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Das Foundation Engineering Ch4a
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Das Foundation Engineering Ch4a

Chapter 4: Bearing Capacity of Foundation Design

Introduction to Shallow Foundations

  • Overview of chapter focusing on bearing capacity and settlement of shallow foundations.
  • Discussion on three failure modes of bearing capacity and introduction to Tazaki's theory.
  • Mention of groundwater table effects on bearing capacity calculations.

Types of Foundations

  • Explanation of shallow vs. deep foundations; shallow foundation depth is ≤3-4 times its width.
  • Definition and examples of shallow foundations, including excavation depth considerations.
  • Introduction to various types of footings: isolated, wall/strip, combined, and mat footings.

Spread Footings

  • Description of spread footings as enlargements at the bottom to distribute loads over a larger area.
  • Importance of spread footing in preventing soil punching under high loads from columns.
  • Visual representation and explanation of square and rectangular footings for load distribution.

Wall Footings

  • Definition and purpose of wall or strip footings in supporting bearing walls from superstructures.
  • Emphasis on continuous footings for spreading loads effectively across the foundation width.
  • Importance of foundation width (b), applicable to both isolated and continuous foundations.

Foundation Types and Applications

Ring Footing

  • Discusses the concept of combining isolated footings into a rectangular shape to support two columns, saving cost and time.
  • Explains how to construct a ring footing by creating a larger circular base with a smaller circle cut out.
  • Highlights the application of ring footings in oil reservoirs or similar structures.

Mat Foundation

  • Introduces mat foundation as an alternative when loads from superstructures are too large for spread footings.
  • Describes mat foundations as large spread footings that cover the entire footprint of a structure.
  • Emphasizes the cost-effectiveness of using mat foundations for high-rise buildings.

Soil Failure Types

  • Discusses soil strength and shear stress, noting that most foundation failures are geotechnical rather than structural.
  • Identifies three types of soil failure: general shear failure, local shear failure, and puncture shear failure.
  • Explains settlement as displacement caused by load application on foundations.

General Shear Failure

  • Details how increased load leads to settlement until reaching ultimate bearing capacity (qu).
  • Defines general shear failure occurring suddenly when soil cannot support additional load.
  • Reiterates the importance of understanding ultimate bearing capacity in foundation design.

Understanding Failure Modes in Soil Mechanics

General Overview of Settlement and Load

  • Discusses the impact of increased load on ground surface settlement.
  • Introduces local shear failure, occurring in medium compacted soil.
  • Describes how local shear failure extends gradually from the foundation.

Characteristics of Local Shear Failure

  • Explains that considerable movement is needed for ground surface extension.
  • Notes that local shear failure allows for increased load with larger settlement.
  • Highlights the absence of a peak load in local shear failure.

Punching Shear Failure Explained

  • Defines punching shear failure as occurring in loose soils like sand or soft clay.
  • Illustrates that the ground surface remains flat without significant extension beyond qu.
  • Emphasizes the importance of understanding these failure modes for bearing capacity calculations.

Importance of Bearing Capacity Calculations

  • States that general shear failure is primarily used for calculating bearing capacity.
  • Mentions that local and punching shear failures are controlled by limiting settlement.
  • Outlines the two major parts to learn: bearing capacity and settlement.

Key Theories in Bearing Capacity

  • Introduces Kazakh bearing capacity theory as a fundamental concept.
  • Discusses Mirhoff Tazaki's contributions to geotechnical engineering regarding strip footings.
  • Identifies the bottom of foundations as critical when calculating bearing capacity.

Essential Parameters for Calculating Ultimate Bearing Capacity

  • Defines df as the distance between ground surface and foundation bottom crucial for calculations.
  • Lists necessary soil properties such as unit weight, cohesion, and friction angle for calculations.
  • Describes geostatic pressure at specific locations related to bearing capacity failures.

Understanding Failure Surfaces and Bearing Capacity

  • Introduction to failure surfaces under load and the importance of understanding how they fail.
  • Explanation of the term q , which represents original pressure at the foundation's bottom.
  • Definition of effective stress ( sigma' ) and its significance in relation to groundwater.

