Invited Lecture ADVANCES IN SiC/SiC COMPOSITES FOR ...
Transcript of Invited Lecture ADVANCES IN SiC/SiC COMPOSITES FOR ...
Abstract, CIMTEC 2006, June 2006 Invited Lecture
ADVANCES IN SiC/SiC COMPOSITES FOR AEROSPACE APPLICATIONS
James A. DiCarlo Senior Technologist, Ceramics NASA Glenn Research Center
In recent years, supported by a variety of materials development programs, NASA Glenn Research Center has significantly increased the thermostructural capability of SiC/SiC composite materials for high-temperature aerospace applications. These state-of-the-art advances have occurred in every key constituent of the composite: fiber, fiber coating, matrix, and environmental barrier coating, as well as processes for forming the fiber architectures needed for complex-shaped components such as turbine vanes for gas turbine engines. This presentation will briefly elaborate on the nature of these advances in terms of performance data and underlying mechanisms. Based on a list of first-order property goals for typical high-temperature applications, key data from a variety of laboratory tests are presented which demonstrate that the NASA-developed constituent materials and processes do indeed result in SiC/SiC systems with the desired thermal and structural capabilities. Remaining process and microstructural issues for further property enhancement are discussed, as well as on-going approaches at NASA to solve these issues. NASA efforts to develop physics-based property models that can be used not only for component design and life modeling, but also for constituent material and process improvement will also be discussed.
National Aeronautics and Space Administration • ADVANCES IN SiC/SiC COMPOSITES
FOR AEROSPACE APPLICATIONS
James A. DiCarlo Materials and Structures Division
NASA Glenn Research Center Cleveland, OH 44135
USA
Presented at CIMTEC 2006 June, 2006, Acireale, Sicily
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Advanced Lightweight High-Temperature Structural Materials are Needed for Multiple Aerospace Applications •
Control Surfaces
Turbine Vanes and
Blades
Combustors
Nozzle Flaps and Seals
, Cooled
Combustor Panels,
Thrusters, Rocket Nozzles
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Typical Function of a Structural Material In a Hot Aerospace Application
• Hot gas layer t QO",I,.d'.UO")
- - - - _ . ....----------------......, Max ThermallEnvironmental Barrier Coating? V Material T
• Thin-Wail Component Max In-Plane
_____ . ...... ________________ ~ Tensile
~Tc • Cooling fluid layer I Stress ... Qout (conduction)
Key Material Property Requirements: • Low Density, Low Permeability, High Emissivity • Microstructural Stability at Maximum Temperature • High Tensile Stress Capability In-Plane and Thru-Thickness • High Thermal Conductivity Thru-Thickness to reduce thermal gradients and stresses
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Advantages of SiC Fiber / SiC Matrix (SiC/SiC) Ceramic Matrix Composites (CMC)
versus Superallovs: - Lower density (-30% metal density) - Higher temperature capability (>1100DC) - Lower thermal expansion
versus Monolithic Ceramics: - Non-catastrophic failure - Higher toughness, better damage tolerance - Capability for larger and more complex shapes
versus Carbon Fiber Composites (C/SiC, C/C): - Higher oxidative durability, more predictable life - Lower permeability
versus Oxide/Oxide Ceramic Composites: - Higher strength, temperature capability, creep-
rupture resistance, thermal conductivity, emissivity - Lower permeability
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Objective / Outline • • Present brief review of recent NASA efforts aimed at
developing Advanced Constituent Materials and Processes for SiC/SiC composites to better meet the thermal, structural, and conductivity requirements for aerospace components.
• NASA developments to 2002: • Sylramic-iBN SiC Fibers • SiC Matrices based on Silicon melt infiltration
• More recent developments: • Silicon free Matrices • Special Post-production Treatment • Advanced Fiber Architectures
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Acknowledgements
SiC/SiC Development Team at NASA Glenn
• Fibers/Architectures: Hee Mann Yun
(now at MATECH/GSM)
• Matrices: Ram Bhatt
• Modeling: Greg Morscher Jerry Lang
NASA Funding Programs
• Ultra Efficient Engine Technologies (UEET)
• Internal Research and Development
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NASA 2002 Fabrication Route for SiC/SiC Components
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Sylramic Fiber
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Weaving, Braiding Into 20 or 30 preforms
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NASA Treatment to form Sylramic-iBN fibers
• • . ~ .. "" . • • • • • • • • •
~ . ~"'-----' . r Furnace . ~ .• ", . Reactor ~
Cast SiC Matrix f. SiC/SiC preform
CVI-MI SiC/SiC
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CREEP STRAIN after 10
hours, %
NASA Advanced Process for Sylramic SiC Fibers
In -2000, NASA developed a high-temperature process for commercial Sylramic SiC fibers to produce the stoichiometric Sylramic-iBN fiber with a thermally stable in-situ grown BN (iBN) coating and state-of-theart tensile strength and creep-rupture resistance.
