VECTOR MECH. FOR EGR: STATS & DYNAM (LL
VECTOR MECH. FOR EGR: STATS & DYNAM (LL
12th Edition
ISBN: 9781260663778
Author: BEER
Publisher: MCG
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Chapter 9.1, Problem 9.24P

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

Fig. P9.24

Expert Solution & Answer
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To determine

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

Answer to Problem 9.24P

The polar moment of inertia of the shaded area with respect to point P is 1.155r4_

The polar radius of gyration of the shaded area with respect to point P is 0.676r_

Explanation of Solution

Calculation:

Sketch the horizontal strip along circular portion as shown in Figure 1.

VECTOR MECH. FOR EGR: STATS & DYNAM (LL, Chapter 9.1, Problem 9.24P

Write the curve equation of circle as follows:

x2+y2=r2 (1)

Modify Equation (1).

x2+y2=r2x2=r2y2x=r2y2

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

dA=xdy (2)

Substitute r2y2 for x in Equation (2).

dA=(r2y2)dy

Find the shaded area (A) using the relation:

A=dA (3)

Substitute (r2y2)dy for dA and apply the limits in Equation (3).

A=(r2y2)dy=2r2rr2y2dy (4)

Consider y=rsinθ

Differentiate both sides of the Equation.

dy=rcosθdθ

Substitute rsinθ for y and rcosθdθ for dy and apply the limits in Equation (4).

A=2π6π2r2(rsinθ)2rcosθdθ=2π6π2r2cos2θdθ=2r2[θ2+sin2θ4]π6π2=2r2[π22+sin2(π2)4(π62)+sin2(π6)4]

A=2r2[π22(π62)+sin2(π6)4]=2r2(π3+38)=2.5274r2

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

dIx=y2dA

Substitute (r2y2)dy for dA.

dIx=y2((r2y2)dy) (5)

Integrate Equation (5) with respect to y.

Ix=dIx=2r2ry2((r2y2)dy) (6)

Consider y=rsinθ

Differentiate both sides of the Equation.

dy=rcosθdθ

Substitute rsinθ for y and rcosθdθ for dy and apply the limits in Equation (6).

Ix=2π6π2rsinθ2((r2(rsinθ)2)(rcosθdθ))=2π6π2r2sin2θ(rcosθ)rcosθdθ=2π6π2r4sin2θcos2θdθ=2π6π2r4(14sin22θ)dθ

Ix=r42[θ2sin4θ8]π6π2=r42[π22sin4(π2)8(π62sin4(π6)8)]=r42[π22(π62sin(2π3)8)]=r42(π3316)

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

dIy=13x3dy (7)

Substitute r2y2 for x in Equation (7).

dIy=13(r2y2)3dy (8)

Integrate Equation (8) with respect to y.

Iy=dIy=r2r13(r2y2)3dy (9)

Consider y=rsinθ

Differentiate both sides of the Equation.

dy=rcosθdθ

Substitute rsinθ for y and rcosθdθ for dy and apply the limits in Equation (9).

Iy=r2r13(r2(rsinθ)2)3rcosθdθ=23π6π2[r2(rsinθ)2]32rcosθdθ=23π6π2[r3cos3θ]rcosθdθ=23π6π2r4cos4θdθ

=23π6π2r4cos2θ(1sin2θ)dθ=23π6π2r4(cos2θ14sin22θ)dθ=23r4[(θ2+sin2θ4)14(θ2sin4θ8)]π6π2=23r4[(π22+sin2(π2)4)14((π6)2sin4(π6)8)]

Iy=23r4[π2214(π22)((π6)2+sin(π3)414(π62sin(2π3)8))]=23r4[π4π16+π12+14(32)π48+132(32)]=23r4(π4+9364)

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

(JP)=Ix+Iy (10)

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

Substitute 23r4(π4+9364) for Iy and r42(π3316) for Ix in Equation (10).

(JP)=r42(π3316)+23r4(π4+9364)=r4(π3+316)=r4(1.047+0.10825)=1.1545r4

Thus, the polar moment of inertia of the shaded area with respect to point P is 1.155r4_

Find the polar radius of gyration (kP) of the shaded area with respect to point P as shown below:

(kP2)=JPA (11)

Here, JP is polar moment of inertia.

Substitute 1.1545r4 for JP and 2.5274r2 for A in Equation (11).

(kP2)=1.1545r42.5274r2=0.457r2kP=0.676r

Thus, the polar radius of gyration of the shaded area with respect to point P is 0.676r_.

