Journal of the Korean Geotechnical Society (한국지반공학회논문집)

Korean Geotechnical Society (한국지반공학회)
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A Review of Strength Estimation Method on Ulsan Sedimentary Rocks

울산지역 퇴적암의 강도 추정법 연구 - 점 하중 강도지수로 일축 압축강도 추정 -

  • 민덕기 (울산대학교 공과대학 건설환경 공학부) ;
  • 문종규 (동명기술공단(주), 토질 및 기초기술사)
  • Published : 2006.08.01
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Abstract

In the ASTM and ISRM, an uniaxial compressive strength(${\sigma}_{c}$) has been estimated to be 23(ASTM) or $20{\sim}25$(ISRM) times of point load strength index using a diametral test regardless of the rock rating or geological conditions. This paper presents a relationship between $I_{s}$ and ${\sigma}_{c}$ of a weak sedimentary rocks on Ulsan of the Kyung-Sang Basin in Korea. In the results of 291 for ${\sigma}_{c}$ test and 2310 for $I_{s}$ test from 77 spots, the predicted errors of ${\sigma}_{c}$ determined by strength ratio of ${\sigma}_{c}/I_{s}$ have been relatively less than those determined by linear regression analysis. And in case of weak sedimentary rocks such as mudstones, shales and sandstones, ${\sigma}_{c}$ should be lower than those suggested by ISRM and ASTM.

암석의 점하중 강도지수($I_{s}$)로 일축압축강도(${\sigma}_{c}$)를 추정함에 있어, ASTM이나 ISRM에서는 암종이나 지질학적 생성과정에 관계없이 직경방향 점하중 강도($I_{s}//$)의 23배(ASTM) 혹은 $20{\sim}25$배(ISRM)로 취하고 있다. 여기서는 경상분지의 울산에서 채취한 연약한 퇴적암의 시험결과로 ${\sigma}_{c}$$I_{s}$의 관계를 제시한다. ${\sigma}_{c}$$I_{s}$ 시험결과 ${\sigma}_{c}$의 추정값은 선형 회귀분석 보다는 강도비(${\sigma}_{c}/I_{s}$)로 표현하는 것이 추정오차가 적었다. 그리고 약면이 내포된 퇴적암의 강도비는 ${\sigma}_{c}/I_{s}//$보다 ${\sigma}_{c}/I_{s}{\bot}$의 추정오차가 더 작으므로 ${\sigma}_{c}$추정치는 ASTM이나 ISRM에서 제시한 값보다 낮게 취해야 참값에 가까울 수 있다는 결론을 얻었다.

