VECTOR MECHANICS FOR ENGINEERS: STATICS
VECTOR MECHANICS FOR ENGINEERS: STATICS
12th Edition
ISBN: 9781259977121
Author: BEER
Publisher: MCG
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Chapter 9.2, Problem 9.41P
To determine

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

Expert Solution & Answer
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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.

VECTOR MECHANICS FOR ENGINEERS: STATICS, 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

VECTOR MECHANICS FOR ENGINEERS: STATICS

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