Empirical design curves are presented for the critical stress of thin-walled cylinders loaded in axial compression. These curves are plotted in terms of nondimensional parameters of small-deflection theory and are compared with theoretical curves derived for the buckling of cylinders with simply supported and clamped edges. An empirical equation is given for the buckling of cylinders having a length-radius ratio greater than about 0.75. The test data obtained from various sources follow the general trend of the theoretical curve for cylinders with clamped edges, agreeing closely with the theory in the case of short cylinders, but falling considerably below the theoretical results for long cylinders. The discrepancy in the case of long cylinders increases with increasing values of the ratio of radius to wall thickness. Plotting curves for different values of this ratio reduces the scatter in the test data and a certain degree of correlation with theory is achieved. Advantage is taken of this correlation to obtain estimated design curves for cylinders with simply supported edges, for which little experimental information is available. (author

Batdorf, S B

Shildcrout, Murry

Stein, Manuel

English

NASA Technical Reports Server

—1
f
#
1
TECHNICALNOTE
No.1343
CRITICALSTRESSOF THIN-WALLEDCYLINDERS
INAXIALCOMPRESSION
By S. B. Batdorf, Murry Schildcrout, and ManuelStein
Langley Memorial Aeronautical Laboratory
Langley Field, Va.
Washington
June1947
AFMDC
TEClf?ULy.LL:BRARY
ML 2811
.-
https://ntrs.nasa.gov/search.jsp?R=19930082161 2020-06-17T21:25:32+00:00Z
l,
NATIONALADVISORYCCMMITTEE
TECHNICALNOTENO,
TECHLIBRARYKAFB,NM J&-:-
I!lll[llllllllllllllllllllll=“--QW4b20
FORAERONAUTICS
1343
,.
CRITICALSTRESSOFTEIN+ALLEDCYLZNDERS
ByS.B.Batdorf,MuzzrySchildcrout,
SUMWRY
Ih@ricaldestmcurvssarepresented
IltAXIALCOMPRESSION
andManuelStein
forthecritical
stress% thin-wall;dcylindersL%dedinaxialcompression.
Thesecurvesareplottedintermsof,thenondimensional
pemmetersofsmall-deflect~onheoryandarecomparedwith
theoreticalcurvesderivedforthelndclingofcylinderswith
simplysupportedandclampededges.Anqpirfcalequationis
givenforthein.mlslingof.cylindershavinga length-radius
ratiogreaterthana%out0.75.
Thetestda~aobtainedfromvariousourcesfollowthe
generaltrendofthetheoreticalcurveforcylinderswith
chanpgde~ges,agreeingcloselywiththetheoryinthecaseof
shortcylinders,but fallingconsiderably%e~owthetheoretical
resultsforlongcylinders.Thediscrepancyintheeaseof
longcylindersincreaseswithincreasingvaluesoftheratio
of.radiustowallthickness.Plottingcurvesfordifferent
valuesof’thisratioreducesthescatterinthetestdqta
—
anda certaindegreeofcorrelationwiththeoryisachieved.
Advantigeistakenofthiscorrelationtoobtainestimated
designcurvesforcylinderswithsimplysupmrtededges,for
—
whichlittlexperimentalinformationisavai:al?le.
--.-— .
RXVTE!?OFPREEOL??WORKGNPROBLZM
Solutionstotheproblemoftinedeterminationoft@ critical
stressofthin-walledcylinderssubJectedtoaxialcompression -
havebeenpresentedbya largenumberofauthors.Southyell,
Timoshenlm,,??l’&e,andnumerousothe~authorshaveo%tained
.,,-
,.
2theoreticalsolutionsbytheuseofthe
(See,forexample,referencesto4,)
NACATNNoo1343
small-deflectionheory.
Thevaluegivenbythe
small-deflectionheoryfortheWcklingstressofa thin-walled
cylinderofmoderate,lengthhavingsimplysupportedgesis
(1)
where
ax cr:ticalcampi*essivestrese
E YOW*S modulus .—
t wallihfclmespof cylinder
1“ radiusofcylinder —
P Poissonteratio(inthepresentpaperv :stakentobe0.316
whenevera valueisassignedtoit)
Experiments(references~“tc~10)haveshownthattheqctub.1.
critictistressismuchlowerthanthatpzw.licteiibyequation(l).
