At-Rest, Active, and Passive Pressure
Lateral earth pressure against a wall depends on wall movement relative to the soil. Three limiting conditions define the range:
- At-rest pressure (K0): no wall movement. K0 = 1 − sinφ' (Jaky, for normally consolidated soils); K0,OC = K0,NC · OCR^(sinφ') for overconsolidated soils. Typical K0 = 0.4–0.5 for loose to medium sands.
- Active pressure (Ka): wall moves away from soil (yielding), soil fails in shear toward wall. Requires wall rotation of about 0.001–0.004H for sands (less for dense, more for loose). Ka ≤ K0 always.
- Passive pressure (Kp): wall moves into soil. Requires large movement (0.01–0.05H) to mobilize. Kp >> K0 >> Ka.
Rankine's Equations
Rankine (1857) assumes a frictionless vertical wall back and horizontal backfill. The lateral earth pressure coefficients are:
Ka = tan²(45° − φ'/2) = (1 − sinφ')/(1 + sinφ')
Kp = tan²(45° + φ'/2) = (1 + sinφ')/(1 − sinφ')
For φ' = 30°: Ka = 0.333, Kp = 3.00. For φ' = 35°: Ka = 0.271, Kp = 3.69. The total horizontal active force per unit length: Pa = 0.5·Ka·γ·H². Its resultant acts at H/3 from the base.
For cohesive soils (c-φ material), the Rankine active pressure becomes:
σa = Ka·γz − 2c√Ka
Note the negative pressure (tension) zone near the surface: z_tension = 2c/(γ√Ka). In practice, do not rely on tensile capacity — use K0 at the surface or assume zero pressure in the tension zone.
Coulomb's Equation
Coulomb (1776) accounts for wall-soil friction angle δ and backfill slope β, making it more accurate for non-vertical walls and inclined fill:
Ka = sin²(θ+φ') / {sin²θ · sin(θ−δ) · [1 + √(sin(φ'+δ)·sin(φ'−β) / (sin(θ−δ)·sin(θ+β)))]²}
where θ = wall back face inclination from horizontal. For a vertical wall (θ=90°), level backfill (β=0), and δ=0, Coulomb Ka reduces to Rankine Ka. Wall friction δ = 2φ'/3 for concrete against soil per AASHTO. Use Coulomb for active pressure with friction; use Rankine for passive pressure because Coulomb overestimates passive pressure significantly when δ > 0 (a log-spiral failure surface governs instead of planar).
Surcharge Effects
For a uniform surcharge q (kPa) on the backfill surface, add Ka·q as a uniform horizontal pressure over the full wall height. A line load Q (kN/m) at distance d from the wall adds a trapezoidal distribution per Boussinesq elastic theory. Traffic surcharge: AASHTO LRFD Section 3.11.6 uses a standard 1.8 m (6 ft) equivalent soil surcharge for highway loading adjacent to walls.
Water table effects: If the water table is at depth hw from the surface within the backfill, effective pressure uses γ' below the water table, but full hydrostatic pressure γw·(H−hw) adds directly to the wall. This is why drainage is critical — a wall designed for drained conditions can fail catastrophically if drainage clogs and the water table rises.
Wall Types and Selection
| Wall Type | Typical Height | Advantage | Limitation |
|---|---|---|---|
| Gravity (concrete or stone) | < 3 m | Simple; no reinforcement | Heavy; high material cost at height |
| Cantilever RC (T-wall) | 2–8 m | Efficient; standard design | Requires spread footing; settlement-sensitive |
| Counterfort RC | > 8 m | Reduces stem bending | More complex formwork |
| MSE (Mechanically Stabilized Earth) | 3–20 m | Flexible; fast; settlement-tolerant | Requires reinforcement; site access for equipment |
| Sheet pile / soldier pile | Variable | Tight spaces; temp or perm | Requires embedment below dredge line |
Stability Checks for Cantilever RC Wall
Overturning: FS_OT = ΣMR / ΣMO ≥ 2.0 (ASD, AASHTO); moments taken about toe. Stabilizing moments from wall stem weight, base slab weight, and soil above heel. Driving moment from Pa acting at H/3.
Sliding: FS_slide = (μ·ΣV + Pp·B_key) / Pa_horizontal ≥ 1.5. Friction coefficient μ = tanφ' for concrete on sand (typically 0.5–0.6); reduce by 2/3 for unfavorable conditions. Passive resistance at toe provides additional resistance when shear key is present.
Bearing: Calculate bearing pressure distribution under base using q = ΣV/B ± (ΣM·6e/B²) where e = eccentricity = B/2 − (ΣMR − ΣMO)/ΣV. Must have e < B/6 for full bearing contact (no tension). Maximum bearing pressure must not exceed allowable soil bearing capacity.
Global stability: perform circular slip surface analysis (Bishop's method) through the retained soil and below the wall base; FS ≥ 1.5 per AASHTO.
Drainage Requirements
Clogged drainage is responsible for more retaining wall failures than inadequate structural design. Standard practice:
- Granular drainage blanket (ASTM C33 No. 57 stone or similar) placed against wall back face, minimum 300 mm thick.
- Perforated pipe collector drain at base of drainage blanket, daylighted or connected to storm system.
- Geotextile filter fabric (ASTM D4751, AOS ≤ 0.212 mm for fine backfill) wrapping drain stone to prevent fines migration.
- Weep holes at ≤ 2.5 m spacing as backup if pipe drain clogs.
AASHTO LRFD Article 11.6.3.4 requires drainage design for all permanent retaining structures. For MSE walls, the FHWA MSE Wall and RSS design manual (FHWA-NHI-10-024) provides complete drainage guidelines.
LRFD for Cantilever Wall Design (ACI 318)
The stem of a cantilever wall is designed as a vertical cantilever beam per ACI 318. The factored lateral pressure at depth z: wu = 1.6 × Ka × γ × z (ASCE 7 load factor for lateral soil pressure). Flexural reinforcement: Mu = wu·H³/6 at the base; As = Mu / (φ·fy·(d − a/2)) with φ = 0.9. Minimum As = 0.0018·b·h (temperature and shrinkage reinforcement, ACI 318 Section 24.4). Provide vertical expansion joints at 9–12 m spacing to control thermal cracking.