Synopses & Reviews
AN ACCESSIBLE, HIGHLY VISUAL GUIDE TO MECHANICS AND STRENGTH OF MATERIALS FOR STRUCTURAL DESIGN
This updated edition of the classic Parker/Ambrose guide introduces the basics of applied mechanics and strength of materials by combining clear explanations with fundamental practice exercises. Generously supplemented with more than 250 two- and three-dimensional illustrations, this book emphasizes visualizing concepts rather than rote learning and complex mathematics. Simplified Mechanics and Strength of Materials, Sixth Edition features:
* A study of indeterminate structures and ultimate strength resistance of structures, as well as combined forces and stresses
* Up-to-date code and technology information
* Analysis of trusses, beams, compression members, connectors for structural steel, retaining walls, and rigid frames
* An examination of noncoplanar force systems, stress and deformation, and properties of sections
* Exercise problems, with answers, that emphasize direct problem solving using basic concepts, simple analytical formulas, and logical procedures
Whether used alone or in conjunction with Simplified Engineering for Architects and Builders, Ninth Edition, this book is a fundamental resource for students and professionals in architecture, landscape architecture, construction, and civil engineering.
Another in the "Simplified" series of books from Parker and Ambrose. This manual takes the basics of strength of materials and helps the professional apply them to structural design.
Requiring little in the way of mathematic ability, but providing much information, this guide shows readers how they can understand and predict how a building and its materials will perform when exposed to a variety of external forces (mechanics). New information in this edition includes an analysis of indeterminate structures and the ultimate strength resistance of those structures. A greater emphasis is also placed on the fundamentals, providing professionals with simple concise solutions to common structural problems. Updated code and technology information is included, as are many more illustrations, and a wealth of problems and answers for self-study.
Offers fundamental, practical information in the fields of mechanics and strength of materials, emphasizing elementary structural theory. Revised and expanded to incorporate more specific illustrations of determinate work in the design and investigation of building structures. Features the latest data on indeterminate structures as well as computer applications. Examples utilize elements taken from realistic situations instead of abstract geometric shapes.
About the Author
JAMES AMBROSE is Editor of the Parker/Ambrose Series of Simplified Design Guides. He has practiced as an architect in California and Illinois, and as a structural engineer in Illinois. He recently retired as a professor of architecture at the University of Southern California.
Table of Contents
Preface to the Sixth Edition.
Preface to the First Edition.
Units of Measurement.
Accuracy of Computations.
1. Structures: Purpose and Function.
1.2 Special Considerations for Loads.
1.3 Generation of Structures.
1.5 Internal Forces.
1.6 Functional Requirements of Structures.
1.7 Types of Internal Force.
1.8 Stress and Strain.
1.9 Dynamic Effects.
1.10 Design for Structural Response.
2. Forces and Force Actions.
2.1 Loads and Resistance.
2.2 Forces and Stresses.
2.3 Types of Forces.
2.5 Properties of Forces.
2.7 Force Components and Combinations.
2.8 Graphical Analysis of Forces.
2.9 Investigation of Force Actions.
2.12 Forces on a Beam.
3. Analysis of Trusses.
3.1 Graphical Analysis of Trusses.
3.2 Algebraic Analysis of Trusses.
3.3 The Method of Sections.
4. Analysis of Beams.
4.1 Types of Beams.
4.2 Loads and Reactions.
4.3 Shear in Beams.
4.4 Bending Moments in Beams.
4.5 Sense of Bending in Beams.
4.6 Cantilever Beams.
4.11 Tabulated Values for Beam Behavior.
5. Continuous and Restrained Beams.
5.1 Bending Moments for Continuous Beams.
5.2 Restrained Beams.
5.3 Beams with Internal Pins.
5.4 Approximate Analysis of Continuous Beams.
6. Retaining Walls.
6.1 Horizontal Earth Pressure.
6.2 Stability of Retaining Walls.
6.3 Vertical Soil Pressure.
7. Rigid Frames.
7.1 Cantilever Frames.
7.2 Single-Span Frames.
8. Noncoplanar Force Systems.
8.1 Concurrent Systems.
8.2 Parallel Systems.
8.3 General Noncoplanar Systems.
9. Properties of Sections.
9.2 Moment of Inertia.
9.3 Transferring Moments of Inertia.
9.4 Miscellaneous Properties.
9.5 Tables of Properties of Sections.
10. Stress and Deformation.
10.1 Mechanical Properties of Materials.
10.2 Design Use of Direct Stress.
10.3 Deformation and Stress: Relations and Issues.
10.4 Inelastic and Nonlinear Behavior.
11. Stress and Strain in Beams.
11.1 Development of Bending Resistance.
11.2 Investigation of Beams.
11.3 Computation of Safe Loads.
11.4 Design of Beams for Flexure.
11.5 Shear Stress in Beams.
11.6 Shear in Steel Beams.
11.7 Flitched Beams.
11.8 Deflection of Beams.
11.9 Deflection Computations.
11.10 Plastic Behavior in Steel Beams.
12. Compression Members.
12.1 Slenderness Effects.
12.2 Wood Columns.
12.3 Steel Columns.
13. Combined Forces and Stresses.
13.1 Combined Action: Tension Plus Bending.
13.2 Combined Action: Compression Plus Bending.
13.3 Development of Shear Stress.
13.4 Stress on an Oblique Section.
13.5 Combined Direct and Shear Stresses.
14. Connections for Structural Steel.
14.1 Bolted Connections.
14.2 Design of a Bolted Connection.
14.3 Welded Connections.
15. Reinforced Concrete Beams.
15.1 General Considerations.
15.2 Flexure: Stress Method.
15.3 General Application of Strength Methods.
15.4 Flexure: Strength Method.
15.6 Shear in Concrete Beams.
15.7 Design for Shear in Concrete Beams.
Answers to Selected Exercise Problems.