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Department of the NavyNaval Air Systems CommandCode AIR-52032C 83 09n 09 0Washington, D.C. 20361 7 UJ O6r
OTIC FILE GORY
SLCURITY CLASSIFICATION OF THIS PAGE (non Data Entered),
PAGE READ INSTRUCTIONSaEPORT DOCUMENTAON BEFORE COMPLETING FORM1. REPORT NUMBER 2. GOVT ACCESSION NO. 3, RECIPIENT'S CATALOG NUMBER
NOl0019-81 -C-0184 , 84. TITLE (and Subtitle) 5. TYPE OF REPORT & PERIOD COVERED
Processing Science for AS/3501-6 Carbon/Epoxy Final Report for PeriodComposites 1 Aug 81 - 30 Apr 83
6. PERFOPMING OG. REPORT NUMBER
7. AUTHOR(S) S. CONTRACT OR GRANT NUMBER(s)
J. F. Carpenter NO0019-81-C-01849. PERFORMING ORGANIZATION NAME AND ADDRESS 10. PROGRAM ELEMENT. PROJECT, TASK
AREA & WORK UNIT NUMBERS
McDonnell Aircraft CompanyMcDonnell Douglas CorporationPO Box 516, St. Louis, MO 63166
II. CONTROLLING OFFICE NAME AND ADDRESS 12. REPORT DATE
Dear ;,ment of the Navy 8 September 1983Naval Air Systems Command 13. NUMBER OF PAGES
Washington, DC 20361 Code: AIR 5304 4414. MONITORING AGENCY NAME & ADDRESS(If difftrent from Controlling Office) IS. SECURITY CLASS. (of this report)
See Block 11 Unclassified15s. DECLASSIFICATION/DOWNGRADING
SCHEDULE
16. DISTRIBUTION STATEMENT (of this Report)
Approved for public release, distribution unlimited.
17. DISTRIBUTION STATEMENT (of the abstract entered In Block 20. it different from Report)
1$. SUPPLEMENTARY NOTES
19. KEY WORDS (Continue on revers, side it necessary and identify by block number)
Composite, Carbon/EpoxyPhysiochemical CharacterizationModels for Resin Curing ProcessesRheology of ResinsThermosetting Resins
.2q. ABSTRACT (Continue en reverse side ti necessary and Identify by block number)
S- 'The objectives of this program were to investigate the curing behavior ofthermosetting matrix resins under conditions relatible to the processing para-meters of the companion carbon/epoxy prepreg material and to investigate theinterrelationships of volatiles transport, physiochemical and mechanicalproperties.-
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MCDOaN.VLL AIRCRWAFT COMPRANY
FORWARD
This f inal report covers the work performed from 1 August1981 to 30 April 1983 under Contract N00019-81-C-0184 by theMaterial and Process Development Department of the McDonnell Air-craft Company, McDonnell Douglas Corporation, St. Louis, Missouri.The program was administered under the direction of the Naval AirSystems Command by Mr. Maxwell Stander and previously by Mr.Richard L. Dempsey.
The program was managed at McDonnell by Mr. R. J. Juergens,with Dr. J. F. Carpenter as Principal Investigator. Majorcontributors were Messrs. T. T. Bartels, G. T. Stillwell and C. E.Wilson of the McDonnell Materials Laboratory.
iAccession ForVTIS GRA&T
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TABLE OF CONTENTS
SECTION PAUE
1 INTRODUCTION AND SUMMARY...................1
2 PROGRAM4 PLAN...............................2
3 TECHNICAL RESULTS....................5
3.1 Phase I -Develop a Model for Resin Rheologyand Flow..........................5
3.2 Phase II -Correlate*Physiochemicai Propertieswith Resin Rheology .. ................ 2
3.3 Phase III - Determine Resin Volatile Effects 283.4 Phase IV - Relate Resin and Laminate
Properties......................31
4 SIGNIFICANT RESULTS............. . . . . 33
5 RECOM4MENDATIONS........................34
R.EFER.ENCES...........................35
DISTRIBUTION LIST..............................37
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LIST OF ILLUSTRATIONS
FIGURE PAGE
1 ProgrPam.la. .. .. .. ............ 2
2 Isothermal Rheograms in Replicate for 3 501-6 Resin,
4--.Batch B-i @ 135C . .................. 7
3 Computer Drawn Isothermal Rheogram for 3501-6Resin, Batch B-i @ 135C . ............... 10
4 Computer Drawn Family of Isothermal Rheograms for3501-6 Resin, Batch B-i @ 125, 130, 135, and 140*C .11
5 Rheograms for 3501-6, Batch B-i, for DifferentHeating Rates ..................... 12
6 Computer Drawn Dynamic Heating Rheogram for 3501-6
Batch B-i @ 10 C/MIN...................15
7 Computer Drawn Cure Cycle Rheogram for 3501-6,Batch B-i . .. .. ... :. .. .. ... .. .. .. 16
8 Computer Drawn Isothermal Rheograis for 3501-6Resin Comparing Batches B-1, B-2, and B-3 @ 135*C . 17
9 Computer Drawn Dynamic Heating Rheograms for 3501-6Resin Comparing Batches B-1, B-2, and B-3 @1 0 C/MIN........................18
10 Computer Drawn Cure Cycle Rheograms for 3 501-6Resin Comparing Batches B-1. B-2, and B-3 ....... 18
~.11 DSC Thermogramn fcr 3501-6 Resin, Batch B-i @V10
0 C/MIN. ....................... 21
12 DSC Thermogram for 3501-6, Batch B-i @ l.25*C/MIN . 25
13 DSC Thermogram for 3501-6, Batch B-i @ 2-.5C/MIN .. 26
14 DSC Thermogram for 3501-6, Batch B-1 @ 5*C/MIN . . . 26
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LIST OF TABLES
TABLE PAGE
1 CONSTANTS FOR ISOTHERMAL VISCOSITY EQUATION,BATCH B-I ........... ..................... 8
2 RHEOMETRICS DATA FOR VARIED LINEAR HEATING RATES . 13
3 CORRELATION OF LINEAR HEATING RATE DATA ...... . 13
4 BATCH PARAMETERS FOR MATHEMATICAL MODEL ...... . 16
5 FLOW NUMBERS FOR 3501-6 NEAT RESIN BATCHES .... .. 19
6 COMPARISON OF EVENT TEMPERATURES FOR VISCOSITY(RDS) AND THERMAL (DSC) DATA FOR LINEAR HEATINGRATES ......... ...................... 22
7 DSC-2 KINETIC FACTORS FOR 3501-6 RESIN, BATCH B-i . 24
8 THERMAL DATA FOR COMPLETE CURE OF 3501-6,BATCH B-1 ....... ................... .27
9 PHYSIOCHEMICAL PROPERTIES ... ............. 28
10 VARIATION OF RESIN BUBBLE SIZE WITH DISTANCE FROMTHE SURFACE ........ .................... 29
11 DSC EVALUATION OF CHEMICAL BLOWING AGENTS,@ 50C/MIN ..................... 30
12 LAMINATE MECHANICAL PROPERTIES ... .......... . 31
13 LAMINATE PHYSICAL PROPERTIES ... ............ 32
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_ MCD@NNELL AIRCRAFTr COMUPANIV
LIST OF ABBREVIATIONS
RDS Rheometrics Dynamic Spectrometer
CPS Centipoise
HPLC High Performance Liquid Chromatography
KCPS Thousand Centipoise
GPC Ge] Permeation Chromatography
DSC Differential Scanning Calorimetry
TADS Thermal Analysis Data Station
phr Parts per Hundred Resin
T Temperature
Tgel Temperature at Gel
Tos Reaction Onset Temperature
Texo Reaction Exotherm Temperature
TCR Complete Reaction Temperature
ri Viscosity
"no Zero Time Viscosity
it Time
T Tgel Time to Gel
G' Storage Modulus
Got Loss Modulus
AHH Enthalpy
.(Dynamic Frequency
M Torque
* Linear Heating Rate
k Kinetic Factor
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1.0 INTRODUCTION AND SUMMARY
The processing parameters currently used in the fabricationof carbon/epoxy composite structures have essentially been derivedfrom experience, as a result of extensive iterative testing. Thepurpose of this program was to develop a generic, and in-depth,scientific understanding of the effect of processing parameters onthe behavior of prepreg resin.
