(a) Explanation Given information: The modulus of elasticity E is 200 GPa . The yield stress ( σ Y ) is 250 MPa . Calculation: Sketch the rigid bar ABC as shown in Figure 1. Refer to Figure 1. Take a moment about C , ∑ M C = 0 1.76 ( Q − P B E ) − 2.64 P A D = 0 Sketch the deformation as shown in Figure 2. Refer to Figure 2. The value of deflection at A δ A = 2.64 θ . Find the deflection at B , δ B using the relation: δ B = a θ (1) Substitute 1.76 m for a in Equation (1). δ B = 1.76 θ Calculate the area ( A ) using the relation: A = 37.5 × 6 = 225 mm 2 ( 1 m 10 3 mm ) 2 = 225 × 10 − 6 m 2 Find the value of force of the member AD , P A D using the relation: P A D = E A L A D δ A (2) Here, A is the cross sectional area, δ A is deflection at A , and L A D is length of rod AC . Substitute 200 GPa for E , 225 × 10 − 6 m 2 for A , 1.7 m for L A D in Equation (2). P A D = 200 GPa ( 10 9 Pa 1 GPa ) 225 × 10 − 6 1.7 δ A = 200 × 10 9 × 225 × 10 − 6 1.7 δ A = 26.47 × 10 6 δ A (3) Substitute 2.64 θ for δ A in Equation (3). P A D = 26.47 × 10 6 ( 2.64 θ ) = 69.88 × 10 6 θ Express the normal stress using the Equation as follows: σ A D = P A D A (4) Substitute 26.47 × 10 6 δ A for P A D and 225 × 10 − 6 m 2 for A in Equation (4). σ A D = 69.88 × 10 6 δ A 225 × 10 − 6 = 310.57 × 10 9 θ = 310.6 × 10 9 θ Find the value of P B E using the relation: P B E = E A L B E δ B (5) Substitute 200 GPa for E , 225 × 10 − 6 m 2 for A , 1.0 m for L B E in Equation (5). P B E = 200 GPa ( 10 9 Pa 1 GPa ) ( 225 × 10 − 6 ) 1.0 δ B = 200 × 10 9 × ( 225 × 10 − 6 ) 1.0 δ B = 45 × 10 6 δ B Substitute 1.76 θ for δ B . P B E = 45 × 10 6 ( 1.76 θ ) = 79.2 × 10 6 θ Calculate the normal stress along BE using the relation: σ B E = P B E A (6) Substitute 79 (b) To determine Find the maximum deflection at point B .

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Chapter 2.13, Problem 114P

(a)

To determine

Find the value of the normal stress in each link.

(b)

To determine

Find the maximum deflection at point B.

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Chapter 2.13, Problem 113P

Chapter 2.13, Problem 115P

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Chapter 2 Solutions

EBK MECHANICS OF MATERIALS

Ch. 2.1 - A nylon thread is subjected to a 8.5-N tension...Ch. 2.1 - A 4.8-ft-long steel wire of 14 -in.-diameter is...Ch. 2.1 - An 18-m-long steel wire of 5-mm diameter is to be...Ch. 2.1 - Two gage marks are placed exactly 250 mm apart on...Ch. 2.1 - An aluminum pipe must not stretch more than 0.05...Ch. 2.1 - A control rod made of yellow brass must not...Ch. 2.1 - A steel control rod is 5.5 ft long and must not...Ch. 2.1 - A cast-iron tube is used to support a compressive...Ch. 2.1 - A 4-m-long steel rod must not stretch more than 3...Ch. 2.1 - A nylon thread is to be subjected to a 10-N...

