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 9.5, Problem 9.137P

A 2-mm thick piece of sheet steel is cut and bent into the machine component shown. Knowing that the density of steel is 7850 kg/m3, determine the mass moment of inertia of the component with respect to each of the coordinate axes.

Chapter 9.5, Problem 9.137P, A 2-mm thick piece of sheet steel is cut and bent into the machine component shown. Knowing that the

Fig. P9.137

Expert Solution & Answer
Check Mark
To determine

Find the mass moment of inertia with respect to x,y,z coordinate axes.

Answer to Problem 9.137P

The mass moment of inertia with respect to x coordinate axes is 5.14×103kgm2_.

The mass moment of inertia with respect to y coordinate axes is 7.54×103kgm2_.

The mass moment of inertia with respect to z coordinate axes is 3.47×103kgm2_.

Explanation of Solution

Given information:

The thickness (t) of sheet steel is 2mm.

The density ρ of steel is 7,850kg/m3.

Calculation:

Divided the section into three geometric portions as shown below:

  • Upper Flange
  • Lower Flange
  • Horizontal base

Find the mass of the upper flange component using the relation as shown below:

m=ρV=ρtA (1)

Here, V is volume of component of upper flange and A is the area of the section.

Find the area A of upper flange as shown below:

A=bh (2)

Here, b is the width of section and h is the height of section.

Substitute 80mm for b and 100mm for h in Equation (2).

A=80×100=8,000mm2(1m103mm)2=0.008m2

Substitute 2mm for t, 7,850kg/m3 for ρ, and 0.008m2 for A in Equation (1).

m=7,850×0.008×2mm(1m103mm)=7,850×0.008×0.002=0.1256kg

Find the mass of the lower flange component using the relation as shown below:

m=ρV=ρtA (3)

Here, V is volume of component of lower flange.

Find the area A of lower flange as shown below:

A=bh (4)

Here, b is the width of section and h is the height of section.

Substitute 80mm for b and 100mm for h in Equation (4).

A=80×100=8,000mm2(1m103mm)2=0.008m2

Substitute 2mm for t, 7,850kg/m3 for ρ, and 0.008m2 for A in Equation (3).

m=7,850×0.008×2mm(1m103mm)=7,850×0.008×0.002=0.1256kg

Find the moment of inertia about x axis of upper lower flange section as shown below:

Ix=Ix+md2=112×md2+m[b2+h2] (5)

Substitute 0.1256kg for m, 0.1m for b, 0.08m for d, and 0.04m for h in Equation (5).

Ix=112×0.12560×0.082+0.12560[0.12+0.042]=6.6986×105+0.001456=1.52395×103kgm2

Find the moment of inertia about y axis of upper lower flange section as shown below:

Iy=Iy+md2=112×md2+m[b2+h2] (6)

Substitute 0.1256kg for m, 0.1m for d, 0.05m for b , and 0.1m for h in Equation (6).

Iy=112×0.12560×0.12+0.12560[0.052+0.12]=1.04666×104+0.00157=1.67466×103kgm2

Find the moment of inertia about z axis of upper lower flange section as shown below:

Iz=Iz+md2=112×m[b2+h2]+m[b12+h12] (7)

Substitute 0.1256kg for m, 100mm for b, 80mm for h , 40mm for h1, and 50mm for b1 in Equation (7).

Iz=[112×0.12560×[100mm(1m103mm)+80mm(1m103mm)]+0.12560[50mm(1m103mm)+40mm(1m103mm)]]=112×0.12560×[0.12+0.082]+0.12560[0.052+0.042]=1.716533×104+5.1496×104=0.68661×103kgm2

Find the mass of the horizontal base using the relation as shown below:

m=ρV=ρtA (8)

Find the area A of horizontal base as shown below:

A=bh (9)

Here, b is the width of section and h is the height of section.

Substitute 200mm for b and 200mm for h in Equation (9).

A=200×200=40,000mm2(1m103mm)2=0.04m2

Substitute 2mm for t, 7,850kg/m3 for ρ, and 0.04m2 for A in Equation (8).

m=7,850×0.008×2mm(1m103mm)=7,850×0.04×0.002=0.628kg

Find the moment of inertia about x axis of horizontal base as shown in below:

Ix=112ma2 (10)

Substitute 0.6280kg for m and 200mm for a in Equation (10).

Ix=112×0.1256×200mm(1m103mm)=112×0.1256×0.2=2.0933×103kgm2

Find the moment of inertia about y axis of horizontal base as shown in below:

Iy=112m(a2+b2) (11)

Substitute 0.6280kg for m, 200mm for a, and 200mm for b, in Equation (11).

Iy=112×0.6280×[200mm(1m103mm)2+×200mm(1m103mm)2]=112×0.1256×[0.22+0.22]=4.1867×103kgm2

Find the moment of inertia about z axis of horizontal base as shown in below:

Iz=112mb2 (12)

Substitute 0.6280kg for m and 200mm for b in Equation (12).

Iz=112×0.1256×200mm(1m103mm)=112×0.1256×0.2=2.0933×103kgm2

Find the total moment of inertia Ix of composite shape as shown below:

Ix=2(Ix)flange+(Ix)base (13)

Here, (Ix)flange is moment of inertia of flange section about x axis and (Ix)base is moment of inertia of base section x axis.

Substitute 1.52395×103kgm2 for (Ix)flange and 2.0933×103kgm2 for (Ix)base in Equation (13).

Ix=2(1.52395×103)+2.0933×103=3.0479×103+2.0933×103=5.14×103

Thus, the mass moment of inertia with respect to x coordinate axes is 5.14×103kgm2_.

Find the total moment of inertia Iy of composite shape as shown below:

Iy=2(Iy)flange+(Iy)base (14)

Here, (Ix)flange is moment of inertia of flange section about y axis and (Ix)base is moment of inertia of base about y axis section.

Substitute 1.67467×103kgm2 for (Ix)flange and 4.1867×103kgm2 for (Ix)base in Equation (14).

Iy=2(1.67467×103)+(4.1867×103)=3.34934×103+4.1867×103=7.536×103kgm2

Thus, the mass moment of inertia with respect to y coordinate axes is 7.54×103kgm2_.

Find the total moment of inertia Iz of composite shape as shown below:

Iz=2(Iz)flange+(Iz)base (15)

Here, (Iz)flange is moment of inertia of flange section about z axis and (Iz)base is moment of inertia of base about z axis section.

Substitute 0.68661×103kgm2 for (Ix)flange and 2.0933×103kgm2 for (Ix)base in Equation (15).

Iy=2(0.68661×103)+(2.0933×103)=1.373×103+2.0933×103=3.466×103kgm2

Thus, the mass moment of inertia with respect to z coordinate axes is 3.47×103kgm2_.

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Chapter 9 Solutions

VECTOR MECH. FOR EGR: STATS & DYNAM (LL

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