Specifically the objectives of the program were to investi-gate the curing behavior of the neat resin under conditionsrelatable to the processing parameters of the companion carbon/epoxy prepreg material and to investigate the inter-relationshipsof volatiles transport, physiochemical and mechanical properties.
These objectives wece accomplished by the development of a* mathematical model for the rheclogy and complete cure of the
3501-6 resin system. The first part of the model is an expressionwhich describes 3501-6 resin viscosity as a function of the timeand temperature of cure. The model was used to compare the totalflow behavior of the resin under varied conditions of cure and thebehavior of three batches of resin in wbich tne major epoxide com-ponent had different starting viscosities.
A computer program was written which uses the parameters ofthe mathematical model to plot viscosity profiles and calculatethe total flow of 3501-6 resin for any desired combination of timeand temperature of cure.
The mathematical model was expanded to include an expressionfor the time to complete cure as a function of cure temperature.
The model is applicable to other thermosetting resins and can' be used to establish cure cycle conditions fromn a minimum of
- experimental determinations. It is also envisioned as being a
useful methodology for the real-time control of automaticprocessing equipment (i.e. autoclave control).
Variations in the resin rheology of three special batches ofresin were compared, as were differences in chemical compositionof the prepreg and mechanical properties of the laminates. Theeffects of volatiles on resin processing were also investigated.
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2.0 PROGRAM PLAN
The technical approach is given in the Program Plan, Figure1. The rheology of 3 501-6 resin was determined over a broad rangeof varied heating conditions. A model for the curing behavior ofthe neat resin was developed through the derivation of a mathemati-cal expression which relates the resin viscosity to the time andtemperature of resin cure. Physiochemical properties were deter-
z mined arnd the thermal analysis data was used to expand the curingbehavior model to include a mathematical expression which relatesthe time required for complete cure to temperature. A computerprogram was written which uses the parameters of the mathematicalmodel to plot visco~sity profiles for any desired cure cycle.
Phase~Deiv Mode Testle Vaidt ofe ei ielg
0 3 Resin Batches e Phsomet ic: Dynamic 0 Viscosity ProfilesSpectrometer 0 Total Flow
Phae N. Curreat Physladwsodcl Prepds 1 el el
Thifermtal SroannigCeia roete rwest ei k
CaOnM"t 0 Infrared0 Atomic Ahsorption
Phmnveluoda Resin D.d. fetrieMtoso
0 Types0 Transport
Pe VPopert Daae-d reeesirpete
= UI" 1. P IPIWQ*WWOWWEL m -OW CPm 3@
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j Three batches of 3501-6 resin were compared. These batcheshad been formulated to contain tetraglycidyl methylenedianiline(TGMDA) having three different starting viscosities. The types ofresin volatiles and their transport mechanisms were investigated.As a last step, the resin properties determined in this programwere compared with previously published data for their compositelaminate properties.
PHASE I - DEVELOP A MODEL FOR RESIN RHEOLOGY AND FLOW
The objective of this phase was to develop a rheologicalmodel which represents the behavior of 3501-6 resin under condi-tions relatable to the processing parameters of the companioncarbon/epoxide prepreg. This objective was accomplished bydetermining the rheological characteristics of the resin using theRDS-7700 rheometrics dynamic spectrometer. During resin heatingthe viscosity was measured for four different isothermal con-ditions, three dynamic heating conditions, and a typical curecycle. A mathematical expression which relates the viscosity tothe time of heating was written for each of the four isothermalconditions. The four equations w9..- 'hen used to derive a generalexpression which relates viscos.- , the time and temperature ofcure for all isothermal conditions.
It was found that the general expression for isothermal vis-cosity change could be converted to an expression applicable todynamic heating (varied linear heating rates' by integrating thetime dependent term. Then, together, the equations for isothermaland dynamic heating constitute a set of equations which predictsthe viscosity for any time/temperature sequence of resin cure.
This set of equations is proposed as a mathematical model forresin rheology during cure. A computer/plotter was programmed toinclude the equations of the model, and viscosity profiles areautomatically produced for any combination of cure cycle
parameters.
The rheologies of three batches of 3501-6 resins werecompared. These batches were made by standard processing and withnormal component concentrations, but contained TGMDA with variedstarting viscosities.
P ASE II - CORRELATE PHYSIOCHEMICAL PROPERTIES WITH RESIN RHEOLOGY
The objective of this phase was to determine relationshipsbetween physiochemical properties and resin rheology and to deter-mine the applicability of physiochemical data to an expanded
V curing bc.iavior model. Differential scanning calorimetry (DSC)was used for thermal analysis of the resin system and the chemicalcharacteristics w re determined using infrared, liquid chromatogra-phy and atomic absorption. The physiochemical properties werecompared with the variations in rheology for the three resin
I batches tested.
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The DSC data was used to expand the model for resin curingbehavior to include a mathematical expression which relatesCemperature to the time required for complete cure.
PHASE III - DETERMINE RESIN VOLATILES EFFECTS
The objective of this phase was to characterize resinvolatiles and explore techniques useful to modeling theirformation and migration during cure. As-received resins wereinitially compared under ambient pressure cure and vacuum cureconditions for the types and amounts of volatiles. Bubble sizeand distribution was compared using a Bausch and Lomb imageanalyzer. Later, prepreg materials were compared for outgassingcharacteristics by submerging the specimens in silicone oil andobserving bubble formation during resin cure.
A means was developed to introduce known amounts of bothcondensible and non-condensible volatiles using a method that isapplicable to the study of resin volatiles transport in neat resinand the characterization of voids in cured composites.
