University of Florida/Egm3520/s13.team1.r5

Team 1: Report 5

R5.1: Problem 4.7[edit | edit source]

Figure P4.7. — Contents taken from Page 238 in the *Mechanics of Materials: 6th Edition* textbook. Authors: **F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK** ISBN:9780077565664.

Contents taken from Page 238 in the Mechanics of Materials: 6th Edition textbook. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

Two W4 x 13 rolled sections are welded together as shown. Knowing that for the steel alloy used, $\sigma _{\gamma }=36ksi$ and $\sigma _{\upsilon }=58ksi$ and using a factor of safety of 3.0, determine the largest couple that can be applied when the assembly is bent about the z axis.

Honor Pledge: On my honor, I have neither given nor received unauthorized aid in doing this assignment.

R5.1 Solution[edit | edit source]

**Appendix C:Page A18**
Term	Desig	Value
Area	A	3.83 in²
Depth	d	4.16 in
Width	w	4.06 in
Moment of Inertia_x	I_x	11.3 in⁴
Moment of Inertia_y	I_y	3.86 in⁴

**Problem Given**
Yield Strength	$\sigma _{\gamma }=36ksi$
Ultimate Stress	$\sigma _{\upsilon }=58ksi$
Factor of Safety	3

Determine Allowable Stress: $\sigma _{all}={\frac {\sigma _{\upsilon }}{F.S.}}={\frac {58ksi}{3}}=19.33ksi$

Use Parallel Axis Theorem to determine the Polar Moment of Inertia: ${\color {blue}I_{z}=\left[I_{x}+A\left({\frac {d}{2}}\right)^{2}\right]+\left[I_{x}+A\left({\frac {d}{2}}\right)^{2}\right]}\implies {\color {blue}2\left[I_{x}+A\left({\frac {d}{2}}\right)^{2}\right]}$

\implies 2\left[11.3in^{4}+\left(3.83in^{2}\right)\left(2.08in\right)^{2}\right]=55.74in^{4}

Determine the Couple Moment: ${\color {blue}\sigma _{all}={\frac {Mc}{I}}}\implies {\color {blue}M={\frac {\left(\sigma _{all}\right)\left(I\right)}{c}}}$

\implies M={\frac {\left(19.33ksi\right)\left(55.74in^{4}\right)}{4.16in}}={\color {red}259kip*in}

R5.2: Problem 4.8[edit | edit source]

Egm 3520.s13.team1.wcs (discuss • contribs) 07:27, 27 March 2013 (UTC)

Figure P4.8. — Contents taken from Page 238 in the *Mechanics of Materials: 6th Edition* textbook. Authors: **F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK** ISBN:9780077565664.

Contents taken from Page 238 in the Mechanics of Materials: 6th Edition textbook. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

Two W4 x 13 rolled sections are welded together as shown. Knowing that for the steel alloy used, $\sigma _{\gamma }=36ksi$ and $\sigma _{\upsilon }=58ksi$ and using a factor of safety of 3.0, determine the largest couple that can be applied when the assembly is bent about the z axis.

Honor Pledge: On my honor, I have neither given nor received unauthorized aid in doing this assignment.

R5.2 Solution[edit | edit source]

**Appendix C:Page A18**
Term	Desig	Value
Area	A	3.83 in²
Depth	d	4.16 in
Width	w	4.06 in
Moment of Inertia_x	I_x	11.3 in⁴
Moment of Inertia_y	I_y	3.86 in⁴

**Problem Given**
Yield Strength	$\sigma _{\gamma }=36ksi$
Ultimate Stress	$\sigma _{\upsilon }=58ksi$
Factor of Safety	3

Determine Allowable Stress: $\sigma _{all}={\frac {\sigma _{\upsilon }}{F.S.}}={\frac {58ksi}{3}}=19.33ksi$

Use Parallel Axis Theorem to determine the Polar Moment of Inertia: ${\color {blue}I_{z}=\left[I_{x}+A\left({\frac {d}{2}}\right)^{2}\right]+\left[I_{x}+A\left({\frac {d}{2}}\right)^{2}\right]}\implies {\color {blue}2\left[I_{x}+A\left({\frac {d}{2}}\right)^{2}\right]}$

\implies 2\left[3.86in^{4}+\left(3.83in^{2}\right)\left(2.03in\right)^{2}\right]=39.29in^{4}

Determine the Couple Moment: ${\color {blue}\sigma _{all}={\frac {Mc}{I}}}\implies {\color {blue}M={\frac {\left(\sigma _{all}\right)\left(I\right)}{c}}}$

\implies M={\frac {\left(19.33ksi\right)\left(39.29in^{4}\right)}{4.06in}}={\color {red}187.1kip*in}

R5.3: Problem 4.13[edit | edit source]

Figure P4.13. — Contents taken from Page 238 in the *Mechanics of Materials: 6th Edition* textbook. Authors: **F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK** ISBN:9780077565664.