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Chapter 9 Solutions

VECTOR MECH. FOR EGR: STATS & DYNAM (LL

Ch. 9.1 - Prob. 9.11PCh. 9.1 - Prob. 9.12PCh. 9.1 - 9.12 through 9.14 Determine by direct integration...Ch. 9.1 - 9.12 through 9.14 Determine by direct integration...Ch. 9.1 - Prob. 9.15PCh. 9.1 - Prob. 9.16PCh. 9.1 - Prob. 9.17PCh. 9.1 - Prob. 9.18PCh. 9.1 - Determine the moment of inertia and the radius of...Ch. 9.1 - Prob. 9.20PCh. 9.1 - Determine the polar moment of inertia and the...Ch. 9.1 - Prob. 9.22PCh. 9.1 - Prob. 9.23PCh. 9.1 - 9.23 and 9.24 Determine the polar moment of...Ch. 9.1 - Prob. 9.25PCh. 9.1 - Prob. 9.26PCh. 9.1 - Prob. 9.27PCh. 9.1 - Prob. 9.28PCh. 9.1 - Prob. 9.29PCh. 9.1 - Prove that the centroidal polar moment of inertia...Ch. 9.2 - 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 - Determine the moments of inertia of the shaded...Ch. 9.2 - Determine the moments of inertia of the shaded...Ch. 9.2 - Prob. 9.37PCh. 9.2 - Prob. 9.38PCh. 9.2 - Prob. 9.39PCh. 9.2 - Prob. 9.40PCh. 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 - Prob. 9.43PCh. 9.2 - Prob. 9.44PCh. 9.2 - 9.45 and 9.46 Determine the polar moment of...Ch. 9.2 - Prob. 9.46PCh. 9.2 - 9.47 and 9.48 Determine the polar moment of...Ch. 9.2 - 9.47 and 9.48 Determine the polar moment of...Ch. 9.2 - To form a reinforced box section, two rolled W...Ch. 9.2 - Two channels are welded to a d 12-in. steel plate...Ch. 9.2 - Prob. 9.51PCh. 9.2 - Two 20-mm steel plates are welded to a rolled S...Ch. 9.2 - A channel and a plate are welded together as shown...Ch. 9.2 - Prob. 9.54PCh. 9.2 - Two L76 76 6.4-mm angles are welded to a C250 ...Ch. 9.2 - Prob. 9.56PCh. 9.2 - Prob. 9.57PCh. 9.2 - 9.57 and 9.58 The panel shown forms the end of a...Ch. 9.2 - Prob. 9.59PCh. 9.2 - Prob. 9.60PCh. 9.2 - Prob. 9.61PCh. 9.2 - Prob. 9.62PCh. 9.2 - Prob. 9.63PCh. 9.2 - Prob. 9.64PCh. 9.2 - Prob. 9.65PCh. 9.2 - Prob. 9.66PCh. 9.3 - 9.67 through 9.70 Determine by direct integration...Ch. 9.3 - 9.67 through 9.70 Determine by direct integration...Ch. 9.3 - 9.67 through 9.70 Determine by direct integration...Ch. 9.3 - Prob. 9.70PCh. 9.3 - Prob. 9.71PCh. 9.3 - Prob. 9.72PCh. 9.3 - Prob. 9.73PCh. 9.3 - 9.71 through 9.74 Using the parallel-axis theorem,...Ch. 9.3 - Prob. 9.75PCh. 9.3 - 9.75 through 9.78 Using the parallel-axis theorem,...Ch. 9.3 - Prob. 9.77PCh. 9.3 - Prob. 9.78PCh. 9.3 - Determine for the quarter ellipse of Prob. 9.67...Ch. 9.3 - Determine the moments of inertia and the product...Ch. 9.3 - Determine the moments of inertia and the product...Ch. 9.3 - 9.75 through 9.78 Using the parallel-axis theorem,...Ch. 9.3 - Determine the moments of inertia and the product...Ch. 9.3 - Determine the moments of inertia and the product...Ch. 9.3 - Prob. 9.85PCh. 9.3 - 9.86 through 9.88 For the area indicated,...Ch. 9.3 - Prob. 9.87PCh. 9.3 - Prob. 9.88PCh. 9.3 - Prob. 9.89PCh. 9.3 - 9.89 and 9.90 For the angle cross section...Ch. 9.4 - Using Mohrs circle, determine for the quarter...Ch. 9.4 - Using Mohrs circle, determine the moments of...Ch. 9.4 - Prob. 9.93PCh. 9.4 - Using Mohrs circle, determine the moments of...Ch. 9.4 - Using Mohrs circle, determine the moments of...Ch. 9.4 - Using Mohrs circle, determine the moments of...Ch. 9.4 - For the quarter ellipse of Prob. 9.67, use Mohrs...Ch. 9.4 - 9.98 though 9.102 Using Mohrs circle, determine...Ch. 9.4 - Prob. 9.99PCh. 9.4 - 9.98 though 9.102 Using Mohrs circle, determine...Ch. 9.4 - Prob. 9.101PCh. 9.4 - Prob. 9.102PCh. 9.4 - Prob. 9.103PCh. 9.4 - 9.104 and 9.105 Using Mohrs circle, determine the...Ch. 9.4 - 9.104 and 9.105 Using Mohrs circle, determine the...Ch. 