👷🏻‍♀️Intro to Civil Engineering Unit 6 – Soil Mechanics & Foundations

Soil mechanics is the study of soil behavior and properties in engineering contexts. It examines how soils interact with water, respond to loads, and affect foundation stability. This knowledge is crucial for designing safe and efficient structures in civil engineering projects. Key soil properties include grain size, plasticity, and shear strength. Understanding these characteristics helps engineers predict soil behavior, classify soils, and make informed decisions about foundation design and construction methods. Water's influence on soil behavior is also a critical consideration in geotechnical engineering.

Study Guides for Unit 6

6.1

Soil Classification and Properties

6 min read

6.2

Soil Mechanics

5 min read

6.3

Foundation Types and Design

3 min read

6.4

Earthworks and Excavation

4 min read

What's Soil Mechanics All About?

Soil mechanics studies the behavior and properties of soils as an engineering material
Focuses on the interaction between soil particles, water, and air within the soil matrix
Investigates how soils respond to various loading conditions (static loads, dynamic loads, earthquakes)
Explores the stability of soil masses and their potential for failure (slope stability, landslides, soil liquefaction)
Examines the compressibility and consolidation of soils under applied loads
Analyzes the shear strength of soils, which is crucial for designing foundations and earth retaining structures
Considers the permeability and seepage of water through soils, affecting groundwater flow and drainage

Key Soil Properties You Need to Know

Grain size distribution describes the relative proportions of different particle sizes in a soil sample
- Classified into gravel (>2mm), sand (0.075-2mm), silt (0.002-0.075mm), and clay (<0.002mm)
Plasticity refers to a soil's ability to undergo deformation without cracking or crumbling
- Measured by Atterberg limits (liquid limit, plastic limit, plasticity index)
Porosity is the ratio of void space to the total volume of a soil sample
- Affects soil compressibility, permeability, and water retention
Permeability measures a soil's ability to allow fluid flow through its pores
- Depends on factors like grain size, void ratio, and soil structure
Shear strength represents a soil's resistance to shearing stresses
- Influenced by cohesion (c) and angle of internal friction ( $\phi$ )
Compressibility describes a soil's tendency to decrease in volume under applied loads
- Related to the soil's void ratio and stress history
Specific gravity is the ratio of the density of soil solids to the density of water
- Used in various calculations and soil classification

How Water Affects Soil Behavior

Water content (w) is the ratio of the mass of water to the mass of solid particles in a soil sample
- Influences soil consistency, strength, and compressibility
Saturation occurs when all the void spaces in a soil are filled with water
- Affects soil behavior under loading and drainage conditions
Capillary action causes water to rise above the water table in fine-grained soils
- Can lead to swelling, shrinkage, and changes in soil strength
Pore water pressure (u) is the pressure exerted by water within soil pores
- Influences effective stress ( $\sigma'$ ) and soil shear strength
Seepage refers to the flow of water through soil pores
- Can cause soil erosion, piping, and instability in earth structures
Consolidation is the gradual reduction in soil volume due to the dissipation of excess pore water pressure
- Occurs in saturated, fine-grained soils under sustained loading
Frost action can cause soil heaving and damage to structures in cold climates
- Results from the formation of ice lenses in soil pores

Stress and Strain in Soils

Total stress ( $\sigma$ $σ$ ) is the sum of effective stress ( $\sigma'$ $σ^{'}$ ) and pore water pressure (u)
- $\sigma = \sigma' + u$
Effective stress ( $\sigma'$ $σ^{'}$ ) is the stress carried by the soil skeleton
- Controls soil deformation and strength
Vertical stress ( $\sigma_v$ $σ_{v}$ ) is the stress acting perpendicular to a horizontal plane
- Increases with depth due to the weight of overlying soil
Horizontal stress ( $\sigma_h$ $σ_{h}$ ) is the stress acting parallel to a horizontal plane
- Often expressed as a fraction of vertical stress ( $K_0 = \sigma_h / \sigma_v$ )
Shear stress ( $\tau$ $τ$ ) is the stress acting parallel to a plane
- Causes soil particles to slide or roll relative to each other
Normal strain ( $\varepsilon$ $ε$ ) is the change in length per unit length in the direction of the applied stress
- $\varepsilon = \Delta L / L$
Shear strain ( $\gamma$ $γ$ ) is the angular distortion caused by shear stress
- $\gamma = \Delta x / h$
Elastic moduli (Young's modulus E, shear modulus G) relate stress to strain in the elastic range
- Useful for predicting soil deformation under working loads