Ch. 2.1 - A block of 10-in. length and 1.8 1.6-in. cross...Ch. 2.1 - A square yellow-brass bar must not stretch more...Ch. 2.1 - Rod BD is made of steel (E = 29 106 psi) and is...Ch. 2.1 - The 4-mm-diameter cable BC is made of a steel with...Ch. 2.1 - A single axial load of magnitude P = 15 kips is...Ch. 2.1 - A 250-mm-long aluminum tube (E = 70 GPa) of 36-mm...Ch. 2.1 - The specimen shown has been cut from a...Ch. 2.1 - The brass tube AB (E = 105 GPa) has a...Ch. 2.1 - Both portions of the rod ABC are made of an...Ch. 2.1 - The rod ABC is made of an aluminum for which E =...Ch. 2.1 - For the steel truss (E = 200 GPa) and loading...Ch. 2.1 - For the steel truss (E = 29 106 psi) and loading...Ch. 2.1 - Members AB and BC are made of steel (E = 29 106...Ch. 2.1 - The steel frame (E = 200 GPa) shown has a diagonal...Ch. 2.1 - Link BD is made of brass (E = 105 GPa) and has a...Ch. 2.1 - Members ABC and DEF are joined with steel links (E...Ch. 2.1 - Each of the links AB and CD is made of aluminum (E...Ch. 2.1 - The length of the 332-in.-diameter steel wire CD...Ch. 2.1 - A homogenous cable of length L and uniform cross...Ch. 2.1 - The vertical load P is applied at the center A of...Ch. 2.1 - Denoting by the "engineering strain'' in a...Ch. 2.1 - The volume of a tensile specimen is essentially...Ch. 2.3 - An axial centric force of magnitude P = 450 kN is...Ch. 2.3 - An axial centric force of magnitude P = 450 kN is...Ch. 2.3 - The 4.5-ft concrete post is reinforced with six...Ch. 2.3 - The 4.5-ft concrete post is reinforced with six...Ch. 2.3 - An axial force of 200 kW is applied to the...Ch. 2.3 - The length of the assembly shown decreases by 0.40...Ch. 2.3 - A polystyrene rod consisting of two cylindrical...Ch. 2.3 - Three steel rods (E = 29 106 psi) support an...Ch. 2.3 - Fig. P2.41 2.41 Two cylindrical rods, one of steel...Ch. 2.3 - Solve Prob. 2.41, assuming that rod AC is made of...Ch. 2.3 - Each of the rods BD and CE is made of brass (E =...Ch. 2.3 - The rigid bar AD is supported by two steel wires...Ch. 2.3 - The rigid bar ABC is suspended from three wines of...Ch. 2.3 - The rigid bar AD is supported by two steel wires...Ch. 2.3 - The aluminum shell is fully bonded to the brass...Ch. 2.3 - The aluminum shell is fully bonded to the brass...Ch. 2.3 - The brass shell (b = 11.6 10-6/F) is fully bonded...Ch. 2.3 - The concrete post (Ec = 3.6 106) psi and c = 5.5 ...Ch. 2.3 - A rod consisting of two cylindrical portions AB...Ch. 2.3 - A rod consisting of two cylindrical portions AB...Ch. 2.3 - Fig. P2.52 2.52 A rod consisting of two...Ch. 2.3 - The steel rails of a railroad (rack (Es = 200GPa,...Ch. 2.3 - Two steel bars (Es = 200 GPa and s = 11.7 10-6/C)...Ch. 2.3 - Determine the maximum load P that can be applied...Ch. 2.3 - An aluminum rod (Ea = 70 GPa, a = 23.6 10-6/C)...Ch. 2.3 - Knowing that a 0.02-in. gap exists when the...Ch. 2.3 - Determine (a) the compressive force in the bars...Ch. 2.3 - At room temperature (20C) a 0.5-mm gap exists...Ch. 2.9 - A standard tension test is used to determine the...Ch. 2.9 - A 2-m length of an aluminum pipe of 240-nun outer...Ch. 2.9 - A line of slope 4:10 has been scribed on a...Ch. 2.9 - A 2.75-kN tensile load is applied to a test coupon...Ch. 2.9 - Fig. P2.65 2.65 In a standard tensile test a steel...Ch. 2.9 - The change in diameter of a large steel bolt is...Ch. 2.9 - The brass rod AD is fitted with a jacket that is...Ch. 2.9 - A