-A163 909 INTERFRANE DUCKLING OF ALUMINIUM ALLOY STIFFENED v/1PLATING(U) ADMIRALTY MARINN TECHNOLOGY ESTALISHNNNTDUNFERMLINE (SCOTLAND) J D CLARKE ET AL. OCT 65
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REPORT AmTE(W R 8 5 104
C iCOPY No 37.. ADMIRALTY RESEARCH ESTABLISHMENT
.. ARINE TECHNOLOGY)
I-I
INTERFRAME BUCKLING OF ALUMINIUM ALLOY
STIFFENED PLATING (U)
J. 0. ClIark eJ. W. Swan
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St. Leonard's HillDUNFERMLINE Fife KY11 5PW
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A"TE(S) R85104
INTERFRAME BUCKLING OF ALUMINIUM ALLOY
STIFFENED PLATING (UL)
BY
J D CLARKE AND J N SWAN
Summary (ULL):
Compression tests on five stiffened N8 aluminium alloy platescovering typical full scale warship scantlings are described. Thepanels were manufactured using normal shipyard production methodsto ensure typical initial distortion and residual stresses.
Maximum loads and post-buckling load/deflection results arecompared with theoretical predictions using the ARE computerprogram Nl06C.
AcceSsion For
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ARE Dunfermline
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DISTRIBUTION 3
INTRODUCTION .. ... ... ... ... ... ... 4
SEXPERIMENTAL DETAILS AND PROCEDURE 4-7
Details of Test Grillages .- 5... ... 4-5
Yield Stress Measurements 5-6
Residual Stress and Distortion Measurements 6
Loading Rig and Instrumentation 6-7
Test Procedure .. .. .. .. .. 7
RESULTS 7-9 -
Load/Deflection Behaviour ... ... ... 7-8 .
Plate Deformation 9 F
Plate Stresses ... 9
COMPARISON WITH THEORETICAL PREDICTIONS 9-10
RECOMMENDATIONS FOR FURTHER WORK ... ... ... 10
" CONCLUSIONS 11
ACKNOWLEDGEMENTS ... ... ... ... ... ... 11
REFERENCES 1-10 12
TABLES 1-5e ... .. .. ... ... 13-26
FIGURES 1-33
IF APPENDIX A ... ... ... ... ... ... ... 27-28
ABSTRACT CARDS
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INTERFRAME BUCKLING OF ALUMINIUM ALLOYSTIFFENED PLATING
INTRODUCTION
1. Although the only recent major use of aluminium alloys inBritish warship hulls has been the superstructure of the Type 21frigates, they have potential applications for advanced navalvessels eg SKATHs, hydrofoils and Surface Effect Ships. For this
reason it was considered that a series of measurements and testsshould be conducted to raise our understanding of the factorsaffecting the buckling of stiffened aluminium plating nearer toour current understanding of steel structures.
2. Four panels 3.7 m x 2.7 m with different plate and stiffenersizes were ordered from Yarrow Shipbuilders Ltd. Normal ship-building practice was requested for welding to ensure typicalimperfections. During construction extensive measurements toobtain in-built residual stresses were taken by ARE and aftermanufacture the panels were surveyed to obtain plate and stiffenerdistortion (M)A. Each panel was then cut into two and end andside supports were welded on to give eight compression test pspecimens each having three longitudinals and two full framespaces. Compression tests have now been carried out on five ofthese and the results are presented here and compared withtheoretical estimates.
3. The tests were similar to those previously reported forstiffened steel structures (2) except that the sides of thespecimens were supported only at the frames so that the failuremode was interframe buckling, and secondly the applied loading wasdisplacement controlled so that the post-buckling behaviour couldbe monitored. A secondary objective of the tests was to check thetheoretical estimates of post-buckling behaviour calculated by theARE program N106C (3).
4. In parallel with these tests theoretical and experimentalwork was carried out on the development of weld induced residualstresses and distortion at Cambridge University (4) and on platebuckling at Imperial College (5) and Cambridge University (6,7).
EXPERIMENTAL DETAILS AND PROCEDURE
Details of Test Grillaes
5. The stiffened panels from which the test grillages were takenwere fabricated in NS (5083) aluminium alloy. The first threepanels had identical longitudinal stiffeners (38 x 76 mm x1.65 kg/m T bars) with nominal plate thicknesses of 5, 8 and12 mm. The fourth panel had 8 mm thick plating with 78 x 8 mmflat bar longitudinal stiffeners. In all cases the transverseframes were 64 x 127 mm x 3.85 kg/m T bars at a spacing of 1000mm.
*( ) References on Page 12
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6. The panels were divided into two test grillages, each withdimensions as shown in Figure 1. This subdivision resulted ineach grillage containing two different plates joined by alongitudinal butt weld offset from the centreline. The ends ofthe grillages were reinforced with doubler plates to avoid localfailures and steel beams were used to distribute the load from thefour jacks at one end and the six load cells at the other. Thewidth of the plating along the outer edges was chosen to have anelastic buckling stress with one edge simply supported equal tothat for a full width panel simply supported on both edges. Underelastic interframe buckling the grillage can therefore be con- .sidered to represent the combined behaviour of three longitudinalstiffener/plate sections. In the absence of buckling, ie foruniform elastic or plastic stresses the total cross sectional arearepresents approximately 2.75 stiffener/plate combinations. An
::"estimated allowance for this difference has been made below when.comparing measurements with theoretical predictions. The error inthis estimate is thought to be small, but can be checked later
• using three dimensional elasto-plastic finite element analysis if*. considered necessary.
7. Average grillage dimensions and material properties aresummarised in Table 1, and Table 2 gives plate slendernessparameters and upper limits to the failure loads based on platebuckling with no allowance for stiffener deformations.
