Characterizing the Shear Modulus Variations of Crude Oil-Contaminated Clay on Small-Strain Range

Document Type : Research Article

Authors

1 Geotechnical master of science, Faculty of Engineering, Razi University, Kermanshah, Iran

2 Associate professor, Faculty of Engineering, Razi University, Kermanshah, Iran

Abstract

The environment is constantly exposed to various pollutants. Petroleum products may contaminate soils located next to industrial areas and other facilities. Oil pollution is one of the pollutions that can cause irreparable damage to the environment. Every day, a large amount of petroleum products enters the environment in various ways. Oil pollution affects the mechanical, chemical and dynamic properties of the soil. Changing the geotechnical properties of the soil is an important issue for structures adjacent to or on oil contaminated soil that can cause collapsing or variation in soil resistance. Since the behavior of many structures and foundations during dynamic loads is in the range of small strains, investigating and evaluating the velocity of waves in the soil skeleton can provide researchers and engineers with useful and significant information about the small-strain behavior of the soil. The importance and value of oil industry structures in Iran, as one of the active countries among oil exporting countries and as a country with a high level of seismicity, has made the research a vital way to improve the design level and accuracy of the behavior of structures exposed to pollution. Despite the wide range of oil industry structures in Iran and the other countries, there is limited literatures on oil-contaminated soil behaviors. Heretofore, the effects of diverse kinds of hydrocarbon contaminants on majority of geotechnical properties of clay soils such as grain size, hydraulic conductivity, plasticity, compressibility, internal friction, cohesion, and shear strength have been investigated. However, there has not been a concentrated research study examining shear wave velocity of hydrocarbon-contaminated clay soils as an important geotechnical property of soil due to the fact that, in small/very small strain levels, the maximum shear modulus of soils can be determined using shear wave velocity. This study aimed to measure the shear wave velocity and consequently, identify the shear modulus of clay soils in oil-contaminated condition with different percentages of contamination, and to compare them with non-oil-contaminated clay soils on small-strain range, using a Bender Element system. In order to prepare comparable clean and contaminated samples (containing 2, 4, 6, 8, 10 and 12 weight percent (wt%) of crude oil, respectively), it was performed similar to the density test method. In this regard, all the clean and contaminated clay samples were tested with a minimum moisture content equal to the optimal moisture content. Bender element tests were conducted on the identically prepared clean and contaminated clay samples at various amounts of frequency (5–20 kHz) and under various confining pressure (50–500 kPa) to find the best method for accurately determining shear wave travel time in the Bender Elements tests. Thereafter, Bender Elements placed in triaxial cell in Razi university laboratory. Bender Elements test conducted to examine shear wave velocity in the clean and contaminated specimens. As a contribution to the literature and potential engineering application, the experimental test results indicated that whilst adding 10wt% of crude oil in clay samples with an increase in the confining pressure, it correspondingly increase the shear wave velocity and consequently increase the shear modulus among of all samples. In addition, at each level of confining pressure, the shear modulus of clean clay was lower than the other contaminated samples. Moreover, under all confining pressures and excitation frequencies, the addition of 10wt% of crude oil caused significant changes in the maximum shear modulus, which was due to the effects of hydrocarbons on the behavior of clay particles. The degree of change due to hydrocarbons is highly dependent on the amount of confining pressure, so that the more the confining pressure is increased; the shear waves velocity an then the shear modulus is increased.

