Fundamentals of AIV, FIV, and Random Vibrations in Industrial Piping | EveryEng

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Self-paced Advanced

Fundamentals of AIV, FIV, and Random Vibrations in Industrial Piping

4(83)

16 enrolled

4880 views

₹ 10999

475 min

Anytime

English

Anindya BhattacharyaAsset Engineer

Oil & Gas Upstream

Pharmaceutical & Healthcare

7-day money-back guarantee
Lifetime access
Certificate of completion

Volume pricing for groups of 5+

Why enroll

Participants should join this online course to understand

1. Theory of random vibrations.

2. Background theory behind acoustic and flow-induced vibrations.

3. Essentials of Energy Institute guideline for avoiding vibration-induced fatigue.

which will in turn up-skill the participant with the required knowledge to perform FIV and AIV analysis.

Your instructor

Anindya Bhattacharya

Asset Engineer

Asset Engineer

26+ yrs experience·United Kingdom

Is this course for you?

You should take this if

You work in Oil & Gas Upstream or Pharmaceutical & Healthcare
You're a Civil & Structural / Mechanical Engineering professional
You have 3+ years of hands-on experience in this field
You prefer self-paced learning you can revisit

You should skip if

You're new to this field with no prior experience
You need a different specialisation outside Civil & Structural
You need live interaction with an instructor

Course details

This course provides a comprehensive introduction to Acoustic-Induced Vibrations (AIV), Flow-Induced Vibrations (FIV), and Random Vibrations in industrial piping systems. Participants will learn the fundamental mechanisms that cause vibrations in piping due to fluid flow, pressure fluctuations, and acoustic phenomena, as well as the impact of these vibrations on system integrity, fatigue life, and operational safety.

The program covers the theoretical background, practical analysis methods, and code-based considerations for vibration assessment, helping engineers understand how to predict, evaluate, and mitigate vibration-related issues.

Course suitable for

Key topics covered

1. What makes a vibration problem categorised as “random vibration”?-Some real life examples.

2. Various approaches to address random vibrations- Introduction to statistical approaches, concept of probability distribution functions.

3. Fourier Transform- the heart of random vibrations.

4. Acoustic and Flow induced vibrations- Associated fluid dynamics, Theoretical background

5. How to address Acoustic and Flow induced vibrations? - A detailed review of Energy Institute Guidelines.

6. Pipe supports used to suppress vibrations- Some real life examples.

7. Use of Viscous dampers to address random vibrations in piping systems- Background theory and applications.

Course content

The course is readily available, allowing learners to start and complete it at their own pace.

3 modules26 lectures7 hr 55 min

Opportunities that await you!

Career opportunities

✎ Where this fits — what comes before, what comes next

₹10999

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Questions and Answers

Q: You're asked during pre-commissioning to sign off an unbraced 8-inch carbon steel line downstream of a choke valve. The EPC justification references EI guidance. You're searching "Energy Institute AIV velocity threshold gas piping downstream of control valve". Based on why the limit exists, what condition actually triggers mandatory AIV assessment?

Q: Mechanical completion is in two weeks, punch list is long, and you have no instrument datasheets. During cold commissioning you notice audible rattling on a 2-inch branch. You're googling "flow induced vibration site acceptance check sequence without datasheets". What verification sequence reduces FIV risk fastest before introducing hydrocarbons?

Q: A gas line drops 60 bar across a valve into a 12-inch header. No noise calc is available. You're searching "back of envelope acoustic power estimate control valve gas". For screening, which estimate best supports an AIV concern?

Q: You're revising a late-stage design to mitigate AIV on a high-pressure gas letdown. Searching "AIV mitigation design diffuser perforated plate vs thicker pipe". With no schedule change allowed, what selection aligns with the failure mechanism?