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MSU ECE 405 - chap4

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Chapter 4. TENSION MEMBER DESIGN4.1 INTRODUCTORY CONCEPTS4.7 Design of tension membersCE 405: Design of Steel Structures – Prof. Dr. A. Varma Tension Member Design Chapter 4. TENSION MEMBER DESIGN 4.1 INTRODUCTORY CONCEPTS • Stress: The stress in an axially loaded tension member is given by Equation (4.1) AP=f (4.1) where, P is the magnitude of load, and A is the cross-sectional area normal to the load • The stress in a tension member is uniform throughout the cross-section except: - near the point of application of load, and - at the cross-section with holes for bolts or other discontinuities, etc. • For example, consider an 8 x ½ in. bar connected to a gusset plate and loaded in tension as shown below in Figure 4.1 bbaa8 x ½ in. barGusset plate7/8 in. diameter holeSection a-aSection b-bbbaa8 x ½ in. barGusset plate7/8 in. diameter holebbaa8 x ½ in. barGusset plate7/8 in. diameter holeSection a-aSection b-bSection a-aSection b-b Figure 4.1 Example of tension member. • Area of bar at section a – a = 8 x ½ = 4 in2 • Area of bar at section b – b = (8 – 2 x 7/8 ) x ½ = 3.12 in2 1CE 405: Design of Steel Structures – Prof. Dr. A. Varma Tension Member Design • Therefore, by definition (Equation 4.1) the reduced area of section b – b will be subjected to higher stresses • However, the reduced area and therefore the higher stresses will be localized around section b – b. • The unreduced area of the member is called its gross area = Ag • The reduced area of the member is called its net area = An 4.2 STEEL STRESS-STRAIN BEHAVIOR • The stress-strain behavior of steel is shown below in Figure 4.2 Strain, εεyεuεyεuStress, fFyFuEStrain, εεyεuεyεuStress, fFyFuεyεuεyεuStress, fFyFuE Figure 4.2 Stress-strain behavior of steel • In Figure 4.2, E is the elastic modulus = 29000 ksi. Fy is the yield stress and Fu is the ultimate stress εy is the yield strain and εu is the ultimate strain 2CE 405: Design of Steel Structures – Prof. Dr. A. Varma Tension Member Design • Deformations are caused by the strain ε. Figure 4.2 indicates that the structural deflections will be small as long as the material is elastic (f < Fy) • Deformations due to the strain ε will be large after the steel reaches its yield stress Fy. 4.3 DESIGN STRENGTH • A tension member can fail by reaching one of two limit states: (1) excessive deformation; or (2) fracture • Excessive deformation can occur due to the yielding of the gross section (for example section a-a from Figure 4.1) along the length of the member • Fracture of the net section can occur if the stress at the net section (for example section b-b in Figure 4.1) reaches the ultimate stress Fu. • The objective of design is to prevent these failure before reaching the ultimate loads on the structure (Obvious). • This is also the load and resistance factor design approach recommended by AISC for designing steel structures 4.3.1 Load and Resistance Factor Design The load and resistance factor design approach is recommended by AISC for designing steel structures. It can be understood as follows: Step I. Determine the ultimate loads acting on the structure - The values of D, L, W, etc. given by ASCE 7-98 are nominal loads (not maximum or ultimate) - During its design life, a structure can be subjected to some maximum or ultimate loads caused by combinations of D, L, or W loading. 3CE 405: Design of Steel Structures – Prof. Dr. A. Varma Tension Member Design - The ultimate load on the structure can be calculated using factored load combinations, which are given by ASCE and AISC (see pages 2-10 and 2-11 of AISC manual). The most relevant of these load combinations are given below: 1.4 D (4.2 – 1) 1.2 D + 1.6 L + 0.5 (Lr or S) (4.2 – 2) 1.2 D + 1.6 (Lr or S) + (0.5 L or 0.8 W) (4.2 – 3) 1.2 D + 1.6 W + 0.5 L + 0.5 (Lr or S) (4.2 – 4) 0.9 D + 1.6 W (4.2 – 5) Step II. Conduct linear elastic structural analysis - Determine the design forces (Pu, Vu, and Mu) for each structural member Step III. Design the members - The failure (design) strength of the designed member must be greater than the corresponding design forces calculated in Step II. See Equation (4.3) below: φ Rn > ∑γiiQ (4.3) - Where, Rn is the calculated failure strength of the member - φ is the resistance factor used to account for the reliability of the material behavior and equations for Rn - Qi is the nominal load - γi is the load factor used to account for the variability in loading and to estimate the ultimate loading condition. 4.3.2 Design Strength of Tension Members • Yielding of the gross section will occur when the stress f reaches Fy. ygFAP==f 4CE 405: Design of Steel Structures – Prof. Dr. A. Varma Tension Member Design Therefore, nominal yield strength = Pn = Ag Fy (4.4) Factored yield strength = φt Pn (4.5) where, φt = 0.9 for tension yielding limit state • See the AISC manual, section on specifications, Chapter D (page 16.1 –24) • Facture of the net section will occur after the stress on the net section area reaches the ultimate stress Fu ueFAP==f Therefore, nominal fracture strength = Pn = Ae FuWhere, Ae is the effective net area, which may be equal to the net area or smaller. The topic of Ae will be addressed later. Factored fracture strength = φt Ae Fu (4.6) Where, φt = 0.75 for tension fracture limit state (See page 16.1-24 of AISC manual) 4.3.3 Important notes • Note 1. Why is fracture (& not yielding) the relevant limit state at the net section? Yielding will occur first in the net section. However, the deformations induced by yielding will be localized around the net section. These localized deformations will not cause excessive deformations in the complete tension member. Hence, yielding at the net section will not be a failure limit state. • Note 2. Why is the resistance factor (φt) smaller for fracture than for yielding? The smaller resistance factor for fracture (φt = 0.75 as compared to φt = 0.90 for yielding) reflects the more serious nature and consequences of reaching the fracture limit state. • Note 3. What is the design strength of the tension member? 5CE 405: Design of Steel Structures – Prof. Dr. A. Varma Tension Member Design The design strength of the tension member will be the lesser value of the


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