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 19, Problem 19.165RP

A 4-lb uniform rod is supported by a pin at O and a spring at A and is connected to a dashpot at B. Determine (a) the differential equation of motion for small oscillations, (b) the angle that the rod will form with the horizontal 5 s after end B has been pushed 0.9 in. down and released.

Chapter 19, Problem 19.165RP, A 4-lb uniform rod is supported by a pin at O and a spring at A and is connected to a dashpot at B.

Fig. P19.165

(a)

Expert Solution
Check Mark
To determine

The differential equation of motion for small oscillations.

Answer to Problem 19.165RP

The differential equation of motion for small oscillations is 0.072464θ¨+1.125θ˙+1.25θ=0_.

Explanation of Solution

Given information:

The weight of the uniform rod (W) is 4 lb.

The distance between A to O (a) is 6 inch.

The distance between O to B (b) is 18 in.

The spring constant (k) is 5 lb/ft.

The damping coefficient (c) is 0.5lbs/ft.

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

Calculation:

Calculate the mass of the uniform rod (m) using the formula:

W=mgm=Wg

Substitute 4 lb for W and 32.2ft/s2 for g.

m=432.2=0.124224lbs2/ft

Show the free body diagram of the rod as Figure (1).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19, Problem 19.165RP

For small angle, take sinθ as θ and cosθ as 1.

Calculate the deflection at the point A (δyA) using the relation:

δyA=aθ

Substitute 6 in. for a.

δyA=(6in112ftin.)θ=θ2

Calculate the deflection at the point B (δyB) using the relation:

δyB=bθ

Substitute 18 in. for b.

δyB=(18in112ftin.)θ=3θ2

Calculate the deflection at the point C (δyC) using the relation:

δyC=aθ

Substitute 6 in. for a.

δyC=(6in112ftin.)θ=θ2

Take the moment about O.

MO=(MO)eff[Fs×(612ft)]+[4×(612ft)][FD×(1812ft)]=I¯α+[(ma¯t)×(612ft)] (1)

Calculate for the spring force (Fs) using the relation:

Fs=k(δyA+(δst)A)

Substitute θ2 for δyA.

Fs=k(θ2+(δst)A)

Calculate the damping force (FD) using the relation:

FD=cδy˙B

Substitute 3θ˙2 for δy˙B.

FD=c3θ˙2

Calculate the moment of inertia (I¯) of the rod using the formula:

I¯=112m(a+b)2

Substitute 6 in. for a and 18 in. for b.

I¯=112m(6+1812ft)2=13m

The angle (α) will be same as the angular acceleration (θ¨).

Calculate the acceleration (a¯t) using the relation:

a¯t=(a)α

Substitute 6 in. for a and θ¨ for α.

a¯t=(612ft)θ¨=θ¨2

Substitute k(θ2+(δst)A) for Fs, c3θ˙2 for FD, 13m for I¯, θ¨ for α, and θ¨2 for a¯t in Equation (1).

{[k(θ2+(δst)A)×(612ft)]+[4×(612ft)][c3θ˙2×(1812ft)]}={13mθ¨+[(mθ¨2)×(612ft)]}{13mθ¨+[(mθ¨2)×(612ft)]+[k(θ2+(δst)A)×(612ft)][4×(612ft)]+[c3θ˙2×(1812ft)]}=0m3θ¨+m4θ¨+k2(θ2+(δst)A)2+94cθ˙=0 (2)

Consider equilibrium.

Take the moment about O.

MO=0k(δst)A(612ft)4(612ft)=0k2(δst)A=4(612ft)k2(δst)A=2

Substitute 2 for k2(δst)A in Equation (2).

m3θ¨+m4θ¨+(k2θ2+k2(δst)A)2+94cθ˙=0m3θ¨+m4θ¨+k2θ2+22+94cθ˙=0

Substitute 0.124224lbs2/ft for m, 5 lb/ft for k, and 0.5lbs/ft for c.

0.1242243θ¨+0.1242244θ¨+52θ2+22+94(0.5)θ˙=00.041408θ¨+0.031056θ¨+2.5(0.5θ)+1.125θ˙=00.072464θ¨+1.125θ˙+1.25θ=0 (3)

Therefore, the differential equation of motion for small oscillations is 0.072464θ¨+1.125θ˙+1.25θ=0_.

(b)

Expert Solution
Check Mark
To determine

The angle that the rod (θ) will form with the horizontal 5 sec after end B has been pushed 0.9 in. down and released.

Answer to Problem 19.165RP

The angle that the rod (θ) is 0_ and the rod return back to its equilibrium position after a finite time.

Explanation of Solution

Given information:

The weight of the uniform rod (W) is 4 lb.

The distance between A to O (a) is 6 inch.

The distance between O to B (b) is 18 inch.

The spring constant (k) is 5 lb/ft.

The damping coefficient (c) is 0.5lbs/ft.

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

Calculation:

Consider the equation (3).

Substitute λ for θ in the equation (3).

0.072464λ2+1.125λ+1.25=0

Solve the above equation.

λ1=1.2046λ2=14.3204

Since the computed roots are real and distinct.

Write the expression for the general solution for the differential equation as follows:

θ=C1eλ1t+C2eλ2t (4)

Substitute 0 for t.

θ(0)=C1eλ1(0)+C2eλ2(0)0=C1+C2

Differentiate the equation (4) with respect to time ‘t’.

θ˙=C1teλ1t+C2teλ2t

Substitute 0 for t.

θ˙(0)=C1(0)eλ1(0)+C2(0)eλ2(0)=0

The above solution corresponds to a no vibratory motion because the roots λ1 and λ2 are both negative, then the values of the above solution will be zero as time ‘t’ increases indefinitely. Thus, the system returns back to its equilibrium position after a finite time.

Therefore, the angle that the rod (θ) is 0_ and the rod return back to its equilibrium position after a finite time.

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Chapter 19 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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