9.4 - For a given area, the moments of inertia with...Ch. 9.4 - it is known that for a given area Iy = 48 106 mm4...Ch. 9.4 - Prob. 9.108PCh. 9.4 - Prob. 9.109PCh. 9.4 - Prob. 9.110PCh. 9.5 - A thin plate with a mass m is cut in the shape of...Ch. 9.5 - A ring with a mass m is cut from a thin uniform...Ch. 9.5 - A thin elliptical plate has a mass m. Determine...Ch. 9.5 - The parabolic spandrel shown was cut from a thin,...Ch. 9.5 - Prob. 9.115PCh. 9.5 - Fig. P9.115 and P9.116 9.116 A piece of thin,...Ch. 9.5 - A thin plate of mass m is cut in the shape of an...Ch. 9.5 - Fig. P9.117 and P9.118 9.118 A thin plate of mass...Ch. 9.5 - Determine by direct integration the mass moment of...Ch. 9.5 - The area shown is revolved about the x axis to...Ch. 9.5 - The area shown is revolved about the x axis to...Ch. 9.5 - Determine by direct integration the mass moment of...Ch. 9.5 - Fig. P9.122 and P9.123 9.123 Determine by direct...Ch. 9.5 - Prob. 9.124PCh. 9.5 - Prob. 9.125PCh. 9.5 - Prob. 9.126PCh. 9.5 - Prob. 9.127PCh. 9.5 - Prob. 9.128PCh. 9.5 - Prob. 9.129PCh. 9.5 - Knowing that the thin cylindrical shell shown has...Ch. 9.5 - A circular hole of radius r is to be drilled...Ch. 9.5 - The cups and the arms of an anemometer are...Ch. 9.5 - Prob. 9.133PCh. 9.5 - Determine the mass moment of inertia of the 0.9-lb...Ch. 9.5 - Prob. 9.135PCh. 9.5 - Prob. 9.136PCh. 9.5 - A 2-mm thick piece of sheet steel is cut and bent...Ch. 9.5 - A section of sheet steel 0.03 in. thick is cut and...Ch. 9.5 - A corner reflector for tracking by radar has two...Ch. 9.5 - A farmer constructs a trough by welding a...Ch. 9.5 - The machine element shown is fabricated from...Ch. 9.5 - Determine the mass moments of inertia and the...Ch. 9.5 - Determine the mass moment of inertia of the steel...Ch. 9.5 - Prob. 9.144PCh. 9.5 - Determine the mass moment of inertia of the steel...Ch. 9.5 - Aluminum wire with a weight per unit length of...Ch. 9.5 - The figure shown is formed of 18-in.-diameter...Ch. 9.5 - A homogeneous wire with a mass per unit length of...Ch. 9.6 - Determine the mass products of inertia Ixy, Iyz,...Ch. 9.6 - Determine the mass products of inertia Ixy, Iyz,...Ch. 9.6 - Determine the mass products of inertia Ixy, Iyz,...Ch. 9.6 - Determine the mass products of inertia Ixy, Iyz,...Ch. 9.6 - 9.153 through 9.156 A section of sheet steel 2 mm...Ch. 9.6 - Prob. 9.154PCh. 9.6 - Prob. 9.155PCh. 9.6 - 9.153 through 9.156 A section of sheet steel 2 mm...Ch. 9.6 - Prob. 9.157PCh. 9.6 - Prob. 9.158PCh. 9.6 - Prob. 9.159PCh. 9.6 - Prob. 9.160PCh. 9.6 - Prob. 9.161PCh. 9.6 - For the homogeneous tetrahedron of mass m shown,...Ch. 9.6 - Prob. 9.163PCh. 9.6 - Prob. 9.164PCh. 9.6 - Prob. 9.165PCh. 9.6 - Determine the mass moment of inertia of the steel...Ch. 9.6 - Prob. 9.167PCh. 9.6 - Prob. 9.168PCh. 9.6 - Prob. 9.169PCh. 9.6 - 9.170 through 9.172 For the wire figure of the...Ch. 9.6 - Prob. 9.171PCh. 9.6 - Prob. 9.172PCh. 9.6 - Prob. 9.173PCh. 9.6 - Prob. 9.174PCh. 9.6 - Prob. 9.175PCh. 9.6 - Prob. 9.176PCh. 9.6 - Prob. 9.177PCh. 9.6 - Prob. 9.178PCh. 9.6 - Prob. 9.179PCh. 9.6 - Prob. 9.180PCh. 9.6 - Prob. 9.181PCh. 9.6 - Prob. 9.182PCh. 9.6 - Prob. 9.183PCh. 9.6 - Prob. 9.184PCh. 9 - Determine by direct integration the moments of...Ch. 9 - Determine the moment of inertia and the radius of...Ch. 9 - Prob. 9.187RPCh. 9 - Prob. 9.188RPCh. 9 - Prob. 9.189RPCh. 9 - Two L4 4 12-in. angles are welded to a steel...Ch. 9 - Prob. 9.191RPCh. 9 - Prob. 9.192RPCh. 9 - Prob. 9.193RPCh. 9 - Prob. 9.194RPCh. 9 - Prob. 9.195RPCh. 9 - Determine the mass moment of inertia of the steel...
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