1400C (2550F) 2 .00
~:~~ ~SYl~~~.IBN 0.20
0.10
0.05
0.02
0.01 15 20 30 40 50607080 100 150 200 STRESS KSI
1.OO.--__ ---'-"=-=.....,,<='-'-LL-"a"'ir'----_---,
Sylramic
Tyranno SA...!!,2) .......... ~
-. ---:::.~
Svlr'11l'
100 ;0 C 'C
50 2' iil ~.:::-:-- ......
- ~ ....... ~
....... HloNic.S ~
20 ~ ?-7<'
Time, hr 10 !!!. 5O~~=L~~~~=L~~~~~
0.01 0.1 10 100 1.000
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Durability Benefit of In-Situ BN Coating
Without NASA treatment, almost
every Sylramic SiC fiber in each tow contacts another
fiber, allowing rapid and detrimental fiber bonding upon oxygen
ingress
With NASA treatment, in-situ BN coating prevents SiC-SiC
contact between Sylramic-iBN fibers, delaying oxide bonding
and increasing SiC/SiC durability and reproducibility
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CVI-MI SIC/SIC Panels with Sylramic-iBN Fibers Show Improved In-Plane UTS and Burner Rig Durability
After burner rig h UTS - 450 MPa 70.,1
~~ PLS - 16\0 MPa ~ As-fabricated 1:'" ! Sylramic-iBN i", Fiber
03-001 · S I " H" N" I S Y ramlc or 1- Ica on-Fiber
.. After burner ~ UTS - 400 MPa rig at 800
oC, ~ ~_ ... ~ __ r 10
10 hours As-fabricated
Ii JO
Room Temperature
0.' 0.' 0.'
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National Aeronautics and Space Administration • In-Plane 500-Hour Rupture Strength in Air for NASA CVI-MI SiC/SiC versus Competing Materials (-Yr 2002)
C'CI 160 I -Max SiC/SiC Design Strength I Il.. -Max in-plane \ :E 140 stress for ~ \ .r:: SiC/SiC \ '" ~ C, 120 combustors and
~ \ ~ -\ -~-O: ~ ~-I: vanes ~ 100 - .. - - ---(J)
NASA ~ 80
"'" CMC I '" SiC/SiC with :::I .-- 1\ \ 60 -Best Syl-iBN c. 1\ \ / 1\ :::I Superalloy fibers + 0:: 40 ... \ AS-BOO Si3N4 \ \ CVI-MI
:I: . 20 monolithic matrices 0 0 ceramic It) 0
900 1000 1100 1200 1300 1400 1500
Stress-Rupture Temperature, DC
With upper use temperatures near -1315DC , NASA 2002 SiC/SiC systems display higher thermostructural capability than competing materials
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CVI-MI SiC/SiC Properties Needed Further Improvement
• On scientific side, temperature capability, thermal conductivity, and design strength were less than the best SiC monolithic ceramics.
• On technical side, lifing risks still exist for SiC/SiC component failure due to unexpected hot spots and/or loss of the thermal barrier coatings.
NASA Activities :
• Understand, mechanistically model, and minimize sources for property limitations.
• Key Concerns: Improving SiC/SiC • Microstructural Stability at higher temperatures • Structural Capability at higher temperatures • Thru- Thickness thermal conductivity • Thru- Thickness strength (IL TS or interlaminar tensile
strength for 20 composites)
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Stability Issues for CVI-MI SiC/SiC
Key Issues:
• For long times above 1300oC, free Si in matrix diffuses thru grain boundaries of initial CVI SiC matrix coating, attacks BN fiber coating and SiC fiber, and reduces UTS.
• Free Si in matrix also degrades composite creep-rupture resistance, reducing CVI-MI SiC/SiC structural capability at high temperatures.
• CVI BN fiber coating, which is deposited below 1000°C, densifies and shrinks at high temperatures, reducing fibermatrix load transfer, thru-thickness conductivity and tensile strength.
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NASA Approaches to Microstructural Stability Issues
• Retain Sylramic-iBN SiC fiber because of its high strength, high creep-rupture resistance, high thermal conductivity, and microstructural stability to over 1650oC.
• Develop materials and processes for two advanced SiC/SiC systems with Si-free matrices: - Full CVI SiC - Partial CVI SiC + SiC derived from polymer infiltration and
pyrolysis (hybrid CVI-PIP).
