Simplified Engineering for Architects and Builders (eBook)
Wiley (Verlag)
978-1-118-97530-5 (ISBN)
Simplified Engineering for Architects and Builders is the go-to reference on structural design, giving architects and designers a concise introduction to the structures commonly used for typical buildings. The clear, accessible presentation is designed to give you the essential engineering information you need without getting bogged down in excess math, making this book an ideal reference for busy design professionals. This new 12th edition has been completely revised to reflect the latest standards and practices. The instructor site includes a complete suite of teaching resources, including an instructor's manual.
Structural design is an essential component of the architect's repertoire, and engineering principles are at the foundation of every sound structure. You need to know the physics, but you don't necessarily need to know all of the math. This book gives you exactly what you need without losing you in a tangle of equations, so you can quickly grasp and apply the material.
- Understand fundamental concepts like forces, loading, and reactions
- Learn how to design for wood, steel, or concrete construction
- Study structural design standards and develop sound structural systems
- Determine the best possible solutions to difficult design challenges
The industry-leading reference for over 80 years, Simplified Engineering for Architects and Builders is the definitive guide to practical structural design.
JAMES AMBROSE is Editor of the Parker/Ambrose Series of Simplified Design Guides. He practiced as an architect in California and Illinois, and as a structural engineer in Illinois. He was a professor of architecture at the University of Southern California. PATRICK TRIPENY is the Director of the Center for Teaching and Learning Excellence and is a Professor of Architecture at the University of Utah. He teaches the architectural structures sequence in the School of Architecture and the graduate design studio. He is the recipient of several teaching awards including the ACSA/AIAS New Faculty Teaching Award in 2001 and the University of Utah's Early Career Teaching Award in 2000-2001.
The bestselling structural design reference, fully updated and revised Simplified Engineering for Architects and Builders is the go-to reference on structural design, giving architects and designers a concise introduction to the structures commonly used for typical buildings. The clear, accessible presentation is designed to give you the essential engineering information you need without getting bogged down in excess math, making this book an ideal reference for busy design professionals. This new 12th edition has been completely revised to reflect the latest standards and practices. The instructor site includes a complete suite of teaching resources, including an instructor's manual. Structural design is an essential component of the architect's repertoire, and engineering principles are at the foundation of every sound structure. You need to know the physics, but you don't necessarily need to know all of the math. This book gives you exactly what you need without losing you in a tangle of equations, so you can quickly grasp and apply the material. Understand fundamental concepts like forces, loading, and reactions Learn how to design for wood, steel, or concrete construction Study structural design standards and develop sound structural systems Determine the best possible solutions to difficult design challenges The industry-leading reference for over 80 years, Simplified Engineering for Architects and Builders is the definitive guide to practical structural design.
JAMES AMBROSE is Editor of the Parker/Ambrose Series of Simplified Design Guides. He practiced as an architect in California and Illinois, and as a structural engineer in Illinois. He was a professor of architecture at the University of Southern California. PATRICK TRIPENY is the Director of the Center for Teaching and Learning Excellence and is a Professor of Architecture at the University of Utah. He teaches the architectural structures sequence in the School of Architecture and the graduate design studio. He is the recipient of several teaching awards including the ACSA/AIAS New Faculty Teaching Award in 2001 and the University of Utah's Early Career Teaching Award in 2000-2001.
Introduction
The principal purpose of this book is to develop the topic of structural design. However, to do the necessary work for design, use must be made of various methods of structural investigation. The work of investigation consists of the consideration of the tasks required of a structure and the evaluation of the responses of the structure in performing these tasks. Investigation may be performed in various ways, the principal ones being the use of modeling by either mathematics or the construction of physical models. For the designer, a major first step in any investigation is the visualization of the structure and the force actions to which it must respond. In this book, extensive use is made of graphic illustrations in order to encourage the reader in the development of the habit of first clearly seeing what is happening, before proceeding with the essentially abstract procedures of mathematical investigation. When working a problem within the book, the reader is encouraged to begin it by drawing an illustration of the problem.
Structural Mechanics
The branch of physics called mechanics concerns the actions of forces on physical bodies. Most of engineering design and investigation is based on applications of the science of mechanics. Statics is the branch of mechanics that deals with bodies held in a state of unchanging motion by the balanced nature (called static equilibrium) of the forces acting on them. Dynamics is the branch of mechanics that concerns bodies in motion or in a process of change of shape due to actions of forces. A static condition is essentially unchanging with regard to time; a dynamic condition implies a time-dependent action and response.
When external forces act on a body, two things happen. First, internal forces that resist the actions of the external forces are set up in the body. These internal forces produce stresses in the material of the body. Second, the external forces produce deformations, or changes in shape, of the body. Strength of materials, or mechanics of materials, is the study of the properties of material bodies that enable them to resist the actions of external forces, of the stresses within the bodies, and of the deformations of bodies that result from external forces.
Taken together, the topics of applied mechanics and strength of materials are often given the overall designation of structural mechanics or structural analysis. This is the fundamental basis for structural investigation, which is essentially an analytical process. On the other hand, design is a progressive refining process in which a structure is first visualized; then it is investigated for required force responses and its performance is evaluated. Finally—possibly after several cycles of investigation and modification—an acceptable form is derived for the structure.
