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Essentials of Critical State Soil Mechanics for Practical Understanding

Critical-State Soil Mechanics (CSSM) provides an effective stress framework for understanding soil behavior under shear-induced loading. This introductory guide covers key CSSM concepts, including one-dimensional consolidation behavior and shear stress versus normal stress relationships. Learn about important material constants, constitutive models, and stress paths in soil mechanics. Discover the significance of overconsolidation, effective stress, and stress paths in undrained and drained soil conditions as outlined by CSSM. Gain insights into critical-state lines, void ratios, and stress paths in varying soil states. This concise guide aims to simplify CSSM principles, making it accessible for practical applications and soil engineering studies.

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Essentials of Critical State Soil Mechanics for Practical Understanding

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  1. 2006 Critical-State Soil Mechanics For Dummies Paul W. Mayne, PhD, P.E.Civil & Environmental EngineeringGeorgia Institute of TechnologyAtlanta, GA 30332-0355www.ce.gatech.eduEmail: paul.mayne@ce.gatech.edu

  2. PROLOGUE • Critical-state soil mechanics is an effective stress framework describing mechanical soil response • In its simplest form here, we consider only shear-induced loading. • We merely tie together two well-known concepts: (1) one-dimensional consolidation behavior, represented by e-logsv’ curves; and (2) shear stress-vs. normal stress (t-sv’) from direct shear box or simple shearing. • Herein, only the bare essence of CSSM concepts are presented, sufficient to describe strength & compressibility response.

  3. Critical State Soil Mechanics (CSSM) • Experimental evidence provided by Hvorslev (1936; 1960, ASCE); Henkel (1960, ASCE Boulder) Henkel & Sowa (1961, ASTM STP 361) • Mathematics presented elsewhere, including: Schofield & Wroth (1968); Burland (1968); Wood (1990). • In basic form: 3 material constants (f', Cc, Cs) plus initial state (e0, svo', OCR) • Constitutive Models, include: Original Cam-Clay, Modified Cam Clay, NorSand, Bounding Surface, MIT-E3 (Whittle, 1993) & MIT-S1 (Pestana) and others (Adachi, Oka, Ohta, Dafalias) • "Undrained" is just one specific stress path • Yet !!! CSSM is missing from most textbooks and undergrad & grad curricula in the USA.

  4. svo'=300 kPa sp'=900 kPa Cr = 0.04 Cc = 0.38 One-Dimensional Consolidation Overconsolidation Ratio, OCR = 3 Cs = swelling index (= Cr) cv = coef. of consolidation D' = constrained modulus Cae = coef. secondary compression k ≈ hydraulic conductivity sv’

  5. sv’ t t t t d gs Direct Simple Shear (DSS) Direct Shear Test Results sv’ Direct Shear Box (DSB)

  6. Void Ratio, e NC CSL CSL Effective stress sv' CSL tanf' CSSM for Dummies CC Void Ratio, e NC Log sv' CSSM Premise: “All stress paths fail on the critical state line (CSL)” Shear stress t f c=0 Effective stress sv'

  7. De ef CSL CSSM for Dummies CC Void Ratio, e Void Ratio, e e0 NC NC CSL CSL svo Effective stress sv' Log sv' tmax = c + s tanf tanf' STRESS PATH No.1 NC Drained Soil Shear stress t Given: e0, svo’, NC (OCR=1) Drained Path: Du = 0 Volume Change is Contractive:evol = De/(1+e0) < 0 c’=0 svo Effective stress sv'

  8. e0 svf svo CSL svf svo CSSM for Dummies CC Void Ratio, e Void Ratio, e NC NC CSL CSL Effective stress sv' Log sv' tanf' STRESS PATH No.2 NC Undrained Soil Du tmax = cu=su Shear stress t Given: e0, svo’, NC (OCR=1) Undrained Path: DV/V0 = 0 +Du = Positive Excess Porewater Pressures Effective stress sv'