Yield Stress Measurements
8. Tensile stress/strain measurements were made on at least sixspecimens from each plate and group of stiffeners. In order toestablish the effect of strain rate and hold time a number ofthese were tested according to the recommendations of the DOE-TRRLPanel for Testing Procedures for Steel Models (8), ie at a strainrate of 300 pc/min with a hold of 2 mins at a strain of 0.005.Since it was found that testing at 3000 PE/min gave very similarresults most of the testing was carried out at this rate. Theaverage reduction in 0.2% proof stress at 300 pV/min below that at3000 p0/min was 2%. There were further load reductions during the2 min hold of 2.0% at a strain of 0.005 and 2.6% at 0.01.
9. Attempts were made to measure the compressive yield but thesewere not satisfactory because of buckling effects. CambridgeUniversity (6) have developed a technique using small coupons withPTFE anti-buckling supports. They report compressive values forN8 aluminium alloy but there are no corresponding tensile values.
*. In steel, comparisons (8) have given static yield values 3% higherin compression but the CP118 minimum specified proof stresses forN8 aluminium alloy are 5.6% lower in compression. In the absenceof any other information it has been assumed in the theoreticalanalysis reported below that there is no significant difference inthe yield behaviour in compression, but a total reduction of 4%has been allowed for hold time effects. This reduction has not[ been included in the values given in Table 1 or in the "stress/strain curves for the stiffeners shown in Figures 2 to 4.
It can be seen from the proof stress values in Table 1 that thevariation from plate to plate is much greater than the hold time
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correction. Within each plate the results are fairly consistentbut results for the stiffeners showed a large scatter as can beseen from Figures 2 to 4. In fact the average proof stress of87 MN/m 2 for the flat bar stiffener is below the minimumspecification value of 125 MN/m 2 for N8 alloy (9).
Residual Stress and Distortion Measurements
10. Full details of the measurements on the original panels aregiven in (1). Residual stresses were determined from accurate7 :- -- distance measurements between indents on the plate surface before
and after welcing. Average and maximum values are given inTable 1. The stiffeners all exhibited a combination of direct andbending stress but there was no systematic correlation between the
.'., magnitude of the bending stress and the stiffener distortion.
11. Plate deformations are given in Table 1 and stiffenerdistortions in Table 3. The stiffener distortions were measuredusing three different methods. The original panels were surveyedwith a displacement transducer mounted on a bar, and measurementswere also made using a swept laser beam as a reference plane asreported in (1). As a further check some measurements were alsomade after the test grillages had been manufactured using thelaser deflection method described in (10). All three sets ofvalues, where available, are listed in Table 3. It can be seenthat there are quite large differences in the results althoughthey show similar trends. The initial measurements were all madeon the plate side and some of the variation could be due to localdistortions in the plate surface caused by welding. The lasermeasurements on the final grillages were made on both the plate-side and on the stiffener flanges. The results again show the ..
same trends with differences of typically 0.5 mm between measure-ments on either side. An exceptionally large difference wasrecorded for stiffener 6 of grillage 4A which also has the largestdistortion measured on either side. In this ca'e there may havebeen a significant difference in the weld gap during fabrication. 4'
12. Table 3 also gives the values assumed in the theoreticalanalysis. Any apparently inconsistent values have been eliminatedbefore taking averages.
Loading Rig and Instrumentation
13. The test frame is illustrated in Figure 5. The grillageswere loaded by four 500 kN Dartec servohydraulic jacks operated indisplacement mode. These incorporate load cells, but as a checkon the longitudinal loading at the supports the load was alsomeasured at the reaction end using six load cells. The supportsat the frame ends were double bottle screws connected to barswhich enabled the top and bottom connections to slide longitudi- Lnally under load. The upper supports can be seen in Figure 6,similar supports were attached underneath.
14. For grillage 3A theoretical estimates of the failure load(Figure 30) suggested that this might exceed the 2000 kNavailable, and two 250 kN pressure controlled jacks were added to
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the rig for this test. When the load on the servohydraulic jacks.,- reached 600 kN these jacks were switched in. Although the failure r
load did not exceed 2000 kN they were useful as it was found thatthe pump pressure was low and the servohydraulic jacks could only
- provide a total load of 1680 kN.
". 15. The strain in the plating and longitudinals was monitoredusing foil resistance strain gauges distributed as shown inFigure 7. These were recorded via a Peekel strain gauge loggerfor subsequent computer analysis. Plate and stiffenerdeflections were monitored by ARE deflection transducers arrangedas shown in Figure 8. These were supported on a Dexion datumframe which has been removed in Figure 6 but can be seen in Figure .9a. The deflection signals were also recorded by the Peekel .logger.
16. An additional measure of plate deflection was obtained from atransducer which was scanned along the centreline of the plate
*' panels on the unwelded side (see track in Figure 8). The outputwas recorded on an X-Y plotter and subsequently digitised toproduce scaled plots.
Test Procedure
17. The height of the test grillages within the rig was adjustedwith the bottle screws until the centreline of the jacks and loadcells coincided with the calculated position of the neutral axis.The flexure plates were than clamped in position.
18. The load was applied by the four jacks operating together indisplacement mode so that the post buckling behaviour could bedetermined. At a number of points over the load/deflection curvethe strains and deflections were logged. The deflection was heldfor at least three minutes before logging to minimise short termcreep effects. At a number of load increments prior to bucklingthe load was returned to zero and the strains were logged so thatstresses could be determined from the elastic relaxation. Theplate deflection was scanned at each load point using the trans-ducer mentioned above.
.. 19. At the higher deflections care had to be taken to ensure thatthe grillage did not move the datum frame, and deflection trans-ducers which were nearing their limiting range were removed orreset. The tests were continued until the overall behaviour couldno longer be accurately monitored.
