Part I 1. Compute the force in each member of the Warren truss shown in Fig. 1000 Ib 3000 Ib в MATHalino.com 60° 60° 60° 60° 10' 10' 4000 Ib Figure P-408 2. Determine the force in bars BD, CD, and DE of the nacelle truss shown in Fig. 60 kN 120 kN 120 kN 120 kN 3 m 3 m 6 m 3 m 2 m MATHalino.com A 4 m Figure P-427 moɔ.onilsHTAM MATHalino.com

statics rigid of bodies 

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Part I 1. Compute the force in each member of the Warren truss shown in Fig. 1000 Ib 3000 Ib в D MATHalino.com 60° 60° 60° 60° 10' 10' 4000 Ib Figure P-408 2. Determine the force in bars BD, CD, and DE of the nacelle truss shown in Fig. 60 kN 120 kN 120 kN 120 kN 3 m 3 m 6 m 3 m 2 m MATHalino com A 4 m Figure P-427 moo.onilsHTAM MATHalino.com

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Part II 1. The blocks shown in Fig. P-522 are separated by a solid strut which is attached to the blocks with frictionless pins. If the coefficient of friction for all surfaces is 0.20, determine the value of horizontal force P to cause motion to impend to the right. Assume that the strut is a uniform rod weighing 300 lb. 200 lb 400 lb 130° 45° Figure P-522 2. The maximum tension that can be developed in the cord shown in Fig. below is 500 N. If the pulley at A is free to rotate and the coefficient of static friction at the fixed drums B and C is µ, = 0.25, determine the largest mass of the cylinder that can be lifted by the cord. B 45 MATH: