A new approach to the effect of sample dimensions and measurement techniques on ultrasonic wave velocity

Though the velocity of ultrasonic waves passing through materials is a highly preferred parameter to indirectly and non-destructively determine the strength properties of rock and concrete, many studies have emphasized that such waves are influenced by many factors, such as sample diameter, length,...

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Published inEngineering geology Vol. 251; pp. 63 - 70
Main Authors Ersoy, Hakan, Karahan, Murat, Babacan, Ali Erden, Sünnetci, Muhammet Oğuz
Format Journal Article
LanguageEnglish
Published Elsevier B.V 09.03.2019
Subjects
concrete
face
geometry
Measurement techniques
polypropylenes
Sample dimension
Ultrasonic wave velocity
ultrasonics
Ultrasonic wave velocity
Sample dimension
Measurement techniques
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Abstract Though the velocity of ultrasonic waves passing through materials is a highly preferred parameter to indirectly and non-destructively determine the strength properties of rock and concrete, many studies have emphasized that such waves are influenced by many factors, such as sample diameter, length, and measurement techniques (semi-direct or indirect). Direct techniques use opposite sides of the materials, semidirect techniques use adjacent faces, and indirect techniques use the same face. In contrast to the results given in many studies so far, the results from this study indicate that the ultrasonic wave velocity is not dependent on the sample geometry and measurement techniques. The tests conducted on the materials of three different lengths showed that ultrasonic wave velocity was not affected by sample length because the differences in values obtained from different lengths were <0.5% for both the polypropylene and rock samples and 1.5% for the concrete samples. The ultrasonic tests were performed on the samples for four different diameters and the differences in values were <1.2% for the polypropylene samples and 1.8% for concrete the samples. The results of testing the different techniques showed that when the travel distance increases, the differences between the values obtained by different methods decrease and this difference is <3% if the sample length is >20 cm. The results clearly indicated that the ultrasonic velocity value of the materials is related to the material homogeneity rather than the sample diameter, length, and different measurement techniques. •The study focuses on effect of sample size and measurement technique on p-wave velocity.•Almost homogeneous material such as polypropylene mono-mineral rock samples and concrete were used in this study.•Sample sizes do not influence longitudinal wave velocity values.•The wave velocity values obtained from different ultrasonic techniques are very similar if the travel distance is >20 cm.
AbstractList Though the velocity of ultrasonic waves passing through materials is a highly preferred parameter to indirectly and non-destructively determine the strength properties of rock and concrete, many studies have emphasized that such waves are influenced by many factors, such as sample diameter, length, and measurement techniques (semi-direct or indirect). Direct techniques use opposite sides of the materials, semidirect techniques use adjacent faces, and indirect techniques use the same face. In contrast to the results given in many studies so far, the results from this study indicate that the ultrasonic wave velocity is not dependent on the sample geometry and measurement techniques. The tests conducted on the materials of three different lengths showed that ultrasonic wave velocity was not affected by sample length because the differences in values obtained from different lengths were <0.5% for both the polypropylene and rock samples and 1.5% for the concrete samples. The ultrasonic tests were performed on the samples for four different diameters and the differences in values were <1.2% for the polypropylene samples and 1.8% for concrete the samples. The results of testing the different techniques showed that when the travel distance increases, the differences between the values obtained by different methods decrease and this difference is <3% if the sample length is >20 cm. The results clearly indicated that the ultrasonic velocity value of the materials is related to the material homogeneity rather than the sample diameter, length, and different measurement techniques.
Though the velocity of ultrasonic waves passing through materials is a highly preferred parameter to indirectly and non-destructively determine the strength properties of rock and concrete, many studies have emphasized that such waves are influenced by many factors, such as sample diameter, length, and measurement techniques (semi-direct or indirect). Direct techniques use opposite sides of the materials, semidirect techniques use adjacent faces, and indirect techniques use the same face. In contrast to the results given in many studies so far, the results from this study indicate that the ultrasonic wave velocity is not dependent on the sample geometry and measurement techniques. The tests conducted on the materials of three different lengths showed that ultrasonic wave velocity was not affected by sample length because the differences in values obtained from different lengths were <0.5% for both the polypropylene and rock samples and 1.5% for the concrete samples. The ultrasonic tests were performed on the samples for four different diameters and the differences in values were <1.2% for the polypropylene samples and 1.8% for concrete the samples. The results of testing the different techniques showed that when the travel distance increases, the differences between the values obtained by different methods decrease and this difference is <3% if the sample length is >20 cm. The results clearly indicated that the ultrasonic velocity value of the materials is related to the material homogeneity rather than the sample diameter, length, and different measurement techniques. •The study focuses on effect of sample size and measurement technique on p-wave velocity.•Almost homogeneous material such as polypropylene mono-mineral rock samples and concrete were used in this study.•Sample sizes do not influence longitudinal wave velocity values.•The wave velocity values obtained from different ultrasonic techniques are very similar if the travel distance is >20 cm.
Author Karahan, Murat
Ersoy, Hakan
Babacan, Ali Erden
Sünnetci, Muhammet Oğuz
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Snippet Though the velocity of ultrasonic waves passing through materials is a highly preferred parameter to indirectly and non-destructively determine the strength...
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StartPage 63
SubjectTerms concrete
face
geometry
Measurement techniques
polypropylenes
Sample dimension
Ultrasonic wave velocity
ultrasonics
Title A new approach to the effect of sample dimensions and measurement techniques on ultrasonic wave velocity
URI https://dx.doi.org/10.1016/j.enggeo.2019.02.011
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