Explanation Given information : The mass of the bowl ( m B ) is 1 kg. The mass of the serving table ( m t ) is 5 kg. The angle θ 1 for the un-stretched spring is 90 ° . The stiffness of the each spring ( k ) value is 200 N / m . Explanation : Show the free body diagram of the spring system with serving table as in Figure (1). Observation: From Figure 1, only the spring force F s p , weight of the table W t , and weight of the bowl W b will do the work, when the virtual angular displacement takes place. The spring force F s p , weight of the table W t , and weight of the bowl W b will act towards the negative sense of their corresponding virtual displacement. Virtual displacement: Write the position coordinate at the centre of the bowl. y G b = l sin θ + b (I) Here, the length of link is l and the vertical distance between the point A and the centre of the bowl is b . Write the position coordinate at point B. y G t = l sin θ + a (II) Here, the vertical distance between the point A and the centre of the table is a . Write the position coordinate at point C. x C = l cos θ (III) Determine the rotation of the disk. F s p = k x = k l cos θ (IV) Here, the displacement of the spring from its equilibrium position is x . Determine the weight of the bowl. W b = m b 2 g (V) Here, the acceleration due to gravity is g . Determine the weight of the serving table. W t = m t 2 g (VI) Virtual work equation: Write the virtual work equation to determine the angle. δ U = 0 − W b δ y G b − W t δ y G t − F s p δ y C = 0 (VII) Conclusion : Differentiate Equation (I) with respect to θ . δ y G b δ θ = l cos θ δ y G b = l cos θ δ θ Substitute 250 mm for l . δ y G b = ( 250 mm × 1 m 1 , 000 mm ) cos θ δ θ = 0.25 cos θ δ θ Differentiate the Equation (II) with respect to θ . δ y G t δ θ = l cos θ δ y G t = l cos θ δ θ Substitute 250 mm for l . δ y G t = ( 250 mm × 1 m 1 , 000 mm ) cos θ δ θ = 0.25 cos θ δ θ Differentiate the Equation (III) with respect to θ . δ y C δ θ = − l sin θ δ y C = − l sin θ δ θ Substitute 250 mm for l . δ y C = − ( 250 mm × 1 m 1 , 000 mm ) sin θ δ θ = − 0

13th Edition

ISBN: 9780132915540

Author: Russell C. Hibbeler

Publisher: Prentice Hall

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Chapter 11.3, Problem 18P

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The angle θ for the equilibrium condition of the table.

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Chapter 11 Solutions

Engineering Mechanics: Statics

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The angle θ for the equilibrium condition of the table.

Solution Summary: The author shows the free body diagram of the spring system with serving table as in Figure (1).

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The angle θ for the equilibrium condition of the table.

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Chapter 11 Solutions