Exceptinthecaseofshortcylinders,thee~erimcntsususlly
givevaluesonly15to50percent:fthatp~etictodtheoretically;
moreover,theobservedlmoklepatternisdiffei*entfromthat
predictedonthebasisoftheory.A num30rofattemptshavebeen
madetcexplainthesediscrepanciesthcmreticslly.Fl&ge(refer-
ence3) consideredthedeviation~ftheactusledgesupportm.Q@
thesupportconditionsa sumedinthetheoreticaltreatment.DonneXL
(reference~)and‘alsoFl@gaccnsidei~edtkmLlltid”dev:a’tionfrom
theperfectcylindricalshape.Neitlmrofthetwoattempted
explanationssatisfactorilyaccountstcrthed;.strep.zmcyexisting
betweentheWmore+zical.endex~ertientalv uesof,thebncld.tng
stressesofcylinders.
VonKe4n&and.!?i%ien(r~ference?.1)introdmm%a larfie-
deflection’tieo~t accmntforthebuc’Hlngbehavioroflong
cylindorq..TheyGhowed‘thata longcylind~rcanbeineqtilibriun”
ina buckledstateata stress,thakismuchE&4&w thanWle’crltlcal
wlmessofsmall-deflectionheoryandalso”succeedod,:inaccounting
forthebucklepatternobservedinthee,arlystage~ofbuckling.
Reference11rnzggestedhatwhena cylinderhaseminj.tialimperfec-
tionorissubjectedtoa shock,itmightpassintooneofthese
buckledstateswithouteverhavingreachedthecritjcalloadgiven.
byequation(l).Basedonthessmeapproach,a theoryfortho
htichling8tre&s ofperfect
(refeyence12),whichgave
cylinder~-wasp~+opoeedbyTaien
—
.-
,
.
—
I?ACATNO,1343 3
,.
% =‘0.-370~ (Ioadingbyrigidscrew-powertestingmachine) (2)
Ux=0.238E+ (loadingby,ideal
deadweight)
hydraulictesting~chineor
(3)
Thelarge-deflectionheoriesfailintworespectstodescribe
~dequatelytinebucklingbehaviorofactualcylinders.First,the
theoriesareformuktodonlyforlongcylinders;equations”(2)-d (3)
seriouslyunderestimateth criticalstressofveryshortcylinders.
Second,even
mentallythe
.
forlongcylinders,attemptstodetermineexperi-
nuwricalcoefficientC inthebucklingfmmula
C7x .= q (4)
haveresultedinappreciableexperimmtalscattqr.Theexperimental
scatterisdueatleastinparttotheinitialimperfectionsf
constructionalwayspresentInrealcylinders,(Seefig.1 taken
frorureference13,fig.18.)
Inth,“absenceof”a completeandsatisfactorytheo~etical
solutionforuhecriticalstressofcylinders,a numberofauthors
haveproposede~iricalfo:mmlasderivedfromtestdata(refer-
ences6to”8)..,Onesuchformula,whichtakesintoaccounthe
lengthofthecylinder,isdustoBallers%dtandWagner(refeNnce8):
H2Thefirstyarameterinthisequation$. isappropriateforflat
~ is”’%udedtotakeintoaccountsheetandthesecondparamtir
theeffectofcurvatwe.Morer~cen~lyKhemitsuandNoJima
(reference9)compiledallavailableprqtiousexperimentalresults
4 I?ACATNNo.1343
andconducteda numberoftestsoftheirown.Theformulaof
Wagner
better
andBallerstedtwasmodifiedinreference9 to%ringitinto
agreementwithexperimentasfollows:
(6)
Withinitsrengeofapplication ,.
