Detection of cracks in stationary rotors via the modal frequency changes induced by a roving disc

Z.N. Haji; Sunday Oyadiji

doi:10.1115/ESDA2014-20611

Detection of cracks in stationary rotors via the modal frequency changes induced by a roving disc

Z.N. Haji
, Sunday Oyadiji

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

In this study, a crack identification approach based on a finite element cracked model is presented to identify the location and depth ratios of a crack in rotor systems. A Bernoulli-Euler rotor carrying an auxiliary roving disc has been used to model the cracked rotor, in which the effect of a transverse open crack is modelled as a time-varying stiffness matrix. In order to predict the crack location in the rotor-disc-bearing system, the suggested approach utilises the variation of the normalized natural frequency curves versus the non-dimensional location of a roving disc which traverses along the rotor span. The merit of the suggested approach is to identify the location and sizes of a crack in a rotor by determining only the natural frequencies of the stationary rotor system. The first four natural frequencies are employed for the identification and localisation of a crack in the stationary rotor. Furthermore, this approach is not only efficient and practicable for high crack depth ratios but also for small crack depth ratios and for a crack close to or at the node of mode shapes, where natural frequencies are unaffected. Copyright ?? 2014 by ASME.

Original language	English
Title of host publication	{ASME} 2014 12th {Biennial} {Conference} on {Engineering} {Systems} {Design} and {Analysis}, {ESDA} 2014
Publisher	American Society of Mechanical Engineers
Volume	2
ISBN (Print)	9780791845844 (ISBN)
DOIs	https://doi.org/10.1115/ESDA2014-20611
Publication status	Published - 2014

Keywords

Bearing systems
Crack detection
Cracked rotor
Crack identification
Crack location
Crack propagation
Finite element method
Modal frequency
Natural frequencies
Rotor systems
Stationary rotors
Stiffness matrix
Time-varying stiffness matrix

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10.1115/ESDA2014-20611

Cite this

@inproceedings{737d5caa3b634b3b9383452f1b01150a,

title = "Detection of cracks in stationary rotors via the modal frequency changes induced by a roving disc",

abstract = "In this study, a crack identification approach based on a finite element cracked model is presented to identify the location and depth ratios of a crack in rotor systems. A Bernoulli-Euler rotor carrying an auxiliary roving disc has been used to model the cracked rotor, in which the effect of a transverse open crack is modelled as a time-varying stiffness matrix. In order to predict the crack location in the rotor-disc-bearing system, the suggested approach utilises the variation of the normalized natural frequency curves versus the non-dimensional location of a roving disc which traverses along the rotor span. The merit of the suggested approach is to identify the location and sizes of a crack in a rotor by determining only the natural frequencies of the stationary rotor system. The first four natural frequencies are employed for the identification and localisation of a crack in the stationary rotor. Furthermore, this approach is not only efficient and practicable for high crack depth ratios but also for small crack depth ratios and for a crack close to or at the node of mode shapes, where natural frequencies are unaffected. Copyright ?? 2014 by ASME.",

keywords = "Bearing systems, Crack detection, Cracked rotor, Crack identification, Crack location, Crack propagation, Finite element method, Modal frequency, Natural frequencies, Rotor systems, Stationary rotors, Stiffness matrix, Time-varying stiffness matrix",

author = "Z.N. Haji and Sunday Oyadiji",

year = "2014",

doi = "10.1115/ESDA2014-20611",

language = "English",

isbn = "9780791845844 (ISBN)",

volume = "2",

booktitle = "\{ASME\} 2014 12th \{Biennial\} \{Conference\} on \{Engineering\} \{Systems\} \{Design\} and \{Analysis\}, \{ESDA\} 2014",

publisher = "American Society of Mechanical Engineers",

address = "United States",

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Detection of cracks in stationary rotors via the modal frequency changes induced by a roving disc. / Haji, Z.N.; Oyadiji, Sunday.
{ASME} 2014 12th {Biennial} {Conference} on {Engineering} {Systems} {Design} and {Analysis}, {ESDA} 2014. Vol. 2 American Society of Mechanical Engineers, 2014.

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Detection of cracks in stationary rotors via the modal frequency changes induced by a roving disc

AU - Haji, Z.N.

AU - Oyadiji, Sunday

PY - 2014

Y1 - 2014

N2 - In this study, a crack identification approach based on a finite element cracked model is presented to identify the location and depth ratios of a crack in rotor systems. A Bernoulli-Euler rotor carrying an auxiliary roving disc has been used to model the cracked rotor, in which the effect of a transverse open crack is modelled as a time-varying stiffness matrix. In order to predict the crack location in the rotor-disc-bearing system, the suggested approach utilises the variation of the normalized natural frequency curves versus the non-dimensional location of a roving disc which traverses along the rotor span. The merit of the suggested approach is to identify the location and sizes of a crack in a rotor by determining only the natural frequencies of the stationary rotor system. The first four natural frequencies are employed for the identification and localisation of a crack in the stationary rotor. Furthermore, this approach is not only efficient and practicable for high crack depth ratios but also for small crack depth ratios and for a crack close to or at the node of mode shapes, where natural frequencies are unaffected. Copyright ?? 2014 by ASME.

AB - In this study, a crack identification approach based on a finite element cracked model is presented to identify the location and depth ratios of a crack in rotor systems. A Bernoulli-Euler rotor carrying an auxiliary roving disc has been used to model the cracked rotor, in which the effect of a transverse open crack is modelled as a time-varying stiffness matrix. In order to predict the crack location in the rotor-disc-bearing system, the suggested approach utilises the variation of the normalized natural frequency curves versus the non-dimensional location of a roving disc which traverses along the rotor span. The merit of the suggested approach is to identify the location and sizes of a crack in a rotor by determining only the natural frequencies of the stationary rotor system. The first four natural frequencies are employed for the identification and localisation of a crack in the stationary rotor. Furthermore, this approach is not only efficient and practicable for high crack depth ratios but also for small crack depth ratios and for a crack close to or at the node of mode shapes, where natural frequencies are unaffected. Copyright ?? 2014 by ASME.

KW - Bearing systems

KW - Crack detection

KW - Cracked rotor

KW - Crack identification

KW - Crack location

KW - Crack propagation

KW - Finite element method

KW - Modal frequency

KW - Natural frequencies

KW - Rotor systems

KW - Stationary rotors

KW - Stiffness matrix

KW - Time-varying stiffness matrix

U2 - 10.1115/ESDA2014-20611

DO - 10.1115/ESDA2014-20611

M3 - Conference contribution

SN - 9780791845844 (ISBN)

VL - 2

BT - {ASME} 2014 12th {Biennial} {Conference} on {Engineering} {Systems} {Design} and {Analysis}, {ESDA} 2014

PB - American Society of Mechanical Engineers

ER -

Detection of cracks in stationary rotors via the modal frequency changes induced by a roving disc

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Keywords

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