E-Book, Englisch, 378 Seiten
ISBN: 978-1-4822-1727-8
Verlag: Taylor & Francis
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
Practical Rock Mechanics provides an introduction for graduate students as well as a reference guide for practicing engineering geologists and geotechnical engineers. The book considers fundamental geological processes that give rise to the nature of rock masses and control their mechanical behavior. Stresses in the earth’s crust are discussed and methods of measurement and prediction explained. Ways to investigate, describe, test, and characterize rocks in the laboratory and at project scale are reviewed. The application of rock mechanics principles to the design of engineering structures including tunnels, foundations, and slopes is addressed. The book is illustrated throughout with simple figures and photographs, and important concepts are illustrated by modern case examples. Mathematical equations are kept to the minimum necessary and are explained fully—the book leans towards practice rather than theory.
This text:
- Addresses the principles of rock mechanics as it applies to both structural geology and engineering practice
- Demonstrates the importance of and methods of geological characterisation to rock engineering
- Examines the standard methods of rock mechanics testing and measurement as well as interpretation of data in practice
- Explains connections between main parameters both empirically as well as on the basis of scientific theory
- Provides examples of the practice of rock mechanics to major engineering projects
Practical Rock Mechanics teaches from first principles and aids readers’ understanding of the concepts of stress and stress transformation and the practical application of rock mechanics theory. This text can help ensure that ground models and designs are correct, realistic, and produced cost-effectively.
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Weitere Infos & Material
Introduction to rock mechanics
Introduction
Differentiating between soil and rock
Mechanics of failure
Classification of intact rock
Compressive strength of weak rock
Origins of shear strength in intact rock
Shear strength parameters for the sample in Figure
Stability of a cut slope in weak rock
Discontinuities in rock masses
The importance of discontinuities to stability
Early lessons and the relevance of rock mechanics
Application of rock mechanics
History of the subject area
Rock mechanics as a scientific discipline
Load changes
Fundamental mechanics
Definitions
Mohr circle representation of stress-state
Stress concentration in underground openings
Stresses below foundations
Effective stress
Rock deformation and behaviour
Direct shear
Simple shear and associated rock structures
Surface features on rock fractures
Conclusions to this section
Geological processes and the nature of rock masses
Introduction
Earth stresses
Faults
Folding
Rock textures, fabrics and effect on properties
Rock joints and other discontinuities
Major geological structures
Hydrogeology of rock masses
Introduction
Fundamental concepts and definitions
Hydraulic conductivity and permeability
Measuring hydraulic conductivity
Typical parameters
Unconfined and confined aquifers and storage
Compartmentalisation, aquicludes and aquitards
Flow paths
Characterisation and prediction of hydrogeological conditions for projects
Grouting
Hydrogeological modelling
Characterising rock for engineering purposes
Introduction
Initial stages of site investigation
Field mapping
Trial excavations
Discontinuity surveys
Remote measurement
Interpretation
Rose diagrams
Stereographic interpretation
Roughness measurement
Ground investigation techniques
Description and classification of rocks
Rock mass classifications
Interpreting ground conditions and reporting
Contracts for construction
Instrumentation and monitoring
Properties and parameters for design
Introduction
Sampling
Role of index testing
Basic characterisation
Rock strength and its measurement
Rock deformability
Rock shear strength at mass scale
Hydraulic conductivity and related parameters
Foundations on rock
Introduction
Design of shallow foundations
Difficult sites
Deep foundations
Case example: The Izmit Bay crossing: Rock engineering for the anchorage of a major suspension bridge
Site formation
Rock slopes
engineering
Design of engineering works
Slope formation
Quarrying
Open-pit slopes
Underground excavations
Introduction
Difference between tunnels and caverns
Stability categories for underground excavations
Investigation
Design
Construction
Cavern construction
Conversion factors (to two decimal places)
References