.
equation(6) is inconsiderablyetteragreementwithe~erlment
thanequation(5)but,becauseofthechangeintiee~onentsof
theparameters,equation(6) doesnothaveaqyrs.tiomilbasisand
mustberegadedaspurei.yempirical.A completedtvorceoftheory
andexperiment,however,csmnotberegardedasa satisfactory
permanentsettlementoftheproblem,andthepresentreportattempte
tobrtigtheoryendexgerhnentintoreascnalleaccord.
CONTRIBUTIONOFPRESENTPAPER
Inthepresentpapertheavailablet stdataforcritical.
stressesofcylindersarereexamined.ndtheoreticalresultsare
usedasa guideinfairingthe”curves,inextend~ther-e of
vslidityoftheexistingemyiricalresults,andinachievinga
morerationalinterpretationofthetestdata.Borthispurpose
thetestdataareplottedintermsoftheparametersofcylinder
theoryandarecompmedtiththeoreticalresults‘derivedinthe
appendix
The
onthebasisofsmall-deflectionheory.
and.
cylinder-theorype.z’smtersused
5%=”+
,.
z
~2 —
--4=rtl.+
,
l -
are
—
.
,.
.
.
—
[
.
..
NACATNNo.1343
where
/’ Ets
D flexuralstiffnessofplateperunitlength~(,12(1- U2))
L lengthofcylindey
z cuiva.tureparemeter
~ criticalstresscoefficientappearingintheequation
5
kx#D. .Cx=-
L2t
>---”
.-
.-
Thee~erimentaldataareusedastheprincipalguidein
determiningthecriticalcmnpressivestreeses oflongcylinders”
(l=gevaluesofZ)andthetheoreticalresultsareusedmainly
tosupplementthetestd@a indeterminingthecriticelstress
ofveryshortcylinders(mallmlues ofZ). Theexpertiental
scatterisreducedbypresentingdifferentcurvesforcylinders:
witlndifferentvaluesoftheratio fradiustowallthickness
ontheassumptionthatfor”longcylinikrsthfsratiofurn3shessome
indicationftheinitielimperfectionsfthecylinder.Although
thesecurvesweredeterminedpartlyonthebasisoftheoretical
considerations,theyareforconveniencereferredtohereinas
empirical, curves.
Thecritical
the equation
..
. RESULTSANDCONCLUSIONS
compressive6tressfor-cylindersisgivenby.
. . %3ax= % —T. ;-
“.
whe~ theveluesof .& meybeobtainedfromfigure2 for
cylinderswitheither&mped orsimplysupportedges.The
designcuz’vesforcylitierswithclemped.edgesareestablished
bythetestresults,reportedinreferences~ to9. (Seefig. 3.) “ ‘ ‘
Eachcurvewasfaired
Qlottedforcylinders
througha seriesoftestpointswhich-were-
Wth nearlythessmeratio fradiustowall
6 . NACATNNo, 1343
thfcknesar/t. Theestimated( ashed)partsofthedestgcurves
forsimplesupport were obtained%yfairingbetweenthelmown
experimental.curvesforlongcylinders(largevaluesof Z),which
accordhgtotheoryshouldbethesamewhetherthecylindershave
simplysupportedorclampededges,endthetheoreticalcurvesfor
very &hortcyl~nders( mallvaluesof Z).
ForlongcylinderstheImokling@tressisconsld.erablybe ow
thetheoreticalbuokllngstress~theamountofthediscrepancy
dependingon theratioofradiustowallthickness.Forveryshort
cylinderstheveluesofthecriticalstr6ssesapproachthosefor
flatplates(simplysupportednds,kx = 1; clampedends,
kx= h),forwhichtheagreementletweentheoreticalandexperimental.
resultsisknowntobegood.Thegeneraltrendofeachempirical
curveissimilartothatofthetheoreticalcurve,Infifcatfngthe
existenceofa certaindegreeofeorrelekionbetweentheoryand
testdata.
