Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics
Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics
11th Edition
ISBN: 9781259639272
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek, Phillip J. Cornwell, Brian Self
Publisher: McGraw-Hill Education
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Chapter 9.2, Problem 9.48P

9.47 and 9.48 Determine the polar moment of inertia of the area shown with respect to (a) point O, (b) the centroid of the area.

Chapter 9.2, Problem 9.48P, 9.47 and 9.48 Determine the polar moment of inertia of the area shown with respect to (a) point O,

Fig. P9.48

(a)

Expert Solution
Check Mark
To determine

Find the polar moment of inertia of the area with respect to point O.

Answer to Problem 9.48P

The polar moment of inertia of the area with respect to point O is 12.16×106mm4_.

Explanation of Solution

Calculation:

Sketch the cross section as shown in Figure 1.

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 9.2, Problem 9.48P

Refer to Figure1.

It is divided into 4 parts as shown above.

Find the area of section 1 ellipsoid using the relation:

A1=π2(ar) (1)

Substitute 84mm for a and 42mm for r in Equation (1).

A1=π2(84)(42)=5,541.76mm2

Find the area of section 2 ellipsoid using the relation:

A2=π2(ro)2 (2)

Here, ro is radius of outer section.

Substitute 42mm for r in Equation (2).

A2=π2(42)2=2,770.88mm2

Find the area of section 3 ellipsoid using the relation:

A3=π2(ar) (3)

Substitute 54mm for a and 27mm for r in Equation (3).

A3=π2(54)(27)=2,290.22mm2

Find the area of section 4 ellipsoid using the relation:

A4=π2(ri)2 (4)

Substitute 27mm for r in Equation (4).

A4=π2(27)2=1,145.11mm2

Find the total are of section (A) as shown below:

A=A1+A2+A3+A4 (5)

Substitute 5,541.76mm2 for A1, 2,770.88mm2 for A2, 2,290.22mm2 for A3, and 1,145.11mm2 for A4 in Equation (5).

A=5,541.76+2,770.882,290.221,145.11=4,877.32mm2

Find the centroid (x1) section 1 as shown below:

x1=112π=35.6507mm

Find the centroid (x2) section 2 as shown below:

x2=56π=17.8254mm

Find the centroid (x3) section 3 as shown below:

x3=72π=22.9183mm

Find the centroid (x4) section 4 as shown below:

x4=36π=11.4592mm

Find the centroid (x¯) using the relation as follows:

x¯=A1x1+A2x2+A3x3+A4x4A1+A2+A3+A4 (6)

Substitute 5,541.76mm2 for A1, 2,770.88mm2 for A2, 2,290.22mm2 for A3, 1,145.11mm2 for A4, 35.6507mm for x1, and 17.8254mm for x2, 22.9183mm for  x3, 11.4592mm for x4 , in Equation (6).

x¯=5,541.76(35.6507)+2,770.88(17.8254)2,290.22(22.9183)1,145.11(11.4592)5,541.76+2,770.882,290.221,145.11=197,567.62+49,392.044+52,487.94913,122.04,877.32=22.3094mm

Find the polar moment of inertia (JO)1 section 1 as shown below:

(JO)1=π8(aro)[a2+ro2] (7)

Substitute 84mm for a and 42mm for ro in Equation (7).

(JO)1=π8(84×42)[842+422]=π8(84×42)8,820=12,219,601.62=12.21960×106mm4

Find the polar moment of inertia (JO)2 section 2 as shown below:

(JO)2=π4ro2 (8)

Substitute 42mm for ro in Equation (8).

(JO)2=π4(42)2=2.444392×106mm4

Find the polar moment of inertia (JO)3 section 3 as shown below:

(JO)3=π8(ari)[a2+ri2] (9)

Substitute 54mm for a and 27mm for ri in Equation (9).

(JO)3=π8(54×27)[542+272]=572.555[3,645]=2.08696×106mm4

Find the polar moment of inertia (JO)2 section 2 as shown below:

(JO)4=π4ri2 (10)

Substitute 27mm for ri in Equation (10).

(JO)4=π4(27)2=0.41739×106mm4

Find the total moment of inertia (JO) using the relation:

(JO)=(JO)1+(JO)2(JO)3(JO)4 (11)

Substitute 12.21960×106mm4 for (JO)1, 2.444392×106mm4 for (JO)2, 2.08696×106mm4 for (JO)3, and 0.41739×106mm4 for (JO)4 in Equation (11).

(JO)=12.21960×106+2.444392×1062.08696×1060.41739×106=12,159,652=12.16×106mm4

Thus, the polar moment of inertia of the area with respect to point O is 12.16×106mm4_.

(b)

Expert Solution
Check Mark
To determine

Find the centroid of area.

Answer to Problem 9.48P

The centroid of area is 9.73×106mm4_.

Explanation of Solution

Calculation:

Find the centroid of area using the relation:

JO=JC+AX¯2 (12)

Substitute 12.16×106mm4 for JO, 4,877.32mm2 for A, and 22.3094mm for x¯,and 0.7468in for y¯ in Equation (12).

12.16×106=JC+(4,877.32)(22.3094)212.16×106=JC+2,427,487.66JC=9.73×106mm4

Thus, the centroid of area is 9.73×106mm4_.

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Please help me answer the following, thanks.
Determine the polar moment of inertia of the area shown with respect to (a) point , (b) the centroid of the area.
For the entire section shown, the moments of inertia with respect to the centroidal x and y axes at point C are Ix = 0.162(106) mm4 and Iy = 0.454(106) mm4, respectively. a. Determine the product of inertia with respect to the centroid at C, in mm4. b. Use a Mohr's Circle to determine the orientation (in degrees) of the principal axes of the section about the centroid C. c. Use the same Mohr's Circle to determine the values of the principal moments of inertia about the centroid C, in mm4.

Chapter 9 Solutions

Connect 1 Semester Access Card for Vector Mechanics for Engineers: Statics and Dynamics

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Prob. 9.126PCh. 9.5 - Prob. 9.127PCh. 9.5 - Prob. 9.128PCh. 9.5 - Prob. 9.129PCh. 9.5 - Prob. 9.130PCh. 9.5 - Prob. 9.131PCh. 9.5 - The cups and the arms of an anemometer are...Ch. 9.5 - Prob. 9.133PCh. 9.5 - Determine the mass moment of inertia of the 0.9-lb...Ch. 9.5 - Prob. 9.135PCh. 9.5 - Prob. 9.136PCh. 9.5 - Prob. 9.137PCh. 9.5 - A section of sheet steel 0.03 in. thick is cut and...Ch. 9.5 - Prob. 9.139PCh. 9.5 - A farmer constructs a trough by welding a...Ch. 9.5 - The machine element shown is fabricated from...Ch. 9.5 - Determine the mass moments of inertia and the...Ch. 9.5 - Determine the mass moment of inertia of the steel...Ch. 9.5 - Prob. 9.144PCh. 9.5 - Determine the mass moment of inertia of the steel...Ch. 9.5 - Aluminum wire with a weight per unit length of...Ch. 9.5 - The figure shown is formed of 18-in.-diameter...Ch. 9.5 - A homogeneous wire with a mass per unit length of...Ch. 9.6 - Determine the mass products of inertia Ixy, Iyz,...Ch. 9.6 - Determine the mass products of inertia Ixy, Iyz,...Ch. 9.6 - 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