ASABE PE REVIEW MACHINE DESIGN
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ASABE PE REVIEWMACHINE DESIGN
Larry F. Stikeleather, P.E.
Note: some problems patterned after problems in “Mechanical Engineering Exam File” by Richard K.Pefley, P.E., Engineering Press, Inc. 1986
Reference for fatigue and shaft sizing is mainly basedupon “Machine Design, Theory and Practice” by Deutschman, Michels, and Wilson (an old but great book)
Biological & Agric. Engr, NCSU
9/2013
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Other references recommended
Any basic text on Machine Design should serve you well in preparation for the PE exam. For example:Design of Machine Elements, M.F. SpottsMachine Elements in Mechanical Design, Robert L. MottMachine Design an integrated approach, Robert L. NortonMechanical Engineering Design, Shigley/Mischke/Budynas
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Machine design—what is it?Subset of Mechanical design…which is Subset of Engineering design…which isSubset of Design….which isSubset of the topic of Problem Solving
What is a machine? …a combination of resistant bodies arranged so that by their means the mechanical forces of nature can be compelled to do work accompanied by certain determinate motions.
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Big picture
Mechanics
Statics Dynamics
kinematics Kinetics
motion Motion and forces
Change with timeTime not a
factor
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The Design Process•Recognize need/define problem•Create a solution/design•Prepare model/prototype/solution•Test and evaluate•Communicate design
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Important to review the fundamentals of….
•Statics•Dynamics•Materials/material properties•elasticity•homogeneity•isotropy•mass and area parameters
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Lets begin our brief review
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T=I rotary motion equivalent of F=MAI= mass moment of inertia M*r^2 dMnot to be confused with the area moment of inertia whichwe will discuss later.
Remember the parallel axis theorem If Icg is a mass moment of inertia about some axis “aa” thru the centroid (cg) of a body then the moment of inertia aboutan axis “bb” which is parallel to “aa” and some distance “d” away is given by:Ibb = Icg + (d^2)* M where M is the mass
Note: This same theorem also works for area moments of inertia in the same way
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More generally I=M k^2 where k is called the radius of gyrationwhich can be thought of as the radius where all the mass couldconcentrated (relative to the axis of interest) to give the same moment of inertia I that the body with distributed mass has.
For a solid cylinderI= M(k^2) = ½ M (R^2) whereR= radiusM= massk= radius of gyration
For a hollow cylinder I = M(k^2) = ½ M(R1^2 + R2^2)
Note: this intuitively seems like it should be (R1^2 –R2^2)but that is not the case. Deriving this is a good review of basiccalculus.
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(Note: Must remember 1N=1Kg*m/s2 also remember that radian is dimensionless…length/length)
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Area Moment of inertia for some shapes
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Review problem #135
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Solution synthesis: We know I= bh3/12for a rectangular section.Solution execution: We must decide onthe max I. Will Ixx or Iyy be larger. ForIxx, b=8 and h=12. But for Iyy, b=12 andh=8 so it is obvious that Ixx will belarger. Since the tube is hollow we mustsubtract out the contribution of thematerial that does not exist….therectangular air space on the inside.Hence the solution is:I=boho3/12 – bihi3/12Where bo=8, ho=12, bi=7, hi=11This gives I=(8)(12^3)/12 – (7)(11^3)/12I=1152-776.4=375.6….the answer (d)
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Factors of safety
N = allowable stress (or load) of material
Working or design or actual stress
More generallyN = load which will cause failure
Load which exits
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Often safety factor is a policy question. Here are some rulesOf thumb.
Recommended N materials loads environ. Cond.
1.25 – 1.5 very reliable certain controlled1.5-2 well known det. Easily fairly const.2-2.5 avg. Can be det. Ordinary2.5-3 less tried “” “”3-4 untried matl’s “” “”3-4 well known uncertain uncertain
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Design relationships for elastic designAxial loading
= Sy/N = F/AWhere F= axial forceA = cross sectional area
Transverse shear
= Ssy/N = VQ/(I*b)Where V = vertical shearQ = y dA = max at the neutral axis
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Design relationships for elastic design
Bending
Where = max allowable design stressSy = yield stress of material, tensileN = safety factorM = bending momentC = distance from neutral surface to outer fiberI = area moment of inertia about neutral axisS= I/C referred to as the section modulus
= M/S
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Hooke’s law/stresses/strains
Problem: a round metal rod 1” dia is 10 ft long. A tensileload of 10000 lbf is applied and it is determined that the rodelongated about 0.140 inches. What type of material is the bar likely made of ? How much did the diameter of therod change when the load was applied ?
ԑ
E=σ/ԑ
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Plan:We will apply Hooke’s law to determine what the modulus of elasticity E is. Then we should also be able to apply the same law to determine the change in diameter of the rod.