RESULTS
Load/Deflection Behaviour
20. The loading sequence and average deflections for eachgrillage are given in Tables 4a to 4e. The loads quoted are theaverage of the values given by the load cells and the jacks. Themaximum differences between this average and the jack load were2.6% at the maximum load and 3.8% at the maximum deflection. Thelongitudinal deflections quoted are the average values of the
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differences between the appropriate four pairs of transducersillustrated in Figure 8. 61 is the length change over the framespace nearest to the jacks, 62iS the corresponding value for theother frame space, and 63 is the change in overall length of thegrillage. In each case a contraction is shown as negative. As ingeneral the measuring points did not coincide with the neutralaxis a correction has been applied to allow for the effect ofrotation of the transverse frames.- The method used is describedin Appendix A...- :.
21. w, and w2 are average values of the vertical deflections ofthe three stiffeners in each frame space relative to their ends(positive upwards). The deflections of each stiffener are listedseparately in Tables 5a to 5e. The values for stiffenersdeflecting downwards are less accurate for large deflectionsbecause of the effect of stiffener tripping, which tended to occurnear the centre of the frame space, ie near the location of thevertical deflection transducer on the table.
22. The permanent deformation after the final load is illustratedin Figures 9 to 11. In many cases the maximum deflection did notcoincide with the location of the deflection transducer so theresults have not been presented here. In all cases the trippingonly became noticeable in the post-buckling region and did notappear to influence the maximum load.
23. Figure 12 shows the load/deflection curves across both framespaces for each grillage, and Figures 13 to 17 show the values foreach frame space separately. For grillage 3A there was a suddenjump in deflection just past the maximum load and the probablepath is shown dotted. In addition to the measurements taken afterthree minute holds, continuous load/overall grillage contractionplots were taken as an indication of the behaviour of the grillageduring the test. For other grillages the load scale was theoutput from one jack only and the results are not included here.For grillage 3A, which was the last grillage tested, the jacksignals were summed to give total load and the trace for the finalloading is illustrated in Figure 18. It can be seen that near themaximum load the reduction during the three minute hold isconsiderable. The dynamic jump does not occur at constantgrillage displacement because the frame acts as a spring and thereis an additional contraction as the stiffness of the grillagereduces. The stiffness of the frame can be determined from thedifference between the jack displacement and the overall grillagedisplacement. Results from all five tests fall within the bandshown in Figure 19. The non-linearity is thought to be partly dueto the initial closure of gaps, eg bolt clearances, in the rig.This plot can be used to define the limiting post-bucklingstiffness which can be controlled in the frame.
24. It can be seen from Tables 4a and 5a that the stiffeners ingrillage 1A did not behave similarly. In one frame space theouter stiffeners deformed vertically in opposite directionsproducing a considerable amount of twist in the structure. It wa7decided therefore to test the second grillage fabricated fromYarrows panel 1 as well. This grillage (IB) behaved much moreuniformly, but as can be seen from Figure 12 the load/shorteningcurves were very similar.
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Plate Deformation
25. Figures 20 to 23 show the plate deflection traces measuredalong the centreline of the plate panels on the unwelded side (seeFigure 8). It was not possible to obtain a complete trace at someof the higher loads because the deflection transducer was out ofrange. In some cases therefore the permanent deformation showncorresponds to higher load values than for the deformation shown
* under load. Tables 4b to 4e give the load levels corresponding tothe scan numbers.
26. A large part of the deflection, particularly in the case of I-
grillage 3A which has the thickest plate, is due to the stiffenerdistortion. It can be seen that the plating generally bucklesinto three half waves and that the initial deformation, particu-larly for grillage 1B has a three half wave component.
Plate Stresses
27. The longitudinal stresses derived from the elastic strainrelaxation is shown in Figures 24 to 26. Account was taken oftransverse strains using a Poisson's ratio of 0.3. In the platethe values are the average of the top and bottom gauges. At thestiffener positions the values were interpolated to give thestress at the centre of the plate.
28. The reason for the low values on one gauge for grillage 3A isnot known but could be due to partial failure of the adhesive.The average plate stresses have been derived by integrating thesevalues and are plotted against edge strain as a fraction of yieldvalues in Figure 27. These plots have been used to check the Lvalidity of the stress/strain curves assumed in the theoreticalanalysis discussed below.
COMPARISON WITH THEORETICAL PREDICTIONS
29. A number of calculations have been carried out using the _computer program N106C (3) to give an indication of the accuracyof this program in predicting maximum loads and post-bucklingbehaviour. A single stiffener and associated plating wasrepresented and symmetric behaviour was assumed beyond the midf;-ame positions. Each half frame length was subdivided into tenelements each with twenty fibres representing the stiffener andone variable width fibre representing the plating. Since measuredresidual stresses in the stiffeners were low and variable in signthey were ignored in this analysis.
30. Following the recommendation of Dier and Dowling (6) andMoflin and Dwight (6) it was assumed that the non dimensionalisedplate behaviour could be represented by that for steel with the
same a value 8 = b/t ,rJ. Appropriate curves were therefore
selected (via the parameter NEW in N106) which corresponded to ab/t value which for steel would give the same 8. This was notpossible for grillage lB since the equivalent b/t in steel (160) F
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was outside the range of values incorporated in the program. Fromthe residual stress and distortion measurements (1) it appearedthat the appropriate curves would be between the "nearly perfect"and "moderate" sets given in (3). Since the effective b/t valuesdid not coincide exactly with the values available calculationswere carried out for two NEW values which bracketed the range, ie.nearly perfect", low b/t and "moderate", high b/t. For grillagelB the best approximation available was to use the b/t = 90 curve vfor "severe" imperfections. This was slightly above the curveshown in Figure 27. Calculations were also carried out for thisgrillage using the Faulkner formula (NEW = 3). In each casecalculations were made using the average, and maximum vertical rstiffener distortions given in Table 3. The average values areprobably more representative as there will be an interaction inthe buckling behaviour of adjacent stiffeners.
