2.5 Fundamentals of Foundation

2.5 Fundamentals of Foundation

Introduction to Foundation Engineering

• A foundation is the lowest part of a structure that transfers its weight, along with all imposed loads, to the underlying soil or rock in a safe, stable, and controlled manner.

• It forms the critical interface between the superstructure and the ground, ensuring that stresses are distributed without exceeding the ground's bearing capacity and without causing excessive or differential settlement.

• Foundation engineering integrates principles from soil mechanics, structural engineering, and construction technology to achieve a safe, economical, and durable design.

• This unit systematically explores the definition, classification, functions, site investigation requirements, and concepts of major foundation types, providing a comprehensive framework for understanding their role in civil engineering projects.

---

1. Definition and Core Functions of a Foundation

1.1 Formal Definition

• A foundation is the engineered, load-bearing element of a structure that:

  1. Distributes concentrated structural loads over a sufficient area of soil or rock.

  2. Transmits these loads to a depth where the supporting material possesses adequate strength and stiffness.

  3. Is placed at a depth safe from environmental influences like frost action, moisture variation, and scour.

1.2 Primary Functions

• Load Distribution: To spread the concentrated column/wall loads over a wider area, reducing the contact pressure to a value less than or equal to the soil's safe bearing capacity.

• Stress Reduction: To ensure the intensity of load (stress) at the foundation level does not cause shear failure in the supporting soil.

• Settlement Control: To limit both total settlement and, more critically, differential settlement to values tolerable for the superstructure.

• Stability Provision: To provide lateral and rotational stability to the structure against forces like wind, earthquake, and earth pressure.

• Level and Alignment: To provide a firm, level, and properly aligned base for constructing the superstructure.

• Mitigation of Adverse Soil Effects: To minimize the impact of problematic soil behaviors such as swelling/shrinkage (expansive clays), collapse (loess), or liquefaction (saturated loose sands).

---

2. Classification of Foundations: Shallow vs. Deep

Foundations are broadly classified based on the depth (D) to width (B) ratio of the foundation element and the mechanism of load transfer.

2.1 Shallow Foundations

• Definition: Foundations where the depth of embedment ($\boldsymbol{D_f}$) is less than or equal to the width ($\boldsymbol{B}$) of the foundation ($\boldsymbol{D_f \leq B}$).

• Mechanism: Primarily transfer load to the soil through vertical bearing pressure on the soil directly beneath the foundation base.

• Types:

  1. Spread Footing (Isolated Footing): Supports a single column. Can be square, rectangular, or circular.

  2. Combined Footing: Supports two or more columns when individual footings would overlap or be too close.

  3. Strip Footing (Continuous Footing): Supports a load-bearing wall. A long strip of concrete.

  4. Mat Foundation (Raft Foundation): A large, continuous slab supporting all columns and walls of a structure. Used when soil bearing capacity is low or column loads are heavy.

2.2 Deep Foundations

• Definition: Foundations where the depth of embedment is significantly greater than the width ($\boldsymbol{D_f > B}$). Typically, $\boldsymbol{D_f > 3B}$ to 5B.

• Mechanism: Transfer structural loads to deeper, more competent soil strata or rock through a combination of end-bearing at the tip and skin friction (shaft resistance) along their embedded surface.

• Types:

  1. Pile Foundation: Slender, column-like elements (concrete, steel, timber) driven, drilled, or cast-in-place into the ground.

  2. Pier Foundation (Drilled Shafts/Caissons): Large-diameter, cylindrical foundations constructed by excavating a deep hole and filling it with concrete. Can be socketed into rock.