PHASE IV - RELATE RESIN AND LAMINATE PROPERTIES
The objective of this phase was to determine whether the neatresin properties determined in this program exhibited any corre-lation with previously determined laminate properties. The objec-tives were achieved by comparing laminate physical and mechanicalproperties, determined earlier in Reference (1), with the rheologi-cal and physiochemical properties determined in this program. Theresin batches compared differed only in the viscosity of the baseepoxide (TGMDA) used in their formulation.
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M 3.0 TECHNICAL RESULTS AND DISCUSSION
Three batches of 3501-6 resin were s'..ected for the program.Thae differences among the three batche.. of resin is in thestarting viscosity of the major epoxide component, tetraglycidylmethylenedianiline (TGMDA):
BATCH TGMDA VISCOSITY (CPS)B-I 10,700B-2 14,000B-3 18,000
All batches were formulated by tne supplier's standard pro-cessing procedure and all were formulated to contain the followingstandard concentrations of starting components:
TOTALCOMPONENT PERCENT (WT)
Tegraglycidyl Methylenedianiline 56.5Alicyclic Diepoxy Carboxylate 9.0Epoxy Cresol Novalac 8.54,4' Diaminodiphenyl Sulfone 25.0Boron Trifluoride Amine Complex 1.1
In earlier work, these batches gave different behavioralresponse to processing, Reference (1).
3.1 PHASE I - DEVELOP A MODEL FOR RESIN RHEOLOGY AND FLOW - Inthis phase resin flow measurements were made under varied curemodes and a mathematical model was developed which describes3501-6 resin viscosity and flow as a function of the time andtemperature of processing. The effects of varied cure cycles onresin flow was demonstrated. The model was used to compare the
j rheologies of three batches of resin having varied startingviscosities for the major epoxide component. The flow propertiesof the three batches were shown to be quite similar.
Instrumental Technique - The Rheometrics RDS-7700 instrumentwas used for this program. It is a dynamic, oscillatory rheometercapable of measurements over a wide range of temperatures. It can
be programmed for any combination of linear heating rates,isothermal holds, and simulated cure cycle conditions. Itprovides continuous printout and data plots for selectedproperties, including dynamic viscosity (n), loss modulus (G") andstorage modulus (G'), together with time (t), temperature (T), andtorque (M).
The rheological properties for the neat resins were measured= under the following conditions:
Starting Temperature = 500CStrain = 50%Shear Rate = 10 rads/secPlate Gap = 0.5mm + 0.01mm
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All samples were preconditioned at room temperature by pres-sing about 1 gram of resin between two pieces of non-porous Tefloncloth (CHR-6TB) to produce a resin wafer about 5mm thick. Thewafers were exposed in a vacuum desiccator for 24 hr and removedjust prior to running the rheograms. The sample preconditioningwas used to remove moisture and any other vclatiles that mightcause erratic variations in rheology.
The RDS-7700 instrument was used to gener, e plots of viscos-ity vs. time for the temperature conditions o. the tests. Theseviscosity profile data were used to calculate a measure of thetotal flow achieved for the varied time/temperature parameters ofthe tests.
The reciprocal of viscosity is termed "fluidity". Fluidityintegrated as a function of time was taken as a measure of total
Rflow under the pressure conditions of the rheometrics instrument.
Isothermal Heating Conditions - The change in viscosity as afunction of time and temperature was first studied for the iso-thermal case.
Under isothermal conditions the change in viscosity with timecan be expressed by the equation:
logn = k(t) + logno (1)
where: n = Time Dependent Viscosity (poise)o = Zero Time Viscosity (Constant for Isothermal Runs)k = Kinetiv Factor
Et = Time (minutes)
This model for the isothermal case has been proposed byseveral investigators, References (2-6). Figure 2 shows a plot offour isothermal runs for viscosity as a function of time at 135 C.A linear regression line for logrn vs. time is also shown. Theminimum viscosity was reached in an average time of 6 minutes.
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Replicate runs were made for Batch B-I at four differenttemperatures. The values calculated for the constants k and logno at each temperature are given in Table 1. The kinetic factor(k) decreases with decreasing temperature and zero-time viscosity(no) increases with decreasing temperature.
Table 1. Constants for Isothermal Viscosity Equation, Batch B-1log il= k(t)+ log 101
Temperature k log u/o Corral(OC) Coef tr2)
140 0.0554 - 0.0517 0.982
135 0.0401 0.1193 0.985
130 0.0318 0.2856 0.988
125 0.0247 0.4001 0.988
OP33aMU.SI: The kinetic factor (k) can be expressed as a function oftemperature (T, *K) by an expression similar to that derived inReference (7).
c 10Al/Tk T2 (2)
* 'For Batch B-i, log (kT2 ) vs. l/T is solved by linear regression togive:
2log 4140.2 + 13.9885 (3)lg TT
r= 0.994 (correlation coef.)
Thus:
k = -74 i01 [• 0 - 4 1 4 0 / T ]
kT9.74x 10 [2 (4)
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In a like manner, the isothermal values for log no (Equation1) for Batch B-i was reduced by assuming:
710 C2 10 A 2/T (5.T 2
The linear regression of log (no T2 ) vs. l/T gave the values of
the constants as:
C2 = 8.81 x 10 - 7 (6)
A2 = 4645.8
with a correlation coefficient of r2 = 0.989.
Thus, a mathematical model for isothermal resin flow is givenby the following expression, which relates viscosity to the timeand temperature of processing:
logn = cl [l lT (t) + log 1OA2/ (7)
For Batch B-1 the expression is:
log-7 13[1f 4 14 0 .2/T (t) + g8.81 x 10 - 7 1 4 (8)
A desktop computer, interfaced with a digital X-Y plotter,was programed to solve Equation (7) and automatically plotviscosity as a function of time/temperature.
A computer generated plot for the isothermal viscosity pro-file of Batch B-l, at 135*C, is shown in Figure 3. The computerprogram provides for the superimposition of experimental data.Each point shown on the rheogram in Figure 3 represents an averageviscosity value for replicate determinations. Figure 4 shows acomputer drawn family of curves for isothermal determinations at125, 130, 135, and 140*C.
k
*UCDON WELL DOUILAS COPOMtRAT
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4 11003 Experimental
3
LogVismoety
Poise
0100 04 0 2 ;
Tim- min OaMuse
Figure 3.Computer Drawn Isothermal Rheogramn for 3501-6 Resin, Batch B-1 @1350C
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1400 13135*C
4 8100
3
* LogViscosity
Poles
Time - in P3IS
Figure 4. Computer Drawn Family of Isothermal Rheogramsfor 3501-4 Resin, Batch B-1 @ 125, 130, 135 and 1400C
Dynamic Heating Conditions - Dynamic runs were made for thethree test batches of 3501-6 at linear heating rates of 1, 2, and4*C/min. Typical rheograms for Batch B-I at the three differentheating rates are shown in Figure 5. Data for critical points(minimum viscosity and gel) of the curves for Batches B-1, B-2,and B-3 are given in Table 2. As expected, the faster the heat-uprate, the lower the minimum viscosity and the shorter the time togel.
