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Egm3520.s13.team1.stevenchiu (discuss • contribs) 15:28, 6 February 2013 (UTC)

Egm 3520.s13.team1.wcs (discuss • contribs) 15:52, 6 February 2013 (UTC)

Pb-9.1 sec.9 p.9-8. Contents taken from the notes of Dr. Loc Vu-Quoc

Text can be viewed here

Solve for the reactions at B and at A in the Example 2.04 (see p.9-1) with the stress-strain relation (1) p.9-5.

Diagram

File:2.04l.PNG

Template:Center top Given Template:Center bottom
Template:Center top Applied Forces Template:Center bottom	Template:Center top Area Template:Center bottom	Template:Center top Length Template:Center bottom	Template:Center topYoung's Modulus Template:Center bottom
${\displaystyle F_D=300kN}$	${\displaystyle A_{CK}=A_{KB}=A_{CB}=400m{m}^2=A_1}$	${\displaystyle L_{AD}=L_{DC}=L_{CK}=L_{KB}=L=150mm}$	${\displaystyle E_{AD}=E_{DC}=E_{CK}=E_{KB}=E}$
${\displaystyle F_K=600kN}$	${\displaystyle A_{AD}=A_{DC}=A_{AC}=250m{m}^2=A_2}$

${\displaystyle \sigma =E{ϵ}^{1/2}}$

${\displaystyle ⟹\delta =ϵL=\frac{{\sigma }^2}{E^2}L=\frac{P^{2}L}{A^2{E}^2}}$

File:2.04hg.PNG

FBD 3:

${\displaystyle \sum F=-P_{CK}-F_K+R_B=0}$

${\displaystyle ⟹P_{CK}=P_1=R_B-F_K}$

FBD 4:

${\displaystyle \sum F=-P_{DC}-F_K=0}$

${\displaystyle ⟹P_{DC}=P_2=R_B-F_K}$

FBD 5:

${\displaystyle \sum F=-P_{AD}-F_D-F_K+R_B=0}$

${\displaystyle ⟹P_{AD}=P_3=R_B-F_D-F_K}$

Left

${\displaystyle {\delta }_L=\sum \frac{P_i^2{L}_i}{A_i^2{E}_i^2}=(0+\frac{P_1^{2}L}{A_1^2{E}^2}+\frac{P_2^{2}L}{A_2^2{E}^2}+\frac{P_3^{2}L}{A_2^2{E}^2})}$

Sub: ${\displaystyle P_1=P_2}$

Right

${\displaystyle {\delta }_R=\frac{P_1^{2}L}{A_1^2{E}^2}+\frac{P_2^{2}L}{A_1^2{E}^2}}$

Sub: ${\displaystyle P_1=P_2=-R_B}$

Total

${\displaystyle {\delta }_{\text{Total}}={\delta }_L+{\delta }_R=\frac{P_1^{2}L}{A_1^2{E}^2}+\frac{P_2^{2}L}{A_2^2{E}^2}+\frac{P_3^{2}L}{A_2^2{E}^2}-\frac{R_B^{2}L}{A_1^2{E}^2}-\frac{R_B^{2}L}{A_2^2{E}^2}=0}$

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${\displaystyle ⟹\frac{P_1^2}{A_1^2}+\frac{P_1^2}{A_1^2}+\frac{P_3^2}{A_2^2}-\frac{R_B^2}{A_1^2}-\frac{R_B^2}{A_2^2}=0}$

${\displaystyle ⟹-\frac{1}{A_1^2}{R}_B^2+\frac{1}{A_1^2}(1.2*10^6)R_B+\frac{(6*10^6{)}^2}{A_1^2}-\frac{1}{A_2^2}{R}_B^2+\frac{1}{A_2^2}(1.2*10^6)R_B+\frac{(9*10^6{)}^2}{A_2^2}-\frac{1}{A_2^2}{R}_B^2+\frac{1}{A_2^2}(1.8*10^6)R_B+\frac{(9*10^6{)}^2}{A_2^2}-\frac{1}{A_1^2}{R}_B^2-\frac{1}{A_2^2}{R}_B^2}$

${\displaystyle ⟹(-\frac{2}{A_1^2}-\frac{3}{A_2^2})R_B^2+(4*10^6)(\frac{1}{A_2^2}+\frac{2}{A_2^2})R_B+\frac{(6*10^6{)}^2}{A_1^2}+\frac{(9*10^6{)}^2}{A_2^2}+(9*10^6{)}^2{A}_2^2}$

${\displaystyle ⟹-6.05*10^7{R}_B^2+1.6065*10^{14}{R}_B+2.097*10^{21}}$

${\displaystyle R_B\approx 200kN}$

${\displaystyle \sum F=R_A-F_D-F_K+R_B=0}$

${\displaystyle ⟹R_A=300+600-200=0}$

${\displaystyle ⟹R_A=700kN}$

Do the results depend on the length of each segment and the Young's modulus?

Solution 2

While working to determine ${\displaystyle {\delta }_{Total}}$, which was an equilibrium equation, the resultants were found not to be dependent on segment length or the Young's modulus because both were constants and were subsequently cancelled out. Refer to process above.