  3. Pile Walls (Sheet Piles): Used for earth retention and excavation support rather than primary vertical load-bearing.

  4. Well Foundation: Used for bridges and heavy structures in water; a large hollow structure sunk into the riverbed.

2.3 Comparative Summary

Feature	Shallow Foundations	Deep Foundations
Depth	$\boldsymbol{D_f \leq B}$	$\boldsymbol{D_f > B}$ (often > 3B)
Load Transfer	Primarily through base (bearing)	End-bearing + Shaft Friction
Soil Suitability	Competent soil at shallow depth	Weak/compressible surface soils, need to reach deep strata
Construction	Generally simpler, open excavation	More complex, specialized equipment
Typical Cost	Lower	Higher
Applications	Light to medium buildings, walls	High-rises, bridges, heavy industrial plants, marine structures

---

3. Factors Affecting Foundation Selection and Design

The choice of foundation type and its design parameters is governed by a complex interplay of factors.

3.1 Load-Related Factors

• Magnitude of Loads: Dead load, live load, wind load, seismic load. Heavy loads often necessitate deep foundations.

• Nature of Loads: Static vs. dynamic (machinery), vertical vs. horizontal (retaining walls), concentric vs. eccentric.

• Load Distribution: Isolated column loads vs. continuous wall loads.

3.2 Subsurface (Geotechnical) Factors – Most Critical

• Soil Profile and Stratigraphy: Sequence, thickness, and extent of soil layers.

• Bearing Capacity: Ultimate and allowable bearing capacity of the soil at various depths.

• Compressibility and Settlement Characteristics: Expected magnitude and rate of settlement (consolidation of clays).

• Depth of Groundwater Table: Affects effective stress, bearing capacity, and requires dewatering for construction.

• Presence of Problematic Soils:

  • Expansive/Shrinking Clays

  • Collapsible Soils (Loess)

  • Soft/Compressible Clays and Peat

  • Loose Sands (liquefaction risk)

• Depth to Competent Strata: Location of firm soil or rock suitable for bearing.

3.3 Superstructure-Related Factors

• Structural Form and Sensitivity: Framed buildings, load-bearing walls, silos, chimneys. Sensitivity to differential settlement.

• Architectural Requirements: Presence of basements, underground utilities, adjacent structures.

3.4 Construction and Environmental Factors

• Construction Methods and Access: Availability of equipment, space constraints.

• Noise and Vibration Limitations: In urban areas, may preclude driven piles.

• Durability Requirements: Exposure to chemicals, sulfate attack, marine environment.

• Frost Depth: Foundation must be placed below the local frost penetration depth to prevent frost heave.

• Scour Potential: For bridges in watercourses.

3.5 Economic and Regulatory Factors

• Project Cost: Balancing initial cost with long-term performance and risk.

• Time Constraints: Drilled shafts may be slower than driven piles.

• Local Building Codes and Regulations: Prescriptive or performance-based requirements.

---

4. Site Investigation for Foundation Design

A thorough site investigation is non-negotiable for safe and economical foundation design.

4.1 Objectives Specific to Foundation Engineering

• To establish a reliable subsurface profile (soil/rock layers) across the site.

• To determine geotechnical design parameters ($\boldsymbol{c}$, $\boldsymbol{\phi}$, $\boldsymbol{E_s}$, $\boldsymbol{C_c}$, etc.) for each relevant layer.

• To locate the groundwater table and assess its fluctuations.

• To evaluate the allowable bearing capacity at various depths.

• To estimate the magnitude and rate of settlement.

• To identify any construction difficulties (boulders, high water table, artesian pressure).

4.2 Investigation Program Components

• Desk Study: Review of geological maps, previous reports, aerial photographs.

• Field Reconnaissance: Walk-over survey to observe surface conditions, drainage, signs of slope instability, existing structures.

• Subsurface Exploration:

  • Borings: To obtain samples and conduct Standard Penetration Tests (SPT). Number and depth planned based on structure footprint and variability.

  • Field Tests: SPT, Cone Penetration Test (CPT), Vane Shear Test (VST), Pressuremeter Test (PMT) to obtain in-situ properties.

  • Laboratory Testing: On disturbed and undisturbed samples to determine classification, strength, and compressibility.

• Geophysical Surveys: Useful for profiling large areas, detecting rock depth, cavities.

4.3 Foundation Investigation Report

• This report translates investigation data into actionable design information. It must include:

  • Recommended foundation type (shallow/deep) and embedment depth.