31. Results of the calculations are compared with the measuredload/shortening behaviour in Figures 28 to 31. Except in the caseof grillage 3A where the calculated load/displacement curve has asharp peak, the estimates of maximum load bracket the measuredvalues. In each case however the post-buckling load carryingcapability is underestimated. One contribution to this differenceis the rotational restraint at the ends of the transverse frames -provided by the supports. The rotational stiffness of thesesupports was measured after the tests by applying a known momentand results are given in Figure 32. Over the initial part of therange the plot is linear with a stiffness of 2.0 x 107 Nmm/radianwhich corresponds to 1.4 x 107 Nmm/radian per stiffener. Figure 33shows the effect of rotational constraint on the bucklingbehaviour of grillage lB (NEW = 31, Average stiffener distortion).The measured value of 1.4 x 107 Nmm/radian gives a significantincrease in the post-buckling strength, but a value ofapproximately 5 x 107 Nmm/radian would be needed to match theobserved behaviour. A possible explanation is the effect of theshort end frames which are reinforced with doubler plates. Theseare not represented by the simple two half span model used forthese comparisons.
RECOMMENDATIONS FOR FURTHER WORK
32. It is important to establish the reason for the difference :nthe predicted and measured post-buckling behaviour. Some N101Ccalculations should therefore be carried out using a four spanrepresentation which includes the effect of the stiffer endsections. The effect of residual stresses in the stiffenersshould also be investigated to see if these are a possible rea:oenfor the over-estimate of the peak load for grillage 3A.
33. There are three remaining test grillages 2B, 3B and 4.These have welded edge supports but have not been strain kLauged.Consideration will be given to testing these with fully rotationalframe supports to eliminate this uncertainty in the comr.atincn.Attention will also be given to the accurate measurements oflongitudinal displacements, but it should be possible to nimplifythe instrumentation by omitting the strain measurements and someof the deflection measurements.
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CONCLUSIONS
34. One of the most significant facts to emerge from these testsis the variation in yield strength in material which is supposed Lto satisfy the N8 specification. If aluminium alloy is used in %future ships in critical locations where strength is important itwill be necessary to have adequate quality control.
35. It appears that in most cases the maximum strength ofaluminium alloy structures can be calculated using N106C with theplating behaviour represented by an equivalent steel b/t valuegiving the same B. It should be noted that the peak load forsharply varying load/deflection curves may be overestimated.
36. The post-buckling strength measured during the test washigher than that predicted by the simple two half frame finiteelement model used. This was partly due to the rotationalrestraint at the frame ends but could also be due to theadditional rotational restraint at the ends provided by the shortsections with doubler plates. It should be noted that sincedesign calculations are usually carried out using the two halfframe representation, there will be a similar underestimation ofthe post-buckling strength for stiffeners close to hard cornerswhere the frame rotation is constrained and in cases where thecollapse only occurs over one or two frame spaces.
37. In future tests care should be taken to minimise errors inlongitudinal displacements caused by frame rotation.
ACKNOWLEDGEMENTS
38. The authors would like to acknowledge the assistance of manyARE personnel in conducting these tests. In particularMr Somerville for the procurement of the panels and measurement ofimperfections, Mr Penman and Mr Aitcheson for tensile testing,distortion measurements, instrumentation and assistance with theanalyzis, Mr Hugill for some of the N106 calculations, andMr Adamson and Mr Duncan for carefully setting up the grillagesand their instrumentation in the test frame.
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REFERENCES
.. 1. Somerville W L. 'Welding Stresses and Distortions in N8(5083) Aluminium Alloy Stiffened Plates'. AMTE(S) ReportR85103, To be published.
2. Smith C S. 'Compressive Strength of Welded Steel ShipGrillages'. NCRE Report R611, May 1975.
3. Dow R S. 'Nl06C: A Computer Program for Elasto-Plastic,Large Deflection Buckling and Post-Buckling Behaviour ofPlane Frames and Stiffened Panels'. AMTE(S) R80726,July 1980.
4. Wong M P. 'Theoretical Analysis of Longitudinal ResidualStresses and Distortions in Welded Plates'. CambridgeUniversity Engineering Department Report NoCUED/D-Struct/TR86. 1981.
5. Dier A F and Dowling P J. 'Aluminium Plated Structures -
Final Report for AMTE'. Imperial College, Department ofCivil Engineering Report CESLIC-APS2, July 1981.
6. Moflin D S and Dwight J B. 'Tests on Individual AluminiumPlates under In-Plane Compression'. Cambridge UniversityED/D-Struct/TRl00, 1983.
7. Moflin D S. 'A Finite Strip Method for the Collapse Analysisof Compressed Plates and Plate Assemblages'. CambridgeUniversity ED/D-Struct/TRI01, 1983.
8. Recommended Standard Practices for Structural Testing ofSteel Models, TRRL Supplementary Report 254, 1977.
9. British Standard Code of Practice CPl18, The Structural Useof Aluminium.
10. Brown J C. 'A Laser Based Distortion Measuring System'. LAMTE(S) TM82450, August 1982.
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TABLE 5a
GRILLAGE 1A VERTICAL DEFLECTIONS OF STIFFENERS
+ve upwards
SCAN LOAD CHANNEL NO. (SEE FIGURE8L
NO. (kN) 116 117j 119 1123 1124 1126
Deflection relative to ends (mm)
10 542 -0.3 -0.2 0.0 0.0 -0.2 +0.313 648 +0.3 +0.1 +0.1 +0.1 -0.3 +0.515 722 +0.5 +0.3 -0.1 +0.2 -0.3 +0.717 834 +1.3 +1.2 -0.9 -1.1 -2.3 +0.818 836 +2.2 +2.0 -1.5 -6.5 -6.5 -0.2
-22-
UNLIMITED
. . .