Atlargevaluesof Z thecurvesfor k= becomestraight
linesgivenIJYtheformula
“;‘kx=1.15CZ (8)
whereC devendsontheratiofradiustowallthicknessof the
cylindersin’themar&ershownin
and(8) thefollowingexpression
figure40 ~omequation8(7)
forthecriticalstregsisobtai~d
“ (9)
Equations(8).&nd(9) maybeusedwhenthe“lengthofthecylinder
ismorethanabout3/4 ofthe,radfus.Theempiricalcurvesof
reference10tndicatsthatthecriticalstressissubstantial~v
independentoflengthwhenthelengthisgreaterthanshout3/4 of
theradius.(Thisresultmaybecheckedbynotingthatfor 2>0.5+
theexperimentalcurvesoffigure2 aresubstantiallystraightIinee
ofunitslope.)
Tnfigure5,theenipirical-formula ofKanemitsuandNoJima
(equation(6)ofthepresentpaper,andthelestprev~ouslyputlfshed
formulaforthebuoklingofcylinders)isplottedintermsofthe
parameters~ and Z. Thecurvesarecutoffatthosevaluesof Z
correspondingtothelowerlimitsoftherangeofdimensionswithin
whichtheformulawasintendedto”.aPPIY~.~ngeneral-~?’orther~ge
covered,thecqes arein.reasonableagreementwiththetestdata
andwiththecurvesof‘thepresentpaperfor,cyllndersw~thclamped
.,,
,.,, ,..
.
..
.. . k’
.NACA~~00 1343 7.
,..,..
edges. !Phepractical importmceof the present approachlies in the ._...__
fact thattheuse.of.thetheoreticalparametersandthetheoreticsll
solutionsa a guidein’falring%hecurvespemitsthermmval of
the.lowerlimitsonthese.cux-res.adalsopermitsestimatedcurves “
tobedrawnforthebuclding stresses for simply supportedcylinders,“
althoughe~erimental.dataare”amilableonlyforcylinderswith
clempededges. ,.
Ls@eyMmorie,l.AeronauticalL boratory .’ ‘--, . .- “- -..._
NationalAdvisoryCommitteeforAeronautics
LengleyField,Vs.,March~, 1947.
,.,
,.
. . .
,
. .
,.
..
,.
,,
. ... ,
,,,..
,.
.,:.
,,< ,
.,
,,,.
. . .
,.,,
,.,,
,,
., .,,..
,,.
.,
,,
-,.
r.,., ,,.. ,., . .,,. . . .
,
,.
. ..
.,
. .
.“
8m
l
r
t
w
x
Y
c
D
E
L
Q
z
%
kx
mm TNNo.1343
APPENDIX
THEORYlKIRCYLINDERSBUCKLINGUNDER
AXIALCOMERZSSION
symbols
positiveinteger
radiusofcylinder
wellthicknessofcylinder
radialcomponentofdisplacement,positiveoutward
axialcoordinateofcylinder
ctrctierential.coordinateofcylinder
coefficientappecuxhig
flexruxd.stiffnessof
Youngtsmodulus
lengthofcylinder
in ux=CE~
(:20- )
~!3plateperunitlength _
H*)
operatoron w definedfnappendix
curvatureparemeter
.(
— (.$ +-+-$$11- P* or
coefficientofdeflectionfunction
critical-cmpressive-stresscoefficientappearinginthe
..
f o-a ~ = kXfi2~ —
x --
L%
52 ‘
-1*Z2m - ~)4~=~~-l)2+PJ+#J(m:1)2+p51~- (m- l)2kx
Vm deflectionfunctiondefinedintheappendix
,
.
-.
.
NACATNI?O.1343 9
k halfwave~engthofbucldesincircumferential.
w Poissonisratio
direction
ax criticalexial.
$ &+$
‘4-S+23A7
theinverseof+!
compressi~estress
+4.
-%ay
V4 definedby v-%%= .
TheoreticalSolution
Thecriticalcompressivestressatwhichbucldingoccursin
a cylindricalshe~& beobtainedbysolvingtheequationof
equilibrium.
Equationofe.quilibrium.-TheequatimofeQtilibrlumfor
a slightlybuc%bdcylindricalshellunderaxialcompressionis
(z%ference14’)
(Ml)
wherex isthecoordinateintheaxieJ’directions.nd y isthe
coordinateinthecircumferentialdirection.Theaccompanying
figureshowsthe
,..
—
coord~tesystemusedinthesnalysis.
.
