Vector Mechanics for Engineers: Statics and Dynamics
Vector Mechanics for Engineers: Statics and Dynamics
12th Edition
ISBN: 9781259638091
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek, Phillip J. Cornwell, Brian Self
Publisher: McGraw-Hill Education
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Textbook Question
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Chapter 13.4, Problem 13.188P

When the rope is at an angle of α = 30°, the 1-lb sphere A has a speed v0 = 4 ft/s. The coefficient of restitution between A and the 2-lb wedge B is 0.7 and the length of rope l = 2.6 ft. The spring constant has a value of 2 lb/in. and θ = 20°. Determine (a) the velocities of A and B immediately after the impact, (b) the maximum deflection of the spring, assuming A does not strike B again before this point.

Chapter 13.4, Problem 13.188P, When the rope is at an angle of  = 30, the 1-lb sphere A has a speed v0 = 4 ft/s. The coefficient of

(a)

Expert Solution
Check Mark
To determine

Find the velocity of A (vA) and B (vB) immediately after impact.

Answer to Problem 13.188P

The velocity of A (vA) and B (vB) immediately after impact are 2.36ft/s(83.8°)_ and 3.23ft/s()_ respectively.

Explanation of Solution

Given information:

The angle of the rope (α) is 30°.

The weight of the sphere A (WA) is 1lb.

The weight of the wedge B (WB) is 2lb.

The speed of the sphere A (vA) is 4ft/s.

The coefficient of restitution between A and wedge (e) is 0.7.

The length of the rope (l) is 2.6ft.

The spring constant (k) is 2lb/in.

The angle (θ) is 20°.

The acceleration due to gravity (g) is 32.2ft/s2.

Calculation:

Calculate the mass of sphere A (mA) using the relation:

mA=WAg

Substitute 1lb for WA and 32.2ft/s2 for g.

mA=1lb32.2ft/s2=0.031lbs2/ft

Calculate the mass of wedge B (mB) using the relation:

mB=WBg

Substitute 2lb for WB and 32.2ft/s2 for g.

mB=2lb32.2ft/s2=0.06211lbs2/ft

Calculate the initial altitude of sphere (h0) using the relation:

h0=l(1cosα)

Substitute 2.6ft for l and 30° for α.

h0=(2.6ft)(1cos30°)=0.3483ft

Calculate the initial potential energy of sphere (V0) using the formula:

V0=mAgh0

Substitute 0.031lbs2/ft for mA, 32.2ft/s2 for g, and 0.3483ft for h0.

V0=(0.031lbs2/ft)(32.2ft/s2)(0.3483ft)=0.3483lbft

Calculate the initial kinetic energy of sphere (T0) using the formula:

T0=12mAv02

Here, v0 is the initial velocity of sphere.

Substitute 0.031lbs2/ft for mA and 4ft/s for v0.

T0=12(0.031lbs2/ft)(4ft/s)2=0.248lbft

Calculate the altitude of sphere just before impact (h1) using the relation:

h1=l(1cosα)

Substitute 2.6ft for l and 0° for α.

h1=(2.6ft)(1cos0°)=(2.6ft)(11)=0

Calculate the initial potential energy of sphere just before impact (V1) using the relation:

V1=mAgh1

Substitute 0.031lbs2/ft for mA, 32.2ft/s2 for g, and 0 for h1.

V1=(0.031lbs2/ft)(32.2ft/s2)(0)=0

Calculate the kinetic energy of sphere just before impact (T1) using the formula:

T1=12mAvA2

Here, vA is the final velocity of sphere.

Substitute 0.031lbs2/ft for mA.

T1=12(0.031lbs2/ft)(vA)2=0.0155vA2lbft

The expression for the principle of conservation of energy between initial and final stage of sphere as follows:

T0+V0=T1+V1

Substitute 0.248lbft for T0, 0.3483lbft for V0, 0.0155vA2lbft for T1, and 0 for V1.

0.248lbft+0.3483lbft=0.0155vA2lbft+00.0155vA2=0.5963vA=(0.59630.0155)0.5vA=6.20ft/s

Show the impulse-momentum diagram for sphere as in Figure (1).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 13.4, Problem 13.188P , additional homework tip  1

The expression for the momentum in tangential direction as follows:

mAvAsinθ=mA(vA)t

Here, (vA)t is the tangential component of velocity of sphere at the end of restitution period.

Substitute 0.031lbs2/ft for mA, 20° for θ, and 6.20ft/s for vA.

