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PAPERBACK list:$86.50 Web:$77.85 add to cart Rights & Permissions Free Resources Display this book on your site! Related Titles Assessment of the Performance of Engineered Waste Containment Barriers The Changing Transitions to Adulthood in Developing Countries: Selected Studies Other Related Titles NCHRP Web Doc 14 Laboratory Determination of Resilient Modulus for Flexible Pavement Design: Final Report (1997) Transportation Research Board (TRB) Web Search Builder Use this book's key terms to search within this book, across our collection, or across the Web. Skim This Chapter Skim this chapter and use this chapter's key terms to search within this book. Reference Finder Paste in your own text to find books that relate to your topic. Page 286   E-mail  Facebook  Digg  Stumble  Twitter More Page 286 Front Matter (R1-R4) Table of Contents (R5-R7) Acknowledgments (R8-R8) Abstract (R9-R9) Executive Summary (R10-R13) 1 Introduction and Research Approach (1-9) 2 Resilient Modulus Testing of Asphalt Concrete (10-96) 3 Resilient Modulus Evaluation of Aggregate Base and Subgrade Materials (97-250) 4 Significant General Findings (251-277) 5 Summary, Conclusions and General Recommendations (278-285) References (286-294) A: Diametral Test Equipment and Equations for Data Reduction (295-314) B: Asphalt Concrete Specimen Preparation (315-316) C: Diametral Test Procedure for Resilient Modulus of Asphalt Concrete (317-334) D: Repeated Load Test System Calibration (335-342) E: Test Procedure for Resilient Modulus of Unstabilized Aggregate Base and Subgrade Materials (343-386) F: Effect of Laboratory Testing Variability on Pavement Thickness (387-396) G: Specimen Preparation of Cohesive Soil (397-406) H: Multi-Lab Validation Study (407-434) I: Comparison of Laboratory and Backcalculated Resilient Moduli (435-440) J: Effect of Diametral Test Variables (441-456)

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REFERENCES "The AASHTO Road Test", (1962), Report 6, Highway Research Board, Special Report 61F, National Research Council, Publication 955. 2. Barksdale, R.D., (1971), "Compressive Stress Pulse Times in Flexible Pavements for use in Dynamic Testing", Highway Research Record 345, Highway Research Board. 3. Monismith, C.~., (1989), "Resilient Modulus Testing: Interpretation of Laboratory Results for Design Purposes", Proceedings of the Workshop on Resilient Modulus Testing, Oregon State University, Corvallis, Oregon. Uzan, I., (1985), "Characterization of Granular Materials", TRB, No. 1022, Symposium on Mechanics of Granular Materials, pp. 52-59. 5. Duncan, EM., and Seed, R.B., (1986), "Compaction-Induced Earth Pressures Under Ko Conditions", ASCE, Vol. 112, No. 1, January, pp. 1-23. 6. Allen, I.~. and Thompson, M.R., (19743, "Resilient Response of Granular Materials Subjected to Time-Dependent Lateral Stresses", Transportation Research Board, TRR No. 510, pp. 1-13. Selig, E.T., (1987), "Tensile Zone Effects on Performance of Layered Systems", Geotechnique, Vol. 37, No. 3, pp. 247-254. 8. Nijboer, L.W. (1957), "Einige Betrachtungen uber das MarshalIverfabren zur Untersuchung bituminoser Massen", St4asse und Autobahn S. 9. Heukelom W. and Klomp, A.~.G. (1964), Road Design and Dynamic Loading", Proceedings, Association of Asphalt Paving Technologists, Vol. 33. 10. McLeod, N.W. (1967), "The Asphalt Institute's Layer Equivalency Program", Asphalt Institute, College Park, MD, Res. Series 15. Van der Poet, C. (1954), "A General System Describing He Visco-Elastic Properties of Bitumens and Its Relation to Routine Test Data", KoninklijkeJShell Laboratorium, Amsterdam, Shell Biitumen Rept. 9. 12. CIaessen, A.~.M. and others (1977), Asphalt Pavement Design: The Shell Method", Proceedings, 4th International Conference on He Structure Design of Asphalt Pavements, University of Michigan, Ann Arbor. 13. Kallas, B.F., and Shook, ].F. (1969), "Factors Influencing Dynamic Modulus of Asphalt Concrete", Proceedings, Association of Asphalt Paving Technologists, Vol. 38. 286

