Flow-induced vibration in pipes

Challengess and solutions - A review

Research output: Contribution to journalArticle

3 Citations (Scopus)

Abstract

The Flow-induced vibration has recently been the topic of experimental, numerical, and theoretical studies. It was intended to implement better applications for controlling the flow using orifice technique. Having the flow under control, the orifice becomes an instrument for measuring the flow. The flow of all fluid such as water, oil, gas and vapours through an orifice was tested and mathematical models were developed adequately. The basic theme for these enormous studies was the need for the very accurate flow measurements through orifices. All experimental, theoretical, numerical, and analytical studies have agreed that there is more than one avenue to develop, modify, and enhance such measurements. However, one factor that affects the flow measurements is the vibration which was not treated as required until the mid-20th century due to enormous discoveries that damages could be rooted to vibration. Researchers have studied vibration and then proposed mathematical models in conjunction with the pressure and velocity measurements of the flowing fluids and then the effect of the vibration, induced or not induced, has been under continuous investigation. This paper is an attempt to review the previous studies regarding understanding the nature of the vibration and the possible effects of vibration on the flow and on the piping structure in order to limit the damage caused by the vibration. This study shows that the need for more experimental studies and more comprehensive analytical approaches are, in particular, very essential to develop better results.

Original languageEnglish
Pages (from-to)362-382
Number of pages21
JournalJournal of Engineering Science and Technology
Volume11
Issue number3
Publication statusPublished - 1 Mar 2016

Fingerprint

Orifices
Pipe
Flow measurement
Mathematical models
Fluids
Gas oils
Pressure measurement
Velocity measurement
Vapors
Water

Keywords

  • CFD and vibration
  • Navier-Stokes theorem
  • Numerical analysis
  • Orifice
  • Vibration

ASJC Scopus subject areas

  • Engineering(all)

Cite this

@article{6e1a7c6631a0400b8c56fce0be56e4fd,
title = "Flow-induced vibration in pipes: Challengess and solutions - A review",
abstract = "The Flow-induced vibration has recently been the topic of experimental, numerical, and theoretical studies. It was intended to implement better applications for controlling the flow using orifice technique. Having the flow under control, the orifice becomes an instrument for measuring the flow. The flow of all fluid such as water, oil, gas and vapours through an orifice was tested and mathematical models were developed adequately. The basic theme for these enormous studies was the need for the very accurate flow measurements through orifices. All experimental, theoretical, numerical, and analytical studies have agreed that there is more than one avenue to develop, modify, and enhance such measurements. However, one factor that affects the flow measurements is the vibration which was not treated as required until the mid-20th century due to enormous discoveries that damages could be rooted to vibration. Researchers have studied vibration and then proposed mathematical models in conjunction with the pressure and velocity measurements of the flowing fluids and then the effect of the vibration, induced or not induced, has been under continuous investigation. This paper is an attempt to review the previous studies regarding understanding the nature of the vibration and the possible effects of vibration on the flow and on the piping structure in order to limit the damage caused by the vibration. This study shows that the need for more experimental studies and more comprehensive analytical approaches are, in particular, very essential to develop better results.",
keywords = "CFD and vibration, Navier-Stokes theorem, Numerical analysis, Orifice, Vibration",
author = "M. Siba and {Wan Mahmood}, {Wan Mohd Faizal} and Nuawi, {Mohd. Zaki} and {Mohammad Rasani}, {Mohammad Rasidi} and M. Nassir",
year = "2016",
month = "3",
day = "1",
language = "English",
volume = "11",
pages = "362--382",
journal = "Journal of Engineering Science and Technology",
issn = "1823-4690",
publisher = "Taylor's University College",
number = "3",

}

TY - JOUR

T1 - Flow-induced vibration in pipes

T2 - Challengess and solutions - A review

AU - Siba, M.

AU - Wan Mahmood, Wan Mohd Faizal

AU - Nuawi, Mohd. Zaki

AU - Mohammad Rasani, Mohammad Rasidi

AU - Nassir, M.

PY - 2016/3/1

Y1 - 2016/3/1

N2 - The Flow-induced vibration has recently been the topic of experimental, numerical, and theoretical studies. It was intended to implement better applications for controlling the flow using orifice technique. Having the flow under control, the orifice becomes an instrument for measuring the flow. The flow of all fluid such as water, oil, gas and vapours through an orifice was tested and mathematical models were developed adequately. The basic theme for these enormous studies was the need for the very accurate flow measurements through orifices. All experimental, theoretical, numerical, and analytical studies have agreed that there is more than one avenue to develop, modify, and enhance such measurements. However, one factor that affects the flow measurements is the vibration which was not treated as required until the mid-20th century due to enormous discoveries that damages could be rooted to vibration. Researchers have studied vibration and then proposed mathematical models in conjunction with the pressure and velocity measurements of the flowing fluids and then the effect of the vibration, induced or not induced, has been under continuous investigation. This paper is an attempt to review the previous studies regarding understanding the nature of the vibration and the possible effects of vibration on the flow and on the piping structure in order to limit the damage caused by the vibration. This study shows that the need for more experimental studies and more comprehensive analytical approaches are, in particular, very essential to develop better results.

AB - The Flow-induced vibration has recently been the topic of experimental, numerical, and theoretical studies. It was intended to implement better applications for controlling the flow using orifice technique. Having the flow under control, the orifice becomes an instrument for measuring the flow. The flow of all fluid such as water, oil, gas and vapours through an orifice was tested and mathematical models were developed adequately. The basic theme for these enormous studies was the need for the very accurate flow measurements through orifices. All experimental, theoretical, numerical, and analytical studies have agreed that there is more than one avenue to develop, modify, and enhance such measurements. However, one factor that affects the flow measurements is the vibration which was not treated as required until the mid-20th century due to enormous discoveries that damages could be rooted to vibration. Researchers have studied vibration and then proposed mathematical models in conjunction with the pressure and velocity measurements of the flowing fluids and then the effect of the vibration, induced or not induced, has been under continuous investigation. This paper is an attempt to review the previous studies regarding understanding the nature of the vibration and the possible effects of vibration on the flow and on the piping structure in order to limit the damage caused by the vibration. This study shows that the need for more experimental studies and more comprehensive analytical approaches are, in particular, very essential to develop better results.

KW - CFD and vibration

KW - Navier-Stokes theorem

KW - Numerical analysis

KW - Orifice

KW - Vibration

UR - http://www.scopus.com/inward/record.url?scp=84975760102&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84975760102&partnerID=8YFLogxK

M3 - Article

VL - 11

SP - 362

EP - 382

JO - Journal of Engineering Science and Technology

JF - Journal of Engineering Science and Technology

SN - 1823-4690

IS - 3

ER -