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1341 CImln 20CImin 10C/min
SViscesity 12Flo w=5.6 Flow =6.4 Flow 1 72Poise
I1 _.00
10
0 -04 6 o10 2
Time - minGP33001S
Figure 5. Rheograms for 350146 Batch, 8.1 for Different Heating Rates
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Table 2. Rheometric's Data for Varied Linear Heating Rates
Minimum Temperature atBatch Heating Rate, 0 Viscosity, 1 Temperature, T (C) Time to Gel', tool Gel Point,
Number (OCimin) (Poise) at Minimum ui (min)•T,,,(°C)
1 7.2 110 111 167
B-1 2 4.7 120 63 184
4 2.7 130 36 194
1 6.8 112 115 171
B-2 2 5.7 126 63 186
4 3.2 136 36 202
1 8.6 114 112 168
B-3 2 5.8 122 64 186
4 3.2 140 36 206
1.0o0 poise GP334M17
The temperatures for minimum viscosity and ge- can bepredicted for other linear heating rates by the equations given inTable 3. Calculation of these temperatures provides usefulinformation; however, what is needed is a means of using the dataobtained from a minimum number of isothermal runs to predict theviscosity profiles obtained under the dynamic conditions of variedlinear heating rates.
Table 3. Correlation of Linear Heating Rats Data
Batch Equation Relating Temperature Equation Relating Temperature
Number and Heating Rate for Minimum and Heating Rate for ResinViscosity Gel"
4,535 log 4,451
-1 log € T(OK +11.8465 T(*K) +10.4,45
r2 0.999 r2 =0.982
390024,0959B-2 log = 3 +10.1149 log 0= +9.2256
T('K) T('K)
r2 = 0.959 r2 =1.000
0. Heating rate (Kftini
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Equation (1) can be converted into a form applicable to thedynamic heating case by replacing the first (isothermal) term withan integral expression to give:
tgel
logn = f k dt + log (o (9)
For linear heating rates, time can be expressed in terms oftemperature by:
T -T O dTt and dt-=-- (10)
Equation (7) is then modified to give the followingmathematical model for dynamic heating:
log n = CI f {l ! IdT + log 1 A2 1T (11)-"OTO
The computer/plotter was programmed to include Equation (11).A computer plot for dynamic heating at °C/min, together withexperimental points, is shown in Figure 6.
Equation (7) for isothermal heating, together with EquationR(11) for the dynamic heating case, constitute a mathematical model
which provides the capability to calculate viscosity for anytime/temperature sequence (i.e., the resin rheology portion of aprocessing model).
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0 Ex~ ont
3 1
LOUVWsosty \0
Poise 2N
I
00
Time - min oP3Mega
Figure 6L Computer Drawn Dynamic Heating Rheogramn for 350146, Batch 8.1 @ IlCImIn
To verify the suitability of the model, a typical cure cyclerun was made on the Rheometrics instrumrent. The cycle included aramp at 2*C/min to 116*C, a hold at 116*C for 60 minutes, a rampat 3*C/min to 117*C, followed by a hold at 177*C. Figure 7 showsexperimental data together with a computer drawn curve using therheology model.
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a2) HoWd 116C for 60 mmn
4 () Rw*~ 3'Cftfin to 1WC05',
LogViscosity
2
1E
0E0 20 40 6 80 00 10 14
D ~ ne-mtE cl
Figure~ 1 7.CmutrDaw ue yl Regamfr351,Bac
fromli ths7dt. The~ praeer fa yWor the model foBach of-t1
thre w Batch is1 tive ins able . ei elctea 2,10
Ta"l 4. atch pa~erweter for Mathematical Model
10g 17 = Ci [loAl~frI (t) + log [C21OA2ff1T2
Batch C, As C2 A2
B-3 2-16 x 1012 -3.467.i 1.45 x l~y 4,140.8
Where: 7) = Viscosity (Poise)
T=Temperature (K)
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The rheology models for the three batches were used togenerate computer curves depicting the viscosity profiles.
The rheological properties of Batches B-I, B-2, B-3 werecompared using computer drawn curves. The isothermal viscosityprofiles are shown in Figure 8. Figure 9 shows batch comparisonat a heating rate of 1C/min and Figure 10 shows the modelrheograms under the conditions of a typical cure cycle. Theviscosity profiles for the three resin batches are quite similarand show no significant trends relatable to the viscosity of theTGMDA used in their formulation.
-B-
41B-1 \B133
LogViscosity
Poise
A -
0 20 40 60 80 100 120 140
Time. min
Figure 8. Computer Drawn Isothermal Rheograms for 3501.6 Resin Comparing Batches B-i,B-2, and B-3 @ 1350C
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B-=83/
3
LogViscosity
Poise
2
11
0 20 40 080100 120 140Time- mini OP33a40o
Figure 9. Computer Drawn Dynamic Heating Rheograms for 3501.6 Resin Comparing BatchesB-1, B-2, and B-3 I l0 CImin
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,COAEL DOGACOPNTO
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Total Resin Flow - The total flow at constant pressure isdescribed as the value obtained by integrating the reciprocal ofviscosity (fluidity) from zero-time (to) tc the point where theflow ceases, i.e., time to gel (tgel):
f tgelFLOW NUMBER =j dt/- (12)
to
Flow numbers for Batches B-l, B-2, and B-3 are shown in Table5. Individual values obtained in replicate runs are shown inparentheses. These values were obtained by machine-integration ofthe viscosity profiles from the RDS experimental runs and not fromthe rheology model. The flow-numbers are a measure of total flowfor each condition of time and Lemperature under an equivalentpressure.
Table 5. Flow Numbers for 3501-6 Neat Resin Batches
Flow Numbers (Minutes/Poise)BatchI
B1 B.2 83
1. Dynamic (°C/min)
1 7.24 7.51 6.16(6.89, 7.59) (8.43, 6.58) (5.93, 6.40)
2 6.43 5.52 5.55(6.42, 6.44) (5.52, 5.53) (5.26, 5.85)
4 5.61 5.05 4.19(5.36, 5.86) (4.91, 5.19) (4.61,5.76)
2. Isothermal (°C)
125 5.71 5.38 6.04(5.63, 5.66, 5.85) (5.13, 5.63) (5.69, 6.39)
130 5.55 4.53 5.30(5.46, 5.63) (4.46, 4.59) (4.67, 5.93)
135 5.08 4.25 4.46(4.86, 5.00, 5.02, 5.40) (4.25, -) (4.22, 4.71)
140 4.91 4.29 4.33(4.36, 5.45) (4.35, 4.22) (3.98, 4.09, 4.91)
3. Cure Cycle 5.96(6.14, 5.77)
WCONNELL OUOLAS CORPORATIONI' 19
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MCDONNELL AIRCRAFT COM*PANV
For the three batches tested, the following observations weremade:
o Dynamic Cure Mode - Increasing the heating rate giveslower total flow. The total flow of a resin batch is inline with the viscosity of the starting YGMDA.
o Isothermal Cure Mode - Increasing the isothermal tempera-ture also gives lower total flow. The total flow of BatchB-3 is higher than expected from the relative viscosity ofthe starting material.
o Cure Cycle - The cure cycle tested (Ramp at 20C/min to116°C - hold 116 0C for 60 min - ramp 3*C/min to gel) did
not maximize flow.
o The data indicates that it is possible to achieveequivalent flow for all batches by tailoring cureconditions. These batches represent variation in TGMDAviscosity over the full range of commercially availablematerial.