Contents taken from Page 238 in the Mechanics of Materials: 6th Edition textbook. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

Knowing that a beam of the cross section shown is bent about a horizontal axis and that the bending moment is 6 kN*m, determine the total force acting on the shaded portion of the web.

Honor Pledge: On my honor, I have neither given nor received unauthorized aid in doing this assignment.

R5.3 Solution[edit | edit source]

The first step of the problem is to split the shaded portions into two separate portions.

Calculate each moment of inertia about the horizontal axis at the centroid.

For section A the moment of inertia is :

I_{XA}={\frac {1}{12}}bh^{3}+Ad^{2}

I_{XA}={\frac {1}{12}}*216*36^{3}+(216*36)*36^{2}

I_{XA}=10.9*10^{6}mm^{4}=10.9*10^{-6}m^{4}

For section B the moment of inertia is :

I_{XB}={\frac {1}{12}}bh^{3}+Ad^{2}

I_{XB}={\frac {1}{12}}*76*90^{3}+(72*90)*36^{2}

I_{XB}=17.5*10^{6}mm^{4}=17.5*10^{-6}m^{4}

Next add both moments of inertia to calculate the total moment of inertia

I_{XTotal}=I_{XA}+I_{XB}

I_{XTotal}=28.4*10^{-6}m^{4}

Next we need to calculate the stress using the pure bending equation

$\sigma ={\frac {My}{I_{XTotal}}}={\frac {6*10^{3}y}{28.4*10^{-6}}}=0.211*10^{9}y$

The final step is to calculate the force on the beam's cross section. We know that force is equal to stress on an area.

$F=\int _{y_{1}}^{y_{2}}\sigma bdy$

Now input the values for the cross section of the beam into the equation

$y_{1}=0,y_{2}=0.09m,b=0.072$

$F=\int _{0}^{0.09}0.211*10^{9}*0.072*y*dy$

$F=7.59*10^{6}(0.09^{2}-0)=61.5kN$

R5.4: Problem 4.16[edit | edit source]

Contents taken from Page 239 in the Mechanics of Materials: 6th Edition textbook. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

A "T" shapes beam that is made of nylon, the allowable stress is 24 MPa in tension and 30 MPa in compression. The largest couple M that can be applied to the beam is?

Honor Pledge: On my honor, I have neither given nor received unauthorized aid in doing this assignment.

R5.4 Solution[edit | edit source]

1) $\displaystyle A=600mm^{2}$

\displaystyle y=7.5mm

\displaystyle A*y=4500mm^{3}

2) $\displaystyle A=500mm^{2}$

\displaystyle y=20mm

\displaystyle A*y=10000mm^{3}

1+2) A = 1100 mm^2 A*y = 14500 mm^3 y = (14500)/(1100) = 13.18mm

I = (1/12)*b* h^3 + A * d^3

I_1 = (1/12) (40) * (15^3) + 600*(20^2) = 251250 mm^4

I_2 = (1/12) (20)* (25^3) + 500*(10^2) = 76041.66 mm^4

I = I_1 + I_2 = 327291.67 mm^4 = 3.27 *10^-7 m^4

M = σ* I/y

Top M_1 = (24 * 10^6)(3.27*10^-7) / 0.02682 = 292.617 N-m

Bottom M_2 = (30*10^6) (3.27 * 10^-7)/0.01318 = 744.973 N-m

the smaller value is correct couple... so M_1

R5.5: Problem 4.20[edit | edit source]

Figure P4.20. — Contents taken from Page 239 in the *Mechanics of Materials: 6th Edition* textbook. Authors: **F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK** ISBN:9780077565664.

Contents taken from Page 239 in the Mechanics of Materials: 6th Edition textbook. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

Honor Pledge: On my honor, I have neither given nor received unauthorized aid in doing this assignment.

The cantilever beam with the trapezoidal cross-section has an allowable tension stress threshold, $\displaystyle \sigma _{T}$ and allowable compressive stress, $\displaystyle \sigma _{C}$ .