We recall Hooke’s law as follows
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Loads and stresses example
Under certain conditions a wheel and axle is subjected to the loading shown in the sketch below.a) What are the loads acting on the axle at section A-A?b) What maximum direct stresses are developed at that
section?
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Plan:•Sum forces and moments•Compute bending moment•Compute bending stress•Compute tensile or compressive stress
Execution:Summing Fx we determine the axial tensile load at A-A=300lbfSumming Fy direct shear load = 1000 lbfSumming moments about the A-A section at the neutral axisWe find the bending moment= 1000*3 + 300*15= 7500 lb-in
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Design relationships for elastic design
Torsion
= Ssy/N = T*r/JWhere T= torque appliedr = radiusJ= polar moment of inertia (area)
J= (pi)(r^4)/2 = (pi)(d^4)/32 J= (pi)(D^4 – d^4)/ 32
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Combined stress
In a two dimensional stress field (where )the principal stresses on the principal planes are givenby:
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Combined stress continued
In combined stresses problems involving shaft designwe are generally dealing with only bending and torsioni.e., where =0
In this case
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Theories of failure
1) Maximum normal stressBased on failure in tension or compression applied to materialsstrong in shear, weak in tension or compression.
Static loadinga) Design based on yielding, keep:
(for materials with different compressive and tensile strengths)
b) For brittle materials (no yield point) …design for:
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Theories of failure cont’d
Fatigue loading (fluctuating loads)
Se=Cf*Cr*Cs*Cw*Sn’
Where Sn’ = endurance limitSe = allowable working stressor modified endurance limitNote: stress concentration factorKf is not in this formula for Se. Kfis included later to be part specific
Sn
Sn’
# cycles
time
stress
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Soderberg failure line for fatigue
safe stress line
Se
Se/N
axis
Syp/N Syp
State of stressKf* ,
Kf
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Maximum shear theory of failure
For design with ductile materials and it is conservative and on the premise: failure occurs when the maximum (spatial)shear stress exceeds the shear strength. Failure is by yielding.
safe stress line
Ses/2
Se/2N
axis
Syp/2N Syp/2
State of stressKf* ,
Kf
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Formulae for sizing a shaft carrying bending and torsion
For a hollow shaft….”Do”=outside dia, “Di” = inside dia
For a solid shaft Di=0 and the equation becomes:
Where “Do” will be the smallest allowable diameter based on max shear theory. M is the bending moment and T is the torsionT is the mean torque assumed to be steady here…and M is the Bending moment which becomes the fluctuating load as the shaft Rotates.
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Other shaft sizing considerations
Other criterion of shaft design may be requirements on torsionalRigidity (twist) and lateral rigidity (deflection)
Torsional rigidity
Where:theta= angle of twist, degreesL = length (carrying torque), in inchesT = torsional moment, lb-inG = torsional (shear) modulus of elasticity
(11.5x10^6 psi, steels) ( 3.8x10^6 psi, Al alloysD = shaft diameter, inches
Theta = 584* T*L/(G*(Do^4-Di^4)) for hollow circ. shaft
Theta = 584* T*L/(G*(Do^4)) for solid circ. shaft
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Review problem #110
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Review Problem #110
Solution synthesis: We are not asked to design for fatigue so we are sizing the shaft as if a static load were applied. There are two types of loads on the shaft, 1) a bending moment caused by the chain force acting 4 inches to the right of the right bearing and 2) the torsion load determined by the power transmitted.
We must compute the torque to get the chain force applied to the sprocket (shaft). We know Hp=T*N/63025 where N is RPM and the torque, T is in lbf-in. This gives T=Hp*63025/N= 20*63025/1000=1260.5 lbf-in.
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Shear and Moment sign conv.
• Positive shear
• Negative shear
• Positive moment
• Negative moment
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Strain gage review problem 513
Given: Full bridge hookupGF=2.08
Vex=2.5 VImplement is a beam 3 inches wide x 0.5 inches thick…
beam is steel…load is 1 ft=12 inches below the gagesThe load causes the bridge output to be Vo=120 µVWhat is the load (resisting force) in pounds?
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Problem: If the above implement problem had been giventhis same Vo for a half-bridge circuit what would have beenthe force acting on the implement?
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Solution: For a half bridge Vo/Vex = -GF*/2
Here is an excellent discussion of strain gage basics:http://zone.ni.com/devzone/cda/tut/p/id/3642
Thus for the same Vo must be twice a largeSo if is twice as large the load is must be twice as large.
