Crack detection in rotating shafts based on 3× energy: Analytical and experimental analyses

A theoretical and experimental dynamic analysis of a rotor-bearing system with a transversely cracked shaft is presented. To model the system for FEM analysis, a finite element for a cracked cylindrical shaft is developed. The additional flexibility due to the crack is evaluated from the linear fracture mechanics, using a breathing crack model derived in a rigorous way. A simplified opening/closing crack model is proposed to reduce the computational effort. The resulting parametrically excited system is nonlinear, and the equations of motion are solved using Hilbert, Hughes, and Taylor integration method (HHT) implemented in Matlab platform, where the stationary vibration caused by gravity and unbalance is analyzed. The results show that for half the first critical speed, the super-harmonic 2 ×Ω and the typical orbit provide good indices for crack detection in rotating shafts.

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Detection of Cracks in Rotating Shafts by Using the Combination Resonances Approach and the Approximated Entropy Algorithm

Shock and Vibration ◽

10.1155/2018/4094631 ◽

2018 ◽

Vol 2018 ◽

pp. 1-14 ◽

Cited By ~ 2

Author(s):

Rodrigo Nicoletti ◽

Aldemir A. Cavalini ◽

Valder Steffen

Keyword(s):

Crack Detection ◽

Data Series ◽

Transverse Cracks ◽

Rotating System ◽

Detection Techniques ◽

Rotating Machine ◽

Rotating Systems ◽

Nonlinear Approach ◽

Vibration Responses ◽

Rotating Shafts

Shaft crack detection is a very serious matter and machines suspected of having a crack must be treated carefully. The importance attributed to this problem is addressed due to the serious consequences when cracks are not early detected in rotating systems. Various crack detection techniques were proposed in the last years, in which the vibration based techniques have demonstrated being efficient. However, these techniques fail for the cases in which incipient cracks are concerned. Recently, a nonlinear approach to detect cracks in rotating shafts was presented. The idea is to excite the shaft by using a harmonic force to induce combination resonances in the system. If the combination resonances appear in the vibration responses of the rotating system, the presence of cracks is confirmed. However, this methodology demonstrated being effective in detecting only deep cracks. In this context, the uniqueness of this paper relies on the possibility of detecting incipient transverse cracks in rotating shafts by associating the combination resonances approach with the so-called Approximated Entropy algorithm (ApEn algorithm). ApEn is a statistical value used to quantify irregularities in data series. Patterns and correspondences between samples of the same series are searched to detect anomalies. Considering that the combination resonances change the pattern of the shaft vibration responses, the ApEn algorithm can be used to highlight the presence of such resonances and, consequently, the detection of incipient cracks. The proposed approach was numerically evaluated by considering a horizontal rotating machine. A preliminary experimental investigation is also presented. The results demonstrated the efficiency of the conveyed methodology.

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Crack detection in rotating shafts using combined wavelet analysis

Journal of Physics Conference Series ◽

10.1088/1742-6596/1297/1/012031 ◽

2019 ◽

Vol 1297 ◽

pp. 012031

Author(s):

M Pricop ◽

T Pazara ◽

C Pricop ◽

G Novac

Keyword(s):

Wavelet Analysis ◽

Crack Detection ◽

Rotating Shafts

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Experimental detection of an early developed crack in rotor-bearing systems using an AMB

International Journal of Structural Integrity ◽

10.1108/ijsi-01-2014-0005 ◽

2015 ◽

Vol 6 (2) ◽

pp. 194-213 ◽

Cited By ~ 4

Author(s):

Athanasios C. Chasalevris ◽

Chris A. Papadopoulos

Keyword(s):

Real Time ◽

Crack Detection ◽

Magnetic Bearing ◽

Fluid Film ◽

Normal Operation ◽

External Excitation ◽

Content Type ◽

Fluid Film Bearings ◽

Rotor Bearing ◽

Rotating Shafts

Purpose – The purpose of this paper is to present a method for early crack detection in rotating shafts. A rotor-bearing system, consisting of an elastic rotor mounted on fluid film bearings, is used to detect the presence of the crack at a depth of around 5 percent of shaft radius. The fluid film bearings, the shaft and the crack introduce coupled bending vibrations both in the horizontal and vertical plane. Experimental time series of the rotor composite response under normal steady-state operation are uncoupled, to develop a signal processing procedure able to reveal the presence of the crack. Design/methodology/approach – The variation of the coupling property that a crack (breathing or not) or a cut (always open) introduces into the system and the localization of the coupling in the time domain is a concept proposed as a means to detect transverse surface cracks in rotating shafts. This consideration is combined with the concept of external excitation for the development of an additional crack-sensitive response during system normal operation. Using an external excitation of an active magnetic bearing of specific duration, frequency and amplitude, the method uses this coupling variation during rotation. Findings – The method is simple, quick and effective for early crack detection, being able to detect cracks as shallow as 5 percent of the shaft radius while the system is under normal operation, and can even be applied real-time. Experimental verification uses a simple elastic rotor with a cut mounted on fluid film bearings, with the cut producing similar coupling phenomena as an opened crack. Experimental results are encouraging. Originality/value – The method used is simple, quick and effective for early crack detection, being able to detect cracks as shallow as 5 percent of the shaft radius while the system is under normal operation, and can even be applied real-time.