UNLIINI T.
TABLE 5b
GRILLAGE 1B VERTICAL DEFLECTIONS OF STIFFENERS
+ve upwards
SCAN LOAD CHANNEL NO. (SEE FIGURE 8NO. (kN) 116 117 119 123 124 126
Deflections relative to ends (mm) .
1 02 22 +0.05 +0.14 +0.03 +0.11 +0.22 +0.063 62 +0.08 +0.07 +0.03 +0.23 +0.19 -0.054 119 +0.16 +0.06 +0.07 +0.37 +0.31 -0.195 0 +0.04 +0.01 +0.06 +0.02 -0.03 -0.016 172 +0.35 +0.13 +0.10 +0.47 +0.43 -0.377 0 +0.02 0.0 +0.05 +0.02 -0.05 +0.028 295 +0.77 +0.30 +0.07 +0.55 +0.65 -0.359 0 +0.02 -0.02 +0.04 +0.02 -0.07 -0.01
10 422 +1.16 +0.47 +0.22 +0.61 +0.79 -0.2111 0 +0.02 -0.03 +0.03 +0.01 -0.08 -0.0312 543 +1.57 +0.73 +0.38 +0.61 +0.92 -0.1313 0 +0.03 +0.04 +0.02 +0.03 -0.12 -0.0314 653 +2.01 +1.22 +0.71 +0.54 +0.93 +0.0515 0 +0.11 0.0 -0.06 -0.11 -0.19 +0.0516 0 +0.28 +0.01 -0.10 -0.05 -0.13 -0.1217 713 +2.83 +1.93 +0.95 +0.18 +0.66 -0.0218 787 +4.30 +3.39 +1.79 -0.81 +0.13 -0.2519 0 +1.20 +0.93 +0.32 -1.06 -0.81 +0.8520 785 +9.69 +7.33 +4.91 -3.17 -2.60 -2.2121 686 +18.31 +16.70 +14.78 -6.83 -8.10 -6.2822 0 +11.41 +10.36 +8.98 -5.95 -6.16 -2.7523 586 +23.77 +23.01 +21.82 -15.73 -13.74 -11.3824 553 +25.77 +26.62 +26.73 A A -14.2125 490 +32.61 +35.55 +36.08 A A -19.1326 0 +25.40 +28.80 +26.90 -15.50 -13.60 -13.00
A Transducer out of range
-23
UNLIMITED
- z.~ .. . . .. * ... *1
UNLIMITED
TABLE 5c
GRILLAGE 2A VERTICAL DEFLECTIONS OF STIFFENERS
+ve upwards
SCAN LOAD CHANNEL NO. (SEE FIGURE 8NO. (kN) 116 117 119 123 124 126
Deflections relative to ends (mm)
1 02 54 -0.01 +0.06 +0.06 +0.06 -0.03 +0.053 99 -0.09 +0.05 +0.10 +0.03 +0.05 +0.024 202 -0.03 +0.13 +0.20 +0.09 +0.13 +0.055 297 +0.05 +0.23 +0.24 +0.14 +0.20 +0.176 0 -0.08 +0.13 +0.11 -0.03 +0.20 +0.067 0 -0.15 +0.15 +0.14 0.0 +0.25 +0.078 455 +0.12 +0.35 +0.34 +0.24 +0.35 +0.079 585 +0.22 +0.47 +0.51 +0.34 +0.36 +0.13
' 0 741 +0.38 +0.54 +0.65 +0.52 +0.37 +0.26
11 0 0.0 +0.21 +0.22 -0.01 +0.33 +0.1112 883 +0.68 +0.43 +1.02 +0.84 +0.66 +0.7313 961 +0.95 +0.54 +1.48 +1.24 +0.85 +1.0414 0 +0.23 +0.29 +0.51 +0.31 +0.56 +0.3715 1023 +1.23 +0.75 +1.91 +1.82 +1.14 +1.2716 1063 +1.54 +0.90 +2.74 +2.87 +1.64 +1.6017 0 +0.82 +0.48 +1.69 +1.51 +1.05 +0.8318 1064 +2.50 +2.56 +4.43 +4.62 +2.56 +1.2819 1057 +2.28 +4.90 +8.41 +9.71 +4.62 +1.2320 0 +1.20 +3.08 +5.98 +6.44 +2.96 +0.8821 1034 +5.33 +9.23 +11.77 +10.52 +4.35 +0.0922 1012 +5.51 +12.01 +15.79 +14.19 +5.60 -0.5823 985 +8.67 +16.55 +19.76 +15.08 +5.09 -1.8024 927 +15.36 +22.70 " +13.96 +3.35 -3.4925 836 +22.43 A A +12.26 -0.69 -5.9626 0 +16.21 A A +9.87 +1.31 -2.21
A Transducer out of range
.24 -
S~~~~~UNLIMITED ~'. .