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Column buckling
A hydraulic actuator is needed to provide these forces: minimum force in contraction…4000 lb. Maximum force in extension (push) …8000lb. The rod is made of steel with a tension or compression yield strength of 40,000psi. Assume a hydraulic system pressure of 2000psi.
a. What nominal (nearest 1/16”) diameter rod is required for a safety factor of 5 and what nominal bore?
b. What size piston is needed?
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We sketch the cylinder as shown here:
With 8000 lbs of push capability we must be concerned aboutpossible buckling of the rod in its most vulnerable positionwhich would be at full extension to 20” length. We will not worry about the cylinder itself buckling and concern ourselveswith the rod.•What do you recall about solving a buckling problem?•Lets review a few basics
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•Is the rod considered to be long or short column?•What are the end conditions?•We must design for Pallowable=8000lbs=Pcr/N•But N the safety factor =5 so Pcr=40000lbs
Recall from buckling theory:
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Plan: •In a typical problem we would determine if the column is long or short then apply the Euler or Johnson equ. accordingly but in our case here we are designing the size of the column and the size information is not given so what do we do?•Piston diameter must be determined based on forces required and the system pressure and the rod size.
Execution:Since we are trying to compute rod diameter we could sizethe rod to be a short or a long column keeping in mind thatthe Euler formula applies to long columns where the stress is less than Sy/2 and where the slenderness ratio L/rn is greater than the critical value given by the table above.Lets use Euler and design it as a long column.
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Assume C = ¼ For “Fixed – Free”
BUT
d=1.448
2 2 640,000 20 4 / 30 10 0.216I
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For a force in tension =4000lbs
(Piston area)(2000psi)=4000Piston area =2.0 in^2 effective areaBut we must remember that in contraction the rod is occupyingPart of the cylinder area.Area of the rod = (Pi)(d^2)/4=3.14*(1.5^2)/4=1.767 in^2
Thus the total bore area must be 2.0 + 1.767=3.767 in^2Hence (pi)*(D^2)/4=3.767 D^2=4.796D=2.19in ------- 2.25 in dia piston
Can a piston 2.25 in dia generate 8000lbs push with a 2000psiHydraulic pressure?Force push=P*Area= 2000*(pi)*(2.25^2)/4= 7952lbs so OK.
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Lets work a follow-on example
Assume you want to check the connector in a slider crankmechanism which is to generate a force at the slider
Lets assume you have chosen the following:Connector length 12”Cross-section ¼ x 1 inch, area = ¼ inch sq.Mat’l Al, E= 10.6x 10^6 psiMax load in connector will be 500 lbfLets assume we need a safety factor N=2
Problem definition: we need Pallowable>= 500 lbfFor safety N=2, will the chosen design have adequate buckling strength?
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Plan: Compute the slenderness ratio and decide if the connector columnIs “long” or “short” then apply either Euler or JB Johnson to compute Pcr.If Pcr/N=Pcr/2=Pallowable>=500 lbf then the proposed size is OK
Execution:Buckling will occur about yy if we assume a pinned-pinned jointabout both axes at each end.
Slenderness Ratio = 166.2
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Now evaluate the critical slenderness ratio:where C=1 for pinned-pinned and Sy=24000psifor say Al 2011 T6 alloy
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If we go back and write the slenderness ratio in terms of the Thickness we should be able to compute the thickness req’dFor the 500 lbf (N=2) allowable load requirement.
Now the connector will still be “long” so plugging Euler:We need Pcr>=1000 lbf (ie, so that Pcr/2 >= 500 lbf)
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Example Shaft ProblemProblem statement: The drive shaft in the sketch below is madeof mild steel tube (3.5” OD x 0.80 wall) welded to universal joint, yokes and a splined shaft as shown. It is driven by anengine developing 250 hp at 2000 rpm what is the stress in theshaft tube? If the shaft is considered to have uniform properties,end to end, what is the critical speed of the shaft?
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Plan: this is a torsion problem with a hollow shaft. The stressin the shaft will be due to shearing stress. We will need to applythe formula for shear stress for a hollow shaft. For the critical speed question we are then dealing with a vibration issue…atwhat frequency (rpm) will the shaft be inclined to go into a resonant condition…what do we know about this? Spring rate?,static deflection? The Rayleigh-Ritz formula? Etc,…since the shaft has only distributed mass we could break it into segmentsand apply the Rayleigh-Ritz but that would be a lot of work forthe time constraint…so that is not likely what is expected…the simplest thing we can so do is compute the max static deflectionand use that to compute the approximate frequency.Note: Rayleigh-Ritz says:The first critical freq (rpm) = 187.7
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Where J is the Polar Moment for A Hollow Shaft
T = Torque
C = Radius to Outermost Fiber
For Hollow Shaft
Solution execution:Stress in the shaft due to torsional shearing stress
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APPENDIX
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Some Engineering Basics
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