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Crack Detection in Shaft Using Lateral and Torsional Vibration Measurements and Analyses

Volume 7: Structures and Dynamics, Parts A and B ◽

10.1115/gt2012-69921 ◽

2012 ◽

Author(s):

A. Tlaisi ◽

A. Akinturk ◽

A. S. J. Swamidas ◽

M. R. Haddara

Keyword(s):

Mesh Generation ◽

Crack Detection ◽

Three Dimensional ◽

Bending Moment ◽

Initial Crack ◽

Rate Of Change ◽

Open Crack ◽

Strain Gages ◽

Different Depths ◽

Rotating Shafts

In this paper experimental and numerical investigations are carried out to identify the presence of a crack in a cylindrical overhanging shaft with a propeller at the free end. In the experimental study, cracks of different depths are located at the (un-cracked) maximum bending moment position. Shaft response parameters for lateral (using an accelerometer) and torsional vibrations (using shear strain gages fixed at three different locations) are obtained using the modal analysis software, LMS Test Lab™. The experimental results are used to validate the numerical results obtained using the three-dimensional isoparametric elements (element types 186 and 187) available in the ANSYS FEM program; the open crack is embedded in the shaft and the mesh generation is suitably modified to incorporate the stress intensity effects present at the crack tip. From the results it is observed that the rate of change of torsional frequencies that occur during initial crack growth can be better used to detect crack presence in rotating shafts than bending frequencies.

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Three-Dimensional Ultrasonic Crack Detection in Anisotropic Materials

Research in Nondestructive Evaluation ◽

10.1080/09349849708968121 ◽

1997 ◽

Vol 9 (2) ◽

pp. 59-79 ◽

Cited By ~ 14

Author(s):

J. Mattsson ◽

A. J. Niklasson ◽

A. Eriksson

Keyword(s):

Crack Detection ◽

Three Dimensional ◽

Anisotropic Materials

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Status of nondestructive control of transport function metal products at JSC EVRAZ NTMK

Ferrous Metallurgy Bulletin of Scientific Technical and Economic Information ◽

10.32339/0135-5910-2020-6-586-590 ◽

2020 ◽

Vol 76 (6) ◽

pp. 586-590

Author(s):

S. P. Bersenev ◽

E. M. Slobtsova

Keyword(s):

Crack Detection ◽

Middle Part ◽

Control Line ◽

Magnetic Powder ◽

Nondestructive Control ◽

Automated Control ◽

Ultrasonic Control ◽

Acoustic Contact ◽

In Series

Achievements in the area of automated ultrasonic control of quality of rails, solid-rolled wheels and tyres, wheels magnetic powder crack detection, carried out at JSC EVRAZ NTMK. The 100% nondestructive control is accomplished by automated control in series at two ultrasonic facilities RWI-01 and four facilities УМКК-1 of magnetic powder control, installed into the exit control line in the wheel-tyre shop. Diagram of location, converters displacement and control operations in the process of control at the facility RWI-01 presented, as well as the structural diagram of the facility УМКК-1. The automated ultrasonic control of rough tyres is made in the tyres control line of the wheel-tyre shop at the facility УКБ-1Д. The facility enables to control internal defects of tyres in radial, axis and circular directions of radiation. Possibilities of the facility УКБ-1Д software were shown. Nondestructive control of railway rails is made at two facilities, comprising the automated control line of the rail and structural shop. The УКР-64Э facility of automated ultrasonic rails control is intended to reveal defects in the area of head, web and middle part of rail foot by pulse echo-method with a immersion acoustic contact. The diagram of rail P65 at the facility УКР-64Э control presented. To reveal defects of the macrostructure in the area of rail head and web by mirror-shadow method, an ultrasonic noncontact electromagnetic-acoustic facility is used. It was noted, that implementation of the 100% nondestructive control into the technology of rolled stuff production enabled to increase the quality of products supplied to customers and to increase their competiveness.

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