Problem Number 2.12, p.73. Contents taken from Mechanics of Materials Textbook 6th edition. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

A nylon thread is to be subjected to a 10-N tension. Knowing that E=3.2 GPa,that the maximum allowable normal stress is 40 MPa, and the length of the thread must not increase by more than 1%, determine the required diameter thread.

Determine maximum stress allowable with the limit in displacement being ${\displaystyle {\displaystyle \delta =\frac{L}{100}}}$:

${\displaystyle {\displaystyle \sigma =E\frac{ϵ}{L}=32MPa}}$

Derive formula relating area of nylon string with ratio of displacement and original length of the string using these three relations:

${\displaystyle {\displaystyle ϵ=\frac{\delta }{L}}}$ ${\displaystyle {\displaystyle \sigma =Eϵ}}$ ${\displaystyle {\displaystyle \sigma =\frac{P}{A}}}$

Write Area in terms of diameter:

${\displaystyle {\displaystyle \sigma =\frac{P}{A}=\frac{P}{\pi (\frac{d}{2}{)}^2}}}$

Solve equation for diameter (d):

${\displaystyle {\displaystyle d=\sqrt{\frac{4P}{\pi \sigma }}=.631mm}}$

Problem Number 2.16, p.74. Contents taken from Mechanics of Materials Textbook 6th edition. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

The brass tube AB (${\displaystyle E=105\text{GPa}}$) has a cross-sectional area of ${\displaystyle 140{\text{mm}}^2}$ and is fitted with a plug at A. The tube is attached at B to a rigid plate that is itself attached at C to the bottom of an aluminum cylinder (E=72 GPa) with a cross-sectional area of 250mm^2. The cylinder is then hung from a support at D. In order to close the cylinder, the plug must move down through 1 mm. Determine the force P that must be applied to the cylinder.

File:Figure P2.16.jpg

${\displaystyle {\displaystyle E_{AB}=105GPa\ge 105*10^{9}Pa}}$

${\displaystyle {\displaystyle X_{AB}=104m{m}^2\ge 1.4*10^{-4}m}}$

${\displaystyle {\displaystyle E_{C}D=72GPa\ge 72*10^{9}Pa}}$

${\displaystyle {\displaystyle X_{C}D=250m{m}^2\ge 2.5*10^{-4}m}}$

Must be moved down 1 mm to find P (force or load required).

${\displaystyle \delta =\frac{PL}{EA}}$

${\displaystyle L_{AB}=375\text{mm}+1\text{mm}=376\text{mm}}$

${\displaystyle {\delta }_{AB}=\frac{P{L}_{AB}}{E_{AB}{A}_{AB}}⟹\frac{P(0.376m)}{(105*10^{9}Pa)(1.40*10^{-4}{m}^2)}=2.558*10^{-8}P}$

${\displaystyle {\delta }_{CD}=\frac{P{L}_{CD}}{E_{CD}{A}_{CD}}⟹\frac{P(0.375)}{(72*10^{9}Pa)(2.5*10^{-4}{m}^2)}=2.0833*10^{-8}Pa}$

${\displaystyle {\delta }_A={\delta }_{AB}+{\delta }_{CD}⟹1*10^{-3}m=(2.558*10^{-8}+2.0833*10^{-8})P}$

${\displaystyle P=\frac{1*10^{-3}m}{2.558*10^{-8}+2.0833*10^{-8}}=21546.35N⟹21.5kN}$

Problem Number 2.24, p.75. Contents taken from Mechanics of Materials Textbook 6th edition. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

For the steel truss (E=29*10^6 psi) and loading shown, determine the deformations of members BD and DE, knowin that their cross-sectional areas are 2 in^2 and 3 in^2, respectively.

Done by method of sections. Cut off the top half of the truss by cutting midway through sections BD, DE and EG.

It is assumed that the structure is in equilibrium.

${\displaystyle {\displaystyle \sum M_E=(-30kips)(0)+(-30kips)(8)+(-30kips)(16)+F_{BD}*15=0⟹}}$

${\displaystyle F_{BD}=48kips}$

${\displaystyle {\displaystyle \sum F_H=30kips+30kips-F_{DE}=0⟹}}$

${\displaystyle F_{DE}=60kips}$

${\displaystyle {\displaystyle {\delta }_{BD}=\frac{F_{BD}{L}_{BD}}{A_{BD}{E}_{BD}}=\frac{48kips*96in}{2in*(29E-6)psi}⟹}}$

${\displaystyle {\delta }_{BD}=0.0794in}$

${\displaystyle {\displaystyle {\delta }_{DE}=\frac{F_{DE}{L}_{DE}}{A_{DE}*E_{DE}}=\frac{60kips*180in}{3in*(29E-6)psi}⟹}}$

${\displaystyle {\delta }_{DE}=0.124in}$

Problem Number 2.40, p.89. Contents taken from Mechanics of Materials Textbook 6th edition. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664

A polystyrene rod consisting of two cylindrical portions AB and BC is restrained at both ends and supports and supports two 6-kip loads as shown. Knowing that E=0.45*10^6 psi, determine (a) the reactions at A and C, (b) the normal stress in each portion of the rod.

