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 9.4, Problem 9.102P
To determine

Find the orientation of the principal centroid axes at the origin and the maximum minimum value of moment of inertia.

Expert Solution & Answer
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Answer to Problem 9.102P

The orientation of the principal axes at the origin is 15.99°counterclockwise_.

The maximum moment of inertia is 19.35in4_.

The minimum moment of inertia is 3.29in4_

Explanation of Solution

Calculation:

Sketch the cross section shown in Figure 1.

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 9.4, Problem 9.102P , additional homework tip  1

Refer to Figure 1.

Find the area (A1) of rectangle section 1 as shown below:

A1=b1h1 (1)

Here, b1 is width of the rectangular section and h1 is height of the rectangular section.

Substitute 3.6in. for b1 and 0.5in. for h1 in Equation (1).

A1=36×0.5=18in2

Find the area (A2) of rectangle section 2 as shown below:

A2=b2h2 (2)

Here, b2 is width of the rectangular section and h2 is height of the rectangular section.

Substitute 0.5in. for b2 and 3.8in. for h2 in Equation (2).

A2=0.5×3.8=1.9in2

Find the area of rectangle section 3 as shown below:

A3=b3h3 (3)

Here, b3 is width of the rectangular section and h3 is height of the rectangular section.

Substitute 1.3in. for b3 and 1.0in. for h3 in Equation (3).

A3=1.3×1.0=1.3in2

Refer to Figure 1.

Find the centroid (x1) as shown below:

(x1)=3.62=1.8in.

Find the centroid (x2) as shown below:

(x2)=0.52=0.25in.

Find the centroid (x3) as shown below:

(x3)=1.32=0.65in.

Find the centroid (y1) as shown below:

(y1)=0.52=0.25in.

Find the centroid (y2) as shown below:

(y2)=0.5+1.9=2.4in.

Find the centroid (y3) as shown below:

(y3)=1.32=0.65in.

Find the centroid of (x¯) using the relation as shown below:

x¯=A1x1+A2x2+A3x3A1+A2+A3 (6)

Substitute 18in2 for A1, 1.9in2 for A2, 1.3in2 for A1, 1.8in. for x1, 0.25in. for x2, and 0.65in. for x3 in Equation (6).

x¯=(1.8×1.8)+(1.9×0.25)+(1.3×0.65)1.8+1.9+1.3=4.565=0.912in.

Find the centroid of (y¯) using the relation as shown below:

y¯=A1y1+A2y2+A3y3A1+A2+A3 (7)

Substitute 18in2 for A1, 1.9in2 for A2, 1.3in2 for A1, 0.25in. for y1, 2.4in. for y2, and 4.8in. for y3 in Equation (7).

y¯=(1.8×0.25)+(1.9×2.4)+(1.3×4.8)1.8+1.9+1.3=11.255=2.25in.

Find the moment of inertia (Ix)1 about x axis using the relation as shown below:

(Ix)1=112b1h13+(b1h1)(h¯)2(Ix)1=112b1h13+(b1h1)(y¯y1)2 (8)

Here, h¯ is vertical distance from the centroid of the segment to the neutral axis.

Substitute 3.6in. for b1,2.25in. for y¯, 0.25in. for y1 and 0.5in. for h1 in Equation (8).

(Ix)1=112(3.6)(0.5)3+(3.6×0.5)(2.250.25)2=0.0375+7.2=7.2375in4

Find the moment of inertia (Ix)2 about x axis using the relation as shown below:

(Ix)2=112b2h23+(b2h2)(h¯)2(Ix)2=112b2h23+(b2h2)(y¯y2)2 (9)

Here, h¯ is vertical distance from the centroid of the segment to the neutral axis.

Substitute 0.5in. for b2,2.25in. for y¯, 2.4in. for y2 and 3.8in. for h2 in Equation (9).

(Ix)2=112(0.5)(3.8)3+(1.9)(2.252.4)2=2.28633+0.04275=2.329in4

Find the moment of inertia (Ix)3 about x axis using the relation as shown below:

(Ix)3=112b3h33+(b3h3)(h¯)2(Ix)3=112b3h33+(b3h3)(y¯y3)2 (10)

Here, h¯ is vertical distance from the centroid of the segment to the neutral axis.

Substitute 1.3in. for b3,2.25in. for y¯, 4.8in. for y3 and 1in. for h3 in Equation (10).

(Ix)3=112(1.3)(1)3+(1.3)(4.82.25)2=0.10833+8.45325=8.5616in4

Find the total moment of inertia (I¯x) about x axis as shown below:

I¯x=(Ix)1+(Ix)2+(Ix)3 (11)

Substitute 7.2375in4 for (Ix)1, 2.329in4 for (Ix)2, and 8.5616in4 for (Ix)3 in Equation (11).

