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Wind loads calculation
- 1. Wind Loads Calculation (ASCE 7) Henry Kurniadi
- 2. Structure Loads • Dead Loads: from the weight of the structure itself. • Wind Loads: could be determined based on ASCE 7 (US Standard), Eurocode 1 (EU Code), Wind Code 2004 (Hong Kong Code), GB 50009 (China PR Standard), AS/NZS 1170.2 (Australia/NZ Standard) or other national/international standards/codes.
- 3. WIND LOADS
- 4. Wind Loads According to ASCE 7 • Wind loads are randomly applied dynamic loads. • They are depend on the wind speed, shape, height and topographic location of the structure. • Calculations using US customary units (Metric units also available in ASCE 7-05).
- 5. Wind Speed Curve in Different Region Sea-side Open area Built-up area Big city (Currently not used)
- 6. Surface Roughness and Exposure Surface Definitions Examples Roughness and Exposure B Urban and suburban areas, wooded areas, or other terrain with numerous closely spaced obstructions having the size of single-family dwellings or larger. C Open terrain with scattered obstructions having heights generally less than 30 ft (9.1 m). This category includes flat open country, grasslands, and all water surfaces in hurricane prone regions. D Flat, unobstructed areas and water surfaces outside hurricane prone regions. This category includes smooth mud flats, salt flats, and unbroken ice.
- 7. Basic Wind Speed, V • Basic wind speed, V, based on 3-second gusts, 33 ft (10 m) above ground in a Ground Roughness Exposure C (defined in mph or m/s). • Some regions, such as: Taiwan, coastal China, coastal USA and Japan have very high wind speed; others such as: Indonesia, India and inland USA have lower wind speed.
- 8. Air Flow • The more the air is streamed, the less the reaction force exerted by the structure. • Wind force highly depends on the shape of the structure.
- 9. Wind Directionality Factor, Kd • Wind Directionality Factor, Kd shall be determined from Table 6-4. • This factor to accommodate the cross-sectional shape of the structure.
- 10. Importance Factor, I • An importance factor, I, for the building or other structure shall be determined from Table 6-1 based on building and structure categories listed in Table 1-1. • This factor to accommodate the importance of the structure.
- 11. Velocity Pressure Coefficient Kz • Velocity pressure exponent, Kz, depends on the site relative height to the ground, z. • This means for rooftop structure, z, would be the total height of the component and the building its installed. • This factor to accommodate the absolute height of the structure from ground level.
- 12. Topographic Factor, Kzt • Local abrupt topography affects wind near the ground. • Wind speed depends on shape of hill, location of building, and height above ground. • The value of Kzt was taken as 1 with assumption flat region environment. • This factor to accommodate the topographic area of the structure location.
- 13. Force Coefficient, Cf For chimneys, tanks & • Force coefficient, Cf other similar structures: determined based on the shape of the structure. • This factor to accommodate the wind-facing area of the For trussed towers: structure.
- 14. Velocity Pressure, qz • From Bernoulli’s equation of flow, the wind pressure: (q in psf, V in mph) • The velocity pressure, qz, evaluated at height z shall be calculated by:
- 15. Gust Effect Factor, G • Factor accounting for: – Gustiness and turbulence – Gust frequency – Gust size – Frequency of structure – Structural damping – Aerodynamic admittance – Gust correlation • Gust effect factor, G, could be calculated by • In general, gust more likely to occur at lower altitude.
- 16. Wind Loads According to ASCE 7 FWT • Design wind force for each component shall be determined by: d FSP FCT FL e FAC c • Moment because of wind force calculated b FBF as: a M FSF a FBF b FAC c FSP FCT FL d FWT e FSF