R5.5 Solution[edit | edit source]

What is largest couple moment $\displaystyle M$ that can be applied?

Given(s):

\displaystyle \sigma _{T}=120\,MPa

\displaystyle \sigma _{C}=-150\,MPa

Relation between cross-sectional area, stress, and moment

\displaystyle M_{max}={\frac {\sigma _{m}I}{c}}

Determine position of centroid in y direction

\displaystyle h

: height

\displaystyle {\bar {y}}={\frac {1}{\sum {A_{i}}}}\int \mathrm {y\,\mathrm {d} } A_{i}

\displaystyle \sum {A_{i}}={\frac {h(b_{1}+b_{2})}{2}}=3240\,mm^{2}

Using composite area method

\displaystyle {\bar {y_{1}}}={\bar {y_{3}}}

\displaystyle A_{1}=A_{3}

\displaystyle {\bar {y}}={\frac {2{\bar {y_{1}}}A_{1}+{\bar {y_{2}}}A_{2}}{\sum {A_{i}}}}

\displaystyle {\color {blue}Area\,1:}

By similar triangles

\displaystyle u={\frac {by}{h}}

\displaystyle \mathrm {d} A=u\mathrm {d} y={\frac {by}{h}}\mathrm {d} y

\displaystyle {\bar {y_{1}}}={\frac {b}{A_{1}h}}\int _{0}^{h}\,\mathrm {y^{2}\,\mathrm {d} } y={\frac {bh^{2}}{3A_{1}}}=36\,mm

\displaystyle {\color {blue}Area\,2:}

Because of symmetry

\displaystyle {\bar {y_{2}}}={\frac {h}{2}}=27\,mm

Therefore, $\displaystyle {\bar {y}}=30\,mm$ and $\displaystyle c\,=30\,mm$

Determine 2nd moment of inertia

\displaystyle I\,=\,\int {\mathrm {y^{2}\,\mathrm {d} } A}\,=\,2\int {\mathrm {y^{2}\,\mathrm {d} } A_{1}}+\int {\mathrm {y^{2}\,\mathrm {d} } A_{2}}\,=\,{\color {Red}2Y+Z}

\displaystyle {\color {Red}Y}\,=\,\int {\mathrm {y^{2}\,\mathrm {d} } A_{1}}\,=\,{\frac {b}{h}}\int _{0}^{h}{\mathrm {y^{3}\,\mathrm {d} } y}\,=\,{\frac {bh^{3}}{4}}

\displaystyle {\color {Red}Z}\,=\,\int {\mathrm {y^{2}\,\mathrm {d} } A_{2}}\,=\,b\int _{0}^{h}{\mathrm {y^{2}\,\mathrm {d} } y}\,=\,{\frac {bh^{3}}{3}}

\displaystyle I=2({\frac {bh^{3}}{4}})+{\frac {bh^{3}}{3}}=3674160\,mm^{4}

Find limiting constraint to the maximum couple moment, $\displaystyle \sigma _{T}$ or $\displaystyle \sigma _{C}$

\displaystyle M_{max}={\frac {\sigma _{T}I}{c}}={\color {blue}-1469.664\,Nm}

\displaystyle M_{max}={\frac {\sigma _{C}I}{c}}={1837.08\,Nm}

R5.6: Problem 3.53[edit | edit source]

Contents taken from Page 174 in the Mechanics of Materials: 6th Edition textbook. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664.

Rod AB is made of aluminum, which has a Young's modulus of 3,700,000 pounds per square inch. Rod BC is made of brass, which has a Young's modulus of 5,600,000 pounds per square inch.

A torque T equal to 12,500 pound inches is applied at point B along the axis AC.

The figure shows that AB is 12 inches in length and 1.5 inches in diameter, and that BC is 18 inches long and 2 inches in diameter.

Find a) The max shear stress in rod AB and b) the max shear stress BC.

Honor Pledge: On my honor, I have neither given nor received unauthorized aid in doing this assignment.

R5.6 solution[edit | edit source]

Formulas used: $R={\frac {D}{2}}$

$\tau ={\frac {TL}{JG}}$

$J={\frac {\pi }{2}}R^{4}$

$\tau _{max}={\frac {TR}{J}}$

Applied torque T is equal to the sum of the reaction forces at points A and C:

$T=T_{AB}+T_{BC}=12.5kip*in$

Total rod twist angle is equal to the sum of section AB and BC's twist angles; total twist angle is equal to zero because points A and C are held stationary:

$\phi =\phi _{AB}+\phi _{BC}=0$