UNLIMITED
TABLE 5d
GRILLAGE 3A VERTICAL DEFLECTIONS OF STIFFENERS
+ve upwards
SCAN LOAD CHANNEL NO. (SEE FIGURE 8
NO. (kN) 116 117 119 123 124 126
Deflections relative to ends (mm)
1 0 :42 198 -0.08 -0.33 -0.20 +0.03 -0.21 -0.023 398 -0.14 -0.58 -0.33 +0.04 -0.27 +0.034 600 -0.20 -0.85 -0.44 +0.07 -0.30 +0.115 0 -0.05 -0.08 -0.16 0.0 -0.13 -0.146 996 -0.37 -1.56 -0.79 +0.13 -0.57 +0.197 0 -0.03 -0.11 -0.14 +0.08 -0.13 -0.158 1185 -0.43 -1.97 -1.03 +0.15 -0.72 +0.249 0 +0.01 -0.15 -0.24 +0.13 -0.18 -0.17
10 1377 -0.59 -2.39 -1.34 +0.30 -0.51 +0.6211 0 +0.12 -0.16 -0.21 +0.13 -0.13 -0.0912 1574 -0.85 -3.33 -1,93 +0.58 -0.35 +1.2913 0 +0.03 -0.59 -0.59 +0.28 -0.19 +0.0514 0 +0.08 -0.60 -0.59 +0.28 -0.21 +0.0915 1663 -1.44 -3.91 -2.85 +0.88 -0.11 +1.9616 0 -0.28 -1.38 -1.16 +0.49 -0.12 +0.4017 0 -0.28 -1.51 -1.22 +0.51 -0.18 +0.4518 1685 -10.33 -2.82 A +3.08 +2.32 +6.6019 842 A -4.74 A +12.34 +15.65 +19.9120 808 A A +13.94 +18.01 +22.06 121 648 At A A +15.19 +20.31 +24.97
1 22 0 . A +10.40 +13.57 +15.94
Transducer out of range
- 25 -
UNLIMITED
UNLI..:
TABLE 5e
GRILLAGE 4A VERTICAL DEFLECTIONS OF STIFFENERS
+ve upwards:..5 .. .. .
SCAN LOAD CHANNEL NO. (SEE FIGURE 8NO. (kN) 116 117 119 123 124 126
Deflections relative to ends (mm)
1 0 •2 96 -0.11 -0.07 -0.13 +0.15 +0.09 +0.203 166 -0.16 -0.14 -0.08 +0.23 +0.12 +0.354 254 -0.24 -0.19 -0.20 +0.34 +0.09 +0.445 0 +0.05 0.0 -0.20 +0.03 -0.01 +0.056 441 -0.61 -0.39 -0.30 +0.59 +0.15 +0.767 595 -1.30 -1.13 -1.38 +1.02 +0.42 +1.588 0 -0.40 -0.44 -0.87 +0.12 +0.20 +0.479 716 -3.00 -2.99 -2.40 +1.72 +1.12 +2.78
10 757 -12.5 -14.3 -12.2 +8.44 +6.15 +8.7311 0 -10.9 -9.4 -8.2 +4.77 +3.13 +4.2612 0 -10.8 -9.3 -7.2 +4.79 +3.39 +4.2913 572 -13.5 -12.0 -10.3 +7.00 +4.85 +6.8314 659 -13.2 -12.9 -10.9 +7.54 +5.35 +7.5615 0 -11.1 -9.5 -8.2 +4.91 +3.18 +4.2016 723 -16.9 -14.6 -12.1 +8.27 +6.06 +8.3017 619 -24.9 A -21.5 +16.6 +11.9 +12.118 577 A t , +19.0 +14.3 +14.419 535 A A A +21.7 +17.6 +17.620 488 A A A +25.4 +20.6 +20.621 426 A A A +30.5 +26.4 +26.822 386 A A A +33.5 +28.9 +29.323 0 A A A +27.0 +23.3 +22.0
A Transducer out of range
rk:
-- 26 -
4 UNLIMITED-:'.-.-
A °
AILIMITE
r= 4f A 7*
.A
C4 06
Cy, L4U
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FIGURE 1
UNLIMITEDAME () 850A... M T. E (S R851
r.. . .. . . . . . . .%. . . . . .. . . .
UNL Ii TED
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TEST FRAME -AFTER COMPLETION OF GRILLAGE 4A TESTAND REMOVAL OF DATUM FRAME
SL 841011 03
FIGURE 6
UNLIMITED
A MT E (S) R 8 510 4
UNLIMITED
0
I I I L I -
- C3r-L
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F I GU RE 7UNL IMI TEO A MTE (S) R 8510 4
-5 7 T 7 .... '* a..- * .. a
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zz
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* a) GRILLAGE 1B SHOWING L. M FRAME
b) GRILLAGE lB PERMANENT DEFORMATION AFTER FINAL LOAD
F IG U RE 9r UNLIMITED
ANMT E (S) R 85 10 4
q7' '
GRILLAGE 2A PERMANENT DEFORMATION AFTER FINAL LOAD
b)
SSL 83 1/9
FIGURE 10UNL IMI TED
A M TE (S) R 8 510 4
a) GRILLAGE 3A PERMNEAT DE, .,IATIlN1 AFTER FINAL LOAD
S L 8 4110 5 3
b) GRILLAGE 4A PERMANENT DEFORMATION AFTER FINAL LOAD
- SL 4 132/103
F FIG UR E 11UNLIMITED
A M TE (S) R 85 10 4
-o - -- -.--. r---- -
UNLIMITED
TOTAL CONTRACTION OF TWO CENTRAL FRAMES
2000
LOAD-; (KN)
3A
1500 2A
I
Ft 500
4 A
0 5 10 isFRAME 1-3 CONTRACTION (51 +&2) MM
F I GU RE 12
UNLIMITED A M TE (S) R 8 5104
UNL IMITED
LLi
-I-
Cp Lfn
F RE1
UNLIITEDAM E () R 510
I TED
LMs
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z7
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%EE
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LAJA
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0 C00 40
F I GUR E 17
U1L IfI ITED AMTE (S) R 85104
U4L IMITED -
GRILLAGE 3A- OVERALL GRILLAGE CONTRACTION
2 000* LOAD
(KN)
-00
1500
0
00
FYAINAC ODNG SQEC
0I 5 0i
1000AL GRLAE CNRCIN03m
FI U E 1
IN.11 E TE( )R851
I777
-. --. L- 34 TIM,-a-* .- - -T- T,--
L uONP.'