(0.031lbs2/ft)(6.20ft/s)sin20°=(0.031lbs2/ft)(vA)t0.031(vA)t=0.0657(vA)t=(2.1203ft/s)70°

Show the impulse-momentum diagram of wedge as in Figure (2).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 13.4, Problem 13.188P , additional homework tip  2

The expression for the momentum in x-direction as follows:

mAvA+0=mA(vA)ncosθ+mA(vA)tsinθ+mBvB

Here, (vA)n is the normal component of velocity of sphere at the end of restitution period.

Substitute 0.031lbs2/ft for mA, 0.06211lbs2/ft for mB, 6.20ft/s for vA, (2.1203ft/s) for (vA)t, and 20  for θ.

(0.031lbs2/ft)(6.20ft/s)+0={(0.031lbs2/ft)(vA)ncos20°+[(0.031lbs2/ft)(2.1203ft/s)sin20°]+(0.06211lbs2/ft)vB}0.19210.02278=0.0291(vA)n+0.0621vB0.0291(vA)n+0.0621vB=0.17 (1)

Calculate the coefficient of restitution (e) using the formula:

e=(vB)n(vA)n(vA)n(vB)n

Substitute 0.7 for e, vAcosθ for (vA)n, 6.20ft/s for vA, 0 for (vB)n, and vBcosθ for (vB)n.

0.7=vBcosθ(vA)n(6.1994ft/s)cosθ0(6.1994ft/s)cos20°(0.7)=vBcos20(vA)n0.9396vB(vA)n=4.0778(vA)n=0.9396vB4.0778

Find the velocity of sphere B immediately after the impact:

Substitute 0.9396vB4.0778 for (vA)n in equation (1).

0.0291((vA)n)+0.0621vB=0.170.0291(0.9396vB4.0778)+0.0621vB=0.170.0273vB0.1186+0.0621vB=0.170.0894vB=0.2886vB=0.28860.0894vB=3.23ft/s

Find the normal component of velocity of sphere:

Substitute 3.2279ft/s for vB in equation (1).

0.0291(vA)n+0.0621(3.2279ft/s)=0.170.0291(vA)n=0.0304(vA)n=1.0446ft/s

Calculate the resultant velocity of sphere A (vA) using the relation:

vA=(vA)n2+(vA)t2

Substitute 1.0446ft/s for (vA)n and 2.1203ft/s for (vA)t.

vA=(1.0446ft/s)2+(2.1203ft/s)2=2.36ft/s

Calculate the angle for (β) using the relation:

β=tan1((vA)t(vA)n)

Substitute 1.0446ft/s for (vA)n and 2.1203ft/s for (vA)t.

β=tan1(2.1203ft/s1.0446ft/s)=63.77°

Calculate the resultant angle of velocity of sphere A (ϕ) using the relation:

ϕ=β+θ

Substitute 63.77  for β and 20° for θ.

ϕ=63.77°+20°=83.77°

Therefore, the velocity of A (vA) and B (vB) immediately after impact are 2.36ft/s(83.8°)_ and 3.23ft/s()_ respectively.

(b)

Expert Solution
Check Mark
To determine

Find the maximum deflection of the spring assuming A does not strike B again before this point.

Answer to Problem 13.188P

The maximum deflection of the spring (Δx) is 1.97in._.

Explanation of Solution

Given information:

The angle of the rope (α) is 30°.

The weight of the sphere A (WA) is 1lb.

The weight of the wedge B (WB) is 2lb.

The speed of the sphere A (vA) is 4ft/s.

The coefficient of restitution between A and wedge (e) is 0.7.

The length of the rope (l) is 2.6ft.

The spring constant (k) is 2lb/in.

The angle (θ) is 20°.

The acceleration due to gravity (g) is 32.2ft/s2.

Calculation:

Calculate the kinetic energy of wedge block just before impact (TB1) using the formula:

TB1=12mBvB2

Here, vB is the final velocity of wedge.

Substitute 0.06211lbs2/ft for mB and 3.23ft/s for vB.

TB1=12(0.06211lbs2/ft)(3.23ft/s)2=0.3239lbft

The expression for the potential energy of spring at the end of impact (VB2) as follows:

VB2=12k(Δx)2

The expression for the principle of conservation of energy for wedge block as follows:

TB1+VB1=TB2+VB2

Here, VB1 is the potential energy of spring just before impact and TB2 is the kinetic energy of spring at the end of impact.

Substitute 0.3239lbft for TB1, 0 for VB1, 0 for TB2, and 12k(Δx)2 for VB2.

0.3239lbft+0=0+12k(Δx)20.3239lbft=12k(Δx)2

Substitute 2lb/in. for k.

0.3239lbft=12(2lb/in.)(12in.1ft)(Δx)2(Δx)2=0.0269lb2Δx=(0.1642ft)(12in.1ft)Δx=1.97in.

Therefore, the maximum deflection of the spring (Δx) is 1.97in._.

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Chapter 13 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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