We begin by first sketching the free body diagram of the system From this diagram we can see that:

${\displaystyle {\displaystyle R_A+R_B=12kips}}$

(1)

Next, we consider the deformation of the rod to be zero. Using equation 2.15 from the text book we see:

${\displaystyle {\displaystyle \delta =\frac{P_{AB}{L}_{AB}}{A_{AB}E}+\frac{P_{BC}{L}_{BC}}{A_{BCE}}=0}}$

(Text 2.15)

Having been given values for all variables in the equation except P we must solve for those two forces. Substituting into the original equation we find:

${\displaystyle {\displaystyle \frac{R_A{L}_{AB}}{A_{AB}}-\frac{R_C{L}_{BC}}{A_{BC}}=0}}$

Calculating the areas gives us:

${\displaystyle {\displaystyle A_{AB}=\pi (0.625{)}^2=1.22i{n}^2}}$

${\displaystyle {\displaystyle A_{BC}=\pi (1{)}^2=3.14i{n}^2}}$

${\displaystyle {\displaystyle R_C=\frac{L_{AB}{A}_{BC}}{L_{BC}{A}_{AB}}*R_A=4.29R_A}}$

(2)

Using the equations (1) and (2) we can solve for ${\displaystyle R_A}$ and ${\displaystyle R_B}$

${\displaystyle R_A=2.3kips}$

${\displaystyle R_B=9.7kips}$

To find the normal stress we simply use formula 1.5 from the first chapter of the text:

${\displaystyle {\displaystyle \sigma =\frac{P}{A}}}$

(Text 1.5)

${\displaystyle {\displaystyle {\sigma }_{AB}=\frac{R_A}{A_{AB}}=1.88ksi}}$

${\displaystyle {\displaystyle {\sigma }_{BC}=\frac{-R_C}{A_{BC}}=-3.09ksi}}$

Problem Number 2.44, p.90. Contents taken from Mechanics of Materials Textbook 6th edition. Authors: F.P BEER, E.R. JOHNSTON, J.T. DEWOLF AND D.F. MAZUREK ISBN:9780077565664 Egm3520.s13.team1.scheppegrell.jas (discuss • contribs) 16:57, 6 February 2013 (UTC)

File:Twofortyfour.png

The rigid bar AD is supported by two steel wires of 1/16in diameter (E=29*10^6 psi) and a pin and bracket at D. Knowing that the wires were initially taut, determine (a) the additional tension in each wire when a 120-lb load P is P is applied at B, (b) the corresponding deflection of point B.

Template:Center top Given Template:Center bottom
Template:Center top Applied Force Template:Center bottom	Template:Center top Area Template:Center bottom	Template:Center top Length Template:Center bottom	Template:Center topYoung's Modulus Template:Center bottom
P=120lb	${\displaystyle A_{AE}=A_{CF}=\frac{\pi }{4}\frac{1}{256}i{n}^2=A}$	${\displaystyle L_{AE}=15in=L_A}$	${\displaystyle E_{AE}=E_{CF}=29*10^{6}psi}$
		${\displaystyle L_{CF}=8in=L_C}$

${\displaystyle {\delta }_i=\frac{P_i{L}_i}{AE}}$

${\displaystyle {\delta }_A=\frac{P_{A}15}{\frac{\pi }{4}\frac{1}{256}(29*10^6)}}$

${\displaystyle {\delta }_C=\frac{P_{C}8}{\frac{\pi }{4}\frac{1}{256}(29*10^6)}}$

${\displaystyle {\delta }_A=\frac{3}{2}{\delta }_B}$

${\displaystyle {\delta }_C=\frac{1}{2}{\delta }_B}$

${\displaystyle \frac{2}{3}\frac{P_{A}15}{\frac{\pi }{4}\frac{1}{256}(29*10^6)}=2\frac{P_{C}8}{\frac{\pi }{4}\frac{1}{256}(29*10^6)}}$

${\displaystyle \frac{2}{3}{P}_{A}15=2P_{C}8}$

${\displaystyle P_A=\frac{8}{5}{P}_C}$

${\displaystyle \frac{8}{5}{P}_C\frac{3}{2}+P_C\frac{1}{2}=120}$

${\displaystyle P_C\frac{29}{10}=120}$

${\displaystyle P_C=\frac{1200}{29}⟹P_A=\frac{1920}{29}}$

${\displaystyle Tensio{n}_C=41.4lb}$

${\displaystyle Tensio{n}_A=66.2lb}$

${\displaystyle {\delta }_C=\frac{8*41.4}{\frac{\pi }{4*256}29*10^6}=3.72*10^{-3}}$

${\displaystyle {\delta }_B={\delta }_B*2=3.72*10^{-3})*2=7.44*10^{-3}inches}$

Deflection of point B is approximately ${\displaystyle 7.44*10^{-3}inches}$

m = meter

mm = millimeter

d = diameter

G = giga

Pa = Pascal

A = area

Q/P = load

N = Newton

δ = deflection

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