Flow numbers can be calculated directly from the viscositycurves generated by the rheology model. The calculated values arein general agreement with those obtained by direct measurement ofthe individual experimental rheograms; however, they are notconsidered to be as accurate. To improve the accuracy of thecalculated flow numbers it will be necessary to assume a higherorder regression fit than the linear regression assumed forequation 7.
3.2 PHASE II - CORRELATE PHYSICOHEMICAL PROPERTIES WITH RESINREHOLOGY - The Objective of this phase was to determine inter-relationships for physiochemical properties and the rheology ofthe resin batches studied and to determine whether physiochemicaldata can be used to expand the processing model. The thermalanalysis data was shown to be applicable to the development of a
,l mathematical expression for calculating the time to complete curefrom the cure temperature. This thermokinetic model, togetherwith the rheology model consitute a viscokinetic model for resincuring behavior.
Determine Resin Thermal Properties - Thermal analysis of the3501-6 resin system was performed by differential scanningcalorimetry using the Perkin Elmer DSC-2 instrument.
A typical DSC thermogram is shown in Figure 11. The initialminor exotherm is associated with the BF3 catalyst and may be dueto the dissociation of the BF3 - amine complex together with thereaction of the novalac epoxide with the sulfone (DDS) curingagent. The major exotherm is mainly due to the TGMDA and carbonylepoxides reacting with the remaining curing agent. The DSC instru-ment pr~rits out the exotherm peak temperatures. The points forminimum viscosity and gel, as determined by RDS, are shown nn thethermogram to locate these events relative to the exotherma! curereaction.
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5.00
3.75
MCAL/sec 2.50
1.25 --
SGel (216"C1 TFxo = 229°C (Major)o I ,,_ I I I I I, I I 1
30 60 90 120 150 180 210 240 270 300 330 360Temperature- "C
Figure 11. DSC Thermogram for 3501-6 Resin, Batch B-1 @ 1O0 Clmin
The DSC exotherm peak temperatures are compared with the RDSviscosity temperatures (minimum viscosity and gel point) in Table6. There appears to be no well defined quantitative correlationsbetween these data. A very general observation for the variedlinear heating rates is that minimum viscosity is near the minorDSC exotherm peak and the gel point is near the major DSC exothermpeak. The reaction associated with the minor exotherm causes theviscosity to start increasing and the flow is decreased comparedwith some other epoxide composite matrix systems, which do notcontain BF3, such as Narmco 5208: Fiberite 976 and Hercules 3502.
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Table 6. Comparison of Event Temperatures for Viscosity (RDS) andThermal (DSC) Data for Linear Heating Rates
Temperature (C)
Heating RDS DSC RDDSCBacRate N h (Minimum (Minor (MajorNumber Viscosity Peak (0 Peak(OCImln) Point) Exotherm) Point) Exotherm)
B-1 123 120 186 1962.5 B-2 128 116 191 196
B-3 129 120 192 196
B-1 133 148 200 215
5.0 B-2 141 145 207 213
B-3 144 145 213 211
B-1 145 159 216 229
10.0 B-2 155 155 225 228
B-3 159 158 235 229
B-1 157 172 233 249
20.0 B-2 170 172 244 248
B-3 175 172 259 248
OP33-OOMe20
4'To study the kinetics of the 3501-6 cure reaction the Perkin
Elmer DSC-2 was interfaced with a thermal analysis data station(TADS) for acquisition and manipulation of data.
Kinetics of 3501-6 Cure Using DSC-2 Data and the TADS Pro-gram - The exothermal cure reaction for transformation of theB-staged starting resin to the cured matrix polymer may beexpressed as:
[RESIN] K [POLYMER] + AH (13)
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Based on the decrease of resin concentration with time, therate equation can be written as:
dad = K (1 - ap (14)
Where:a = degree of polymerizationt = timeK = rate constantn = parameter for data fit
The reaction expressed in Equation (13) is assumed to bediffusion controlled, in which case the order of the reaction ismeaningless. Therefore, the term n is a parameter for mathe-matical data fit and is not applicable to defining the truereaction mechanism.
The classical Arrhenius equation can be used to express therate constant (K) as a function of the temperature (T):
K = KO exp (-E/RT) (15)
Where:R = gas constantT = temperature (*K)E = activation energyKO = constant
Combining equations (14) and (15) gives the kineticexpression:
da (16_),)
- K0 exp (-E/RT) (l)n6)
R. Rush, Reference (8) and R. Fyans, Reference (9) havedescribed the use of Model DSC-2 equipped with the thermal analy-sis data station (TADS) and the TADS kinetic software package fordata manipulation in solving equation (16).
* - It is assumed that E and n are independent of (1- a ) and aredependent of the DSC scan rate. These independent relationshipswere shown for a solid diffusion controlled reaction by Crane,Dynes and Kaelble, Reference (10). The degree of polymerizationa, can be expressed in many ways. The simple approach is usedhere.
In order to calculate a, the partial areas of the exothermmust be obtained. This is done by a subroutine in TADS whichdetermines the total AH and partial areas by using Simpson's Rulefor the area under the DSC curve.
AH partialx a (17)
AH total
1 - a is then calculated and becomes a known for the solving of4 Equation (16).
MCDONELL DMOVOLAS CORPORATION
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Equation (16) can be reduced to a linear form by taking the
natural logarithm to obtain:do'
in d-f = in K. - (E/RT) + n in (I - a) (18)da
Equation (18) has DSC knowns of in -, l/T and ( - a) as
variables to solve for Ko , E and n. This is done by multi-linearregression in TADS.
SThe kinetic factors calculated for 3501-6 neat resin Batch9-I are given in Table 7. The data indicate a pseudo first orderreaction. The magnitude of the activation energy indicates adiffusion controlled network extension of epoxide/hardener system.