,
20 NA.CATNNO c L343
Dividingthroughequation(Al.)%y D @w’es
.
(A2)
wherethedimensionlessparametersZ and ~ aredefinedby
—.L2
d
—
z=~l-p*
... -A Dn2
Theequationofequilibriummay
Qw=o
whereQ isdefinedby
berepresentedby
(A3)
4 12!22-4 #
-.
# ap ,Q=v +>-v ~+~~~
—
Methodofsolution.-Equation(A2)meybesolvedbyuseof .
theGal.erklnmethodasoutlinedinreference15. WhenthiEImethod
isapplied,thedeflectionw isexpressedineeriesfozmas
fOL1OWS
Theset of
conditions
(A4}
—.
functionsVu arechosentosatisfytheboundary
butneednotsatisfytheequationofequizlbrium.The
coefficients~ aredetezmd.nedbytheequatl.ol~s
.’
~21. L
]J ~m,Qwdxdy=O(m=,l,2,3, . . . ~) (W)00
In the,presen%paperthe deflection functions .werechosento
satisfy the following conditions on w at theendsofthecylinder:
.
--
.. NACA~~Oc ~S~S
azw= *ForsimplysupportedgesV= —ax2
Forclempededges w= af =0x
.- Aneqfx=ionfor
ectionandperfectly
the%ounderyconditionsforsimplesupport)in
whereX isthehalf
ferentialdirection.
.
.’
.11
w thatiSsinuaoidel
general(subjectto
theaxialdirectionis
(M)
I
wavelengthofthebucldesinthecircum-
Equation-(A6)isequivalenttoequation(A4)if
Substitutionofe~ressions(A6)and(AT)intoequation(A5)and
inte@?ationoverthelimitsindicatedgive
where
fora givenZ isfoundbyassuming
k= withrespecto ~. ThiEIpro-
vahesof m untileminimumIG is
T@ minimumvslue of kx
a value for m andminimizing
cedure is followed for various
reached.Figure2 presentsthetheoreticalcriticalstresscoe?fl-
cientsforcylinderswithsimplysupportedges ub@ctedtoaxial
compression.
,.
Clanpedad.ges.-A proceduresimilartothatusedforcylinders
kth ~~ly supportedgesmeyhefollowedforcylinderswith
c19mpededges. Thedeflectionfunctionusedisthefollowingseries
.12 NAC?ATN~Oe 1343
I&h termofthisseriesatisfiestheconditionson w atthe
.
edges. The functim Vm isnowdef!itias
Afterthe sameoperationstiecarriedoutfor
thosecarriedoutforthecam ofsimplysupported
equationsresult:
I?orm=l
Form = 2.
~(M2+M~-q#4=0
l?orm=s,4,5, ...
where
.
1,2,,3, l . .) (Ale)
chnped edgesas
ges,thefollowing
-1
>’
.-.J. ,4
%,= ~m-l)2+p~2”i:12Z2(m- 1)4 (w-.3)2q#@ - 1)2+ pq-2-
,(1-1= 1,*,3,...]
Theseequationshavea solutionifthefollowinginfinitedeterminant
vanishes:
.
..
NACA~No. 1343 13I
Md ‘2M@43 o -1430- ”000”0 l . .
Z-2 o M#M)L o -M4 o 0 0 . . .
m=3 -M3 O M3+M> 0.
-i~oo”””
Dk4 o -M4 O M4tM6 o -14600 . ..
m+ o 0“ -% 0 %%0 -% 0 ““”
m=6 o 00
-% oM6~o -% ““” (A12)
m=7 o 0 0 ‘o -y o 0 . . .
-8 0 000 0 -M$ o M@il” , . l
. . . . . . . . .
. . . l . . . . .
l . l . . . . . .
If the rowsandcolumnsare rearremgedthe infinite de?zmminantcan
be factored into the product o: two infinite SUlildmrminants.The
critiml. stresses maythen be chtainedfrom the fcfl.lowingequation:
I oI?3=12W1+4Y+-I&J o *.. o, .0 0 0
3?l=3-M3-M#45 -M! O... 0 0 0 0
m5 o -MjMpq -1+..o 0 0 0
IrIl=7o 0 -% “7%”” 0 0 0 0
.
i
. . . . .
