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 9.2, Problem 9.44P
To determine

Find the moment of inertia (I¯x) and (I¯y) of the area with respect to centroidal axes.

Expert Solution & Answer
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Answer to Problem 9.44P

The moment of inertia (I¯x) and (I¯y) of the area are 18.13in.4_ and 4.51in.4_ respectively.

Explanation of Solution

Calculation:

Show the area with parts of the section as Figure 1.

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 9.2, Problem 9.44P

Calculate the centroid of the area as in Table 1.

SectionArea, A (in.2)(x¯) (in.)(y¯) (in.)

(Ax¯)

(in.3)

(Ay¯)

(in.3)

13.6×0.5=1.83.62=1.80.52=0.253.240.45
23.8×0.5=1.90.52=0.250.5+3.82=2.40.4754.56
31.3×1.0=1.31.32=0.650.5+3.8+12=4.80.8456.24
Total ()5.0  4.56011.25

Calculate the centroid of the area with respect to x axis (X¯) using the formula:

X¯=Ax¯A

Substitute 4.56in.3 for Ax¯ and 5in.2 for A.

X¯=4.565=0.912in.

Calculate the centroid of the area with respect to y axis (Y¯) using the formula:

Y¯=Ay¯A

Substitute 11.25in.3 for Ay¯ and 5in.2 for A.

Y¯=11.255=2.25in.

Consider the x axis.

Consider the section 1.

Calculate the moment of inertia of section 1 (I¯1) using the formula:

I¯1=3.6×0.5312=0.0375in.4

Calculate the centroid of section 1 (d1) from the centroid of entire section using the relation:

d1=Y¯y¯1

Substitute 2.25 in. for Y¯ and 0.25 in. for y¯1.

d1=2.250.25=2in.

Calculate the moment of inertia of section 1 (Ix)1 with respect to x axis using the formula:

(Ix)1=I¯1+A1d12

Substitute 0.0375in.4 for I¯1, 1.8in.2 for A1 and 2 in. for d1.

(Ix)1=0.0375in.4+[1.8×(2)2]=7.2375in.4

Consider the section 2.

Calculate the moment of inertia of section 2 (I¯2) using the formula:

I¯2=0.5×3.8312=2.2863in.4

Calculate the centroid of section 2 (d2) from the centroid of entire section using the relation:

d2=y¯2Y¯

Substitute 2.25 in. for Y¯ and 2.4 in. for y¯2.

d2=2.42.25=0.15in.

Calculate the moment of inertia of section 2 (Ix)2 with respect to x axis using the formula:

(Ix)2=I¯2+A2d22

Substitute 2.2863in.4 for I¯2, 1.9in.2 for A2 and 0.15 in. for d2.

(Ix)2=2.2863in.4+[1.9×(0.15)2]=2.3291in.4

Consider the section 3.

Calculate the moment of inertia of section 3 (I¯3) using the formula:

I¯3=1.3×1.0312=0.1083in.4

Calculate the centroid of section 3 (d3) from the centroid of entire section using the relation:

d3=y¯3Y¯

Substitute 2.25 in. for Y¯ and 4.8 in. for y¯3.

d3=4.82.25=2.55in.

Calculate the moment of inertia of section 3 (Ix)3 with respect to x axis using the formula:

(Ix)3=I¯3+A3d32

Substitute 0.1083in.4 for I¯3, 1.3in.2 for A3 and 2.55 in. for d3.

(Ix)3=0.1083in.4+[1.3×(2.55)2]=8.5616in.4

Calculate the moment of inertia of entire section (I¯x) with respect to x axis using the relation:

I¯x=(Ix)1+(Ix)2+(Ix)3

Substitute 7.2375in.4 for (Ix)1, 2.3291in.4 for (Ix)2 and 8.5616in.4 for (Ix)3.

I¯x=7.2375in.4+2.3291in.4+8.5616in.4=18.13in.4

Consider the y axis.

Consider the section 1.

Calculate the moment of inertia of section 1 (I¯1) using the formula:

I¯1=0.5×3.6312=1.944in.4

Calculate the centroid of section 1 (d1) from the centroid of entire section using the relation:

d1=x¯1X¯

Substitute 0.912 in. for X¯ and 1.8 in. for x¯1.

d1=1.80.912=0.888in.

Calculate the moment of inertia of section 1 (Iy)1 with respect to y axis using the formula:

(Iy)1=I¯1+A1d12

Substitute 1.944in.4 for I¯1, 1.8in.2 for A1 and 0.888 in. for d1.

(Iy)1=1.944in.4+[1.8×(0.888)2]=3.3634in.4

Consider the section 2.

Calculate the moment of inertia of section 2 (I¯2) using the formula:

I¯2=3.8×0.5312=0.0396in.4

Calculate the centroid of section 2 (d2) from the centroid of entire section using the relation:

d2=X¯x¯2

Substitute 0.912 in. for X¯ and 0.25 in. for x¯2.

d2=0.9120.25=0.662in.

Calculate the moment of inertia of section 2 (Iy)2 with respect to y axis using the formula:

(Iy)2=I¯2+A2d22

Substitute 0.0396in.4 for I¯2, 1.9in.2 for A2 and 0.662 in. for d2.

(Iy)2=0.0396in.4+[1.9×(0.662)2]=0.8723in.4

Consider the section 3.

Calculate the moment of inertia of section 3 (I¯3) using the formula:

I¯3=1.0×1.3312=0.1831in.4

Calculate the centroid of section 3 (d3) from the centroid of entire section using the relation:

d3=X¯x¯3

Substitute 0.912 in. for X¯ and 0.65 in. for x¯3.

d3=0.9120.65=0.262in.

Calculate the moment of inertia of section 3 (Iy)3 with respect to y axis using the formula:

(Iy)3=I¯3+A3d32

Substitute 0.1831in.4 for I¯3, 1.3in.2 for A3 and 0.262 in. for d3.

(Iy)3=0.1831in.4+[1.3×(0.262)2]=0.2723in.4

Calculate the moment of inertia of entire section (I¯y) with respect to y axis using the relation:

I¯y=(Iy)1+(Iy)2+(Iy)3

Substitute 3.3634in.4 for (Iy)1, 0.8723in.4 for (Iy)2 and 0.2723in.4 for (Iy)3.

I¯y=3.3634in.4+0.8723in.4+0.2723in.4=4.51in.4

Therefore, the moment of inertia (I¯x) and (I¯y) of the area are 18.13in.4_ and 4.51in.4_ respectively.

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Chapter 9 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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