Transcript Structures
STRUCTURAL ENGINEERING What Does a Structural Engineer Do? What Does a Structural Engineer Do? Roles of a Structural Engineer • Lead engineer/Project engineer • Consultant for an architect • Consultant for another engineer, insurance companies, lawyers, etc. • As well as: – Aerospace design. – Product design, etc. for industries. – Facilities engineer. Lead or Project Engineer • Defines project goals – Costs – Performance requirements • Supervises design based on these requirements. • Outlines tasks – What needs to be done & who will do it • Organizes Project – Calendar – Sequence Palm Valley Interchange Lower Granite Dam Lock Repair – Jarrod Milligan Consulting for an Architect or Engineer • The architect works with the client to establish project requirements: – – – – – space requirements and relationships siting aesthetics lighting budget Consulting for an Architect or Engineer • The engineer’s job is to make the architect look good. – Ensure integrity of structure – Provide economical solutions. – Develop innovative ways to solve new problems and use new materials. Boise Air Terminal Forensic Engineering • Finding out what went wrong. – Insurance companies – Lawyers Design Loads • Design loads include: – Dead loads • Self-weight, • “Permanent” contents. – Live loads • Occupants, • Transient contents – Environmental loads • Wind, snow, earthquake, etc. Uncertainty • Dead loads can be predicted with some confidence. • Live load and environmental load predictions are much more uncertain. – E.g., it is nearly impossible to say what will be the exact maximum occupancy live load in, say, a classroom. – It is also difficult to say how that load will be distributed in the room. Uncertainty (cont.) • Structural codes account for this uncertainty two ways: – We chose a conservative estimate (LARGE estimate) for the load: • E.g., a “50-year” wind load, which is a wind load that occurs, on average, only once in 50 years. – We factor that estimate upwards just to be sure. Load Factors • Newer codes have separate load and resistance factors: – Load factors “overestimate” the load. – Resistance factors “underestimate” the strength of the structure. • Dead load factors range from 1.1 to 1.4 – Smaller uncertainty. • Environmental and live load factors range from 1.7 to 2.0 and higher. – Higher uncertainty Simplified Wind Loads • Since we can’t predict exactly the maximum load a given structure will experience, the code provides: – Rational procedures for estimating a reasonable maximum value – Procedures for arranging the loads on the structure. • Experience has shown that if the engineer follows these procedures he/she can expect the structure to perform properly (i.e., not collapse, etc.) Wind Loads • What factors should the wind design loads consider? Summary • Design loads used by engineers represent rational estimates of loads that we should consider in our design. – Experience has shown if we design for these loads, the building should survive for a reasonable amount of time (50 years or more). Summary (cont.) • The models try to consider situations that will have a significant effect on the design load. – Max wind speed, building height and shape, etc. • The maximum loads estimated by the design codes are then factored to add a safety margin to our calculations. Example Building Design Methods • Method 1 – Simplified Procedure: – – – – – Simple diaphragm building, Low-rise, Enclosed, Regular geometry, symmetric, Not flexible, prone to flutter/vortex shedding, torsion etc. • Method 2 – Analytic Procedure. • Method 3 – Wind Tunnel Procedure. Wind Loads on Structures Gust Factor, G • G = 0.85 for rigid, low rise buildings Wall Pressure Coefficients, Cp Wind Velocity Pressure Importance Factor • • • • Agriculture Buildings “Typical” Buildings Hazardous Buildings Essential Facilities Category I Category II Category III Category IV Wind Load Map: Western US Wind speeds in MPH (kph) Velocity Pressure Exposure Coefficients Exposure B, Case 2 Velocity Pressure Exposure Coefficients Notes • Case 1 – a. All components and cladding. – b. Main wind force resisting system in low-rise structure designed using Figure 6-10 [Method 2]. • Case 2 – a. All main force wind resisting systems in buildings except those in low-rise buildings designed using Figure 6-10. – b. All main wind force resisting systems in other structures. • We will use Case 2. Velocity Pressure Exposure Coefficients (cont.) Exposure Categories • Exposure B: – Urban and suburban areas, wooded areas… Exposure B shall be assumed unless the site meets the definition of another type of exposure. • Exposure C – Open terrain with scattered obstructions… • Exposure D – Flat unobstructed areas exposed to wind flowing over open water for a distance of at least one mile… Directionality Factor Kd Topographic Factor Kzt If flat terrain Kzt = 1 Wind Loads • Calculate Wind Loads – Wind From East – Wind From West 6.14 5.66 9.80 9.05 8.06 6.89 6.89 5.66 5.66 15.97 14.71 13.72 12.54 12.54 15.97 14.71 13.72 12.54 12.54