. . .
l . . .“. . . . .
l . . . . . l . .
3?4 o (1 o 0... M2+M4-M4 o 0
111=4o 0 0 0..*-M4M4+l~-M6 O
m=6 00 0 0l .. o -!.!6M6+lb-~
Im=8o 0 0 0.. 0 0 -~ M&M~*.
l I . . .,. . . . .. . . . . . . . ..I . . . . . l . .,
. . .
. . .
. . .
.,*
.
. . .
. . .
l . .
. . .
Theinfinite eubdeterminentinvolving termswith odd subscripts
corresponds‘to a symhetricti ?mckl- pattern (a buclil.ing”pattern
symmetricala%out hepkne peq’pendiculartnendbfeectdngtheaxis
14 I’?ACATNNO.1343
ofthecylinder).Thehsinitesulxteterminantinvolvingtermswith
evensubscriptscorrespondstosnantisymmetrtcalbuoltl.ingpattern.
Forbrevitythesesubdeterminantswillbereferred-toastheodd
deter@nantandthe evendeterminant,respectively.
Thefirst approximationii ~
Odddeterminant:2M2’+M3=0 (A14)
Evendeterminant:M2-I-M4=0 (Q5)
Thesecondapproximations
Odddeterminsmt:2Ml(M3+M5)+V~ =0. , (A16)
Evendeterminant:M2(M4+M6)+M4M6=0 (A17)
Theseequationsshowthatfora selectedved.ueofthecurvature
parsmeterZ theoritios2 buoklingstress of a cylinder depends
uponthe cirozmferential wavelength. Since a structure buoMesat
the lowest stress at whichinstability can occur, kx is mtnid-zed
withrespectothewavelengthby substituting values of B in%o
theequationsuntiltheminimum-~ canbeobtainedfroma plot
of kx againstp. Fora givenZ thelowerofthetwovalues
obtainedfromequations(Alk)and(A15)isthefirstapproximation
ofthecriticalbuoUingstressand,similarly,thelowerofthe
twuvaluesof kx obtainedfrom equations(M.6)and(JU7)iSthe
secondapproximationofthecriticalbucklingstress.
Figure2 presentsthetheoreticalcriticslstresscoefficients
forcylinderswfthclampededgesinaxialcompressionasobtained
fromthesecondapproximation,tigetherwiththeexactcurvefor,
thecaseofsimplysupportedges.Althoughthissolutionisan
upper-limitsolution,thesecondapproxipatfonrthecritical.
stresscoefficientofa cylinderwithciampededgesmustbevery
closetobeingexactforintermediatendlargevaluesof Z
bece.useitisahpostidenticalwiththeexactsolutionfora
cylinderwithshnplysupportedges,andthecriticalstressof
a cylinderwithclampededgescannotbelessthanthecritical.
stressfora cylinderwithsimplysupportedges.FQrvsluesof
Z approachingzero,theaocuracyofthesecondapproximations
hdicatedbythefactthatitcoincideswiththeknownexact
solution(~ = h)fora longflatplatewithclampededges.
,.
.
.
.
..
NACATNNO.1343 15
1.
2.
3*
k.
5*
6.
.
7*
.
9*
10l
11.
12,
REFERENCES
SouthweU,R. V.: Onthe GeneralTheoryof Elastic Stability.
Phil.Trans.Roy.Sot.(London),ser~A, vol. 213, 1914,-
Pp. 187-244,
TYmoshenko,S.:Theory&fElastfc”Stability.
Inc.,1936,ch.xx.
Fli@ge,W.: StatikundDynsmik~er Schalen.
(Berlin),1934,pp.189-199.
Mc&aw-HiUBookCo.,
JuliusSprhger ,
Dean,W.R.: OntheTheoryofElasticStability.Proc.Roy.
Sot.(London),ser.A, vol. 107,no.744,April1,19=~
pp.734-760.
