A horizontal load Pis applied to an assembly consisting of two inclined bars, as shown in the figure. The cross-sectiona

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A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 1 (20.28 KiB) Viewed 86 times

A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 2 (17.96 KiB) Viewed 86 times

A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 3 (20.17 KiB) Viewed 86 times

A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 4 (15.89 KiB) Viewed 86 times

A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 5 (18.44 KiB) Viewed 86 times

A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 6 (16.97 KiB) Viewed 86 times

A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 7 (16.34 KiB) Viewed 86 times

A Horizontal Load Pis Applied To An Assembly Consisting Of Two Inclined Bars As Shown In The Figure The Cross Sectiona 8 (13.02 KiB) Viewed 86 times

A horizontal load Pis applied to an assembly consisting of two inclined bars, as shown in the figure. The cross-sectional area of bar (1) is 1.50 in.? and the cross-sectional area of bar (2) is 1.75 in. The normal stress in either bar may not exceed 25 ksi. Determine the maximum load P that may be applied to this assembly. Assume dimensions of a = 16.5 ft, b = 9.5 ft, and c = 15.0 ft. (1) (2)
Part 1 Determine the allowable force Fin member (1) and the allowable force F, in member (2) kips i kips Savefore Attempts: 0 of 3 used Submit Answer
Part 2 Find the angle Ox between member (1) and the horizontal direction, and also the angle Onc between member (2) and the horizontal direction (1) O ABC Ав Oncl OAB = Dec
Part 3 Find the ratio, (F/F), where is the force in member (1) and F2 is the force in member (2). Both bars are in tension, so these forces are both positive according to the sign conventions, F/F2= Save for later Attempts: 0 of 3 used Submit Answer
Part 4 Make an assumption for the maximum load case, referred to as "Load Case A", in which the force in member (1) will control the capacity of the two-bar assembly. For this assumption, which may or may not be correct, the force in member (1) is Fu = Follow. Enter the value of the force in member 2 for Load Case A. F2A = kips Save for Late Attempts: 0 of 3 used Submit Answer
Part 5 Make a new assumption for the maximum load case, referred to as "Load Case B", in which the force in member (2) will control the capacity of the two-bar assembly. For this assumption, which may or may not be correct, the force in member (2) is F2.8 = F2ulow. Enter the value of the force in member 1 for Load Case B. Fu = kips Save for later Attempts: 0 of 3 used Submit Answer
Part 6 Enter the forces in the members corresponding to the correct maximum load case assumption, Load Case A or Load Case B. F = kips F2 = i kips Save for Later Attempts: 0 of 3 used Submit Answer
Part 7 Determine the maximum load P that may be applied to this assembly. P = kips Attempts: 0 of 3 used Submit Answer