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Köp båda 2 för 2966 krRobert L. Mott is professor emeritus of engineering technology at the University of Dayton. He is a member of ASEE, SME, and ASME. He is a Fellow of ASEE and a recipient of the ASEE James H. McGraw Award and the Archie Higdon Distinguished Educator Award from the Mechanics Division. He is a recipient of the SME Education Award. He holds the Bachelor of Mechanical Engineering degree from General Motors Institute (Now Kettering University) and the Master of Science in Mechanical Engineering from Purdue University. He has authored three textbooks; Applied Fluid Mechanics, 7th Edition (2015) and Machine Elements in Mechanical Design, 6th Edition(2018), published by Pearson/Prentice-Hall; and Applied Strength of Materials, 6th Edition (2017) published by CRC Press. His work experience includes serving as a research engineer for General Motors Corporation, consulting for industrial clients, working for the University of Dayton Research Institute, leading the Center for Advanced Manufacturing for UDRI, and expert witness for accident analysis cases for industrial and automotive accident cases. He has also served as a senior personnel for 12 years for the NSF-sponsored National Center for Manufacturing Education based in Dayton, Ohio. Edward M. Vavrek is an associate professor in mechanical engineering technology at Purdue University Northwest, located at the Westville, IN campus, an extension of Purdue University. He is a member of AGMA, ASME, and ASEE. He received his Bachelor of Science in Mechanical Engineering from Purdue University Calumet, Masters in Business Administration from Indiana University Northwest, and Masters in Mechanical and Aeronautical Engineering from the Illinois Institute of Technology. He has significant industrial experience in design and development of machinery, using SolidWorks and Inventor, within the printing/converting, shipbuilding, railroad, steel mill, and automotive industries. He has presented multiple papers on his software developed for the area of machine design. He holds one U.S. patent. He also does extensive private consulting in mechanical design that is highly relevant to the content of this book. Dr. Jyhwen Wang, Ph.D. is a professor with dual appointment in the departments of Engineering Technology and Industrial Distribution and Mechanical Engineering at Texas A&M University in College Station, TX. He holds the degrees of Ph.D. in Mechanical Engineering and Master of Engineering in Manufacturing Engineering from Northwestern University in Evansville, IL, the M.S. in Industrial Engineering and Operations Research from Syracuse University in Syracuse, NY, and the B.S. in Industrial Engineering from Tunghai University in Taichung, Taiwan. He has significant industrial experience with Weirton Steel Corporation in Weirton, West Virginia along with consulting for several organizations. He has participated in funded research and education projects as PI or Co-PI. He is a Fellow of the American Society of Mechanical Engineers and the Society of Manufacturing Engineers. Professional society memberships include ASME, ASEE, SME, NAMRI/SME (North American Manufacturing Research Institute), and NADDRG (North American Deep Drawing Research Group). He has written book sections for Manufacturing Processes for Engineering Materials (2003) and Manufacturing Engineering and Technology(2001) by Kalpakjian and Schmid published by Prentice Hall.
Part 1 Principles of Design and Stress Analysis
1 The Nature of Mechanical Design
The Big Picture
You Are the Designer
11 Objectives of this Chapter
12 The Design Process
13 Skills Needed in Mechanical Design
14 Functions, Design Requirements, and Evaluation Criteria
15 Example of the Integration of Machine Elements into a Mechanical Design
16 Computational AIDS in this Book
17 Design Calculations
18 Preferred Basic Sizes, Screw Threads, and Standard Shapes
19 Unit Systems
110 Distinction Among Weight, Force, and Mass
References
Internet Sites for General Mechanical Design
Internet Sites for Innovation and Managing Complex Design
2 Materials in Mechanical Design
The Big Picture
You Are the Designer
21 Objectives of this Chapter
22 Properties of Materials
23 Classification of Metals and Alloys
24 Variability of Material Properties Data
25 Carbon and Alloy Steel
26 Conditions for Steels and Heat Treatment
27 Stainless Steels
28 Structural Steel
29 Tool Steels
210 Cast Iron
211 Powdered Metals
212 Aluminum
213 Zinc Alloys and Magnesium
214 Nickel-Based Alloys and Titanium
215 Copper, Brass, and Bronze
216 Plastics
217 Composite Materials
218 Materials Selection
References
Internet Sites Related to Design Properties of Materials
Problems
Supplementary Problems
Internet-Based Assignments
3 Stress and Deformation Analysis
The Big Picture
You Are the Designer
31 Objective of This Chapter
32 Philosophy of a Safe Design
33 Representing Stresses on a Stress Element
34 Normal Stresses Due to Direct Axial Load
35 Deformation Under Direct Axial Loading
36 Shear Stress Due to Direct Shear Load
37 Torsional Load Torque, Rotational Speed, and Power
38 Shear Stress Due to Torsional Load
39 Torsional Deformation
310 Torsion in Members Having Noncircular Cross Sections
311 Torsion in Closed, Thin-Walled Tubes
312 Torsion in Open Thin-Walled Tubes
313 Shear Stress Due to Bending
314 Shear Stress Due to Bending Special Shearing Stress Formulas
315 Normal Stress Due to Bending