• Develop special annealing treatment that - Stabilizes BN coating, minimizing gap formation between
fiber and matrix, and also - Removes process-related defects in the SiC matrix to
improve CMC creep-rupture resistance and thermal conductivity
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Annealing Effects on Partial CVI SiC Panels with Different Fibers
CVI SiC - 20 vol. % 500 I 400
SiC/SiC 300 RT
Ultimate 200 Tensile 100
,~ Sylra
'\ \ Hi-Nic , "'" Hi-Nic
mic-iBN
alon
alon Type S Strength,
0 MPa I
o 500 1000 1500 2000 100-hr Exposure Temperature, °C
Intrinsic stability and in-situ grown BN coating for Sylramic-iBN fiber allows annealing of Si-free CVI SiC
matrices to >1500oC with NO loss in in-plane UTS
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Creep-Rupture Behavior for NASA 2D SiC/SiC Systems
14500C 110 ksi 1 AIR 1.4
~ 1.2 c::: 'E 1 .... ~ 0.8 CI) ~ 0.6
CVI-MI matrix
-- (with silicon)
Annealed Full CVI or CVI-PIP matrix (.) 0.4
0.2
o ~
/ (without silicon
i I
o 100 200 300 400 500 600
Time, hours
Si-free matrices with NASA special annealing treatment significantly improves creep rupture resistance of SiC/SiC
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Effects of NASA Special Annealing Treatment on ThruThickness Properties for 2D Sylramic-iBN/SiC Systems
>. -- .s: nI ._ E-... (J Q) ::s ~" I- c:
0 ()
40
30
l20 ;:: co
~10
0
1:1 Unannealed II
Closed Porosity:
Annealed 20°C
Improves .. SiC
matrix
Full CVI CVI·PIP CVI·MI 3
Improves 2 -ILTS,
BN fiber .. ksi
coating
0
• Annealed Inert
20 CVI-MI
ILTS, O-Content. atomic ratio
1.000
0.100
0.010
0.001
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In-Plane 500-Hour Rupture Strength in Air for NASA Advanced SiC/SiC versus Competing Materials (-Yr 2005)
~ 160
~
Advanced
-Max in-plane -l -Max SiC/SiC Design Strength ~ SiC/SiC with stress for \ I.- \ Syl-iBN fibers +
I'\. -- ........... Si-free matrices (Ii 140 SiC/SiC \ '\. r--...... '- / .s::. combustors and '\. I -............ ..... f ::: _ _ v: es.. _ 1-'-\ -\-t-~-_-----'<\--._-t-_--_""'""'::-:::--I~-\--_-._-'t_""x.-~-r--_-j_
en 80 ~ \ Ox-Ox I \ ~ \ e r'----/....." \ CMC II-+---'~\ .-+'\. -----'\.--r---~--., .a 60 +-------l -Best I \ "NASA c. Superalloy I \ / \ 1\ _ SiC/SiC
~ 40 \ I AS-BOO I \ \ with MI-Si
~ 20 t----t----t-~~-j--t~S~i3~N~4~--t_~\\L~m~at~ri~c~es~ o It) o+-___ ~---~--~---~---~---~
900 1000 1100 1200 1300 1400 1500
Stress-Rupture Temperature, °C
Thermostructural capability for advanced SiC/SiC system is state-of-the art with upper use temperatures of -14500C (26400F)
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NASA Continues to Develop Improved SiC/SiC Using Alternate Fiber Architectures and Sylramic-iBN Fibers •
u 2.50 Sylramic-iBN/CVI-PIP ~ 4 Anneal
~ 4J---------~~--------------~~~1
'" ~ 1 20 Hi-Nic-S/CV;;I-:;;M~I-===:::::::::'=-_~=~ 2 ~ 5
200 400 600 800 1000 1200 1400 Temperature,OC
2.5D angle-interlock architecture with low content of Sylramic-iBN fibers in zdirection (-3 vol. %) and NASA special anneal yields stoichiometric CVI-PIP
SiC/SiC system with thru-thickness conductivity and 200C thru-thickness tensile strength significantly improved over original CVI-MI system
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Summary and Future Needs
NASA SiC/SiC systems with high performance Sylramic-iBN fibers are capable of outperforming the best superal/oys, Ox/Ox systems, and monolithic ceramics in in-plane strength capability at high temperatures (to 1450°C), while providing low density, high emissivity, high thermal conductivity, and high thru-thickness strength,
Currently the SiC/SiC constituent materials and processes that provide the best combination of thermal and structural performance are: • Stoichiometric Sylramic-iBN SiC fiber • CVI BN-based fiber coating after NASA special treatment • Stoichiometric SiC matrix with partial CVI plus PIP SiC, again
after NASA special treatment. (Future improvements are needed to reduce porosity in this matrix).
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Although 2D SiC/SiC systems offer simplicity in fabrication of aerospace components, 3D systems reinforced by non-orthogonal high-strength high-conductivity fibers, such as Sylramic-iBN, offer even higher thru-thickness conductivity and strength, (Future improvements are needed to increase Z-direction fiber content.)
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Current SiC/SiC Commercialization Issues Life-cycle cost-benefit analyses need to be conducted for each
SiC/SiC component to determine economic viability, BUT
• High costs still exist for high-performance SiC fibers, for quality controls at every process step, and for generation of accurate design data bases
Constituent vendors are often different and single organizations, complicating production time and resulting in multi-tiers of profit taking, Little or no experience exists demonstrating reliable performance under actual component service conditions SiC/SiC property and lifing models are complex, and approaches for converting models into Finite Element codes for component design are lacking.
Even at design stresses below matrix cracking, lifing analyses of SiC/SiC components at high temperatures can be very complex:
Creep effects, residual stress development - Environmental effects with and without barrier coatings.
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