Part 1: Introduction Chapter 1: Introduction Part 2: Facts; Principles; Methods Chapter 2: Stress and Strain: Important Relationships Chapter 3: The Behavior of Bodies Under Stress Chapter 4: Principles and Analytical Methods Chapter 5: Numerical Methods Chapter 6: Experimental Methods Part 3: Formulas and Examples Chapter 7: Tension, Compression, Shear, and Combined Stress Chapter 8: Beams; Flexure of Straight Bars Chapter 9: Bending of Curved Beams Chapter 10: Torsion Chapter 11: Flat Plates Chapter 12: Columns and Other Compression Members Chapter 13: Shells of Revolution; Pressure Vessels; Pipes Chapter 14: Bodies in Contact Undergoing Direct Bearing and Shear Stress Chapter 15: Elastic Stability Chapter 16: Dynamic and Temperature Stresses Chapter 17: Stress Concentration Factors Appendix A: Properties of a Plane Area Appendix B: Glossary: Definitions Appendix C: Composite Materials Name Index Subject Index
McGraw-Hill authors represent the leading experts in their fields and are dedicated to improving the lives, careers, and interests of readers worldwide Richard G. Budynas is Professor Emeritus of the Kate Gleason College of Engineering at Rochester Institute of Technology. He has over 40 years experience in teaching and practicing mechanical engineering design. He is the author of a McGraw-Hill textbook, Advanced Strength and Applied Stress Analysis, Second Edition; and co-author of a McGraw-Hill reference book, Roark's Formulas for Stress and Strain, Seventh Edition. He was awarded the BME of Union College, MSME of the University of Rochester, and the Ph.D. of the University of Massachusetts. He is a licensed Professional Engineer in the state of New York.