Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics
Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics
12th Edition
ISBN: 9781259977206
Author: BEER, Ferdinand P., Johnston Jr., E. Russell, Mazurek, David, Cornwell, Phillip J., SELF, Brian
Publisher: McGraw-Hill Education
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Chapter 9.2, Problem 9.41P

9.41 through 9.44 Determine the moments of inertia I x ¯ and I y ¯ of the area shown with respect to centroidal axes respectively parallel and perpendicular to side AB.

Chapter 9.2, Problem 9.41P, 9.41 through 9.44 Determine the moments of inertia Ix and Iy of the area shown with respect to

Fig. P9.41

Expert Solution & Answer
Check Mark
To determine

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

Answer to Problem 9.41P

The moment of inertia about x axis is 46.8×106mm4_.

The moment of inertia about y axis is 13.89×106mm4_.

Explanation of Solution

Given information:

The width (b1) of flange is 120mm.

The height (h1) of flange is 30mm.

The width (b2) of web is 120mm.

The height (h2) of web is 40mm.

Calculation:

Sketch the cross section as shown in Figure 1.

Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 9.2, Problem 9.41P

Refer to Figure 1.

Here, area of flange 1 is equal to area of flange 3.

Find the Area (A1) of flange using the relation:

A1=2(b1h1) (1)

Substitute 120mm for (b1), 30mm  for h1 in Equation (1).

A1=2(120×30)=7,200mm2

Find the Area (A2) of flange using the relation:

A2=2(b2h2) (2)

Substitute 40mm for (b2), 120mm  for h2 in Equation (2).

A2=(40×120)=4,800mm2

Find the total area (A) of section using the relation:

A=A1+A2 (3)

Substitute 7,200mm2 for A1 and 4,800mm2 for A2 in Equation (3).

A=7,200+4,800=12,000mm2

Find the centroid section (x1) as shown below:

x1=1202=60mm

Find the centroid section (x2) as shown below:

x2=402=20mm

Find the centroid (x¯) using the relation:

x¯=2(A1x1)+A2x2A1+A2 (4)

Substitute 7,200mm2 for A1, 4,800mm2 for A2, 60mm for x1, 20mm for x2 in Equation (4).

x¯=(7,200×60)+(4,800×20)7,200+4,800=432,000+96,00012,000=44mm

Find the moment of inertia (Ix)F of flange section using the relation:

(Ix)F=112b1h13+(A1)(h¯)2 (5)

Here, A1 is area of individual section and h¯ is the vertical distance from the centroid of the segment to the neutral axis.

Substitute 120mm for (b1), 30mm  for h1, 3,600mm2 for A1, (9015)mm for h¯ in Equation (5).

(Ix)F=112(120)(303)+(3,600)(9015)2=270,000+20,250,000=20,520,000=20.520×106mm4

Find the moment of inertia (Ix)W of web section using the relation:

(Ix)W=112(b2h23) (6)

Substitute 40mm for (b2) and 120mm  for h2, in Equation (6).

(Ix)W=112(40)(120)3=5,760,000=5.760×106mm4

Find the total moment of inertia (I¯x) using the relation as follows:

(I¯x)=(Ix)W+(Ix)F (7)

Substitute 20.520×106mm4 for (Ix)F and 5.760×106mm4 for (Ix)W in Equation (7).

(I¯x)=20.520×106+5.760×106+20.520×106=46,800,00=46.8×106mm4

Thus, the moment of inertia about x axis is 46.8×106mm4_.

Find the moment of inertia (Iy)F of about y axis using the relation:

(Iy)F=112b13h1+(A1)(h¯)2 (8)

Substitute 120mm for (b1), 30mm  for h1, 3,600mm2 for A1, (16)mm for h¯ in Equation (8).

(Iy)F=[2×112(120)3(30)+(3,600)(16)2]=2×(4,320,000+921,600)=10,483,200=10.483×106mm4

Find the moment of inertia (Iy)W of about y axis using the relation:

(Iy)W=112b13h1+(A1)(h¯)2 (9)

Substitute 40mm for (b1), 120mm  for h1, 4,800mm2 for A2, (24)mm for h¯ in Equation (9).

(Iy)W=[112(40)3(120)+(4,800)(24)2]=(640,000+2,764,800)=3,404,800mm4

Find the total moment of inertia (I¯y) of about y axis using the relation:

(I¯y)=(Iy)F+(Iy)w (10)

Substitute 3,404,800mm4 for (Iy)w and 10.483×106mm4 for (I¯y) in Equation (10).

(I¯y)=3,404,800+10.483×106=13.89×106mm4

Thus, the moment of inertia about y axis is 13.89×106mm4_.

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Chapter 9 Solutions

Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics

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