Explanation Given information: The weight of the plate ABCD is W = 50 lb . The coefficient of static friction between the collars and the rod is μ s = 0.40 . Calculation: Consider the following two cases. Case 1 : 0 < P < 30 lb Case 2 : 30 lb < P < 50 lb Case 1 0 < P < 30 lb : Show the free-body diagram of the plate ABCD as in Figure 1. Find the friction force ( F ) using the relation. F = μ s N Here, the coefficient of static friction is μ s and the normal force is N . Take moment about point D . ∑ M D = 0 N A ( 2 ) − 50 ( 3 ) + P ( 5 ) = 0 2 N A − 150 + 5 P = 0 N A = 75 − 2 .5 P When P ≤ 30 lb; N A ≥ 0 ( ← ) ; Resolve the horizontal component of forces. ∑ F x = 0 N D − N A = 0 N D = N A Resolve the vertical component of force. ∑ F y = 0 F A + F D − 50 + P = 0 F A + F D = 50 − P Find the maximum friction force at point A as follows; ( F A ) m = μ s N A Substitute 0.40 for μ s and ( 75 − 2 .5 P ) for N A . ( F A ) m = 0.40 × ( 75 − 2.5 P ) = 30 − P Find the maximum friction force at point D as follows; ( F D ) m = μ s N D Substitute 0.40 for μ s and ( 75 − 2 .5 P ) for N D . ( F D ) m = 0.40 × ( 75 − 2.5 P ) = 30 − P Find the total maximum friction force as follows; ( F A ) m + ( F D ) m = 30 − P + 30 − P = 60 − 2 P The maximum friction force should be less than the total friction force for the plate to move downward. ( F A ) m + ( F D ) m < F A + F D Substitute ( 60 − 2 P ) for [ ( F A ) m + ( F D ) m ] and ( 50 − P ) for ( F A + F D ) . ( 60 − 2 P ) < ( 50 − P ) 10 lb < P P > 10 lb Case 2 30 lb < P < 50 lb : When P ≤ 30 lb; N A ≥ 0 ( → ) ; Refer Figure 1

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Chapter 8.1, Problem 8.30P

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VECTOR MECHANICS FOR ENGINEERS W/CON >B

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Find the range of values of the magnitude P of the vertical force applied at point E .

Solution Summary: The author shows the free-body diagram of the plate ABCD as in Figure 1. Find the friction force (F) using the relation.

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Chapter 8 Solutions