  • Allowable bearing pressure for shallow foundations.

  • Pile type, length, and capacity for deep foundations.

  • Estimated total and differential settlements.

  • Groundwater control recommendations (dewatering needs).

  • Construction precautions (excavation support, protection of adjacent structures).

---

5. Concepts of Spread and Mat Foundations

5.1 Spread Footings (Isolated/Column Footings)

• Concept: The most basic type of shallow foundation. It "spreads" the concentrated column load over a sufficiently large area of soil.

• Design Philosophy: The footing size (plan area) is designed so that the net applied pressure (total load/area minus overburden pressure removed) is less than the net safe bearing capacity of the soil.

• Key Design Aspects:

  1. Size Determination (Bearing Capacity):

     $\boldsymbol{q_{net(safe)} \geq \frac{P}{A}}$

     where, $\boldsymbol{P}$ is the column load and $\boldsymbol{A = B \times L}$ is the footing area.

  2. Settlement Check: Ensure calculated settlement (elastic + consolidation) is within permissible limits.

  3. Structural Design: The footing slab must be thick enough to resist punching shear around the column and bending moment.

     • Critical Section for Moment: At the face of the column.

     • Critical Section for Shear: At a distance $\boldsymbol{d/2}$ from the column face (two-way/punching) and at a distance $\boldsymbol{d}$ from the column face (one-way/beam shear), where $\boldsymbol{d}$ is the effective depth of the footing.

• Types:

  • Pad Footing: Square or rectangular.

  • Sloped/Stepped Footing: To save concrete in large footings.

5.2 Mat (Raft) Foundation

• Concept: A single, continuous, thick reinforced concrete slab that supports the entire building. It behaves like a floor slab turned upside down, resting directly on the soil.

• Principle: The large area of the mat reduces the contact pressure to a very low value. It also helps bridge over localized soft spots in the soil.

• When to Use a Mat Foundation:

  1. Soil has low bearing capacity, requiring very large spread footings that would overlap.

  2. Column loads are very heavy.

  3. To reduce differential settlement in highly variable or compressible soils.

  4. When the structure is sensitive to differential settlement.

  5. To resist uplift forces or provide buoyancy (basement rafts).

• Structural Behavior: Can be analyzed as:

  • Rigid Mat: Assumes the mat is infinitely stiff relative to the soil. Soil pressure is assumed to vary linearly.

  • Flexible Mat: Analyzes the mat as a flexible plate on an elastic foundation (using Winkler's model or elastic continuum theory). More realistic for most large rafts.

• Key Design Considerations:

  1. Bearing Capacity Check: $\boldsymbol{q_{avg} < q_{net(safe)}}$ and $\boldsymbol{q_{max} < 1.3 q_{net(safe)}}$ typically.

  2. Settlement Analysis: Total and differential settlement are paramount. Often governs the design.

  3. Structural Analysis: Determining bending moments and shear forces in the slab due to non-uniform soil pressure and concentrated column loads. Often requires finite element analysis.

• Types of Mat Foundations:

  • Flat Plate Mat: Uniform thickness slab.

  • Plate Thickened under Columns.

  • Two-Way Beam and Slab Raft: Has downstand beams (or upstand beams) in both directions to increase stiffness.

  • Piled Raft: A hybrid system where a raft is supported by piles, used to further control settlement in very poor soils.

---

Summary and Design Synthesis

• The foundation is the critical link between a structure and the ground, performing the vital functions of load transfer, stress distribution, and settlement control.

• The choice between shallow and deep foundations is a fundamental decision based primarily on subsurface conditions and structural loads.

• A comprehensive, well-planned site investigation is the essential first step, providing the data upon which all design decisions rest.

• Spread footings are the workhorse for isolated columns in good soil, while mat foundations provide a solution for poor soils or heavy loads by acting as a unified platform.

• Successful foundation engineering requires a balanced consideration of geotechnical safety, structural adequacy, constructability, and cost-effectiveness.

---