STIFFNESS OF FRAME AND JACK SUPPORTS
1 500
LOAD(K N
1000
0 2 4 6 8 10 12
JACK DEFLECTION MINUS OVERALL GRILLAGE CONTRACTION (mm)
FIGURE 19
UNJLIMITED A MT E (S) R 85 10 4
-7 .
UNLIMITED 5
GRILLAGE 18 PLATE DEFLECTION(ALONG CENTRELINE ON UNWELDED SIDE)
(RELATIVE TO PLATE ENDS)
0- INITIAL DEFORMATION
C3 CV
ID 0
oL 0
-LJ
-3 0
Lu 0:
S 0
* 4''- ~0- DEFORMATION UNDER LOAD SCAN Nos S
L- CS
C3 0
uCLu
LAJ miTRANSDuCERS OUT OF RANGE rfOt SUBSEQUENT SCANS
S 0S 0
Lis
FIUR 20
,*L 0 L- : .*&c - .
UNLIMITED ,'
-.. . ,
GRILLAGE 2R PLATE DEFLECTION,-... (ALONG CENTRELINE ON UNWELDEO SIDE)
(RELRTIVE TO PLATE ENDS)
0 INITIAL DEFORMATIONz (r)
a-
0 0
S0-J
rw 0
z" 0
0. ;' - ; : DFOIWT ION UNDER LORD SCN NOB ..."5 " Z (" " '
- IC
ccs
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Li.
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U I ERMA TION AMDER LOR104
°-"• Z (I) $CA NOS 5
L -
- cc= CMT (S is81/,'
" - - " - , - - ,f- ' -- - ' "., ..
4 . .
.JLILIMI
GRVILLAGE 3A PLATE DEFLECTION(ALONG CENTRELINE ON UNWELDED SIDE)
(RELATIVE TO PLATE ENDS)
0O INITIAL DEFORMATION
to-
C
ic-
C 0
1-- 0
0i 0
2: 0
0:
- 12
o) 0
U3 0
-LJ
TRANSDUCERS OUT OF RANGE FOR SUBSEQUENT SCANS
i~ 0
0- PERMANENT DEFORMATION SCAN NOS3 11z -is
I-
o3 0
UNIMTE
UNLIITE AMTE (S) R 8 51 0 4
*,** *** ,...- *** ~ ** *** ... .* * * * * .. * . *~ *~ ** * %
a UNLIMITED
GRILLAGE 4JR PLATE DEFLECTION(ALONG CENTRELINE ON UNNF'.DED SIDE)
(RELATIVE TO PLATE ENDS)
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oi 0
MI
DEOMTO NESA O
ccI 0
C.4.,I
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TRANSDUCERS OUT OF RANGE FOR SUBSEQUENT SCANS
S 0
0- PERMANENT DEFOR AT ION SCAN NOS 8
O 23
c-
Li
I Lu 0,. CD
FIG6U RE 23
UNLIMITED
AM TE (S) RB5104
* VWW -: -7.7 -
UNLIMITED
S r-4M.......
x EIE4+X*44(N
W
cr
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it UC/W SRS3IS3dO
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rr
UNLIMITED
zzzzzzz
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FIUR 26
UNIIE
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AVERAGE PLATE STRESS / EDGE STRAIN
0-7
0-6
3A (':37-0)
Obit2A (bt 62-0
0-40
0*3/
0/ L/t9
0-2
0 0-2 0.4 0-6 0.8 1.0 1-2
-. e
F I GU RE 27
UNL rIITED AM TE (S) R 8510 4
* . UNL 1111I TED
GRILLAGE l B -COMPARISON OF LUAD ISHORTENINGWITH THEORY MN106)
800
LOAD3(KN)
600
400-
-0- EXPERIMENTAL VALUES
200 THEORETICAL CURVES1 NEW= 3 (FAULKNER) AVERAGE DISTORTION
2 NEW= 3 MAXIMUM DISTORTION
3 NEW= 31 AVERAGE DISTORTION4 NEW: 31 MAXIMUM DISTORTION A
0 10 1FRAME 1-3 CONTRACTION (mm)
FIGURE 28
UNLItUTED ANMT E (S) R 8510 4
- _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __77
UNLI111TED
GRILLAGE 2A- COMPARISON OF LOAD I SHORTENINGWITH THEORY (N106)
2a
1000
-44
800
600
400
-0- EXPERIMENTAL VALUES
rE THEORETICAL CURVES
2001 NEW= 16 AVERAGE STIFFENER DISTORTION2 NEW =16 MAXIMUM STIFFENER DISTORTION
3 NEW =24 AVERAGE STI FF!NER DISTORTI ON
4 NEW = 24 MAXIMUM STIFFENER DISTORTION
0 51015r-
FRAME 1-3 CONTRACTION
FIGURE 29
UI~L II IIT ED A M T E (S) R 85 10 4
GRILLAGE 3A COMPAR.jii ii. LOA4 upri~oootWITH THEORY (N106)
2 PEAK :2113KN
32000
4LOADIKN)
1500
0
0-*
500-394-0- EXPERIMENTAL VALUES
THEORETICAL CURVES
1 NEW = 13 AVERAGE STIFFENER DISTORTION
2 NEW= 13 MAXIMUM STIFFENER DISTORTION3 NEW: 21 AVERAGE STI FFENER DISTORTION4 NEW 21 MAXIMUM STIFFENER DISTORTION
0510 is
FRAME 1-3 CONTRACTION
F I GU RE 30UNI IIITED AMTE (S R P8 5104 U
- v
GRILLAGE 4A -COMPARISON OF IL. SHORTENING* WITH THEORY (N106)
800 32
LO AD(KN)
600
400
200 -- EXPERIM EN TA L VALUESL
THEORETICAL CURVES
1 NEW= 16 AVERAGE STIFFENER DISTORTION2 NEW= 16 MAXIMUM STIFFENER DISTORTION3 NEW= 23 AVERAGE STIFFENER DISTORTION4. NEW= 23 MAXIMUM STIFFENER DISTORTION
0 s 10 15FRAME 1-3 CONTRACTION (m m)
F I GU RE 31UNLIMlITED AMTE (S) R B5 104
UNL INII TED
ROTATIONAL STIFFNESS OF FRAME SUPPORTS
00 i6 4. Q
,Nmm/IRADIAN
APPLIED /0
-' MOMENT/
15 (N mm) 1
+/0
1.0
0
+0+
05 00
0/
00.0O0. 0.15ANGULAR ROTATION (RADIANS)
FIGURE 32UNLIIIITED AM TE () R 85104 F
-. ~~-.e--.--r
GRILLAGE JB- COMPARISON OF LOAD SHORTENING WITH THEORYC ~.>iEFFECT OF ROTATIONAL RESTRAINT AT FRAME ENDS
LOAD(K N) Re 5 10 Nmm IRAO 1
600
400
Re 0
200 - -EXPERIMENTAL VALUES
05 10 15F RA ME 1-3 CONITRACTION (mm)
FIGURE 33
UrJLINITED AMTE (S) R 85104
UNLIMITED
:'*:• . *APPENDIX A
