Vector Mechanics for Engineers: Statics and Dynamics
Vector Mechanics for Engineers: Statics and Dynamics
11th Edition
ISBN: 9780073398242
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek, Phillip J. Cornwell, Brian Self
Publisher: McGraw-Hill Education
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Chapter 13.3, Problem 13.149P

Bullet B weighs 0.5 oz and blocks A and C both weigh 3 lb. The coefficient of friction between the blocks and the plane is μk = 0.25. Initially, the bullet is moving at v0 and blocks A and C are at rest (Fig. 1). After the bullet passes through A, it becomes embedded in block C and all three objects come to stop in the positions shown (Fig. 2). Determine the initial speed of the bullet v0.

Fig. P13.149

Chapter 13.3, Problem 13.149P, Bullet B weighs 0.5 oz and blocks A and C both weigh 3 lb. The coefficient of friction between the

Expert Solution & Answer
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To determine

Find the initial speed (v0) of the bullet.

Answer to Problem 13.149P

The initial speed (v0) of the bullet is 497.08ft/s_.

Explanation of Solution

Given information:

The weight of the bullet B (WB) is 5oz.

The weight of the block A (WA) is 3lb.

The weight of the block C (WC) is 3lb.

The coefficient of friction between the blocks and plane (μk) is 0.25.

The distance between the upper block A and lower block A (dA) is 6in..

The distance between the upper block C and lower block C (dC) is 4in..

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

Calculation:

Show the free body diagram of the block A as the bullet passes through it as Figure (1).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 13.3, Problem 13.149P , additional homework tip  1

The expression for the principle of conservation of momentum to the bullet and block A as follows;

mA(vA)0+mBv0=mAvA+mBv1

Here, mA is the mass of the block A, (vA)0 is the initial velocity of the block A, mB is the mass of the bullet B, v0 is the initial velocity of the bullet before passing through A, vA is the velocity of the block A just after the bullet passes through and v1 is the velocity of the bullet after it passes through block A.

Since the block A is at rest initially, so the velocity (vA)0 will be zero.

Substitute 0 for (vA)0.

0+mBv0=mAvA+mBv1v0=v1+mAvAmB (1)

Calculate the mass of the bullet (mB) using the formula:

mB=WBg

Substitute 5oz for WB and 32.2ft/s2 for g.

mB=5oz32.2ft/s2=532.2×(1lb16oz)=970.5×106lb.s2/ft

Calculate the mass of the block A (mA) using the formula:

mA=WAg

Substitute 3lb for WA and 32.2ft/s2 for g.

mA=3lb32.2ft/s2=93.168×103lb.s2/ft

The expression for the normal force acting on the block A as follows;

NA=mAg

The expression for the work done [(U12)A] by frictional force acting on the block A as it slides through the distance dA as follows;

(U12)A=μkNAdA

Substitute mAg for NA.

(U12)A=μkmAgdA

The expression for the initial kinetic energy of the block A (T1)A while the bullet just passes through the block A as follows;

(T1)A=12mAvA2

The final kinetic energy of the block A (T2)A after the bullet leaves the block is zero as the block A comes to rest finally.

The expression for the principle of work-energy to the block A after the bullet just passes through it as follows;

(T1)A+(U12)A=(T2)A

Substitute 12mAvA2 for (T1)A, μkmAgdA for (U12)A, and 0 for (T2)A.

12mAvA2μkmAgdA=012mAvA2=μkmAgdAvA2=2μkmAgdAmAvA=2μkgdA

Substitute 0.25 for μk, 32.2ft/s2 for g, and 6in. for dA.

vA=2(0.25)(32.2ft/s2)(6in)=(16.1)(6×0.08333ft1in)=(16.1)(0.5)=2.8372ft/s

Show the free body diagram of the block C as the bullet passes through it as in Figure (2).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 13.3, Problem 13.149P , additional homework tip  2

The expression for the principle of conservation of momentum to the bullet and block A as follows;

mC(vC)0+mBv1=mCvC+mBvC

Here, mC is the mass of the block C, (vC)0 is the initial velocity of the block C and vC is the velocity of the block and bullet after the bullet gets embedded in the block C.

The initial velocity of the block C (vC)0 is zero as the block is at rest initially.

Substitute 0 for (vC)0.

0+mBv1=mCvC+mBvCv1=(mB+mC)vCmB (2)

Calculate the mass of the block C (mC) using the formula:

mC=WCg

Substitute 3lb for WC and 32.2ft/s2 for g.

mC=3lb32.2ft/s2=93.168×103lb.s2/ft

The expression for the normal force acting on the block C as follows:

NC=mCg

The expression for the work done [(U12)C] by frictional force acting on the block C as it slides through the distance dC as follows:

(U12)C=μkNCdC=μkmCgdC

The expression for the initial kinetic energy of the block C (T1)C while the bullet just gets embedded in the block C as follows:

(T1)C=12(mB+mC)vC2

The final kinetic energy of the block C with bullet embedded (T2)C is zero as the block C comes to rest finally.

The expression for the principle of work-energy to the block C after the bullet just gets embedded in the block as follows:

(T1)C+(U12)C=(T2)C

Substitute 12(mB+mC)vC2 for (T1)C, μkmCgdC for (U12)C, and 0 for (T2)C.

12(mB+mC)vC2μkmCgdC=012(mB+mC)vC2=μkmCgdCvC2=2μkmCgdCmB+mCvC=2μkmCgdCmB+mC

Substitute 0.25 for μk, 32.2ft/s2 for g, 4in. for dC, 93.168×103lb.s2/ft for mC, and 970.5×106lb.s2/ft for mB.

vC=2(0.25)(93.168×103lb.s2/ft)(32.2ft/s2)(4in)(93.168×103lb.s2/ft+970.5×106lb.s2/ft)=1,500.0048×103(4in)93.168×103=16.1(4×0.08333ft1in)=5.3665=2.3166ft/s

Substitute 2.3166ft/s for vC, 93.168×103lb.s2/ft for mC, and vA 970.5×106lb.s2/ft for mB in the Equation (2).

v1=(mB+mC)vCmB=(93.168×103lb.s2/ft+970.5×106lb.s2/ft)(2.3166ft/s)970.5×106lb.s2/ft=(93.168×103)(2.3166)970.5×106=215.833×103970.5×106=224.71ft/s

Calculate the initial speed of the bullet (v0) using the relation:

Consider the equation (1).

Substitute 224.71ft/s for v1, 970.5×106lb.s2/ft for mB, 2.3166ft/s for vA, and 93.168×103lb.s2/ft for.2.8372ft/s mA in the Equation (1).

v0=v1+mAvAmB=224.71ft/s+(93.168×103lb.s2/ft)(2.8372ft/s)970.5×106lb.s2/ft=224.71+272.3712=497.08ft/s

Therefore, the initial speed (v0) of the bullet is 497.08ft/s_.

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Chapter 13 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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