Keywords

Main Subjects

References

  1. Kramer, S.L. (1996) Geotechnical Earthquake Engineering. Prentice Hall, Upper Saddle River, New York.
  2. Meegoda, N.J. and Ratnaweera, P. (1994) Compressibility of contaminated fine-grained soils. Geotechnical Testing Journal, 17, 101-112.
  3. Ratnaweera, P. and Meegoda, N.J. (2006) Shear Strength and Stress-Strain behavior of Contaminated Soils. Geotechnical Testing Journal, 29(2), 1-8.
  4. Khamechiyan, M., Charkhabi, A.H., and Tajik, M. (2007) Effects of crude oil contamination on geotechnical properties of clayey and sandy soils. Engineering Geology, 89(3-4), 220-229.
  5. Singh, S.K., Srivastava, R.K., and John, S. (2008) Settlement characteristics of clayey soils contaminated   with petroleum hydrocarbons. Soil Sediment Contam Int. J., 17, 290-300.
  6. Singh, S.K., Srivastara, R.K., and Siby, J. (2009) Studies on soil contamination due to used motor oil and its remediation. Canadian Geotechnical Journal, 46, 1077-1083.
  7. Di Matteo, L., Bigotti, F., and Ricco, R. (2011) Compressibility of kaolinitic clay contaminated by ethanol-gasoline blends. Journal of Geotechnical Geoenvironmental Eng., 137, 846-849.
  8. Nazir, A.K. (2011) Effect of motor oil contamination on geotechnical properties of over consolidated clay. Alexandria Engineering Journal, 50, 331-335.
  9. Kermani, M. and Ebadi, T. (2012) The Effect of Oil Contamination on the Geotechnical Properties of Fine-Grained Soils. Soil and Sediment Contamination, 21, 655-671.
  10. Elisha, A.T. (2012) Effect of crude oil contamination on the geotechnical properties of soft clay soils of niger delta region of Nigeria. Electronic Journal of Geotechnical Engineering, 17, 1929-1938.
  11. Khosravi, E., Ghasemzadeh, H., Sabour, M.R., and Yazdani, H. (2013) Geotechnical properties of gas oil-contaminated kaolinite. Engineering Geology, 166, 11-16.
  12. Akinwumi, I.I., Diwa, D., and Obianigwe, N. (2014) Effects of crude oil contamination on the index properties, strength and permeability of lateritic clay. International Journal of Applied Sciences and Engineering Research, 3(4), 816-824.
  13. Estabragh, A.R., Beytolahpour, I., Moradi, M., and Javadi, A.A. (2015) Mechanical behavior of a clay soil contaminated with glycerol and ethanol. Eur. J. Environ. Civ. Eng., 20, 503-519.
  14. Trzciński, J., Williams, D.J., and Zbik, M.S. (2015) Can hydrocarbon contamination influence clay soil grain size composition? Appl. Clay Sci., 109-110, 49-54.
  15. Safehian, H., Rajabi, A.M., and Ghasemzadeh, H. (2017) Effect of diesel-contamination on geotechnical properties of illite soil. Eng. Geol., 241, 55-63.
  16. Rajabi, H. and Sharifipour, M. (2017) An Experimental Characterization of Shear Wave Velocity (Vs) in Clean and Hydrocarbon-Contaminated Sand. Geotech. Geol. Eng., 35, 2727-2745.
  17. Rajabi, H. and Sharifipour, M. (2017) Effects of light crude oil contamination on small-strain shear modulus of Firoozkooh sand. Eur. J. Environ. Civil Eng., 8189, 1-17.
  18. Rajabi, H. and Sharifipour, M. (2018) Influence of weathering process on small-strain shear modulus (Gmax) of hydrocarbon-contaminated sand. Soil Dyn. Earthq. Eng., 107, 129-140.
  19. Dyvik, R. and Madshus, C. (1985) Lab Measurements of Gmax Using Bender Elements. In: Advances in the Art of Testing Soils Under Cyclic Conditions, ASCE, 186-196.
  20. Viggiani, G. and Atkinson, J. (1995) Interpretation of bender element tests. Geotechnique, 45(1), 145-154.
  21. Yamashita, S., Kawaguchi, T., Nakata, Y., Mikami, T., Fujiwara, T., and Shibuya, S. (2009) Interpretation of international parallel test on the measurement of Gmax using bender elements. Soils and Foundations, 49(4), 631-650.
  22. Arroyo, M., Muir Wood, D., Greening, P.D., Medina, L., and Rio, J. (2006) Effects of sample size on bender-based axial G0 measurements. Géotechnique, 56(1), 39-52.
  23. Brignoli, E.G., Gotti, M., and Stokoe, K.H. (1996) Measurement of shear waves in laboratory specimens by means of piezoelectric transducers. Geotechnical Testing Journal, 19(4), 384-397.
  24. Jovičić, V., Coop, M., and Simić, M. (1996) Objective criteria for determining G max from bender element tests. Géotechnique, 46(2), 357-362.
  25. Lo Presti, D., Jamiolkowski, M., Pallara, O., Cavallaro, A., and Pedroni, S. (1998) Shear modulus and damping of soils. Géotechnique, 47, 603-617.
  26. Sanchez-Salinero, I. (1987) Analytical Investigation of Seismic Methods Used for Engineering Applications. University of Texas at Austin.
  27. Leong, E.C., Cahyadi, J., and Rahardjo, H. (2009) Measuring shear and compression wave velocities of soil using bender–extender elements. Canadian Geotechnical Journal, 46(7), 792-812.
  28. Lee, J.S. and Santamarina, J.C. (2005) Bender elements: performance and signal interpretation. Journal of Geotechnical and Geoenvironmental Engineering, 131(9), 1063-1070.
  29. Mancuso, C., Simonelli, A., and Vinale, F. (1989) Numerical analysis of in situ S-wave measurements. Proc., 12th Int. Conf. on Soil Mechanics and Foundation Engineering, Rio de Janeiro, 277-280.
  30. Kumar, J. and Madhusudhan, B. (2010) A note on the measurement of travel times using bender and extender elements. Soil Dynamics and Earthquake Engineering, 30(7), 630-634.
  31. Murillo, C., Sharifipour, M., Caicedo, B., Thorel, L., and Dano, C. (2011) Elastic parameters of intermediate soils based on bender-extender elements pulse tests. Soils and Foundations, 51(4), 637-649.
  32. Arulnathan, R., Boulanger, R., and Riemer, M. (1998) Analysis of bender element tests. Geotech Test J., 21, 120-131.
  33. Leong, E.C., Cahyadi, J., and Rahardjo, H. (2009) Measuring shear and compression wave velocities of soil using bender–extender elements. Canadian Geotechnical Journal, 46(7), 792-812.
  34. Kawaguchi, T., Mitachi, T., and Shibuya, S. (2001) Evaluation of shear wave travel time in laboratory bender element test. Proceedings of the International Conference on Soil Mechanics and Geotechnical Engineering, 1, Balkema Publishers, Istanbul.
  35. Sharifi, A., Sharifipour, M., and Rizvandi, A. (2020) Laboratory investigation into the effect of particle sizes on shear wave parameters using bender elements test results. Geotechnical Testing Journal, 43(5), 1216-1232.
Bulletin of Earthquake Science and Engineering
Volume 8, Issue 2 - Serial Number 27
September 2021
Pages 23-36

Files

History

  • Receive Date: 18 July 2020
  • Revise Date: 24 April 2021
  • Accept Date: 10 January 2021

Share

How to cite

Statistics