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27. SHRP Protocol P07, Resilient Modulus of Asphalt Concrete" (1992), Long Term Pavement Performance Program Directive M-l, November I, 1992. 28. Rogue, R. and Ocular, W.G. (1992), UThe Development of a Measurement and Analysis System to Accurately Determine Asphalt Concrete Properties using the Indirect Tensile Modes, Draft for Association of Asphalt Paving Technologists, Annual Meeting, Charleston, South Carolina. 29. Bonnaure, F.P., Huibers, ASH and Boonders, A. (1982), HA Laboratory Investigation of the Influence of Rest Periods on the Fatigue Characteristics of Bituminous Mixes", Proceedings, Association of Asphalt Paving Technologists, Vol. 5l, Kansas City, Missouri. 30. Terrel, R.~., Awad, I.S., and Foss, L.R. (1974), Techniques for Characterizing Bituminous Materials using a Versatile Triaxial Testing System", ASTM STP No. 561, American Society for Testing and Materials, Philadelphia, PA. 3 ~ . Cochran, G.R. (1989), Minnesota Deparunent of Transportation Experience with Laboratory MR Testing", Proceedings of the Workshop on Resilient Modulus Testing, Oregon State University, Corvallis, Oregon. 32. Vinson, T.S. (1989), "Fundamentals of Resilient Modulus Testing", Proceedings of the Workshop on Resilient Modulus Testing, Oregon State University, Corvallis, Oregon. 33. McGee, N. (1989), "Laboratory MR Investigation of 2331 Mix", Proceedings of the Workshop on Resilient Modulus Testing, Oregon State University, Corvallis, Oregon. 34. Shah, K.A. (1993), "Laboratory Determination of Resilient Modulus of Asphalt Concrete", M.S. Thesis, Department of Civil Engineering, Norm Carolina State University, May. 35. Huang, Y.H. (1993), Pavement Analysis and Design, Prentice Hall, New Jersey, p. 317-318. 36. Seed, H.B., and H.W.N. Fead, (1959), "Apparatus for Repeated Loading Tests on Soils", American Society for Testing Materials, STP No. 254, Philadelphia, pp. 78-87. 37. Terrel, R.~., Awad, I.S., and Foss, L.R., (1974), "Techniques for Characterizing Bituminous Materials using a Versatile Triaxial Testing Systems, Fatigue and Dynamic Testing of Bituminous Mixtures, ASTM STP No. 561, American Society for Testing and Materials, Philadelphia, PA. 38. Barksdale, R.D., (1972), "Laboratory Evaluation of Rutting in Base Course Materialsn, Proceedings of the Third International Conference on He Strucuural Design of Asphalt Pavements", London, England, Vol. I, pp. 161-174. 39. Bishop, A.W., and Wesley, L.D., (1975), "A Hydraulic Triaxial Apparatus for Controlled Stress Pam Testing", Geotechnique, Vol. 25, No. 4, pp. 657~70. 40. Woods, R.D. (1978), "Measurement of Dynamic Soil Properties", Proceedings, ASCE Geotechnical Engineering Division Specialty Conference, Earthquake Engineering and Soil Dynamics, Pasadena, CA., June. 288

