NASAs future robotic missions to Venus and outer planets, namely, Saturn, Uranus, Neptune, result in
extremely high entry conditions that exceed the capabilities of current mid density ablators (PICA or Avcoat). Therefore
mission planners assume the use of a fully dense carbon phenolic heatshield similar to what was flown on Pioneer Venus
and Galileo. Carbon phenolic (CP) is a robust TPS however its high density and thermal conductivity constrain mission
planners to steep entries, high heat fluxes, high pressures and short entry durations, in order for CP to be feasible from a
mass perspective. In 2012 the Game Changing Development Program in NASAs Space Technology Mission Directorate
funded NASA ARC to investigate the feasibility of a Woven Thermal Protection System to meet the needs of NASAs most
challenging entry missions. The high entry conditions pose certification challenges in existing ground based test facilities.
Recent updates to NASAs IHF and AEDCs H3 high temperature arcjet test facilities enable higher heatflux (2000 Wcm2)
and high pressure (5 atm) testing of TPS. Some recent thermal tests of woven TPS will be discussed in this paper. These
upgrades have provided a way to test higher entry conditions of potential outer planet and Venus missions and provided
a baseline against carbon phenolic material. The results of these tests have given preliminary insight to sample
configuration and physical recession profile characteristics

Gonzales, G.

Stackpoole, M.