Keywords

References

  1. 김영수, 서인식, 허도영, 이재호, 김병탁 (2001), '층리면을 고려한 셰일의 공학적 특성', 한국지반공학회 논문집, 제17권, 1호, pp.5-13
  2. 박양대, 윤형대 (1968), '한국지질도-울산도폭', 국립지질 자원연구소
  3. 이영휘, 김용준, 박준규 (2000), '압축강도와 풍화도에 관련된 퇴적암의 공학적 특성', 한국지반공학회 논문집, 제16권, 1호, pp.5-17
  4. 정형식, 유병옥 (1997), '암석의 풍화에 따른 강도변화 특성 및 강도측정에 관한 연구', 한국지반공학회, 제13권, 6호 pp.71-93
  5. ASTM (D 4513-85/91), 'Standard practice for preparing rock core specimens and determining dimensional and shape tolerances'
  6. ASTM (D 5731-95), 'Standard test method for determination of the point load strength index of rock'
  7. ASTM (D 2938-95), 'Standard test method for unconfined compressive strength of intact rock core specimens'
  8. Bieniawski, Z. T. (1975), 'The point-load test in geotechnical practice', Eng. Geol. Vol.9, pp.1-11 https://doi.org/10.1016/0013-7952(75)90024-1
  9. Broch E. and Franklin, J. A. (1972), 'The point-load strength test', Int. J. Rock Mech. Min. Sci. Vol.9, pp.669-697 https://doi.org/10.1016/0148-9062(72)90030-7
  10. Brook, N. (1977), 'The use of irregular specimens for rock strength test', Int. J. Rock Mech. Min. Sci & Geomech. Abstr, Vol.14, pp.193-202 https://doi.org/10.1016/0148-9062(77)90948-2
  11. Bowden, J. P., Lamint-Black, J. and Ullyott, S. (1998), 'Point load testing of week rocks with practicular reference to chalk', Qtly. J. Geol. Vol.31, pp.95-103
  12. Cargill, A. S and Shakoor, A. (1990), 'Evaluation of empirical methods for measuring the uniaxial compressive strength of rock', Int. J. Rock-Mech. Min. Sci. & Geomech. Abstr., Vol.27, pp.495-530 https://doi.org/10.1016/0148-9062(90)91001-N
  13. Chau, K. T and Wong, R. H. C. (1996), 'Uniaxial compressive strength and point load strength of rocks', Int. J. Rock Mech. Min. Sci. & Geomech. Abstr. Vol.33, No.2, pp.183-188
  14. D'Andrea, D. V, Fischer, R. L. and Fogelson, D. E. (1965), 'Prediction of compressive strength from other rock properties', US Bureau of Mines, Report of Investigation, REPT. 6702, pp.1-23
  15. Forster, I. R (1983), 'The influence of core sample geometry on the axial point load test', Int. J. Rock Mech. Min. Sci. & Geomech. Abstr., Vol.20, No.6, pp.291-295 https://doi.org/10.1016/0148-9062(83)90599-5
  16. Grasso, P., Xu, S and Mahtab, A. (1992), 'A problems and promises of index testing of rocks', Int. Tillerson, Wawersik, editors, Rock Mechanics, Balkema, Rotterdam, pp.879-888
  17. Greene, B. H. and Schaffer, A. (1997), 'Laboratory measurement of weak rock strength', Proc. Symp. Characterization of weak and weathered rock masses. Ass. Eng. Geologists. Special Pub. Vol.95.9, pp.73-85
  18. Guidicini, G., Nieble, C. M. and Comides, A. T. (1973), 'Analysis of point load test as a method for preliminary geotechnical clasification of rocks', Bull. Int. Asso. Eng. Geol., No.7, pp.37-52
  19. Gunsallus, K. L. and Kulhawy, F. H. (1984), 'A comparative evaluation of rocks strength measurement', Int. J. Rock Mech. Min. Sci. & Geomech. Abstr, Vol.21, pp.223-248
  20. Hassani, F. P., Scobie, M. J. and Whittaker, B. N. (1980), 'Application of the point load index test to strength determination of rock and proposals for a new size-correction chart', Proc. 21th. US Symp. on Rock Mech., The State-of-the-Art in Rock Mech
  21. Hiramatsu, Y. and Oka, Y. (1966), 'Determining of the tensile strength of rock by a compression test of an regular test piece', Int. J. Rock Mech. Min. Sci, Vol.3, pp.89-99 https://doi.org/10.1016/0148-9062(66)90002-7
  22. Hobbs, D. W. (1963), 'A simple method for assessing the uniaxial compressive strength of rock', Int. J. Rock Mech. Min. Sci. Vol.1, pp.5-15
  23. llivitskii, A. A. and Nickolin, V. I. (1961), 'Determining the strength of rock strata on irregular shaped specimens', Ugol. 36, Vol.1, pp.34-36
  24. ISRM (1981), Part I, 'Suggested method for determination of the uniaxial compressive strength of rock materials'
  25. ISRM (1985), 'Suggested method for determining point load strength'
  26. Jenni, J.P. and Balissat, M. (1979), 'Rock testing methods performed to predict the utilisation possibilities of a tunnel boring machine', Proc. 4th. Congr. Int. Sci. Rock. Mech., Montreaux, pp.267-273
  27. Kahraman, S. (2001), 'Evaluation of simple methods for assessing the uniaxial compressive strength of rock', Int. J. Rock Mech. Min. Sci., Vol.38, pp.98-994
  28. Lashkaripour, G. R. (2001), 'Predictly mechanical properties of mudrock from index parameters', Pub. On-line Springer-Verlag., Vol.33, No.2, pp.183-188
  29. Lee, S. G. (1987), 'Weathering & geotechnical characterization of Korea granites', Ph.D. Thesis, Imperial College, Univ. of London
  30. Pells, P. J. N. (1975), 'The use of the point load test in predicting the compressive strength of rock materials', Australian Geomechanics Journal, Lecture Note, pp.54-56
  31. Peng, Syd. S. (1976), 'Stress analysis of cylinderical rock discs subjected to axial double point load', Int. J Rock Mech. Min. Sci. & Geomech. Abstr., Vol.13, pp.97-101 https://doi.org/10.1016/0148-9062(76)90426-5
  32. Protodyakonov, M. M. and Voblikov, V.S. (1957), 'Determining rock strength with specimens of irregular shape', Ugol. 32. Vol.14. pp.13-17
  33. Protodyakonov, M. M (1960), 'New methods of determining mechanical properties of rocks', Int. Conf on Strata Control, Paris. pp.187-195
  34. Rao, K. S., Venkatappa Rao, G. and Ramarnurthy, T. (1987), 'Strength of sandstone in saturated and partly saturated condiditions', Geotechnical. Engineering., Thailand, Vol.18, pp.99-127
  35. Read, J. R. L., Thornton, P. N. and Regan, W. M. (1980), 'A rational approach to the point load test', Proc. 3rd Austr. & New Zealand Conf Geomech., Wellington, Vol.2
  36. Singh, D. P. and Singh, J. N. (1979), 'Determination of compressive strength of rocks by testing irregular specimens', Mines J. & Fuels, Vol.15, pp.18-22
  37. Wilson, L. C. (1976), 'Tests of bored and driven piles in cretaceous mudstone at Port Elizabeth Africa', Geotechnique, Vol.26, No.1, pp.5-12 https://doi.org/10.1680/geot.1976.26.1.5