Tension member

Calculation

In an axially loaded tension member, the stress is given by:

F = P/A

where P is the magnitude 10 (Hati) of the load and A is the cross-sectional area.

The stress given by this equation is exact, knowing that the cross section is not adjacent to the point of application of the load nor having holes for bolts or other discontinuities. For example, given an 8 x 11.5 plate that is used as a tension member (section a-a) and is connected to a gusset plate with two 7/8-inch-diameter bolts (section b-b):

The area at section a - a (gross area of the member) is 8 x ½ = 4 in²

However, the area at section b - b (net area) is (8 – 2 x 7/8) x ½ = 3.12 ⁱⁿ²

knowing that the higher stress is located at section b - b due to its smaller area.

Design

To design tension members, it is important to analyse how the member would fail under both yielding (excessive deformation) and fracture, which are considered the limit states. The limit state that produces the smallest design strength is considered the controlling limit state. It also prevents the structure from failure.

Using American Institute of Steel Construction standards, the ultimate load on a structure can be calculated from one of the following combination:

1.4 D

1.2 D + 1.6 L + 0.5 (L_r or S)

1.2 D + 1.6 (L_r or S) + (0.5 L or 0.8 W)

1.2 D + 1.6 W + 0.5 L + 0.5 (L_r or S)

0.9 D + 1.6 W

L= 14

the central problem of designing a member is to find a cross section for which the required strength doesn't exceed the available strength:

P_u < ¢ P_n where P_u is the sum of the factored loads.

to prevent yielding

0.90 F_y A_g > P_u

to avoid fracture,

0.75 F_u A_e > P_u

therefore, the design must consider the loads applied to this member, the design forces acting on this member (M_u, P_u, and V_u) and the point where this member would fail.