NASA Technical Reports Server

ThermalTestingofWovenTPSMaterialsinExtremeEntryEnvironments
G.Gonzales §,M.Stackpoole*
§ ERCInc.,MoffettField,CA94035,* NASAAmesResearchCenter,MoffettFieldCA94035
TestinginAmesArcJetFacility(IHFwith6”Nozzle)
TestPurpose:
• Evaluatethe3DwovenHEEETTPSmaterialinasimulatedentryenvironmentatheatfluxes
approaching1700W/cm2.TPScouponshada2inchdiameterflatfacegeometry.
• Primaryobjectivesofthistestserieswere:
1. Demonstrateapplicabilityof3DWovenablatorconceptsathighheatfluxconditions:
1680W/cm2 actual– (coldwall)and~1.3atm stagnation
2. Compareperformancetoheritagelikecarbonphenolicmaterials
• Figure4illustratesthemodelassemblyusedinthis
testseries.TPSstagnationmodelsweremounted
toagraphiteadapter.Testarticleswereinstrumented
withonebackfaceTC,insertedthroughthecenter
ofthemodel.
WovenTPS– TheConcept
• WovenTPSleveragesthematureweavingtechnologythathasevolvedfromthetextileindustry
todesignTPSwithtailorableperformancebyvaryingthematerialcompositionandproperties
whilecontrollingplacementoffiberswithinawovenstructure
• TheresultingwovenTPScanbedesignedandtailored toperformoptimallyforawiderangeof
entryenvironmentswithoutsubstantiallychangingthemanufacturingandcertificationprocess
• ThewovenTPSapproachutilizescommerciallyavailable weavers,usingequipment,modeling
anddesigntoolstooptimizetheweave.Thisallowsforthecontrolofmaterialcompositionand
densityresultingintailoredperformance  byleveraging thistechnologyNASAwillnotbe
burdenedwithmaintainingthecapabilityorhavingtoaccepttheriskformaterialrestart
Weavingflexibilityallows:
• AbilitytodesignTPStomeetspecificmissionneeds
• Tailoringcompositionbyweavingtogetherdifferentfibertypes(carbon,glass,polymer,other)
• Tailoringdensity
• WovenTPSapproachallowsdesign
andmanufactureof ablativeTPS
materialsbyspecificplacementof
fibersina3Dwovenstructure
illustratedinFigure2
ColdwallHeatFlux
2inflatface(W/cm2)
StagnationPressure
(atm)
Shear
(Pa)
1680 1.3 0
TableI HeatingenvironmentforIHF2inchflatfacestagnation
modelsasmeasuredona2inchFlatfacecalorimeter.
Figure5:HEEETmaterial(left),TWCP20degree(mid.),andCMCP(right).
Pretestimagesontop,Posttestimagesonthebottom.
• Imagesofpre andposttestspecimens
areshowninFigure5.Allablated
uniformlyanddidnotexhibitanyunusual
failuremodes.TheHEEETmaterials
performedwell.Theposttest
imagesdonotindicateanyunusual
featuresonthetestsurface.Carbon
phenolicwas alsotestedandbehavedin
acontrolledmanner.Somedelamination
ofthechoppedmaterialwasobservedin
theCMCPmaterial.
Acknowledgements
ThisworkwasperformedundertheSTMD/GCDPfundedHeatshieldforExtremeEntryEnvironment
(HEEET)Program.TheauthorswouldalsoliketoacknowledgetheHEEETteamandinparticularKeith
Peterson,MattGasch,DonEllerby,Tane Boghozian
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Heat-shield for Extreme Entry 
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Introduction
• TheHeatshieldforExtremeEntry
Environment(HEEET)Projectisfundedby
NASA’sSpaceTechnologyMissionDirectorate
undertheGameChangingDevelopment
Program(GCDP).
• HEEETseekstomatureanovelWoven
ThermalProtectionSystem(TPS)technology
toenableinsituroboticsciencemissions
recommendedbytheNASAResearch
CouncilPlanetaryScienceDecadal
SurveycommitteeasoutlinedinFigure1.
• Recommendedsciencemissionsinclude
Venusprobesandlanders,Saturnand
Uranusprobes,andhighspeedsamplereturnmissions.
ArcJetTestObjectives
• Thepurposeofthesetest
seriesistoevaluatethe
behaviorofHEEETmaterial
performanceinhigh/extreme
entryconditionsincurrent
groundbasedtestingfacilities.
• TheIHFandAEDCfacilities
haverecentlybeenupgradedto
expandtheirtestableenvelope
andtestingatthesehigher
conditionswillbepresented.
Additionally,comparisonsto
heritagechopmoldedcarbon
phenolic(CMCP)andtape
wrappedcarbonphenolic
(TWCP)willbepresented.Test
conditionsandexample
missionconditionsareoutline
inFigure3.
Summary
• Facilityupgradeshavewidenedtheenvelopeforgroundbasedtestingcapabilitiesallowingmore
extremeconditionstobetested
• HEEETmaterialperformedwellinall3testseries.
• Nounexpectedfailuremodeswereobserved
• HeritagecarbonphenolicmaterialsweretestedalongsideHEEETtomakeperformance
comparisons.
• Basedonthesearcjetresultsinextremeentryenvironments,HEEETwovenmaterialoptionsare
viablealternativestoheritagecarbonphenolic.
TestingatAEDCFacility(H3)
TestPurpose:
• Evaluatethe3DwovenHEEETdownselectedarchitectureinaturbulentheatingenvironment
underextremestagnationpressure,14atmand~1850W/cm2
• Primaryobjectivesofthistestserieswas:
1. DemonstrateapplicabilityofHEEETcompositionatextremepressure
2. CompareperformancetoheritageCMCP
• Figure 8 shows the model schematic. Each sample was attached to machined carbon phenolic
model holder that was then attached to the facility sting arm.
CWHeatFlux
2inFlatface
(W/cm2)
Stagnation
Pressure(atm)
Shear
(Pa)
DistanceFrom
Nozzle(in)
1850 14 0 3
TableIII CFDcalculatedheatingenvironmentonAEDC2inch
flatfacemodel.
Figure9:HEEETacreagematerialpretestandduringtest.
Remainingrecessionlayerincenteroftestarearemainssmooth
despitehigherrecessionsonedge.
Figure10:CMCPpreandposttestimages.Finalsurfaceismuch
roughercomparedtoHEEETmaterial.
• Photographs of pre and posttest are shown of the HEEET acreage material (Figure 9) and
CMCP (Figure 10)
• The HEEET material ablated very uniformly and did not exhibit any unusual failure modes. Due
to the model conditions being more severe at the edges, and limitations in the thickness of
material available, the insulating layer at the edges was exposed. In the future the recession
layer would be sized to specific mission conditions and this flexibility is a benefit of this type of
woven architecture.
• Chop molded carbon phenolic was also tested. Some delamination of the chopped material
was observed in the CMCP material and the final surface appears somewhat uneven as shown
in Figure 10.TestinginAmesArcJetFacility(IHF3”Nozzle)
TestPurpose:
• EvaluatetheHEEETTPSatextremeheatfluxconditions,~5000W/cm2 (coldwall)and~5atm.
TPScouponshada1inchdiameterflatfacegeometryasdiagramedinFigure6.Figure7shows
preandposttestimages.
• Primaryobjectivesofthistestserieswere:
1. Demonstrateapplicabilityof3DWovenablatorconceptsdevelopedundertheWovenTPS
projectatextremeheatflux/pressure.
CWHeatFlux
1inflatface(W/cm2)
Stagnation
Pressure(atm)
Shear
(Pa)
4800 6 0
Table1– CFDcalculatedheatingenvironmenton1inchflat
facemodel.
Figure6:Modeldesignfor3”nozzletestinIHFfacility.
GraphiteAdapterTPSSample
Exampleofassembledmodel Pretest
Figure7:ExamplesofpreandposttestimagesofHEEETsamples.
• Allsamplesevaluatedablateduniformlywithnounusualfailuremodes
developed.
Figure4:ModelbuildforIHF6”nozzletestof2”flatface
stagnationmodels.
Figure8:ModelschematicofH3testingatAEDC.
Figure1:Fromproofofconcepttovision,HEEETaimsatSaturn,
Venus,andUranusmissions.
Figure2:Weavearchitecture:schematicofonepossibleconfiguration.
ArcjetDesignSpace&HEEETTestHistory
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"Saturn"High"Lat."Steep"(719°)"Entry"
"Saturn"Equitorial,"Shallow"(78°)"Entry"
"Pioneer"Venus"Large"Probe"(732.4°)"
"Venus"VITaL"Steep"(722°)"Entry"
"Venus"VITaL"Shallow"(715°)"Entry"
IHF 3” Nozzle
1” Flat Face
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2” Flat Face
IHF 6” Nozzle
2” Flat Face
HEEET Materials Test Summary =
Stag.Point re(bar)
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Figure3:DesignspaceformissionentryconditionsforSaturnandVenusandtest
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https://ntrs.nasa.gov/search.jsp?R=20140011259 2019-08-31T19:41:15+00:00Z


Thermal Testing of Woven TPS Materials in Extreme Entry Environments

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