A horizontal load P is applied to an assembly consisting of two inclined bars, as shown in the figure. The cross-sectional area of bar (1) is 1.35 in.?, and the cross-sectional area of bar (2) is 1.90 in.?. The normal stress in either bar may not exceed 24 ksi. Determine the maximum load P that may be applied to this assembly. Assume dimensions of a = 15.0 ft, b = 10.0 ft, and c = 13.5 ft. (1) a B P b (2) Part 1 Correct. Determine the allowable force F1 in member (1) and the allowable force F2 in member (2). F1, allow kips 32.4

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A horizontal load P is applied to an assembly consisting of two inclined bars, as shown in the figure. The cross-sectional area of bar (1) is 1.35 in.?, and the cross-sectional area of bar (2) is 1.90 in.². The normal stress in either bar may not exceed 24 ksi. Determine the maximum load P that may be applied to this assembly. Assume dimensions of a = 15.0 ft,b = 10.0 ft, and c = 13.5 ft. (1) a B b (2) Part 1 Correct. Determine the allowable force Fi in member (1) and the allowable force F2 in member (2). F1, allow kips 32.4 F2, allow kips 46 Attempts: 2 of 3 used

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Part 3 Find the ratio, (F|IF2), where F 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. F1IF2 = i 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 F1A = F1. allow. Enter the value of the force in member 2 for Load Case A. F2A = kips Save for Later Attempts: 0 of 3 used Submit Answer