Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects

In-service pipelines are elongated structures which are widely employed to transport various types of liquid components and products in the gas, oil, and petrochemical industries. However, as pipelines age and encounter a number of changing environmental circumstances, defects such as corrosion and...

Full description

Saved in:
Bibliographic Details
Main Author: Ghavamian, Aidin
Format: Thesis
Language:English
Published: 2018
Subjects:
Online Access:http://psasir.upm.edu.my/id/eprint/77647/1/FK%202019%2030%20ir.pdf
http://psasir.upm.edu.my/id/eprint/77647/
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Universiti Putra Malaysia
Language: English
id my.upm.eprints.77647
record_format eprints
spelling my.upm.eprints.776472022-01-25T07:14:10Z http://psasir.upm.edu.my/id/eprint/77647/ Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects Ghavamian, Aidin In-service pipelines are elongated structures which are widely employed to transport various types of liquid components and products in the gas, oil, and petrochemical industries. However, as pipelines age and encounter a number of changing environmental circumstances, defects such as corrosion and cracks can usually develop and affect the working condition of in-service pipelines. Defective pipelines can result in casualties, damage to the environment, litigation, high replacement costs, and property damage. In recent decades, ultrasonic guided waves (UGW) can detect corrosion and defects in pipes successfully, but the detection capabilities using the UGW technique are considerably affected by the complex profiles of the defects. The effects of notch depth, circumferential extent, frequency and pipe size on the reflection coefficient (RC) of the T(0,1) and L(0,2) modes were analysed numerically and experimentally. Good agreement was achieved between simulation and experimental results. The study shows that the RC of the T(0,1) mode obtained from the notches depends on the circumferential extent, notch depth and pipe size (diameter). A higher RC magnitude was obtained for 100% wall thickness notch, whereas the RC of the T(0,1) mode for 50% wall thickness notch was highly sensitive to frequency changes. Furthermore, the RC of the L(0,2) received from both notches was dependent on the notch depth and the pipe size. The effects of frequency on the RC was significant since a smaller RC magnitude was observed for the notch 50% through-wall depth than for the notch of 100% as the frequency changes. In addition, the propagation of the T(0,1) mode reflected from an axisymmetric circumferential notch (defect) with different depths and circumferential extents in steel pipes was parametrically studied using the finite element ABAQUS/Explicit software. The results show that the RC of the T(0,1) mode from the notch increases as the depth and circumferential length of the notch increase. Furthermore, the RC response is dependent on the changes in the crosssection area of the notch. The results reveal that the T(0,1) mode is sensitive to the circumferential axisymmetric defects of various depths and circumferential extents. This study also attempted to approach a basis to use the GW technique for defect sizing in different pipe sizes by obtaining the RC from notches (defects) numerically. Finally, the results showed that it is possible to detect and size of various circumferential defects in different size of pipes when the T(0,1) or L(0,2) modes were incidents using this simulation models. 2018-07 Thesis NonPeerReviewed text en http://psasir.upm.edu.my/id/eprint/77647/1/FK%202019%2030%20ir.pdf Ghavamian, Aidin (2018) Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects. Doctoral thesis, Universiti Putra Malaysia. Wave guides Defect correction methods (Numerical analysis) Pipe lines
institution Universiti Putra Malaysia
building UPM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Putra Malaysia
content_source UPM Institutional Repository
url_provider http://psasir.upm.edu.my/
language English
topic Wave guides
Defect correction methods (Numerical analysis)
Pipe lines
spellingShingle Wave guides
Defect correction methods (Numerical analysis)
Pipe lines
Ghavamian, Aidin
Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects
description In-service pipelines are elongated structures which are widely employed to transport various types of liquid components and products in the gas, oil, and petrochemical industries. However, as pipelines age and encounter a number of changing environmental circumstances, defects such as corrosion and cracks can usually develop and affect the working condition of in-service pipelines. Defective pipelines can result in casualties, damage to the environment, litigation, high replacement costs, and property damage. In recent decades, ultrasonic guided waves (UGW) can detect corrosion and defects in pipes successfully, but the detection capabilities using the UGW technique are considerably affected by the complex profiles of the defects. The effects of notch depth, circumferential extent, frequency and pipe size on the reflection coefficient (RC) of the T(0,1) and L(0,2) modes were analysed numerically and experimentally. Good agreement was achieved between simulation and experimental results. The study shows that the RC of the T(0,1) mode obtained from the notches depends on the circumferential extent, notch depth and pipe size (diameter). A higher RC magnitude was obtained for 100% wall thickness notch, whereas the RC of the T(0,1) mode for 50% wall thickness notch was highly sensitive to frequency changes. Furthermore, the RC of the L(0,2) received from both notches was dependent on the notch depth and the pipe size. The effects of frequency on the RC was significant since a smaller RC magnitude was observed for the notch 50% through-wall depth than for the notch of 100% as the frequency changes. In addition, the propagation of the T(0,1) mode reflected from an axisymmetric circumferential notch (defect) with different depths and circumferential extents in steel pipes was parametrically studied using the finite element ABAQUS/Explicit software. The results show that the RC of the T(0,1) mode from the notch increases as the depth and circumferential length of the notch increase. Furthermore, the RC response is dependent on the changes in the crosssection area of the notch. The results reveal that the T(0,1) mode is sensitive to the circumferential axisymmetric defects of various depths and circumferential extents. This study also attempted to approach a basis to use the GW technique for defect sizing in different pipe sizes by obtaining the RC from notches (defects) numerically. Finally, the results showed that it is possible to detect and size of various circumferential defects in different size of pipes when the T(0,1) or L(0,2) modes were incidents using this simulation models.
format Thesis
author Ghavamian, Aidin
author_facet Ghavamian, Aidin
author_sort Ghavamian, Aidin
title Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects
title_short Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects
title_full Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects
title_fullStr Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects
title_full_unstemmed Numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects
title_sort numerical simulation and experimental investigation of ultrasonic guided wave propagation in pipes with defects
publishDate 2018
url http://psasir.upm.edu.my/id/eprint/77647/1/FK%202019%2030%20ir.pdf
http://psasir.upm.edu.my/id/eprint/77647/
_version_ 1724075563925110784