Structural Wood Design

Abi Aghayere , PhD, PEng, is a professor in the Department of Civil Engineering Technology at Rochester Institute of Technology and the coauthor of Reinforced Concrete Design, Sixth Edition. He is a member of the Editorial Board of ASEE's Journal of Engineering Technology and the winner of RIT's Eisenhart Award for Outstanding Teaching, 2004-2005. He has over seventeen years of diverse experience in the design of building structures of different types and materials. Jason Vigil , PE, is a structural engineer in Rochester, New York, who has been involved in the design of several buildings including many wood structures. He is also an adjunct professor in the Department of Civil Engineering Technology at Rochester Institute of Technology.

Preface. Chapter one INTRODUCTION: WOOD PROPERTIES, SPECIES, AND GRADES. 1.1 Introduction. 1.2 Typical Structural Components of Wood Buildings. 1.3 Typical Structural Systems in Wood Buildings. 1.4 Wood Structural Properties. 1.5 Factors Affecting Wood Strength. 1.6 Lumber Grading. 1.7 Shrinkage of Wood. 1.8 Density of Wood. 1.9 Units of Measurement. 1.10 Building Codes. Chapter two INTRODUCTION TO STRUCTURAL DESIGN LOADS. 2.1 Design Loads. 2.2 Dead Loads. 2.3 Tributary Widths and Areas. 2.4 Live Loads. 2.5 Deflection Criteria. 2.6 Lateral Loads. Chapter three ALLOWABLE STRESS DESIGN METHOD FOR SAWN LUMBER AND GLUED LAMINATED TIMBER. 3.1 Allowable Stress Design Method. 3.2 Glued Laminated Timber. 3.3 Allowable Stress Calculation Examples. 3.4 Load Combinations and the Governing Load Duration Factor. Chapter four DESIGN AND ANALYSIS OF BEAMS AND GIRDERS. 4.1 Design of Joists, Beams, and Girders. 4.2 Analysis of Joists, Beams, and Girders. 4.3 Sawn-Lumber Decking. 4.4 Miscellaneous Stresses in Wood Members. 4.5 Preengineered Lumber Headers. 4.6 Flitch Beams. 4.7 Floor Vibrations. Chapter five WOOD MEMBERS UNDER AXIAL AND BENDING LOADS. 5.1 Introduction. 5.2 Pure Axial Tension: Case 1. 5.3 Axial Tension plus Bending: Case 2. 5.4 Pure Axial Compression: Case 3. 5.5 Axial Compression plus Bending: Case 4. 5.6 Practical Considerations for Roof Truss Design. Chapter six ROOF AND FLOOR SHEATHING UNDER VERTICAL AND LATERAL LOADS (HORIZONTAL DIAPHRAGMS). 6.1 Introduction. 6.2 Roof Sheathing: Analysis and Design. 6.3 Floor Sheathing: Analysis and Design. 6.4 Panel Attachment. 6.5 Horizontal Diaphragms. Chapter seven VERTICAL DIAPHRAGMS UNDER LATERAL LOADS (SHEAR WALLS). 7.1 Introduction. 7.2 Shear Wall Analysis. 7.3 Shear Wall Design Procedure. 7.4 Combined Shear and Uplift in Wall Sheathing. Chapter eight CONNECTIONS. 8.1 Introduction. 8.2 Design Strength. 8.3 Adjustment Factors for Connectors. 8.4 Base Design Values: Laterally Loaded Connectors. 8.5 Base Design Values: Connectors Loaded in Withdrawal. 8.6 Combined Lateral and Withdrawal Loads. 8.7 Preengineered Connectors. 8.8 Practical Considerations. Chapter nine BUILDING DESIGN CASE STUDY. 9.1 Introduction. 9.2 Gravity Loads. 9.3 Seismic Lateral Loads. 9.4 Wind Loads. 9.5 Components and Cladding Wind Pressures. 9.6 Roof Framing Design. 9.7 Second Floor Framing Design. 9.8 Design of a Typical Ground Floor Column. 9.9 Design of a Typical Exterior Wall Stud. 9.10 Design of Roof and Floor Sheathing. 9.11 Design of Wall Sheathing for Lateral Loads. 9.12 Overturning Analysis of Shear Walls: Shear Wall Chord Forces. 9.13 Forces in Horizontal Diaphragm Chords, Drag Struts, and Lap Splices. 9.14 Design of Shear Wall Chords. 9.15 Construction Documents. References. Appendix A Weights of Building Materials. Appendix B Design Aids. Index.