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55. Crockford, W.W., Bendana, L.J., Yang, W.S., Rhee, S.K., and Senadheera, S.P., (1990), "Modeling Stress and Strain States in Pavement Structures Incorporating Thick Granular Layers", The Texas Transportation Institute, College Station, Texas. 56. Elliott, R.P., and Thompson, M.R., (1985), "Mechanistic Design Concepts for Conventional Flexible Pavements", Civil Engineering Studies, Transportation Engineering Series No. 42, University of Illinois at Urbana-Champaign. 57. Li, D., and Selig, E.T., (1994), "Resilient Modulus for Fine-Grained Subgrade Soils"? Journal of Geotechnical Engineering, Proceedings of ASCE, Vol. 120, No. 6, June, pp. 939-957. 58. Brown, S.F., (1979), "The Characterization of Cohesive Soils for Flexible Pavement Design", Proceedings, 7th European Conference on Soil Mechanics and Foundation Engineering, Vol. 2, pp. 15-22. 59. Brown, S.F., Louch, S.C., and O'Reilly, M.P., (1987), "Repeated Loaded Loading of Fine Grained Soils", TRRL Contractors Report, CR72, School of Civil Engineering, University of Nottingham, Nottingham, England. 60. Thompson, M.R., and Robnett, Ah., (1979), "Resilient Properties of Subgrade Soils", Transportation Engineering Journal, January, pp. 71-89. 61. Brown, S.F., and Hyde, A.F.~., (1975), "Significance of Cyclic Confining Stress in Repeated Load Triaxial Testing of Granular Material", Transportation Research Board, Transportation Research Record No. 537, Washington, D.C., pp. 49-58. 62. Khedr, S., (1985), "Deformation Characteristics of Granular Base", Transportation Research Board, Transportation Research Record 1043, pp. 131-138. 63. Shakel, B., (1973), "Changes in Soil Suction in a Sand-Clay Subject to Repeated Triaxial Loading", Highway Research Board, Highway Research Record No. 429, pp. 29-39. 64. Sweere, G.T.H., (1990), Unbound Granular Bases for Roads", Ph.D. Thesis, Technical University of Delft, Delft, Netherlands, September. 65. SHRP, (1989), "Resilient Modulus of Unbound Granular Base/Subbase Materials and Subgrade Soils", Proto co! P46, Strategic Highway Research Program, Federal Highway Administration (formerly Transportation Research Board), Washington, D.C., November. 66. Rowe, P.W., and garden, L., (19463, "Importance of Free Ends in Triaxial Testing", ASCE, Vol. 90, SMI. 67. Morgan, I.R., (19663, "The Response of Granular Materials to Repeated Loading", Proceedings, Third Conference, Australian Road Research Board, Sydney, pp. ~ 178-! 192. 68. Clayton, C.R.~., and Khatrush, S.A. (1987), "A New Device for Measuring Local Axial Strains on Triaxial Specimens, Geotechnique, Vol. 36, No. 4, p. 593-597. 290

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69. Filho, Costa L. de M., (1985), "Measurement of Axial Strains in Triaxial Tests on London Clay", Geotechnical Testing Journal, Vol. 8, No. 1, March, pp. 3-13. 70. Burland, J.B., and Symes, M., (1982), "A Simple Axial Displacement Gauge for Use in the Triaxial Apparatus", Geotechnique, Vol. 32, No. 1, pp. 62~5. 71. Baldi, G., Hight, D.W., and Thomas, G.E., (1988), "A Re-evaluation of Conventional Triaxial Test Methods", Advanced Triaxial Testing of Soil and Rock, ASTM STP 9777, Robert T. Donoghe, Ronald C. Chaney, and Marshall L. Silver, Eds., American Society of Testing and Materials, Philadelphia, pp. 219-263. 72. Pezo, R.F., Claros, F., et al., (1992), "Development of a Reliable Resilient Modulus Test for Subgrade and Nongranular Subbase Materials for Use in Routine Pavement Design", University of Texas at Austin. 73. Pezo, R.F., Kim, D-S., Stokoe, K.H., and Hudson, W.R., (1991), "Developing a Reliable Resilient Modulus Testing System", Paper prepared for presentation at the Transportation Research Board Annual Meeting. 74. Thompson, M.R., and Smith, Kid., (1990), "Repeated Triaxial Characterization of Granular Materials", Transportation Research Board, Paper prepared for He 69th Annual Meeting, Washington, D.C. Thompson, M.R., (1989), "Factors Affecting the Resilient Moduli of Soils and Granular Materials", Proceedings of the Workshop on Resilient Modulus Testing, Oregon State University, Corvallis, Oregon. 76. Black, B.K., and Lee, K.~., (1973), "Saturating Laboratory Samples by Back Pressure", Journal of the Soil Mechanics and Foundations Division, Proceedings of ASCE, Vol. 99, No. SMI, January, pp. 76-93. 77. ASTM, (1992), "Standard Practice for Conducting and InterIaboratory Study to Determine the Precision of a Test", Designation E691-92, American Society for Testing and Materials. 78. Palmer, K., (1993), "Modeling of Resilient Modulus Test Results a, School of Industrial and Systems Engineering, Georgia Institute of Technology, Atlanta, GA, August. 79. Kalcheff, I.V., and Hicks, R.G., (1973), "A Test Procedure for Determining He Resilient Properties of Granular Materials", Journal of Testing Evaluation, JTEVA, Vol. 1, No. 6, pp. 472 479. 80. Kim, Dong-Soo, and Drabbk~n, S., (1994), "Accuracy Improvement of External Resilient Modulus Measurements Using Specimen Grouting to End Platens", Transportation Research Record 1462, pp. 65-71. 81. Barksdale, R.D., and Itani, S.Y., "Influencing of Aggregate Shape on Base Behavior" Transportation Research Board, Record No. 1227, pp. 173-182. 291

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Representative terms from entire chapter:

resilient modulus