Ultrasonic Measurement of Axial Stress

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Volume 10, Issue 5 (September 1982)

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ISSN: 0090-3973
Page Count: 10

Ultrasonic Measurement of Axial Stress
Heyman, JS
Head of Laboratory for Ultrasonics and research associate, National Aeronautics and Space Administration, Langley Research Center, VA

Chern, EJ
Head of Laboratory for Ultrasonics and research associate, National Aeronautics and Space Administration, Langley Research Center, VA

Abstract

Several applications of ultrasonic techniques are gaining acceptance for accurate preload determination of critical fasteners. In this presentation, one class of techniques based on continuous wave ultrasonics is examined in detail, with benefits and limitations discussed as they apply to accurate determination of fastener preload. The theory of acoustic propagation in strained media is reviewed as it applies to bolt geometries. Propagation measurements in these geometrics require an understanding of guided-wave effects which can influence stress determination. However, studies of the acoustic spectra of rods identify diffraction and resulting mode conversion as the main artifact for such a measurement. The acoustic spectra, obtained with a novel tone burst spectroscopy method, clearly show mode conversion effects at low frequencies to be absent at high frequencies.

Changes in the acoustic spectra are shown to accompany applied stress and suggest an instrument technique for measuring changes in fastener strain. The method, called a Reflection Oscillator Ultrasonic Spectrometer (ROUS), is discussed with an improved technique called Pseudo Continuous Wave Method (PCW) described. Data presented are obtained with the PCW for strain in several engineering materials.

Bolt geometry is shown to have an influence on the stress measurements. In particular, percent fastener length under load is evaluated for its effect on material strain measurements. A computer model predicting a linear dependence on the percent of fastener under load is verified using the PCW technique. Other aspects of bolt geometry are discussed including poor geometry bolts, bolts with transverse holes, and bolt-loading anisotropy. Experimental techniques for performing measurements on fasteners with poor geometry are discussed.

Keywords:
acoustic measurement, axial stress, residual stress, continous wave techniques, pulsed phase locked loop system, residual stress and attenuation, phase insensitive transducers

Paper ID: JTE10253J
DOI: 10.1520/JTE10253J
ASTM International is a member of CrossRef.

Author Title Ultrasonic Measurement of Axial Stress Symposium , 0000-00-00 Committee E07

		Home Journals STPs Manuals Topics Subscriptions/Pricing Digital Library / Journals / Journal of Testing and Evaluation (JTE) / Citation Page Volume 10, Issue 5 (September 1982) Click here to download this paper now for $25 PDF (480K) View License Agreement ISSN: 0090-3973 Page Count: 10 Ultrasonic Measurement of Axial Stress Heyman, JS Head of Laboratory for Ultrasonics and research associate, National Aeronautics and Space Administration, Langley Research Center, VA Chern, EJ Head of Laboratory for Ultrasonics and research associate, National Aeronautics and Space Administration, Langley Research Center, VA Abstract Several applications of ultrasonic techniques are gaining acceptance for accurate preload determination of critical fasteners. In this presentation, one class of techniques based on continuous wave ultrasonics is examined in detail, with benefits and limitations discussed as they apply to accurate determination of fastener preload. The theory of acoustic propagation in strained media is reviewed as it applies to bolt geometries. Propagation measurements in these geometrics require an understanding of guided-wave effects which can influence stress determination. However, studies of the acoustic spectra of rods identify diffraction and resulting mode conversion as the main artifact for such a measurement. The acoustic spectra, obtained with a novel tone burst spectroscopy method, clearly show mode conversion effects at low frequencies to be absent at high frequencies. Changes in the acoustic spectra are shown to accompany applied stress and suggest an instrument technique for measuring changes in fastener strain. The method, called a Reflection Oscillator Ultrasonic Spectrometer (ROUS), is discussed with an improved technique called Pseudo Continuous Wave Method (PCW) described. Data presented are obtained with the PCW for strain in several engineering materials. Bolt geometry is shown to have an influence on the stress measurements. In particular, percent fastener length under load is evaluated for its effect on material strain measurements. A computer model predicting a linear dependence on the percent of fastener under load is verified using the PCW technique. Other aspects of bolt geometry are discussed including poor geometry bolts, bolts with transverse holes, and bolt-loading anisotropy. Experimental techniques for performing measurements on fasteners with poor geometry are discussed. Keywords: acoustic measurement, axial stress, residual stress, continous wave techniques, pulsed phase locked loop system, residual stress and attenuation, phase insensitive transducers Paper ID: JTE10253J DOI: 10.1520/JTE10253J ASTM International is a member of CrossRef. Author Title Ultrasonic Measurement of Axial Stress Symposium , 0000-00-00 Committee E07