VECTOR MECHANICS FOR ENGINEERS: STATICS
VECTOR MECHANICS FOR ENGINEERS: STATICS
12th Edition
ISBN: 9781260536225
Author: BEER
Publisher: MCG
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Chapter 9.1, Problem 9.23P

9.23 and 9.24 Determine the polar moment of inertia and the polar radius of gyration of the shaded area shown with respect to point P.

Chapter 9.1, Problem 9.23P, 9.23 and 9.24 Determine the polar moment of inertia and the polar radius of gyration of the shaded

Fig. P9.23

Expert Solution & Answer
Check Mark
To determine

Find the polar moment of inertia and polar radius of gyration of the shaded area shown with respect to point P.

Answer to Problem 9.23P

The polar moment of inertia of the shaded area shown with respect to point P is 6415a4_.

The polar radius of gyration of the shaded area shown with respect to point P is 1.265a_.

Explanation of Solution

Given information:

The equation of the curve is y2=c+k2x2

The equation of the curve is y1=k1x2

Calculation:

Sketch the vertical strip shaded portion as shown in Figure 1.

VECTOR MECHANICS FOR ENGINEERS: STATICS, Chapter 9.1, Problem 9.23P

Write the curve (y1) Equation as follows:

y1=k1x2 (1)

Write the curve (y1) Equation as follows:

y2=c+k2x2 (2)

Refer to Figure 1.

At y1

For x=2a, y1=2a.

Find the constant (k1) using the relation:

Substitute 2a for y1 and 2a for x in Equation (1).

2a=k1(2a)2k1=2a(2a)2k1=12a

Substitute 0 for x and a for y in Equation (2).

a=c+k2(0)2a=c+0a=c

Refer to Figure 1.

At y2

For x=2a, y=2a.

Find the constant (k2) using the relation:

Substitute 2a for y2, a for c, and 2a for x in Equation (2).

2a=a+k2(2a)2k2=2a4a2k2=14a

Substitute 12a for k1 in Equation (1).

y1=(12a)x2

Substitute 14a for k2 and a for c in Equation (2).

y2=a+(14a)x2=a+14ax2

Determine the area of the strip element dA as shown in below:

dA=(y2y1)dx (3)

Substitute a+14ax2 for y2 and (12a)x2 for y1 in Equation (3).

dA=(a+14ax2(12a)x2)dx=(14a(4a2+x2)(12a)x2)dx=14a(4a2x2)dx

Find the shaded area (A) using the relation:

A=dA (4)

Substitute 14a(4a2x2)dx for dA in Equation (4).

A=14a(4a2x2)dx=202a14a(4a2x2)dx=12a[4a2xx33]02a=12a[4a2(2a)(2a)33]

A=12a[8a38a33]=12a[16a33]=83a2

Determine the moment of inertia (dIx) with respect to x axis:

Refer Equation 9.2 in section 9.1B determining the moment of inertia of an area by integration:

dIx=13y3dx=(13y2313y13)dx (5)

Substitute a+14ax2 for y2 and (12a)x2 for y1 in Equation (5).

dIx=(13(a+14ax2)313((12a)x2)3)dx=13([14a(4a2+x3)3]3[12ax2]2)dx=13(164a3(64a6+48a4x2+12a2x4+x6)18a3x6)dx=1192a3(64a6+48a4x2+12a2x47x6)dx (6)

Integrate Equation (6) with respect to x.

Ix=dIxIx=1192a3(64a6+48a4x2+12a2x47x6)dx=202a1192a3(64a6+48a4x2+12a2x47x6)dx=196a3[64a6x+48a4x33+12a2x557x77]02a

Ix=196a3[64a6x+16a4x3+125a2x5x7]02a=196a3[64a6(2a)+16a4(2a)3+125a2(2a)5(2a)7]=196a4[128+128+125×32128]=3215a4

Determine the moment of inertia (dIy) with respect to y axis:

(dIy)=x2dA=x2[14a(4a2x2)dx] (7)

Integrate Equation (7) with respect to x.

Iy=dIy=20214ax2(4a2x2)dx=12a[43a2x315x5]02a=12a[43a2(2a)315(2a)5]

=12a[43a2(8a3)15(32a5)]=12a[32a5332a55]=12a[a5(323325)]=12a[a5(1609615)]

=12a[a5(6415)]Iy=32a464

Find the polar moment of inertia (JP) of the shaded area shown with respect to point P.

(JP)=Ix+Iy (8)

Here, Ix is moment of inertia about x axis and Iy is moment of inertia about y axis.

