International Journal of Highway Engineering (한국도로학회논문집)

Korean Society of Road Engineers (한국도로학회)
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Evaluation of Permanent Deformation Characteristics in Crushed Subbase Materials Using Shear Stress Ratio and Large Repeated Triaxial Compression Test

대형반복삼축시험과 전단응력비 개념을 이용한 쇄석 보조기층의 영구변형 특성평가

  • 임유진 (배재대학교 건설환경공학과) ;
  • 김인태 (명지대학교 교통공학과) ;
  • 곽기헌 (배재대학교 건설환경철도공학과)
  • Received : 2011.07.29
  • Accepted : 2011.11.14
  • Published : 2011.12.15
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Abstract

It is well-known that pavement is easily damaged by several factors including permanent deformation and fatigue crack, causing service life of the pavement to be shorter than expected. It is very important to predict amount of permanent deformation for designing pavement and developing design method of pavement. A new model of permanent deformation of pavement materials based on concept of shear stress ratio has been proposed because the lower pavement materials are highly affected by shear strength of the material. In this study a large repetitive triaxial load test has been adapted for performing test of permanent deformation of crushed subbase materials. The test procedure which includes concept of shear stress ratio has been newly developed. Several important model parameters can be obtained from the test that can be used for making correct permanent deformation model of the material.

일반적으로 도로 포장체의 파손은 다양한 요소에 영향을 받는 것으로 알려져 있다. 그 중 가장 주된 포장체 파손형태로서 영구변형(permanent deformation)과 피로균열(fatigue crack)을 들 수 있으며 이들은 포장체의 공용수명을 단축시키는 주요원인이 된다. 도로 포장체의 영구변형을 정확히 예측하는 것은 도로포장체의 내구성을 파악하여 이를 기반으로 포장을 설계하는 포장설계법의 수립에 있어 매우 중요하다. 포장하부구조의 재료거동은 본질적으로 전단강도(${\tau}_{max}$)와 밀접한 연관성을 가지므로 포장하부구조 내 발생한 전단응력${\tau}$의 전단강도에 대한 발생비를 고려하여 영구변형 모델을 설정할 필요가 대두되고 있다. 이에 본 연구에서는 이와 같은 전단응력비 개념을 도입한 대형반복삼축압축시험을 통하여 도로하부 재료 중 국내에서 사용되는 대표적인 입상의 보조기층 재료에 대한 영구변형 특성을 알아보았으며 이를 기초로 영구변형 모델의 수립에 필요한 모델 매개변수를 시험을 통해 새롭게 제안하고자 하였다.

Keywords

References

  1. 강인중 (2004) "조립재료의 다짐에너지 차이에 의한 강도 및 변형특성 ", 석사학위논문, 경주대학교 대학원
  2. 국토해양부 (2004) "한국형 포장설계법 개발과 포장성능 개선방안연구"-공용성 평가 모형의 수정 및 보완, 한국형 포장설계법 연구 최종보고서, 국토해양부
  3. 국토해양부 (2005) "한국형 포장설계법 개발과 포장성능개선 연구", 한국형포장설계법 연구 최종보고서
  4. 박성완, 황규영 (2008) "반복재하시험에 의한 도로기초의 변형특성 평가", 한국도로학회 논문집, 제 10권, 제 1호, pp49-62
  5. 한국도로공사 (1996) "도로설계실무편람"
  6. 한국도로공사 (2009) "도로공사표준시방서"
  7. 황규영, 박성완 (2006) "함수비와 응력조건 영향에 따른 화강 풍화 노상토의 영구변형", 한국도로학회 학술발표회 논문집, pp.205-210
  8. AASHTO T307-99 (2002) "Determining the Resilient Modulus of Soils and Aggregate Materials", Standard Specifications for Transportation Materials and Methods of Sampling and Testing, 20th Edition, AASHTO, Washington D.C.
  9. Barksdale, (1977) "Performance of Asphalt Concrete Pavements", Transportation Engineering Journal, ASCE, Vol. 103, No. 1, January/February 1977, pp. 55-73
  10. Bui, M. T. (2009) "Influence of Some Particle Characteristics on the Small Strain Response of Granular Materials", PhD Dissertation, University of Southampton
  11. El-Mitiny, M. R. (1980). "Material Characterization for Studying Flexible Pavement Behavior in Fatigue and Permanent Deformation", Ph. D. Dessertation, Ohio State University, Columbus, OH
  12. Fredrick Lekarp, Ulf Isacsson and Andrew Dawson (2000), "State of the Art II : Permanent Strain Response of Unbound Aggregates."Journal of Transpotation Engineering, ASCE
  13. Kenis, W. J. (1978), "Predictive Design Procedure, VESYS User's Manual:An Intrim Design Method for Flexible Pavement Using the VESYS Structural Subsystem." Final Report No. FHWARD-77-154, Federal Highway Administration, Department of Transpotation, Washington, D.C.
  14. Kenis, W. J. and Wang, W. (1997), "Calibrating Mechanistic Flexible Pavement Rutting Models from Full Scale Accelerated Tests." Proc. of the 8th International Conference on Asphalt Pavements, Seattle, WA, 663-672
  15. Khedr, S. (1985). "Deformation characteristics of granular base course in flexible pavement." , Transp. Res. Rec. 1043, Transportation Research Board, Washington, D.C., pp131-138
  16. Kim, I. (2005) "Permanent Deformation Behavior of airport flexible pavement base and subbase courses" , PhD Dissertation, Univ. of Illinois at Urbana -Champaign, USA
  17. Korkiala-Tanttu, L. (2008) "Calculation method for permanent deformation of unbound pavement materials" , PhD Dissertation, VTT, Helsinki, Finland
  18. Lekarp, F., and Dawson, A. (1998). "Modeling permanent deformation behavior of unbound granular materials." , Constr. and Build. Mat., 12(1), pp9-18 https://doi.org/10.1016/S0950-0618(97)00078-0
  19. Monismith, C. L., Ogawa, N., and Frume, C. R. (1975), "Permanent deformation characteristic of subgrade soils due to repeated loading." Transportation Research Record. No. 537, National Research Council, Transportation Research Board, Washington, D.C.
  20. Muhanna, A.S. Rahman, M.S. and Lambe, P.C. (1998), "Model for Resilient Modulus and Permanent Strain of Subgrade Soils" Transpotation Research Record, No 1619, Transportation Research Board, Washington, DC.
  21. Niclas Odermatt (1985), "Permanent Deformation in Fine-grained Subgrade Materials." Licentiate Thesis, Royal Institute of Technology
  22. Puppala, A. J., Mohammad, L. N. and Allen, A.(1999), "Permanent Deformation Characterization of Subgrade Soils from RLT Test." Journal of Materials in Civil Engineering, ASCE
  23. Romain, J. E. (1972), "Rut depth prediction in asphalt pavements." Proc., 3rd Int. Conf. on the Struct., Des. of Asphalt Pavements, 705-710
  24. Saeed, Athar, Hall JR., Jim W., and Barker, Walter(2001), "Performance Related Tests of Aggregates for Use in Unbound Pavement Layers", NCHRP Report 453, TRB, National Research Council, Washington, D.C.
  25. Tseng, K. H. and Lytton, R. L. (1989) "Prediction of Permanent Deformation in Flexible Pavement Materials" , Implication of aggregates in the design, construction, and performance of flexible pavements, Ed. by Schreuders and Marek, STP 1016, ASCE, pp.154-172
  26. Wolff, H., and Visser, A. T. (1994). "Incorporating elasto-plasticity in granular layer pavement design." , Proc., Instn. of Civ. Engrs. Transp., 105, 259-272.

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