Three blocks are positioned on an incline of θθ=23∘∘ as shown. A force of P is applied to Block C and a wire attaches Block A to the wall, preventing that block from moving. The mass of Block A is mA=33kg, the mass of Block B is mB=52kg, and the mass of Block C is mC=52kg. The coefficient of static friction between Block A and Block B is μμAB=0.20, between Block B and Block C is μμBC=0.27, and between Block C and the ground is μμCG=0.37. Determine the maximum value of P before any slipping takes place. Write your answer for P in N units to 2 decimal places
Three blocks are positioned on an incline of θθ=23∘∘ as shown. A force of P is applied to Block C and a wire attaches Block A to the wall, preventing that block from moving. The mass of Block A is mA=33kg, the mass of Block B is mB=52kg, and the mass of Block C is mC=52kg. The coefficient of static friction between Block A and Block B is μμAB=0.20, between Block B and Block C is μμBC=0.27, and between Block C and the ground is μμCG=0.37. Determine the maximum value of P before any slipping takes place. Write your answer for P in N units to 2 decimal places
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Three blocks are positioned on an incline of θθ=23∘∘ as shown. A force of P is applied to Block C and a wire attaches Block A to the wall, preventing that block from moving.
The mass of Block A is mA=33kg, the mass of Block B is mB=52kg, and the mass of Block C is mC=52kg. The coefficient of static friction between Block A and Block B is μμAB=0.20, between Block B and Block C is μμBC=0.27, and between Block C and the ground is μμCG=0.37.
Determine the maximum value of P before any slipping takes place. Write your answer for P in N units to 2 decimal places
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