Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card
Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card
11th Edition
ISBN: 9781259679407
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek, Phillip J. Cornwell
Publisher: McGraw-Hill Education
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Basic Terminology in Mechanics
The area of science and mathematics concerned the motion of the objects, the relation between the force matter, and motion if specified. Forces exerted over the objects result in displacements or changes in the position of an object concerning its enviro…
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Chapter 12, Problem 12.128RP
To determine

(a)

Minimum value of coefficient of static friction between the collar and rod at θ=900.

Expert Solution
Check Mark

Answer to Problem 12.128RP

Minimum value of coefficient of static friction between the collar and rod is 0.454.

Explanation of Solution

Given information:

Mass of the collar C, m=200 gm or 0.2 kg.

Angular rotation of rod, ω =6 rad/s.

Position of block E, θ=900

Calculations:

Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card, Chapter 12, Problem 12.128RP , additional homework tip 1

AB is the axis of rotation and collar C slide on semicircular rod. So, the distance of collar C from the axis AB,

s=rsinθs=0.6sin90s=0.6m

Acceleration of the collar,

a=sω2a=0.6×62a=21.6m/s2

Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card, Chapter 12, Problem 12.128RP , additional homework tip 2

Equilibrium force along x direction,

Fx=mcaN=mcaN=0.2×21.6N=4.32N

Equilibrium force along y direction,

Fy=0F=wμkN=mgμk=mgNμk=0.2×9.814.32μk=1.9624.32μk=0.454

To determine

(b)

Minimum value of coefficient of static friction between the collar and rod at θ=750.

Expert Solution
Check Mark

Answer to Problem 12.128RP

Minimum value of coefficient of static friction between the collar and rod is 0.179.

Explanation of Solution

Given information:

Mass of the collar C, m=200 gm or 0.2 kg.

Angular rotation of rod, ω =6 rad/s.

Position of block E, θ=750

Calculations:

AB is the axis of rotation and collar C slide on semicircular rod. So, the distance of collar C from the axis AB is

s=rsinθs=0.6sin75s=0.579m

Acceleration of the collar,

a=sω2a=0.579×62a=20.86m/s2

For the value of θ=750, the direction is not known. The motion of collar is upward or downward. Consider both possibilities.

For downward impending motion,

Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card, Chapter 12, Problem 12.128RP , additional homework tip 3

Equilibrium force along y direction,

Fy=0Ncosθ+Fsinθ=WNcosθ+μkNsinθ=WN(cosθ+μksinθ)=WN=mcgcosθ+μksinθ(1)

Equilibrium force along normal direction,

Fn=mcaNsinθFcosθ=mcaNsinθμkNcosθ=mcaN(sinθμkcosθ)=mcaN=mcasinθμkcosθ(2)

Equating equation 1 and equation 2,

mcgcosθ+μksinθ=mcasinθμkcosθgsinθgμkcosθ=acosθ+aμksinθaμksinθ+gμkcosθ=gsinθacosθμk(asinθ+gcosθ)=gsinθacosθμk=gsinθacosθasinθ+gcosθμk=gtanθaatanθ+gμk=9.81×tan75020.8620.86×tan750+9.81μk=9.81×3.73220.8620.86×3.732+9.81μk=36.6120.8677.86+9.81μk=15.7587.67μk=0.179

For upward impending motion,

Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card, Chapter 12, Problem 12.128RP , additional homework tip 4

Equilibrium force along y direction,

Fy=0NcosθFsinθ=WNcosθμkNsinθ=WN(cosθμksinθ)=WN=mcgcosθμksinθ(4)

Equilibrium force along normal direction,

Fn=mcaNsinθ+Fcosθ=mcaNsinθ+μkNcosθ=mcaN(sinθ+μkcosθ)=mcaN=mcasinθ+μkcosθ(5)

Equating equation 4 and equation 5,

mcgcosθμksinθ=mcasinθ+μkcosθgsinθ+gμkcosθ=acosθaμksinθaμksinθ+gμkcosθ=acosθgsinθμk(asinθ+gcosθ)=acosθgsinθμk=acosθgsinθasinθ+gcosθμk=atanθgatanθ+gμk=20.86×tan7509.8120.86×tan750+9.81μk=20.86×3.7329.8120.86×3.732+9.81μk=77.869.8177.86+9.81μk=68.0587.67μk=0.776

To determine

(c)

Minimum value of coefficient of static friction between the collar and rod at θ=450.

Expert Solution
Check Mark

Answer to Problem 12.128RP

Minimum value of coefficient of static friction between the collar and rod is 0.218.

Explanation of Solution

Given information:

Mass of the collar C, m=200 gm or 0.2 kg.

Angular rotation of rod, ω =6 rad/s.

Position of block E, θ=450

Calculations:

AB is the axis of rotation and collar C slide on semicircular rod. So, the distance of collar C from the axis AB,

s=rsinθs=0.6sin45s=0.424m

Acceleration of the collar,

a=sω2a=0.424×62a=15.27m/s2

For the value of θ=450, the direction is not known. The motion of collar is upward or downward. Consider both possibilities.

For downward impending motion,

Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card, Chapter 12, Problem 12.128RP , additional homework tip 5

Equilibrium force along y direction,

Fy=0Ncosθ+Fsinθ=WNcosθ+μkNsinθ=WN(cosθ+μksinθ)=WN=mcgcosθ+μksinθ(1)

Equilibrium force along normal direction,

Fn=mcaNsinθFcosθ=mcaNsinθμkNcosθ=mcaN(sinθμkcosθ)=mcaN=mcasinθμkcosθ(2)

Equating equation 1 and equation 2,

mcgcosθ+μksinθ=mcasinθμkcosθgsinθgμkcosθ=acosθ+aμksinθaμksinθ+gμkcosθ=gsinθacosθμk(asinθ+gcosθ)=gsinθacosθμk=gsinθacosθasinθ+gcosθμk=gtanθaatanθ+gμk=9.81×tan45015.2715.27×tan450+9.81μk=9.81×115.2715.27×1+9.81μk=9.8115.2715.27+9.81μk=5.4625.08μk=0.218

For upward impending motion,

Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card, Chapter 12, Problem 12.128RP , additional homework tip 6

Equilibrium force along y direction,

Fy=0

NcosθFsinθ=W

NcosθμkNsinθ=W

N(cosθμksinθ)=W

N=mcgcosθμksinθ(4)

Equilibrium force along normal direction,

Fn=mcaNsinθ+Fcosθ=mcaNsinθ+μkNcosθ=mcaN(sinθ+μkcosθ)=mcaN=mcasinθ+μkcosθ(5)

Equating equation 4 and equation 5,

mcgcosθμksinθ=mcasinθ+μkcosθgsinθ+gμkcosθ=acosθaμksinθaμksinθ+gμkcosθ=acosθgsinθμk(asinθ+gcosθ)=acosθgsinθμk=acosθgsinθasinθ+gcosθμk=atanθgatanθ+gμk=15.27×tan4509.8115.27×tan450+9.81μk=15.27×19.8115.27×1+9.81μk=15.279.8115.27+9.81μk=5.4625.08μk=0.218

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Chapter 12 Solutions

Package: Vector Mechanics For Engineers: Dynamics With 1 Semester Connect Access Card

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