  9. CSL CSSM for Dummies CC Void Ratio, e Void Ratio, e NC NC CSL CSL Effective stress sv' Log sv' tanf' Note: All NC undrained stress paths are parallel to each other, thus: su/svo’ = constant Shear stress t DSS: su/svo’NC = ½sinf’ Effective stress sv'

  10. CSSM for Dummies CC Void Ratio, e OC Void Ratio, e CS NC NC CSL CSL Effective stress sv' sp' Log sv' CSL Overconsolidated States: e0, svo’, and OCR = sp’/svo’ where sp’ = svmax’= Pc’ = preconsolidation stress; OCR = overconsolidation ratio tanf' Shear stress t sp' Effective stress sv'

  11. e0 svo' svf' Du CSSM for Dummies CC Void Ratio, e Void Ratio, e OC CS NC NC CSL CSL Effective stress sv' Log sv' CSL Stress Path No. 3 Undrained OC Soil: e0, svo’, and OCR tanf' Shear stress t Stress Path: DV/V0 = 0 Negative Excess Du svo' Effective stress sv'

  12. e0 svo' svo' CSSM for Dummies CC Void Ratio, e Void Ratio, e OC CS NC NC CSL CSL Effective stress sv' Log sv' CSL Stress Path No. 4 Drained OC Soil: e0, svo’, and OCR tanf' Shear stress t Stress Path: Du = 0 Dilatancy: DV/V0 > 0 Effective stress sv'

  13. Critical state soil mechanics • Initial state: e0, svo’, and OCR = sp’/svo’ • Soil constants: f’, Cc, and Cs (L = 1-Cs/Cc) • For NC soil (OCR =1): • Undrained (evol = 0): +Du and tmax = su = cu • Drained (Du = 0) and contractive (decreaseevol) • For OC soil: • Undrained (evol = 0): -Du and tmax = su = cu • Drained (Du = 0) and dilative (Increaseevol) There’s more ! Semi-drained, Partly undrained, Cyclic…..

  14. e0 De ep svo' se' svf' Equivalent Stress Concept CC NC Void Ratio, e Void Ratio, e NC OC CS sp' sp' CSL CSL Effective stress sv' Log sv' CSL 1. OC State (eo, svo’, sp’) tanf' 2. Project OC state to NC line for equivalent stress, se’ Shear stress t su at se’ suOC = suNC De = Cs log(sp’/svo’) De = Cc log(se’/sp’) 3. se’ = svo’ OCR[1-Cs/Cc] svo' se' Stress sv'

  15. Critical state soil mechanics • Previously: su/svo’ = constant for NC soil • On the virgin compression line: svo’ = se’ • Thus: su/se’ = constant for all soil (NC & OC) • For simple shear: su/se’ = ½sin f’ • Equivalent stress: se’ = svo’ OCR[1-Cs/Cc] Normalized Undrained Shear Strength: su/svo’ = ½ sinf’ OCRL where L = (1-Cs/Cc)

  16. Undrained Shear Strength from CSSM

  17. Undrained Shear Strength from CSSM

  18. Porewater Pressure Response from CSSM

  19. Yield Surface Yield Surfaces NC NC CSL OC OC Void Ratio, e Void Ratio, e sp' CSL sp' Normal stress sv' Log sv' CSL • Yield surface represents 3-d preconsolidation • Quasi-elastic behavior within the yield surface Shear stress t Normal stress sv'

  20. Port of Anchorage, Alaska

  21. fs ub qc  qT Cavity Expansion – Critical State Model for Evaluating OCR in Clays from Piezocone Tests where M = 6 sinf’/(3-sinf’) and L= 1 – Cs/Cc  0.8

  22. Critical state soil mechanics • Initial state: e0, svo’, and OCR = sp’/svo’ • Soil constants: f’, Cc, and Cs (L = 1-Cs/Cc) • Using effective stresses, CSSM addresses: • NC and OC behavior • Undrained vs. Drained (and other paths) • Positive vs. negative porewater pressures • Volume changes (contractive vs. dilative) • su/svo’ = ½ sinf’ OCRL where L = 1-Cs/Cc • Yield surface represents 3-d preconsolidation

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