Vector Mechanics For Engineers
Vector Mechanics For Engineers
12th Edition
ISBN: 9781259977237
Author: BEER
Publisher: MCG
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Chapter 12, Problem 12.133RP

Disk A rotates in a horizontal plane about a vertical axis at the constant rate θ . 0 = 10 rad/s. Slider B has mass 1 kg and moves in a frictionless slot cut in the disk. The slider is attached to a spring of constant k, which is undeformed when r = 0 . Knowing that the slider is released with no radial velocity in the position r = 500 mm, determine the position of the slider and the horizontal force exerted on it by the disk at t = 0.1 s for (a) k = 100 N/m, (b) k = 200 N/m.

  Chapter 12, Problem 12.133RP, Disk A rotates in a horizontal plane about a vertical axis at the constant rate .0=10 rad/s. Slider

Expert Solution
Check Mark
To determine

(a)

The position of slider and horizontal force exerted on at t=0.1s for k=100N/m.

Answer to Problem 12.133RP

r=0.5FA=0

Explanation of Solution

Given information:

Vector Mechanics For Engineers, Chapter 12, Problem 12.133RP , additional homework tip  1

Disk A rotates at constant rate θ˙0=10rad/s

Mass of slider B is 1kg

The spring constant is k

Slider is released at r=500mm

Newton’s second law of motion is denoted as,

F=ma

The radial component of acceleration is defined as,

ar=r¨rθ˙2

The spring force is defined as,

Fspring=kx

Where,

x - Elongation

Calculation:

According to given information, we know that

r=0r0=0.5mθ˙=10rad/sθ¨=0

For block B,

Fr=mBar

Substitute,

Fspring=mBarkr=mB(r¨rθ˙2)(1)

Rearrange,

r¨+(kmBθ˙2)r=0

Then,

Fθ=mBaθFA=mB(0+2r˙θ˙)(2)

Therefore, for k=100N/m

r¨+(kmBθ˙2)r=0r¨+(100N/m1kg(10rad/s)2)r=0r¨=0

Therefore,

dr˙dt=r¨=00r˙dr˙=00.10dtr˙=0

Then,

drdt=r˙=0

At t=0,r0=0.5m

r0rdr=00.10dtr=r0=0.5

Now, according to equation 2,

FA=0

Because of r˙=0

Conclusion:

The position of slider and horizontal force exerted on at t=0.1s for k=100N/m is equal to,

r=0.5FA=0

Expert Solution
Check Mark
To determine

(b)

The position of slider and horizontal force exerted on at t=0.1s for k=200N/m

Answer to Problem 12.133RP

r=0.27mFA=84.147N

Explanation of Solution

Given information:

Vector Mechanics For Engineers, Chapter 12, Problem 12.133RP , additional homework tip  2

Disk A rotates at constant rate θ˙0=10rad/s

Mass of slider B is 1kg

The spring constant is k

Slider is released at r=500mm

Newton’s second law of motion is denoted as,

F=ma

The radial component of acceleration is defined as,

ar=r¨rθ˙2

The spring force is defined as,

Fspring=kx

Where,

x - Elongation

Calculation:

According to sub-part a,

We have found,

r¨+(kmBθ˙2)r=0

At k=200N/m, it becomes,

r¨+(200N/m1kg(10rad/s)2)r=0r¨+100r=0

But we can define r¨ as,

r¨=vrdvrdr

Then,

vrdvrdr+100r=0

At t=0,vr=0,r=r0

0vrvrdvr=100r0rrdrvr=10r02r2

But we know that,

vr=drdt

Therefore,

At t=0,r=r0

drdt=10r02r2r0r1r02r2dr=0t10dt

To solve this, assume

r=r0sinϕdr=r0cosϕdϕ

Therefore,

π/2sin1(r/r0)r0cosϕdϕr02(r0sinϕ)2=0t10dtπ/2sin1(r/r0)dϕ=10t

By solving further,

sin1(r/r0)π/2=10t

Rearrange,

r=r0sin(π/2+10t)r=r0cos10t(1)

Substitute,

r=0.5cos10(0.1)r=0.27m

Differentiate equation 1,

r˙=5sin10t

Now find the force exerted,

FA=mB(0+2r˙θ˙)FA=1kg(2((5sin10×0.1))10rad/s)=84.147N

Conclusion:

The position of slider and horizontal force exerted on at t=0.1s for k=200N/m is equal to,

r=0.27mFA=84.147N

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Chapter 12 Solutions

Vector Mechanics For Engineers

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