Key Parameters for Bearing Capacity

  • Overview of parameters: N_c , N_q , and N_gamma related to cohesion, pressure, and unit weight respectively.
  • Reference to Table 4.1 for Tazaki bearing capacity factors as a resource for calculations.
  • Warning against confusing Tazaki theory with Mirhaf theory when calculating bearing capacity.

Calculating Ultimate Bearing Capacity

  • Importance of knowing which table to use for calculations; Table 4.1 is specific for Tazaki theory.
  • Discussion on friction angle ( phi ) and its impact on determining factors like N_c , N_q , and N_gamma .
  • Example values provided for a 30-degree friction angle: N_c = 37.16, N_q = 22.46, N_gamma = 19.13.

Formulas for Different Footing Types

  • Formula 4.8 used for strip footings; introduction to formula differences based on footing type.
  • Distinction between strip footing (1, 1.5 factor adjustments) versus square footing (1, 1.31 factor adjustments).
  • Clarification that memorization isn't necessary; understanding application is key.

Rectangular Foundations and Circular Footings

  • Mention of upcoming discussions on rectangular foundations using Mirhaf theory in future lectures.
  • Introduction of circular footings with reference to formula 4.18, highlighting different adjustment factors.

Allowable Bearing Capacity Concepts

  • Definition of allowable bearing capacity as a factor of safety applied to ultimate capacity ( q_u / FS).
  • Explanation of net allowable bearing capacity calculation by subtracting original pressure from ultimate capacity.
  • Inquiry into which type—allowable or net allowable—is more conservative in practice.

Understanding Foundation Calculations

Key Concepts in Foundation Design

  • The net allowable should be a smaller number; safety factor must be at least three in all cases.
  • For gamma df calculations, use unit weight of concrete and steel as standard values for civil engineers.
  • Unit weight of concrete is 150 lb/ft³; steel is approximately 490 lb/ft³.

Load Considerations

  • When calculating net allowable load, consider the column load, concrete weight, and soil above.
  • Example 4.1 involves a square foundation with specific soil parameters to determine gross load.
  • Given parameters include friction angle (25°), cohesion (20 kPa), and unit weight of soil (16.5 kN/m³).

Calculation Steps

  • Identify the type of foundation: shallow square foundation (2x2 m).
  • Use appropriate formulas based on friction angle to find necessary parameters for calculations.
  • Calculate ultimate bearing capacity (qu = 1078 kPa); allowable load per unit area is qu divided by safety factor.

Final Load Determination

  • Total allowable gross load calculated as stress or force; ensure clarity between stress and force definitions.
  • Allowable gross load results in a force of 1438 kN; consider implications if asked for net load instead.

Advanced Example Discussion

  • Consideration for calculating net allowable load requires subtracting additional loads from total capacity.
  • Next example focuses on a more complex scenario involving groundwater effects on bearing capacity.

Additional Parameters and Solutions

  • New example features a square footing with dimensions affected by groundwater depth not impacting calculations.
  • Ultimate bearing capacity needs to account for both column loads and concrete weight together affecting failure conditions.

Understanding Effective Stress Calculation

Key Points

  • Review Table 4.1 in the textbook for effective stress calculations.
  • Identify and correct a typo in the example provided.
  • Calculate original effective stress at depth (df): sigma' = gamma_d cdot d - u .

Calculation Steps

  • Use values: cohesion c = 242 , unit weight gamma = 131 , and depth b = 3.25 .
  • Ultimate bearing capacity calculated as 15,900 psf; this is crucial for foundation design.
  • Consider concrete weight: volume of foundation times unit weight gives total self-weight.

Foundation Load Considerations

  • Understand that soil fails under general shear failure when pressure reaches a specific threshold.
  • Two contributors to pressure: column load and concrete dead weight must be considered together.
  • Final pressure calculation yields 165,000 pounds; conservative approach recommended for safety.

Safety Factors and Homework

  • Discuss the importance of being conservative in engineering calculations regarding foundation loads.
  • Factor of safety not applied here to reach true failure conditions; important for accurate assessments.
  • Homework assigned: complete problem 4.1a with reference to example 4.8 for guidance.