Table 7. DSC-2 Kinetic Factors for 35.1-6 Resin Batch B-1
1.25 2.5 5.0(0CImin) (Crin) (°CInin)
i - Kinetic Factor~Constant,
in K. (sec"1) 15.4 13.4 10.5
Activation Energy,Ea (callg) 19.8 18.2 15.6
Psuedo ReactionOrder (n) 1.2 1.5 0.9
GPJ3ISe- 2i
The 3501-6 resin has a bimodal cure exotherm. The set ofkinetic factors reported here is for the major exotherm. Asimilar set of data was determined for the preliminary minorexotherm that is due to the BF3 catalyst. The minor exotherm datawas not consistant and reflects a limitation that has not beenresolved.
DSC Data and a Thermokinetic Model for Complete Cure - Thekinetic factors calculated using the TADS sofware program gavedata that may be used for reference and in comparing 3501-6 withother thermosetting resins. However, the form of the kineticsequation provided by TADS is not immediately applicable to aprocessing model.
An approach that will allow the use of DSC to predict thetime/temperature combinations required for complete cure has beenreported by Carpenter, Reference (7).
MCDONNELL D)OU LAS CORPORATIO
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This technique uses the temperature for complete reaction(TCR), shown in Figures 12-14. A plot of log 0 vs l/TCR for threedifferent heat up rates gives the following equation:
log 4875 + 9.821 (19)TCR
0.8
TCR=
o 0 .6_ -2 8
MCAUsec 0.4
0.2 Min: 184.49
0 I III20 50 80 110 140 170 200 230 260 290 320
Temperature - °C
Figure 12. DSC Thermogram for 3501-6, Batch B-1, @ 1.250Clmin
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2.0
1.5
MOAL/sec 1.0
0.5
20 50 80 110 140 170 20)0 230 260 290 320
Temperature -Figure 13. DSC Thermogram for 35014., Batch 8-1, @ 2.5 CImin P3U1
2.0
1.5
MCAL~sec 1.0
0.5
Min: 215.94
020 50 80 110 140 10 20 30 260 290 32
ii Temperature - *CFigure 14. DSC Thermogram for 3501-4, Batch B-1, @ S*ClmlnAVCDONNVELL SPOMLAS COMPACOARATUOP
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MUCDONiNELL AIRCRAFT COPANV'M
The data is given in Table 8.
Table 8. Thermal Data for Complete Cure of 3501.6, Batch B.i
Critical Heating Rate, 4 Temperature EquationPoint (*CImln) (OC)
1.25 22 og = 4875 + 9.821TTemperature forComplete Reaction (TCR) 2.50 245 r2 = 0.9987
5.00 261
GP33O0423
As was shown in Reference (7), the isothermal time to com-plete reaction (tCR) can be expressed as a function of cure temper-ature by the following equation:
tCR = c T2 104875/T (20)
The constant, (c), can then be determined from:
c =JTCR 10-4875/T dT (21)( OT2
TO
This gives the final expression for time-to-complete reaction
as:
tCR = 1.345 x 10-14 T2 10 4875/T (22)
The isothermal time to complete reaction (tCR) at a cure temp-erature of 350 0 F, by Equation (22), is 3 hr:8 min. A calculationthat includes the contribution of the cure cycle steps prior toreaching 350*F, decreases the calculated time needed at 350F byonly a few minutes. Only final cure and postcure temperatures arerequired.
The mathematical model, equations (7) and (11) predicts therheology and flow of the resin system under conditions of cureencountered in processing. Equations (19) and (22) constitute athermokinetic model which uses DSC data to predict conditions ofcomplete cure. Together, these equations are important parts ofan overall model which describes the behavior of the resin underconditions of composite processing.
Determine Resin Chemical Properties - The three batches of3501-6 resin, made from TGMDA base resins with varied viscosities,were tested for chemical properties. The data, shown in Table 9,fall within limits established in earlier work, Reference (1).
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Table 9. Physiochemical Properties
_ _ I -Viscosity. DDS Carbonyl Epoxy BF3 DOS TGMDA Epoxy
Batch of TGMDA (Total) (Total) (Total) (Unreicted) (Unreacted) (Unreacted(CPS) x 103 (%) (%) (%) (%) (%) (%)
B-1 11 23.8 8.4 1.1 17.8 53.4 7.8
B-2 14 23.5 8.3 1.3 22.2 53.8 8.9
8-3 18 23.7 8.4 1.3 21.6 50.1 8.5
GP33*M24
The variations in base resin viscosities is due to differ-ences in the type of quantity of oligomers produced in the manufac-ture of TGMDA. In general, the greater the oligomer content, thehigher the viscosity. It was thought that the oligomer contentmight affect the kinetics of the cure reaction. If this were thecase, these three batches, which were all B-staged the same,should have different amounts of unreacted components. However,no significant trends in chemical composition were found.
3.3 PHASE III - DETERMINE RESIN VOLATILES EFFECTS - The objectiveof this phase was to characterize resin volatiles and their trans-port and the relationships t voids in the cured system.Exploratory work was conducted relevant to modeling the behaviorof volatiles during resin cure.
As a preliminary investigation, samples of as-received 3501-6neat resin were melted and held at 950C. At this temperature theresin h-.s an approximate viscosity of 10 poise. Even at this lowviscosity no bubbles were formed at ambient pressure. A vacuum of29" Hg was applied and bubbles quickly formed throughout theresin. The bubbles slowly rose to the surface. After about 45minutes most of the bubbles had risen to the top one-fourth of theresin. The vacuum was vented and the sample was quickly returnedto room temperature. The bubbles in the upper layer of the room-temperature solidified resin were thus "frozen" in place.
The bubble size was measured as a function of resin depthusing a Bausch and Lomb Image Analysis System. The bubbles in agiven layer were quite uniform in size. The average bubblediameters at nine different depths are given in Table 10. Thebubble diameters decrease as the bubbles approach the surface.This would suggest that the bubbles are not coalescing to formlarger bubbles as they rise to the surface. The decreasing sizeof the bubbles as they near the surface is also contrary to whatwould be expected from hydrostatic pressure effects in a fluid ofuniform viscosity.
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Table 10. Variation of Resin Bubble Size with Distance from the Surface
Surface, Inner MostLayer Layer
Distance 1 2 3 4 5 6 7 8
Bubble 43 66 77 83 81 98 89 95 95Dia (p)
*Arbtray distance with depth of focusGF33,00IS M
These preliminary experiments indicated the following:
o V7olatiles present in the as-received 3501-6 resin werecapable of producing large quantities of bubbles duringresin cure.
o Of the two suspect volatiles, water and air, absorbedmoisture is the most likely candidate, since copiuousbubble forwation resulted only after reducing the pressureon the melted resin to below the vapor pressure of water.
Fabrication of low-void composites thus requires that prepregproduction and composite processing conditions be controlled toeither remove the resin volatiles or retain them in solidsolution.
Direct Observation of Outgassing - A second method used forquantitative assessment of off-gassing characteristic: of theresin was a technique reported by Brown and McKaque, Reference(11). This method consists of submerging the speciamens indegassed silicone oil and observing the bubble formation duringthe resin cure cycle. A vacuum oven with a large viewport allowedthe use of video equipment to record the out-gassing experiments.The video recording system used provided a continuous readout oftime and temperature superimposed above the sample.