fabric used in air-inflated structures is...Ch. 2.9 - A 1-in. square was scribed on the side of a large...Ch. 2.9 - The block shown is made of a magnesium alloy for...Ch. 2.9 - The homogeneous plate ABCD is subjected to a...Ch. 2.9 - For a member under axial loading, express the...Ch. 2.9 - In many situations it is known that the normal...Ch. 2.9 - In many situations physical constraints prevent...Ch. 2.9 - The plastic block shown is bonded to a rigid...Ch. 2.9 - The plastic block shown is bonded to a rigid...Ch. 2.9 - Two blocks of rubber with a modulus of rigidity G...Ch. 2.9 - Fig. P2.77 and P2.78 2.78 Two blocks of rubber...Ch. 2.9 - An elastomeric bearing (G = 130 psi) is used to...Ch. 2.9 - 2.80 For the elastomeric bearing In Prob. 2.79...Ch. 2.9 - A vibration isolation unit consists of two blocks...Ch. 2.9 - Prob. 82P Ch. 2.9 - Prob. 83P Ch. 2.9 - Prob. 84P Ch. 2.9 - Prob. 85P Ch. 2.9 - A 2.75-kN tensile load is applied to a test coupon...Ch. 2.9 - A vibration isolation support consists of a rod A...Ch. 2.9 - Prob. 88P Ch. 2.9 - Prob. 89P Ch. 2.9 - Show that for any given material, the ratio G/E of...Ch. 2.9 - Prob. 91P Ch. 2.9 - Prob. 92P Ch. 2.13 - Knowing that, for the plate shown, the allowable...Ch. 2.13 - Knowing that P = 38 kN, determine the maximum...Ch. 2.13 - A hole is to be drilled in the plate at A. The...Ch. 2.13 - Fig. P2.95 and P2.96 2.96 (a) For P = 13 kips and...Ch. 2.13 - 2.97 Knowing that the hole has a diameter of 9 mm,...Ch. 2.13 - For P = 100 kN, determine the minimum plate...Ch. 2.13 - Prob. 99P Ch. 2.13 - A centric axial force is applied to the steel bar...Ch. 2.13 - The cylindrical rod AB has a length L = 5 ft and a...Ch. 2.13 - Fig. P2.101 and P.102 2.102 The cylindrical rod AB...Ch. 2.13 - Rod AB is made of a mild steel that is assumed to...Ch. 2.13 - Prob. 104P Ch. 2.13 - Rod ABC consists of two cylindrical portions and...Ch. 2.13 - Prob. 106P Ch. 2.13 - Prob. 107P Ch. 2.13 - Prob. 108P Ch. 2.13 - Each cable has a cross-sectional area of 100 mm2...Ch. 2.13 - Prob. 110P Ch. 2.13 - Two tempered-steel bars, each 316 in. thick, are...Ch. 2.13 - Prob. 112P Ch. 2.13 - Prob. 113P Ch. 2.13 - Prob. 114P Ch. 2.13 - Prob. 115P Ch. 2.13 - Prob. 116P Ch. 2.13 - Prob. 117P Ch. 2.13 - Prob. 118P Ch. 2.13 - Prob. 119P Ch. 2.13 - For the composite bar in Prob. 2.111, determine...Ch. 2.13 - Prob. 121P Ch. 2.13 - Bar AB has a cross-sectional area of 1200 mm2 and...Ch. 2.13 - Bar AB has a cross-sectional area of 1200 mm2 and...Ch. 2 - The uniform wire ABC, of unstretched length 2l, is...Ch. 2 - The aluminum rod ABC (E = 10.1 106 psi), which...Ch. 2 - Two solid cylindrical rods are joined at B and...Ch. 2 - Prob. 127RP Ch. 2 - Prob. 128RP Ch. 2 - Prob. 129RP Ch. 2 - A 4-ft concrete post is reinforced with four steel...Ch. 2 - The steel rods BE and CD each have a 16-mm...Ch. 2 - Prob. 132RP Ch. 2 - Prob. 133RP Ch. 2 - The aluminum test specimen shown is subjected to...Ch. 2 - Prob. 135RP

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Find the value of the normal stress in each link.

Solution Summary: The author explains how to find the value of the normal stress in each link, based on the modulus of elasticity E and the yield stress.

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Find the value of the normal stress in each link.

Find the maximum deflection at point B.

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Chapter 2 Solutions