CORRECTION OF LONGITUDINAL DISPLACEMENTS FORROTATION OF TRANSVERSE FRAMES
Figure Al shows the arrangement adopted for the measurementof longitudinal displacements. In order to avoid errors due tocontact between the transducer and the plating when buckling andvertical movement of the grillage occurred it was found necessaryto raise the pointer above the neutral axis for later tests. Evenin the initial tests the small vertical movement of the framesrelative to the transducer supports was sufficient to introduce anerror in the longitudinal measurement.
If the point is a distance h above the neutral axis rotationof the frame by an angle 0 introduces an error h sin 0.
If the ends of the frames were simply supported and thestiffener exhibited constant curvature the radius of curvature isgiven by
R L (for w << L)
8W
and the angle at the ends is given by
Sin e = Ll2R
where L is the length of the frame
and w is the vertical deflection at the centre of thestiffener (+ve upwards)
Hence the correction due to this rotation is given by
AL = h w
The fractional error in this correction associated withassuming w - L is equal to (2w/L)2 which is less than 1% for themaximum vertical deflection measured (35 mm).
The ends of the stiffeners are not simply supported but areinfluenced by the deflection in the adjacent frames. For thecentral frame it is assumed that if w, = -w2 the rotation will beas assumed above, but if w1 = w 2 the rotation will be zero
For w A w2 a linear relation between these two extremes isassumed giving corrections of:
S(W - w2 ) for the first frame space
and +2h - w2 ) for the second frame space.
-27-
UNLIMITED
I "
UNLIMT
The deformation of the outer frame spaces with doubler platesis small and is assumed to be negligible so that using the sameassumption the corrections for the outer frames are
2 h w,- for the first frame space
L2 h w2
and - for the second frame space.
giving total corrections of
- _ 2 hL (2wl - w2) for the first frame space
2 hand -- (2w, - w 2) for the second frame space.-''% L
The correction over both frame spaces is given by
2 hL (w + w )
which in most cases is less since w1 and w 2 tend to have oppositesigns.
These corrections have been applied to the measured longi-tudinal end shortening using the mean vertical displacements ofthe three stiffeners in each case.
-28 -
UNLIMITED
, .0 ° -.'
............
. . . . . . .. ... .... ... .. . . . . . . . . . . . . . . . . . . . . . . . . .. . . ... -. ...
UtILIMI ItJ
MEASUREMENT OF LONGITUDINAL DISPLACEMENTS
DE FLECTIONTRANSDUCER
.- * 7
h
STi- -NEUTRAL AXIS
FIGURE Al
UN~LINITED AMTE (S) R 85104
77.......7...............
* ~DOCWIENT CONTROL SMET ~I~O(Notse an ccsplatico overleaf)
UNLIMITEDOverall security classification of sheet ......................................................................
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1. DRIC Reference (if known) 2. Originator's Reference 3. Agency Reference 4. Report SecurityClassification
AMTE(S) R85104 UNLIMITED
(if known)
Admiralty Research Establishment DunfermlineSt Leonard's Hill, Dunfermline, Fife, KYll 5PW
Sa. Sponsoring Agency's 6a. Sponsoring Agency (Contract Authority) Name end LocationCode (if known)
7. TitleINTERFRAME BUCKLING OF ALUMINIUM ALLOY STIFFENED PLATING (UL)
7a. Title in Foreign Language (in the case of translations)
7b. Presented at (for conference papers). Title, place and date of conference
8. Author lSurnae.initials ga. Author 2 9b. Authors 3. 4... 10. Date pp ref
Clarke, J D Swan, J W 10.1985 66 10
11. Contract Number 12. Period 13. Project !4. Other References
15. Distribution statement
Distribution controlled by MOD Technical Policy Authority, Research Area Leader 1,CS, ARE Dunfermline
Descriptors (or keywords)
Aluminium, buckling, strength, test, compression, stiffened plate, interframe,-. F. :.,.yield ..
Summary (UL)
-- Compression tests on five stiffened N8 aluminium alloy plates covering typicalfull scale warship scantlings are described. The panels were manufactured usingnormal shipyard production methods to ensure typical initial distortion and residualstresses.
Maximum loads and post-buckling load/deflection results are compared withtheoretical predictions using the ARE computer program N1O6C.
'.77777r,, = Z 7 z.r" .7. .7.7...
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