I¯x=7.2375+2.329+8.5616=18.128in4

Find the moment of inertia (Iy)1 about y axis using the relation as shown below:

(Iy)1=112b13h1+(b1h1)(x¯x1)2 (12)

Substitute 3.6in. for b1,0.912in. for x¯, 0.25in. for x1 and 0.5in. for h1 in Equation (12).

(Iy)1=112(3.6)3(0.5)+(3.6×0.5)(1.80.912)2=1.944+1.419=3.363in4

Find the moment of inertia (Iy)2 about y axis using the relation as shown below:

(Iy)2=112b23h3+(b2h2)(x¯x2)2 (13)

Substitute 0.5in. for b2,0.912in. for x¯, 0.25in. for x2 and 3.8in. for h2 in Equation (13).

(Iy)2=112(0.5)3(3.8)+(1.9)(0.9120.25)2=0.03958+0.83266=0.8723in4

Find the moment of inertia (Iy)3 about y axis using the relation as shown below:

(Iy)3=112b33h3+(b3h3)(x¯x3)2 (14)

Substitute 1.3in. for b3,0.912in. for x¯, 0.65in. for x3 and 1in. for h3 in Equation (14).

(Iy)3=112(1)(1.3)3+(1.3)2(0.9120.65)2=0.1831+0.0892=0.2723in4

Find the total moment of inertia (I¯y) about y axis as shown below:

I¯y=(Iy)1+(Iy)2+(Iy)3 (15)

Substitute 3.3634in4 for (Iy)1, 0.8723in4 for (Iy)2, and 0.2723in4 for (Iy)3 in Equation (15).

I¯y=(3.3634+0.8723+0.2723)=4.5080in4

Refer to problem 9.77.

The product of inertia (I¯xy) about xy axis is 4.25320in4

Consider the point X with co-ordinates (Ix,Ixy) and point Y with co-ordinates (Iy,Ixy).

The diameter of the Mohr circle is defined by XY distance. It is expressed as follows:

X(18.1282,4.25320) and Y(4.5080,4.25320).

Consider that the average moment of inertia (Iave) is represents the distance from origin O to the center of the circle C.

Find the average moment of inertia (I¯ave) using the relation as shown below:

I¯ave=12(I¯x+I¯y) (16)

Here, I¯x is moment of inertia about x axis and I¯y is moment of inertia about y axis.

Substitute 18.128in4 for I¯x and 4.5080in4 for I¯y in Equation (16).

Iave=12(18.1282+4.5080)=12(22.6362)=11.3181in4

Find the radius (R) using the relation as shown below:

R=(I¯xI¯y2)2+I¯xy2 (17)

Here, R is radius and I¯xy is product of inertia.

Substitute 18.128in4 for I¯x, 4.25320in4 for I¯xy,  and 4.5080in4 for I¯y in Equation (17).

R=(12(18.12824.5080))2+(4.25320)2=46.37774+18.0897=8.02915in4

Draw the Mohr circle using the procedure as follows:

  • Plot the point X with coordinate (18.1282,4.25320) and plot the point Y with co-ordinate (4.5080,4.25320).
  • Joint the points X and Y with straight line, which is defined as center of the circle (C).
  • Plot the circle using the center point and diameter (XY).
  • Obtain the line XY by rotating the angle 2θm and also obtain by joining the points X and Y.

Sketch the Mohr circle as shown in Figure 2.

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 9.4, Problem 9.102P , additional homework tip  2

Refer to Figure 2.

tan2θm=2IxyIxIy (18)

Substitute 18.128in4 for I¯x, 4.25320in4 for I¯xy,  and 4.5080in4 for I¯y in Equation (18).

tan2θm=2(4.25320)18.12824.5080=8.506413.6202tan2θm=0.624542θm=tan1(0.62454)2θm=31.986°θm=15.99°

Thus, the orientation of the principal axes at the origin is 15.99°counterclockwise_.

Sketch the orientation of the principal axes as shown in Figure 3.

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 9.4, Problem 9.102P , additional homework tip  3

Find the maximum moment Imax of inertia using the relation:

Imax=Iave+R (19)

Substitute 11.3181in4 for Iave and 8.02915in4 for R in Equation (19).

Imax=11.3181+8.02915=19.35in4

Thus, the maximum moment of inertia is 19.35in4_.

Find the minimum moment Imin of inertia using the relation:

Imin=IaveR (20)

Substitute 11.3181in4 for Iave and 8.02915in4 for R in Equation (20).

Imin=11.31818.02915=3.29in4

Thus, the minimum moment of inertia is 3.29in4_

From the Mohr’s circle, the axis ‘a’ represents I¯min and the axis ‘b’ represents to I¯max.

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Chapter 9 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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