Observations and results obtained using this techniqueincluded the following:
o Careful control of tl-e vacuum level above the silicone oilwas crucial for reproducibility from run to run. Only pre-preg specimens could be compared, since weighted .pecimenshad a tendency to break away from anchors and fl at to thetop of the silicone oil. Making close comparisonsrequired that specimens be observed side by side, duringthe same run.
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o As-received AS/3501-6 prepreg was compared with preprcgdried in a vacuum desiccator overnight. The two prepregspecimens were heated at 4-5F/min to 350*F under vacuum.The as-received material off-gassed vigorously throughoutthe run, while the dried prepreg showed significantly lessoff-gassing. Moisture is again indicated as the majorvolatile. Complete removal of moisture, 'however, appearsdifficult and would be a costly step.
o As-received T300/5208 prepreg was compared with theas-received AS/3501-6 prepreg for conditions of 4-5* /minheating to hold at 375*F under vacuum. Both specimensbubbled vigorously during most of the run. The 5208prepreg bubbled more than 3501-6 at 370"F and beyond.This may have been due to the shorter gel time of 3501-6.Otherwise, this technique did not indicate mucn differencebetween the two specimens.
Quantitative Introduction of Volatiles - To evaluate vola-
tiles transport mechanisms a method is needed for introducingcontrolled amounts of the representative volatiles into the matrixresin. Six chemical blowing agents were selected for this purposeand evaluated by DSC. The blowing agents investigated and theirexotherm (or endotherm) peak temperatures are given in Table 11.
Table 11. DSC Evaluation of Chemical Blowing Agents, @ 5"Chnln
Blowing Agen Temp., C
Celogen, TSH (Uniroyal) 168
I ]Celogen, OT (Uniroyal) 166
Kempore (Olin) 209
Opex, 93 (Olin) 203
Nitropore, OBSH (Olin) 155
Expandex (Olin) (206)
)Endotherr. gP 34
The maximum rate of gas release should occur at the peaK temp-eratures. On this basis the Nitropore OBSH was selected since itdissocaiates between the point of minimum viscosity and the on-setof the major reaction exotherm.
"*ICDONELL DIGLAS CORMPON lOR3
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MCDONNELL AIRCRAFT COMPA IV
Nitropore OBSH chemically is 4, 4'-oxybis (benzenesulfon-hydrazide), which decomposes to give 15% water and 15% nitrogen byweight. This compound was shown to dissolve readily in 3501-6resin at 90C and to dissociate at a suitable temperature (155*C)for volatile formation. A known quantity can be introduced ofboth condensible (H20) and noncondensible (N2 ) volatiles.
Experimental determinations were made using varied concentra.-tions of Nitropore, i.e., 2, 0.2, and 0.02g Nitropore/lO0g resin.The mixtures were subjected to cure cycles with and withoutvacuum. Concentrations in the range of 0.02g Nitropore/lOOgmatrix resin appear to strike a practical balance for futureinvestigations involving volatiles transport mechanisms.
3.4 PHASE IV - RELATE RESIN CHEMORHEOLOGY AND LAMINATE PROPER-TIES -The objective of this phase was to determine whether corre-lation existed between the chemorheo]ogy properties determined inthe first phases of this program and laminate propertiespreviously reported, Reference (1).
The laminate property data available to this program waslimited to the vendor certification and receiving physical andmechancial properties, shown in Tables 12 and 13.
Table 12. Laminate Mechanical Properties
0* Tensile Proper'!es Interlaminar Shear
Strength (R.T.) Modulus (R.T.) Elongation (R.T.) R.T. 250OF 250OFBatch (ksi) (msl) pln./ln. x 103 (ksl) . (ksl) 24 hr Boll
B-1 224, 242, 227 21.2, 20.0, 19.6 11.0, 12.3, 11.8 21.2, 20.3, 20.8 15.0, 15.0, 15.1 10.4, 10.8, 10.6(231) (20.3) (11.7) (20.8) (15.0) (10.6)
B-2 265, 296, 277 20.1, 21.1, 20.4 13.4, 14.2, 43.8 19.5, 19.6, 19') 14.6, 13.7, 15.1 11.4, 11.8, 11.5(279) (20.5) (13.8) (19.4) (14.5) (11.6)
B-3" 257, 274, 269 19.4, 20.2.21.0 13.4, 14.0, 13.3 19.8, 18.5. 18.4 14.6, 14.1, 14.0 12.0. 11.5, 11.4(266) (20.0) (13.6) (18.9) (14.2) (11.6)
Minimum Acceptable
Requirements 200 18.0 10.0 15.0 9.0 7.5
Average"Data from equrvalent batch CIP3340C -24
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Table 13. Laminate F., ical Properties
B -in Flow Volatles PIy 1I ickness ! -lisin Content Fiber Areal WtBach (%) M% ,n) Tc, % gi2
8-1 - - 0.0051 Conforms 41, 40, 40 153, 152, 152(40) (152)
B-2 21.4 0.77 0.0051 Conforms 42, 42, 39 149, 148, 150(41) (149)
B-3* 25.9 1.00 0.0050 Conforms 42, 43, 43 148. 147, 147(43) (147)
Requirements 10 - 30 1.5 Max 0.0052 Adhere to 42 _ 3.0 145 - 155+ / - Itself for
0.0003 10 mm withLess Than
- 10% Damage
) Averagefata Irom equivalent batch OP33000-25
All batches exceeded the minimum property requirements. Notrends were evidenced. Thus, as with the chemorheolgy, thephysical and mechanical tests traditionally used for certificationand receiving inspection were insensitive to variations in theviscosity of the TGMDA component within the suppliersspecifications.
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4.0 SIGNIFICANT RESULTS
o A viscokinetic model for the curing behavior of 3501-6resin was derived from rheometrics and thermal analysisdata.
- The rheological part of the model describes the flowbehavior of the resin for any cure cycle using amathematical expression relating viscosity to the timeand temperature of cure.
- The thermokinetic part of the model describes theconditions required for complete cure using amathematical expression relating the time for completecure to the curing temperature.
o The viscokinetic model, now available, is a pre-requisitefor the future development of a composite processing modelwhich includes the effect of the reinforcing fibers.
o Total resin flow during cure was found to decrease withincreased dwell temperature and with increased heatingrates.
o The form of the viscokinetic model for curing behavior of3501-6 is applicable to other thermosetting resin systemsand is proposed as an approach to rapid optimization ofcuring parameters for future resin systems.
o The curing behavior was quite similar for three batches of3501-6 resin in which the base resin (TGMDA) viscosity hadbeen varied across the extreme of currently manufacturedMY720 epoxide.
- A comparison of the rheology of the three batches withtheir chemical and laminate mechanical properties didnot evidence any correlateable inter-relationships.
