Principles of Physics: A Calculus-Based Text, Hybrid (with Enhanced WebAssign Printed Access Card)
Principles of Physics: A Calculus-Based Text, Hybrid (with Enhanced WebAssign Printed Access Card)
5th Edition
ISBN: 9781305586871
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 4, Problem 52P

(a)

To determine

The tension in the string.

(a)

Expert Solution
Check Mark

Answer to Problem 52P

The tension in the string is m2g(m1Mm2M+m1(m2+M)).

Explanation of Solution

Consider the free body diagram given below.

Principles of Physics: A Calculus-Based Text, Hybrid (with Enhanced WebAssign Printed Access Card), Chapter 4, Problem 52P

Figure I

Here, a is the acceleration of hanging block having mass m1, A is the acceleration of large block having mass M, and aA is the acceleration of top block having mass m2.

Write the expression for the equilibrium condition for hanging block

    m1gT=m1aT=m1(ga)        (I)

Here, m1 is the mass of the hanging block, a is the acceleration of the hanging block, g is the acceleration due to gravity and T is the tension of the cord.

Write the expression for the equilibrium condition for top block

    T=m2(aA)a=Tm2+A        (II)

Here, m2 is the mass of the top block and A is the acceleration of the top block

Write the expression for the equilibrium condition for large block

    MA=TA=TM        (III)

Here, M is the acceleration of the large mass.

Substitute (Tm2+A) for a and TM for A in equation (I) to find T.

    T=m1(g(Tm2+A))=m1(g(Tm2+TM))=m1g(m1Tm2+m1TM)=m1gm1T(M+m2Mm2)

Further, solve it for T.

    T=m1gm1T(M+m2Mm2)T+m1T(M+m2Mm2)=m1gT=m2g(m1Mm2M+m1(m2+M))

Conclusion:

Therefore, the tension in the string is m2g(m1Mm2M+m1(m2+M)).

(b)

To determine

The acceleration of m2.

(b)

Expert Solution
Check Mark

Answer to Problem 52P

The acceleration of m2 is m1g(M+m2)Mm2+m1(M+m2).

Explanation of Solution

The force applied on the block of mass M is zero initially and the block of mass m2 has acceleration in synchronization with the big block so the net acceleration on the block is a.

Substitute TM for A in equation (II).

    a=Tm2+TM=T(M+m2Mm2)

Substitute m1g(Mm2Mm2+m1(M+m2)) for T in above equation to find a.

    a=(m1g(Mm2Mm2+m1(M+m2)))(M+m2Mm2)=m1g(M+m2)Mm2+m1(M+m2)

Conclusion:

Therefore, the acceleration of m2 is m1g(M+m2)Mm2+m1(M+m2).

(c)

To determine

The acceleration of M.

(c)

Expert Solution
Check Mark

Answer to Problem 52P

The acceleration of M is m1m2gm2M+m1(m2+M).

Explanation of Solution

The acceleration of M is A.

Substitute m1g(Mm2Mm2+m1(M+m2)) for T in equation (II).

    A=m1g(Mm2Mm2+m1(M+m2))M=m1m2gm2M+m1(m2+M)

Conclusion:

Therefore, the acceleration of M is m1m2gm2M+m1(m2+M).

(d)

To determine

The acceleration of m1.

(d)

Expert Solution
Check Mark

Answer to Problem 52P

The acceleration of m1 is Mm1gMm2+m1(M+m2).

Explanation of Solution

The block of mass m1 moves in vertical direction only but the net acceleration is the difference between the acceleration of the big block of mass M and the acceleration a of m2.

Write the formula to calculate the acceleration of m1

    am1=aA        (IV)

Here, am1 is the acceleration of mass m1.

Substitute m1g(Mm2Mm2+m1(M+m2)) for T in equation (II).

    A=m1g(Mm2Mm2+m1(M+m2))M=m1m2gm2M+m1(m2+M)

Substitute (m1g(M+m2)Mm2+m1(M+m2)) for a and m1m2gm2M+m1(m2+M) for A in equation (4) to find the value of aA.

    aA=(m1g(M+m2)Mm2+m1(M+m2))(m1m2gMm2+m1(M+m2))=(Mm1gMm2+m1(M+m2))

Conclusion:

Therefore, the acceleration of m1 is Mm1gMm2+m1(M+m2).

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Chapter 4 Solutions

Principles of Physics: A Calculus-Based Text, Hybrid (with Enhanced WebAssign Printed Access Card)

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