Soil Classification Systems

Unified Soil Classification System (USCS) is widely used in geotechnical engineering
- Based on grain size distribution and plasticity characteristics
- Divides soils into coarse-grained (gravels G, sands S) and fine-grained (silts M, clays C) categories
- Further classified by gradation (well-graded W, poorly-graded P) and plasticity (low L, high H)
AASHTO Soil Classification System is commonly used in highway engineering
- Groups soils into seven main categories (A-1 through A-7) based on grain size and plasticity
- Considers soil suitability for road subgrades and embankments
Other classification systems include the British Soil Classification System (BSCS) and the International Soil Classification System (ISCS)
- Adapted to specific regional or national requirements
Soil classification helps engineers predict soil behavior and select appropriate design parameters
- Provides a common language for describing soils across projects and disciplines

Foundations 101: Types and Purposes

Shallow foundations transfer loads to the near-surface soil layers
- Examples include spread footings, strip footings, and mat foundations
Deep foundations transfer loads to deeper, more competent soil or rock layers
- Examples include piles, drilled shafts, and caissons
Spread footings are isolated, square, or rectangular concrete pads that support individual columns or posts
- Suitable for moderate loads and favorable soil conditions
Strip footings are continuous, elongated concrete members that support load-bearing walls
- Distribute loads linearly and provide stability against lateral forces
Mat foundations are large, continuous slabs that cover the entire footprint of a structure
- Used when soil conditions are poor or loads are heavy
Piles are long, slender elements driven or drilled into the ground
- Transfer loads through friction (skin resistance) and end bearing
Drilled shafts are cast-in-place concrete elements installed by drilling and filling with reinforced concrete
- Provide high load capacity and resistance to lateral loads
Caissons are large, hollow, pre-cast concrete elements sunk into the ground
- Often used for bridge piers and underwater structures

Site Investigation and Soil Testing

Desk study involves gathering and reviewing existing information about the site
- Includes geological maps, aerial photographs, and previous site reports
Site reconnaissance is a visual inspection of the site and surrounding area
- Identifies surface features, topography, and potential geotechnical hazards
Subsurface exploration techniques are used to obtain soil samples and in-situ test data
- Examples include boreholes, test pits, and cone penetration tests (CPT)
Laboratory tests are performed on soil samples to determine their physical and mechanical properties
- Includes grain size analysis, Atterberg limits, shear strength tests, and consolidation tests
In-situ tests are conducted in the field to evaluate soil properties and behavior
- Examples include standard penetration test (SPT), vane shear test, and pressuremeter test
Geophysical methods use non-invasive techniques to map subsurface conditions
- Includes seismic refraction, ground-penetrating radar (GPR), and electrical resistivity
Interpretation of site investigation data is crucial for developing a reliable ground model
- Considers spatial variability, anomalies, and potential geotechnical risks

Practical Applications in Civil Engineering

Foundation design involves selecting the appropriate type, size, and depth of foundation based on soil conditions and structural requirements
- Considers bearing capacity, settlement, and lateral stability
Retaining wall design requires an understanding of soil pressures and stability
- Examples include gravity walls, cantilever walls, and mechanically stabilized earth (MSE) walls
Slope stability analysis assesses the potential for slope failures and landslides
- Involves calculating factors of safety and designing stabilization measures
Pavement design considers the subgrade soil properties and expected traffic loads
- Includes flexible (asphalt) and rigid (concrete) pavement systems
Soil improvement techniques are used to enhance soil properties and performance
- Examples include compaction, grouting, and installation of geosynthetics
Excavation support systems are designed to ensure the stability of temporary excavations
- Includes soldier pile and lagging, sheet pile walls, and diaphragm walls
Geotechnical earthquake engineering evaluates the response of soils and foundations to seismic loading
- Considers liquefaction potential, site amplification, and soil-structure interaction