Donnell,L.H.: ANew TheoryfortheBucklingofThinCylinders.
underAxialCompressione dBending.A.S.M.E.TrBnS.,
VOI..56,no.U, NOV. lg3k, pp. 795-806.
Lundquist,EugeneE.: StrengthTestsofThin-WalledDurelumin
CylindersinCompression.NACARep.No.473,1933.
Wilson,WilburM.,endNewmarkjNathanM.: TheStrengthof
ThinCylindricalShellsasColumns.En&.Exp.Sta.
Bull.No.275,Univ.121.,Feb.1933. ~
..-._.
Bellerstedt, W., &ndWagner,H.: Versuche.~~erd~eFeBti@it
diierunversteifterZylinderunterSchub-undLSn@c&ften
Luftfehrtforschung,13d.13,Nr.9,Sept.2Q,1936,
pp.309-312.
Iknemitau,SUnPmjendNojima,NobleM.: AxialCompressionTest
of’ThinCircularCylinders.Celif.Inst.Tech.Thesis,1939.
Robertson,Andrew: TheStrengthofTubularStruts.R.& M!
No.118’j,BritishA.R.C.,1929. ---——
.,
vonI&m&, Theodore,ndTeien, Hsue-Shen: TheBucklingof
ThinCylindrical.Shells underAxial Compression. Jour.
Aero. Sci.,vol. 8, no. 8, June1941, pp. 303-312.
Tsien, Hsue-Shen: A Theoryfor the Buckllngof Thin Shells,
Jour.Aero.Sci.,vol.9,no.10,Aug.1942,pp. 373.384,
*16 NACA~ No.1343
13.Donnell, L, E.: The StabilityofIsotropicorOrthotropic
CylindersorFlatorCurvedPanels,Ietweenandacross
Stiffeners,withAnyEdgeConditionsbetweenHingedand
Fixed,underAnyCombinationofCompressionandShear.
NACA~No. 918,1943.
14,Batdorf,S.%: A Simplified.MethodoflIlastic-Stability
AnalysisforThinCylindricalShells.-XI-Modified
EquilibriumEquation.NACA~No. 1342,1947.
15.Duncan,W.J,: ThePrinciplesoftheGalerkinMethod,
R.& M.No.18h8y,BritishAiR.C.,1938.
.
. . . .
“Perfect” strut “Perfect” cylinders
\/
Practical
struts W“itt=
various
initial
defects
-00
3
Lateral deflection .
/
Practical
cylinders
with
various
I
Max. load
1 for
~ perfect
3 cylinder
Max.load for
practical
! cylinder 1“
Lateral deflection
NATIONAL ADVISOW
CoNurrrEE m AmMJnCS
Figurel.- Effect of initial defects upon the maximum
compreBBi.ve loads of struts and cyllnders.
(From reference 13, fig. 18.)
‘“”r
10 ---!-
,[1
IC/“, ‘///, A’
I
--
I I I [ 1111
––– !%@ su~d edges
- Clompededges
+-LL-Lu
Figure 2.- Critical stress coefficients for thin-walled
I ,, circular cylinders subjected to axial compression,
. .
5
.
. . . .
10’
K?F
0
,E
10E
‘1
5ocy
160ch
/
I
Ih-rL641
M19xldfhnuk :
Eik+5idvltq% 4
Figure 3.- Colnparison of test re6ults with design
recommended for cylinders with clamped edges.
(Data from references 5 to 9.)
curves I
.c
,24 *
.20 \ h= L15CZ
}
for +~().75
%= GE+
.16
\
\
l [2
.08
.04
NATIONAL MIVIS~Y
n
CONMIVTEI~ AEMNAUTICS
800 1200 !600 2000 2400 2800 3200
Figure 4.- Coefficient for
compresfiive stresses of
long cylinders.
computing critical axial
intermediate length and
. . l
lo4’_
1(?_
k“%
,.2
10
/
I
I I I I Ill
f
/
500
/
1000
/
2000
3000
I I I I I II
F~gU~es..-.Critical stress coefficients implied by the
formul~ of Kanemitsu and Nojima (reference
thin-walled cylinders.
9) for m


Critical stress of thin-walled cylinders in axial compression

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