Hollee Hitchcock Becker
Structural Competency for Architects
Hollee Hitchcock Becker
Structural Competency for Architects
- Gebundenes Buch
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
Structural Competency for Architects is a comprehensive guide to the basics of structural system and component design
Andere Kunden interessierten sich auch für
- William Chase ThomsonBridge and Structural Design31,99 €
- Bungale S TaranathTall Building Design245,99 €
- Nina RappaportSupport and Resist: Structural Engineers and Design Innovation41,99 €
- James AmbroseSimplified Engineering for Architects and Builders125,99 €
- Ming HuNet Zero Energy Building198,99 €
- Steven A MooreQuestioning Architectural Judgment203,99 €
- Traci Rose RiderBuilding for Well-Being200,99 €
-
-
-
Structural Competency for Architects is a comprehensive guide to the basics of structural system and component design
Produktdetails
- Produktdetails
- Verlag: Jenny Stanford Publishing
- Seitenzahl: 338
- Erscheinungstermin: 12. August 2014
- Englisch
- Abmessung: 274mm x 218mm x 23mm
- Gewicht: 1157g
- ISBN-13: 9780415817875
- ISBN-10: 0415817870
- Artikelnr.: 41671599
- Verlag: Jenny Stanford Publishing
- Seitenzahl: 338
- Erscheinungstermin: 12. August 2014
- Englisch
- Abmessung: 274mm x 218mm x 23mm
- Gewicht: 1157g
- ISBN-13: 9780415817875
- ISBN-10: 0415817870
- Artikelnr.: 41671599
Hollee Hitchcock Becker is an Assistant Professor at The Catholic University of America in Washington, DC where she teaches Structures and Environmental Design. With a BSCE in engineering and a Masters of Architecture, as well as a 30-year career in engineering, business and education, she understands the differences in learning styles between architects and engineers.
Introduction Part 1: Statics and Strengths of Materials 1. Finding
Reactions 2. Bar Forces in Trusses 3. Statics in Simple 4. Shear and Moment
in Beams 5. Load Tracing 6. Simple Stress and Strain 7. Shear and Flexure
in Beams 8. Deflection in Beams 9. Design of Beams 10. Design of Columns
Part 2: Structural Design Principles 11. Structural Patterns 12. Design
Loads 13. Horizontal Framing Systems 14. Lateral Bracing Systems 15.
Structural Typology Part 3: Wood Design 16. Dimensional Lumber Design 17.
Timber Design 18. Glue-Laminated Lumber Design Part 4: Steel Design 19.
Wood connections 20. Steel Beam Design 21. Design of steel compression
members 22. Steel Tension Design 23. Steel Baseplates 24. Steel Connections
Part 5: Concrete Design 25. Concrete Beam Design 26. Concrete Slab Design
27. Doubly Reinforced beams and T-beams 28. Shear and deflection in
Concrete Beams 29. Concrete Columns 30. Development Length 31. Concrete
Walls 32. Footings 33. Precast and Prestressed Concrete Part 6: Masonry and
Alternate Materials 34. Masonry Design 35. Alternate Structural Materials
Conclusion Appendix Index
Reactions 2. Bar Forces in Trusses 3. Statics in Simple 4. Shear and Moment
in Beams 5. Load Tracing 6. Simple Stress and Strain 7. Shear and Flexure
in Beams 8. Deflection in Beams 9. Design of Beams 10. Design of Columns
Part 2: Structural Design Principles 11. Structural Patterns 12. Design
Loads 13. Horizontal Framing Systems 14. Lateral Bracing Systems 15.
Structural Typology Part 3: Wood Design 16. Dimensional Lumber Design 17.
Timber Design 18. Glue-Laminated Lumber Design Part 4: Steel Design 19.
Wood connections 20. Steel Beam Design 21. Design of steel compression
members 22. Steel Tension Design 23. Steel Baseplates 24. Steel Connections
Part 5: Concrete Design 25. Concrete Beam Design 26. Concrete Slab Design
27. Doubly Reinforced beams and T-beams 28. Shear and deflection in
Concrete Beams 29. Concrete Columns 30. Development Length 31. Concrete
Walls 32. Footings 33. Precast and Prestressed Concrete Part 6: Masonry and
Alternate Materials 34. Masonry Design 35. Alternate Structural Materials
Conclusion Appendix Index
Introduction Part 1: Statics and Strengths of Materials 1. Finding
Reactions 2. Bar Forces in Trusses 3. Statics in Simple 4. Shear and Moment
in Beams 5. Load Tracing 6. Simple Stress and Strain 7. Shear and Flexure
in Beams 8. Deflection in Beams 9. Design of Beams 10. Design of Columns
Part 2: Structural Design Principles 11. Structural Patterns 12. Design
Loads 13. Horizontal Framing Systems 14. Lateral Bracing Systems 15.
Structural Typology Part 3: Wood Design 16. Dimensional Lumber Design 17.
Timber Design 18. Glue-Laminated Lumber Design Part 4: Steel Design 19.
Wood connections 20. Steel Beam Design 21. Design of steel compression
members 22. Steel Tension Design 23. Steel Baseplates 24. Steel Connections
Part 5: Concrete Design 25. Concrete Beam Design 26. Concrete Slab Design
27. Doubly Reinforced beams and T-beams 28. Shear and deflection in
Concrete Beams 29. Concrete Columns 30. Development Length 31. Concrete
Walls 32. Footings 33. Precast and Prestressed Concrete Part 6: Masonry and
Alternate Materials 34. Masonry Design 35. Alternate Structural Materials
Conclusion Appendix Index
Reactions 2. Bar Forces in Trusses 3. Statics in Simple 4. Shear and Moment
in Beams 5. Load Tracing 6. Simple Stress and Strain 7. Shear and Flexure
in Beams 8. Deflection in Beams 9. Design of Beams 10. Design of Columns
Part 2: Structural Design Principles 11. Structural Patterns 12. Design
Loads 13. Horizontal Framing Systems 14. Lateral Bracing Systems 15.
Structural Typology Part 3: Wood Design 16. Dimensional Lumber Design 17.
Timber Design 18. Glue-Laminated Lumber Design Part 4: Steel Design 19.
Wood connections 20. Steel Beam Design 21. Design of steel compression
members 22. Steel Tension Design 23. Steel Baseplates 24. Steel Connections
Part 5: Concrete Design 25. Concrete Beam Design 26. Concrete Slab Design
27. Doubly Reinforced beams and T-beams 28. Shear and deflection in
Concrete Beams 29. Concrete Columns 30. Development Length 31. Concrete
Walls 32. Footings 33. Precast and Prestressed Concrete Part 6: Masonry and
Alternate Materials 34. Masonry Design 35. Alternate Structural Materials
Conclusion Appendix Index