MCDONNELL DOUGLAS CORPORATION
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1 5.0 RECOMMENDATIONS
o Refine the resin rheology model for more exact predictionof experimental viscosity profiles and flow numbers
o Verify generic applicability of the viscokinetic (rheologyand thermokinetic) model to other thermosetting systems.
o Determine the effects of varied autoclave and vacuum bagpressures on rheology and volatiles transport and offgassing.
o Determine the effects of the reinforcing fibers on resinrheology and cure.
o Use a chemical blowing agent for future modeling of thetransport properties of condensable and noncondensablevolatiles.
o Volatile matter requires further study because of thedeleterious effect in composite properties.
t34
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RFENCES
1. Sewell, T. A., "Chemical Composition and Processing Specifica-
tions for Air Force/Navy Advanced Composite NatrixMaterials", Contract No. F33bl5-78-C-5177, Final Report forPeriod 18 September 1978 to 18 January 1982.
2. Roller, M. B., Polymer Engineering and Science, Vol. 15,
No. b, pp. 40b-412, June 1975.
3. Hollands, K. M., and Kalnin, I. L.., "Epoxy Resins", Advanced
Chem. Ser., -No. 92, bO, Am. Chem. Soc., Washington, D.C.(1970).
4. Kamal, M. R., Sourour, S., and Ryan, M., Technical Papers,31st Annual Technical Conference, Society of Plastics Engi-neers, 187, Montreal (May 1973); Kamal, M.R., Polym. Eng.
Science, 14, 231 (1974).
5. White, R. P., Jr., Polym, Eng. Science, 14, 231 (1974).
b. Mussatti, F. G. and Macosoko, C. W., Polym. Eng. Science, 13,236 (1973).
7. Carpenter, J. F., "Instrumental Techniques for DevelopingEpoxy Cure Cycles", 21st National Symposium and Exhibition at
Los Angeles, p. 783, April 197b.
8. Rush, R. M., "Monitoring the Cure of Therraosets via Thermal
Analysis", Perkin-Elmer TAAS (Draft Copy, dated 5 March
1982).
9. Fyans, R. L., "Computerized Thermal Analysis", AmericanLaboratory, 101, January 1981.
10. Crane, L. W., Dynes, P. J., and Kaelble, D. H., Polymer
Letters Edition 11, 533 (1973).
11. Brown, G. G. and McKaque, E. L., "Processing Science of EpoxyResin Composites", Air Force Contract F33bl5-80-C-5021.
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NASA HeadquartersAttn: Mr. C. F. Bersch600 Independence Ave., S.W.Washington, DC 2040b
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NASA 1Langley Research CenterAttn: LibraryHampton, VA 236b5
NASA 1Lewis Research CenterAttn: LibraryCleveland, OH 44185
Defense Technical Information Center 5Cameron Station, Bldg #5Alexandria, VA 22314
Director 2Plastics Technical Evaluation CenterPicatinny ArsenalDover, NJ 07801
U.S. Applied Technology Laboratory 1AVRADCOMAttn: DAVDL-ATL-ATSFort Eustis, VA 23b04
Brunswick Corporation 1Technical Products Division325 Brunswick LaneMarion, VA 24354
Celanese Research Company 1, SOS 1000
- Attn: Mr.- R. J. LealSunwait, NJ 07901E. I. DuPont de Nemours & Co. 1Textile Fibers Dept
~Wilmington, DE 19898
- Fiber Materials, Inc. 1Attn: Mr. J. Herrick
- Biddeford Industrial Park- Biddeford, MIE 04005
General Dynamics 1Covair Aerospace DivisionAttn: Tech LibraryP.O. Box 748Fort Worth, TX 76101
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General Dynamics 1Covair DivisionAttn: Mr. W. Scheck
Dept. 572-10P.O. Box 1128San Diego, CA 92138
General ElectricR&D CenterAttn: Mr. W. HilligBox 8Schnectady, NY 12301
General Electric CompanyValley Forge Space CenterPhiladelphia, PA 19101
B. F. Goodrich Aerospace & Defense
Products500 South Main St.Akron, OH 44318
Graftex DivisionEXXON Industries2917 Highwoods Blvd.Raleigh, NC 27b04
Great Lakes Research CorporationP.O. Box 1031Elizabethton, TN 37b43
Gruman Aerospace Corp. 1Attn: Mr. L. PoveromoBethpage LI, NY 11714
Hercules Incorporated 1Attn: Mr. E. G. Crossland
Magua, UT 84044
HITCO 11600 W. 135th St.Gardena, VA 90406
Illinois Institute of TechnologyResearch Center
10 West 35th St.Chicago, IL bObl6
MUCDOFNNLL [email protected]* CO MPORATOVl
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Lear Fan Corp. 1P.O. Box 60,000Reno, NV 89!Ob
Lockheed California Co. 1Attn: Mr. J. H. WooleyBox 551Burbank, CA 91520
Lockheed-Georgia Co. 1Attn: M. L. E. MeadeMarietta, GA 30063
Lockheed Missiles & Space Co. 1Attn: Mr. H. H. Armstrong
Dept. 62-60Sunnyvale, CA 94088
Material Sciences Corporation1777 Walton RoadBlue Bell, PA 19422
McDonnell Douglas Corp. 1Douglas Aircraft Co.Attn: Mr. R. J. Palmer3855 Lakewood Blvd.Long Beach, CA 90801
North American AviationColumbus Division4300 E. Fifth Ave.Columbus, OH 43216
Northrop Corp.3901 W. BroadwayAttn: Mr. G. Grimes
Mail Code 3852-82Hawthorne, CA 90250
Philco-Ford Corp.Aeronutronic DivisionFord RoadNewport Beach, CA 92663
Rockwell International Corp.Attn: Mr. C. R. Rousseau12214 Lakewood Blvd.Downey, CA 90241
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TRW, Inc.Systems GroupOne Space ParkBldg. 01, km. 2171Redondo Beach, CA 90278
TRW, Inc.23555 Euclid Ave.Cleveland, OH 44117
Union Carbide CorporationChemicals & PlasticsOne River RoadBound Brook, NJ 08805
Union Carbide CorporationCarbon Products DivisionP.O. Box 6116Cleveland, OH 44101
United Aircraft CorporationUnited Aircraft Research LaboratoriesE. Hartford, CT 06108
United Aircraft CorporationHamilton-Standard DivisionAttn: Mr. T. ZajacWindsor Locks, CT 06096
United Aircraft CorporationSikorsky Aircraft DivisionAttn: Mr. J. RayStratford, CT 0bb02
University of CaliforniaLawrence Livermore LaboratoryAttn: Mr. T. t. ChiaoP.O. Box 808Livermore, CA 94550
University of Maryland IAttn: Dr. W. J. BaileyCollege Park, MD 20742
University of WyomingMechanical Engineering Dept.Attn: Dr. D. F. AdamsLaramee, WY 82071
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Westinghouse R&D CenterAttn: Mr. Z. Sanjana1310 Beulah RoadChurchill BoroPittsburgh, PA 15235
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