs: AIV-induced vibrations can accelerate wear and tear, necessitating more frequent maintenance. This not only incurs additional costs but also results in downtime, impacting overall operational efficiency.Safety Concerns: The compromise in structural integrity poses safety risks for both personnel and the environment. Uncontrolled vibrations may lead to catastrophic failures, endangering lives and property.Mitigation Strategies:Damping Devices:Installing damping devices, such as acoustic silencers can absorb and dissipate the energy generated by AIV, reducing vibrations and minimizing the risk of structural damage.Flow Rate Control:By optimizing flow rates and avoiding sudden pressure drops, operators can mitigate the potential for AIV. Proper design and control of flow parameters play a crucial role in preventing the onset of damaging vibrations.Material Selection and Design Modifications:Employing materials with higher resistance to vibration and fatigue, along with modifying the design of piping systems to minimize resonant frequencies, can enhance their ability to withstand AIV.Acoustic-induced Vibration is a complex phenomenon that demands attention in the design, operation, and maintenance of piping systems. Recognizing the potential causes and consequences of AIV is the first step toward implementing effective mitigation strategies. As industries continue to evolve, understanding and addressing the challenges posed by AIV will be crucial in ensuring the reliability, safety, and longevity of piping systems in various applications.

Who this course is for
Piping Stress Engineers
Piping Lead Engineers
Piping Engineers

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