Vector Mechanics For Engineers
Vector Mechanics For Engineers
12th Edition
ISBN: 9781259977305
Author: BEER, Ferdinand P. (ferdinand Pierre), Johnston, E. Russell (elwood Russell), Cornwell, Phillip J., SELF, Brian P.
Publisher: Mcgraw-hill Education,
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Chapter 12.1, Problem 12.19P

Block A has a mass of 40 kg, and block B has a mass of 8 kg. The coefficients of friction between all surfaces of contact are μ s = 0.20 and μ k = 0.15 . If P = 40 N, determine (a) the acceleration of block B, (b) the tension in the cord.

  Chapter 12.1, Problem 12.19P, Block A has a mass of 40 kg, and block B has a mass of 8 kg. The coefficients of friction between

Expert Solution
Check Mark
To determine

(a)

Acceleration of block B.

Answer to Problem 12.19P

Acceleration of block B:

aB=1.794m/s2

Explanation of Solution

Given:

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  1

mA=40kg,mB=8kg

μs=0.20,μk=0.15

P=40N

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  2

From the constraint of the cord:

2xA+xB/A=constant

Then

2vA+vB/A=0

And

2aA+aB/A=0

Now

aB=aA+aB/A

Then

aB=aA+(2aA)

Or:

aB=aA   ... (1)

First, we determine if the blocks will move for the given value of P. Thus, we seek the value of P for which the blocks are in impeding motion, with the impeding motion of A down the incline.

For B:

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  3

+Fy=0 :

NABWBcos25=0

Or:

NAB=mBgcos25

Now

FAB=μsNAB

FAB=0.2mBgcos25

+Fx=0 :

T+FAB+WBsin25=0

Or:

T=0.2mBgcos25+mBgsin25

Or:

T=(8kg)(9.81m/s2)(0.2cos25+sin25)

Or:

T=47.39249N

For A:

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  4

+Fy=0 :

NANABWAcos25+Psin25=0

Or:

NA=(mA+mB)gcos25Psin25

Now

FA=μsNAFA=0.2((mA+mB)gcosθPsin25)

+Fx=0 :

TFAFAB+WAsin25+Pcos25=0

T+mAgsin250.2[(mA+mB)gcos25Psin25]0.2mBgcos25+Pcos25=0

Or:

P(0.2sin25+cos25)=0.2[(mA+2mB)gcos25]mAgsin25

Then

P(0.2sin25+cos25)=47.39249N+9.81m/s2{0.2[(40+2×8)cos2540sin25]kg}

P=19.04N, for impeding motion

Since P<40N, the blocks will move.

Now, consider the motion of the blocks.

For B:

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  5

+Fy=0 :

NABWBcos25=0

Or:

NAB=mBgcos25

Sliding:

FAB=μkNAB=0.15mBcos25

+Fx=mBaB

T+FAB+WBsin25=mBaB

Or:

T=mB[g(0.15cos25+sin25)aB]

T=8[9.81(0.15cos25+sin25)aB]

T=8(5.47952aB)

For A:

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  6

+Fy=0 :

NANABWAcos25+Psin25=0

Or:

NA=(mA+mB)gcos25Psin25

Sliding:

FA=μkNA=0.15(mA+mB)gcos25Psin25

+Fx=mAaA :

TFAFAB+WAsin25+Pcos25=mAaA

Substituting and using Eq. (1):

T=mAgsin250.15(mA+mB)gcos250.15mBgcos25+Pcos25mA(aB)

T=g[mAsin250.15(mA+mB)cos25]+P(0.15sin25+cos25)+mAaB

T=9.81[40sin250.15(40+2×8)cos25]40(0.15sin25+cos25)+40aB

T=129.94004+40aB

Equating the two expressions for T,

8(5.47952aB)=129.94004+40aB

Or:

aB=1.79383m/s2

aB=1.79383m/s2

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  7

Expert Solution
Check Mark
To determine

(b)

Tension in the cable

Answer to Problem 12.19P

Tension in the cable:

T=58.2N

Explanation of Solution

Given:

Vector Mechanics For Engineers, Chapter 12.1, Problem 12.19P , additional homework tip  8

mA=40kg,mB=8kg

μs=0.20,μk=0.15

P=40N

T=8(5.47952aB)

T=8[5.47952(1.79383)]

Or:

T=58.2N

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Vector Mechanics For Engineers

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