ECIV 325

1. ECIV 325 Introduction to Steel Design Instructor Dr. Dimitris C. Rizos rizos@engr.sc.edu

2. Steel Structures

3. Steel Structures

4. Steel Structures

6. Steel Structures

7. Steel Structures

8. Steel Structures

10. GENERAL DESIGN PROCEDURES Problem Definition Service Functions Location Surface & Subsurface Conditions Infrastructure Environmental Impact etc • Constraints • Material Availability • Zoning Requirements • Construction Expertise ...

11. General Design Procedures Geometric/Architectural Design ………. Altern. 1 Altern. 2 Altern. 3 Altern. n Final Layout Floorplans Elevations etc

12. General Design Procedures Preliminary Structural Design ………. Altern. 1 Altern. 2 Altern. 3 Altern. n Prliminary Design: Location and arrangement of load bearing elements, columns, beams, footings etc., Sizing of structural elements for safety and serviceability Architectural Constraints - Simplicity & Duplication - Fabrication & Construction Procedures Economy: Add preliminary $ value to each design Select Alternative for Final Design

13. General Design Procedures FINAL DESIGN Sizing of Members Design of Details Design Drawings* (Blueprints) Bill of Materials Total Cost *Design Drawings Complete and Easy to Read AISC: Detailing for Steel Construction Engineering for Steel Construction

14. Define External Loads Estimate/Assume Initial Size of Structural Elements Calculate Self Weigth Structural Analysis Select New Sizes Check Design (Codes & Specs) Safe Functional Economic NO YES O.K. Preliminary/Final Design

15. Structural Design Safety Seviceability Economy Practicality

16. ECIV 325 OBJECTIVE FOCUS ON DESIGN OF COMPONENTS Steel Structural Members Tension Members Compression Members (Columns) Beams Beam-Columns Connections

17. Sructural Steel – Typical Composition

18. Structural Steel - Properties Elastic Limit: Transition from elastic to inelastic behavior Yield Point: Stress Fy at the elastic limit Elastic Modulus: Slope of elastic part of curve E~29,000 ksi (200,000 Mpa)

19. Structural Steel - Properties Yield Point: Stress Fy at the elastic limit Ult. Tens. Str: Fu is the maximum stress developed in the inelastic zone

20. Structural Steel - Properties Residual Strain: Permanent deformation after unloading

21. Structural Steel - Properties If Yield Point not Clearly Defined 0.2% Method Draw line parallel to elastic part 0.2% Strain

22. Structural Steel - Characteristics Elasticity: Ability of metal to return to its original shape after loading and subsequent unloading Fatigue: Cycling loading and unloading stresses material above its endurance limit and leads to failure Ductility: Deformation without fracture beyond the elastic limit (ineleastic behavior) High Ductility Toughness: Combination of strength and ductility High toughness

23. Structural Steel - Characteristics Maintenance: Susceptible to Corrosion when exposed to air and water Use paints, or weathering steels Fireproofing: Strength reduces with increased temperature - Fireproofing required

24. Structural Steel - Sections Typical Hot Rolled Steel Shapes See AISC Manual PART 1 Section Properties and other shapes

25. Structural Steel - Sections Typical Cold-Formed Light Gage Steel Shapes See LRFD Manual for other sections

26. Structural Steel - Sections Built-Up Members

27. Structural Steel - Characteristics Buckling: Instability due to slenderness

28. Structural Steel Idealized Case: Material Properties - Uniaxial Cases Real Life: Multiaxial scenarios determine material strength UNCERTAINTIES DESIGN MUST ADDRESS UNDERSTRENGTH

29. Design Loads Most important and difficult task is the accurate estimation of loads applied to a structure over its life Second most difficult is to determine load combinations

30. Design Loads - Types • Dead Loads • Self Weight • Loads Permanantly Attached • Walls • Floor • Roof • Plumbing • Fixtures etc • Easier to determine but are not known a priori • Live Loads • Occupancy - Floor Loads • Snow & Ice • Rain • Traffic Loads for Bridges • Impact Loads • Lateral Loads • Wind • Earthquakes • Other

31. Occupancy - Floor Loads Specified by building codes Check Local (state) specs and requirements In the absence of any available codes refer to: ASCE Standard 7 Minimum Design Loads for Buildings and Other Structures SEI/ASCE 7-05 Typical Variation 40-250 psf

32. Snow & Ice • Depend On • Location • Slope of Roofs Typical Variation 10 psf (45o slope) - 100 psf (North Main) • Account for • Snow Drift • Increased wind loads due to increased surface area of ice coated members

33. Rain Loads More sever on flat roofs ponding Geometric Design for Draining Allow for 0.25 in/ft slope with good drainage facilities

34. Bridges - Traffic Loads American Association of Highway and Transportation Officials AASHTO American Railway Engineering Association AREA • Truck and Lane Load • Impact • Longitudinal

35. Lateral Loads - Wind • Depend On • geographic location • height above ground • types of terrain including surrounding buildings • percentage of openings Effects Severe Effects on tall buildings & long flexible structures • Reference • ASCE Wind Forces on Structures, Transactions ASCE 126 • Uniform Building Code

36. Lateral Loads - Earthquakes • Depend On • geographic location - area seismicity • soil conditions • dynamic properties and characteristics of structure • Analysis & Design • Dynamic • Equiv. Static :Horizontal Loads associated to the mass of the structure • Bracing, Special Connections, Design for Shear etc.

37. Other Loads Soil Pressures Hydrostatic Pressures Blast Thermal Forces Centrifugal Forces (trucks on curved bridges)

38. Loads - References ASCE Minimum design loads for buildings and other structures SEI/ASCE 7-05 NY Specifications for Steel Railway Bridges (AREA 1980) Standard Specifications for Highway Bridges (AASHTO) ICC IBC-2006 2006 International Building Code International Code Council (formerly BOCA, ICBO, and SBCCI)

39. Design Loads Real Life: Design loads difficult to predict UNCERTAINTIES DESIGN MUST ADDRESS OVERLOAD

40. ASSIGNEMENT • READING • Chapter 1 • Homework • 1.5-3, 1.5-6