Units of Measurement
Early editions of this book used U.S. units (feet, inches, pounds, etc.) with equivalent SI (Standard International—aka metric) units in brackets for the basic presentation. In this edition, the basic work is developed with U.S. units only. While the building industry in the United States is now in the slow process of changing to SI units, our decision for the presentation here is a pragmatic one. Most of the references used for this book are still developed primarily in U.S. units and most readers educated in the United States use U.S. units as their first language, even if they now also use SI units.
Table I.1 lists the standard units of measurement in the U.S. system with the abbreviations used in this work and a description of common usage in structural design work. In similar form, Table I.2 gives the corresponding units in the SI system. Conversion factors to be used for shifting from one unit system to the other are given in Table I.3. Direct use of the conversion factors will produce what is called a hard conversion of a reasonably precise form. Even though all of the work done in this book with be in U.S. units, the tables with SI units are given as a handy reference to readers who may be using reference books in SI units or using both systems.
Table I.1 Units of Measurement: U.S. System
Name of Unit | Abbreviation | Use in Building Design |
Length |
Foot | ft | Large dimensions, building plans, beam spans |
Inch | in. | Small dimensions, size of member cross sections |
Area |
Square feet | ft2 | Large areas |
Square inches | in.2 | Small areas, properties of cross sections |
Volume |
Cubic yards | yd3 | Large volumes, of soil or concrete (commonly called simply “yards”) |
Cubic feet | ft3 | Quantities of materials |
Cubic inches | in.3 | Small volumes |
Force, Mass |
Pound | lb | Specific weight, force, load |
Kip | kip, k | 1000 pounds |
Ton | ton | 2000 pounds |
Pounds per foot | lb/ft, plf | Linear load (as on a beam) |
Kips per foot | kips/ft, klf | Linear load (as on a beam) |
Pounds per square foot | lb/ft2, psf | Distributed load on a surface, pressure |
Kips per square foot | k/ft2, ksf | Distributed load on a surface, pressure |
Pounds per cubic foot | lb/ft3 | Relative density, unit weight |
Moment |
Foot-pounds | ft-lb | Rotational or bending moment |
Inch-pounds | in.-lb | Rotational or bending moment |
Kip-feet | kip-ft | Rotational or bending moment |
Kip-inches | kip-in. | Rotational or bending moment |
Stress |
Pounds per square foot | lb/ft2, psf | Soil pressure |
Pounds per square inch | lb/in.2, psi | Stresses in structures |
Kips per square foot | kips/ft2, ksf | Soil pressure |
Kips per square inch | kips/in.2, ksi | Stresses in structures |
Temperature |
Degree Fahrenheit | °F | Temperature |
Table I.2 Units of Measurement: SI System
Name of Unit | Abbreviation | Use in Building Design |
Length |
Meter | m | Large dimensions, building plans, beam spans |
Millimeter | mm | Small dimensions, size of member cross sections |
Area |
Square meters | m2 | Large areas |
Square millimeters | mm2 | Small areas, properties of member cross sections |
Volume |
Cubic meters | m3 | Large volumes |
Cubic millimeters | mm3 | Small volumes |
Mass |
Kilogram | kg | Mass of material (equivalent to weight in U.S. units) |
Kilograms per cubic meter | kg/m3 | Density (unit weight) |
Force, Load |
Newton | N | Force or load on structure |
Kilonewton | kN | 1000 newtons |
Stress |
Pascal | Pa | Stress or pressure (1 pascal = 1 N/m2) |
Kilopascal | kPa | 1000 pascals |
Megapascal | MPa | 1,000,000 pascals |
Gigapascal | GPa | 1,000,000,000 pascals |
Temperature |
Degree Celsius | °C | Temperature |
Table I.3 Factors for Conversion of Units
To Convert from U.S. Units to SI Units, Multiply by: | U.S. Unit | SI Unit | To Convert from SI Units to U.S. Units,... |
Erscheint lt. Verlag | 19.1.2016 |
---|---|
Reihe/Serie | Parker/Ambrose Series of Simplified Design Guides |
Parker/Ambrose Series of Simplified Design Guides | Parker/Ambrose Series of Simplified Design Guides |
Sprache | englisch |
Themenwelt | Schulbuch / Wörterbuch ► Lexikon / Chroniken |
Technik ► Architektur | |
Technik ► Bauwesen | |
Weitere Fachgebiete ► Handwerk | |
Schlagworte | applied physics • architectural engineering • architectural materials • architectural physics • architectural reference • Architecture • Architektur • Bauentwurf • Bauingenieur- u. Bauwesen • Baukonstruktion • Building Design • Civil Engineering & Construction • designing sound structures • engineering basics • engineering for builders • engineering for designers • Engineering Principles • James E. Ambrose • Patrick Tripeny • Simplified Engineering for Architects and Builders 12<sup>th</sup> Edition • structural design • structural design engineering • structural design fundamentals • structural design guide • structural design handbook • structural design reference • Structural Design Textbook • Structural physics • Structures • Tragwerke |
ISBN-10 | 1-118-97530-8 / 1118975308 |
ISBN-13 | 978-1-118-97530-5 / 9781118975305 |
Informationen gemäß Produktsicherheitsverordnung (GPSR) | |
Haben Sie eine Frage zum Produkt? |
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