Substitute 32a464 for Iy and 3215a4 for Ix in Equation (8).

(JP)=3215a4+32a464=6415a4

Thus, the polar moment of inertia of the shaded area shown with respect to point P is 6415a4_.

Find the polar radius of gyration of the shaded area shown with respect to point P.

(kP2)=JPA (9)

Here, JP is polar moment of inertia.

Substitute 6415a4 for JP and 83a2 for A in Equation (9).

(kP2)=6415a483a2=6415a4×38a2=85a2kp=1.265a

Thus, the polar radius of gyration of the shaded area shown with respect to point P is 1.265a_.

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Chapter 9 Solutions

VECTOR MECHANICS FOR ENGINEERS: STATICS

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9.31 and 9.32 Determine the moment of inertia and...Ch. 9.2 - 9.31 and 9.32 Determine the moment of inertia and...Ch. 9.2 - 9.33 and 9.34 Determine the moment of inertia and...Ch. 9.2 - 9.33 and 9.34 Determine the moment of inertia and...Ch. 9.2 - Prob. 9.35PCh. 9.2 - Determine the moments of inertia of the shaded...Ch. 9.2 - Prob. 9.37PCh. 9.2 - Fig. P9.37 and P9.38 9.38 Knowing that the shaded...Ch. 9.2 - Prob. 9.39PCh. 9.2 - Fig. P9.39 and P9.40 9.40 The polar moments of...Ch. 9.2 - Prob. 9.41PCh. 9.2 - 9.41 through 9.44 Determine the moments of inertia...Ch. 9.2 - 9.41 through 9.44 Determine the moments of inertia...Ch. 9.2 - 9.41 through 9.44 Determine the moments of inertia...Ch. 9.2 - 9.45 and 9.46 Determine the polar moment of...Ch. 9.2 - 9.45 and 9.46 Determine the polar moment of...Ch. 9.2 - Prob. 9.47PCh. 9.2 - Prob. 9.48PCh. 9.2 - Prob. 9.49PCh. 9.2 - Prob. 9.50PCh. 9.2 - Four L3 3 14 - in. angles are welded to a rolled...Ch. 9.2 - Two 20-mm steel plates are welded to a rolled S...Ch. 9.2 - 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(9.47) that...Ch. 9.6 - Prob. 9.162PCh. 9.6 - Prob. 9.163PCh. 9.6 - Prob. 9.164PCh. 9.6 - Shown is the machine element of Prob. 9.141....Ch. 9.6 - Determine the mass moment of inertia of the steel...Ch. 9.6 - The thin, bent plate shown is of uniform density...Ch. 9.6 - A piece of sheet steel with thickness t and...Ch. 9.6 - Determine the mass moment of inertia of the...Ch. 9.6 - 9.170 through 9.172 For the wire figure of the...Ch. 9.6 - Prob. 9.171PCh. 9.6 - 9.172 Prob. 9.146 9.146 Aluminum wire with a...Ch. 9.6 - For the homogeneous circular cylinder shown with...Ch. 9.6 - For the rectangular prism shown, determine the...Ch. 9.6 - Prob. 9.175PCh. 9.6 - Prob. 9.176PCh. 9.6 - Consider a cube with mass m and side a. (a) Show...Ch. 9.6 - Prob. 9.178PCh. 9.6 - Prob. 9.179PCh. 9.6 - 9.180 through 9.184 For the component described in...Ch. 9.6 - 9.180 through 9.184 For the component described in...Ch. 9.6 - Prob. 9.182PCh. 9.6 - 9.180 through 9.184 For the component described in...Ch. 9.6 - 9.180 through 9.184 For the component described in...Ch. 9 - Determine by direct integration the moments of...Ch. 9 - Determine the moment of inertia and the radius of...Ch. 9 - Determine the moment of inertia and the radius of...Ch. 9 - Determine the moments of inertia Ix and Iy of the...Ch. 9 - Determine the polar moment of inertia of the area...Ch. 9 - Two L4 4 12-in. angles are welded to a steel...Ch. 9 - Using the parallel-axis theorem, determine the...Ch. 9 - Prob. 9.192RPCh. 9 - Fig. P9.193 and P9.194 9.193 A thin plate with a...Ch. 9 - Fig. P9.193 and P9.194 9.194 A thin plate with...Ch. 9 - A 2-mm-thick piece of sheet steel is cut and bent...Ch. 9 - Determine the mass moment of inertia of the steel...
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