Environmental attack has the potential to limit turbine disk durability, particularly in next generation engines which will run hotter; there is a need to understand better oxidation at potential service conditions and develop models that link microstructure to fatigue response. More efficient gas turbine engine designs will require higher operating temperatures. Turbine disks are regarded as critical flight safety components; a failure is a serious hazard. Low cycle fatigue is an important design criteria for turbine disks. Powder metallurgy alloys, like ME3, have led to major improvements in temperature performance through refractory additions (e.g. Mo,W) at the expense of environmental resistance (Al, Cr). Service conditions for aerospace disks can produce major cycle periods extending from minutes to hours and days with total service times exceeding 1,000 hours in aerospace applications. Some of the effects of service can be captured by extended exposures at elevated temperature prior to LCF testing. Some details of the work presented here have been published

Draper, Susan L.

Gabb, Tim P.

Gorman, Timothy T.

Hull, David R.

Perea, Daniel E.

Schreiber, Daniel K.

Sudbrack, Chantal K.

Telesman, Jack

NASA Technical Reports Server

References: [1]  JH Chen, PM Rogers, JA Little, Oxidation of Metals 47 (1997) 381.  [2]  A Encinas-Oropesa et al. in Superalloys 2008, 609. [3]  TP Gabb et al. in Superalloys 2004, 269. [4]  SD Antolovich, P 
Domas, JL Strudel, Met Trans A 10A (1979) 1859.  [5] Sudbrack et al. in Superalloys 2012, 863.  [6] RC Reed, The Superalloys: Fundamentals and Applications (2006) 252. 
 
Acknowledgements: The authors would like to acknowledge Dr. James Smialek and Dr. Mike Nathal (NASA-GRC) for valuable discussions, as well as Jeff Marshman (Carl Zeiss) for focused-ion 
beam assistance.   Support of the NASA Aviation Safety Program, NASA Subsonic Fixed Wing program, NASA Undergraduate Student Research Program is also acknowledged. The atom probe 
work was performed at EMSL, a national scientific user facility at PNNL sponsored by the DOE's Office of Biological and Environmental Research, under a rapid access user proposal (#47633). 
Motivation: Environmental attack has the potential to limit turbine disk durability [1,2], particularly in next generation engines which will run hotter; there is a 
need to understand better oxidation at potential service conditions and develop models that link microstructure to fatigue response. 
safety components; a failure is a serious hazard.  Low cycle fatigue is an 
important design criteria for turbine disks. Powder metallurgy alloys, like ME3, 
have led to major improvements in temperature performance through refractory 
additions (e.g. Mo,W) at the expense of environmental resistance (Al, Cr). Service 
 
   
conditions for aerospace disks can produce major 
cycle periods extending from minutes to hours and 
days with total service times exceeding 1,000 hours in 
aerospace applications. Some of the effects of service 
can be captured by extended exposures at elevated 
temperature prior to LCF testing [3,4]. Some details of 
the work presented here have been published [5]. 
More efficient gas turbine engine designs 
will require higher operating temperatures. 
Turbine disks are regarded as critical flight    
Introduction	  
Engine Disk 
Fatigue Failure 
Boeing 767/GE CF6-80, 6/2/08 (LAX) 
Gas Turbine Engine 
Current à 650 °C 
Long-range goal à 800 °C  
Disk Rim 
20 µm 
Supersolvus  
ME3 disk alloy 
500 nm 
Polycrystalline γ/γ’ Ni-based superalloy  
 
Large grain size for rim creep resistance 
   <D>= 27 – 31 µm (ASTM 7.1-6.8) 
   ALA= 105 – 125 µm (ASTM 3.5-3)  
                                        (i.e. largest grain in cross section) 
Minor phases for creep rupture  
Grain boundary (GB)  strengtheners:  Cr-rich M23C6 
carbides  (d <0.15 µm) 
Reside mostly in grains: MC carbides (0.15-0.7 µm) 
and M3B2 borides (0.4-1 µm) 
     γ’-precipitates for strength & fatigue resistance 
     Tertiary γ’, <d> =  18 – 39 nm 
     Secondary γ’, <d>= 190 –330 nm 
 
      γ’(L12): Ni3(Al,Ti), strong Al partitioning 
      γ (fcc):  Cr, Co, Mo partitioning 
 
As-processed 
Microstructural starting point	  
Produced by 
supersolvus 
heat treatment 
1 
Slight Moderate Aggressive 
Majority no debit, 
Bimodal dist.? 
67%-85% 
Debit 
97%-99% 
Debit 
T initiation  
(single initiation) 
Mixed I/T/O 
initiation (handful) 
Oxide failure 
(multiple) 
T propagation Initial I and then T propagation 
I propagation 
Extensive!! 
 
 
 
Experimental approach	  
•  Coupons & notched LCF specimens extracted from the rim of a fully heated 
forged disk, produced from HIP extruded powder billet  
•  Air Exposures:  704 °C – 815 °C up to 2,020 hours in a  
     resistance furnace held isothermally, then air cooled 
•  NLCF testing at 704 °C, σmax=855 Mpa, σmin/σmax= 0.05,  
     0.333 Hz with cylindrical notched specimens with Kt=2 
 
Oxidation can reduce fatigue life in disk alloys above 650°C by accelerated crack 
initiation and growth at defects; however, it is not well-studied at 650 °C - 800°C:   
•  Identify microstructural features associated with oxidation 
•  Map microstructural features over time and temperature (isothermal kinetics) 
 
 
Examine the effect of environmental attack on fatigue resistance 
 
•  Pre-expose fatigue specimens using a subset of mapped conditions 
•   Examine effect of pre-exposure on fatigue life, crack initiation & propagation 
•  Correlate / model fatigue life to microstructural evolution 
Part I 
Part II 
Kt=2 
5.1 mm 
Load Control 
Effect of prior exposures on fatigue response 
45k	   55k	   33k	   15k	   15k	   7k	   1.3k	   0.4k	  
NLCF testing at 704 °C 
σmax=855 MPa, R(σ)= 0.05, 0.333 Hz 
Each test is represented by a diamond 
Fatigue response and failure modes 
Microstructural features associated with oxidation 
Cross	  sec0onal	  view	  
BSE SEM 
BSE images of supersolvus ME3 oxidized at 815°C 
Like other high-Cr disk superalloys, a continuous Cr2O3 scale forms, with faceted, 
superficial TiO2 grains at the exposed ME3 surface. Beneath the TiO2-Cr2O3 scale, an 
internal subscale of branched Al2O3 extends into a layer where γ’- precipitates have 
been dissolved by Al depletion. This γ’-dissolution layer is recrystallized with finer 
grains and contains micron-sized voids at the grain boundaries.  Throughout these 
layers and beyond, the (Mo,Cr,Co)23C6 carbides have been dissolved from the original 
grain boundaries via grain boundary diffusion of Cr that helps support scale growth.  
815 °C, 2020 h 815 °C, 2020 h 
WDS Chemical Maps 
815 °C, 2020 h 
20 µm 
45k	   53k	   65k	   71k	  
Additional fatigue testing 
•  Tests on specimens exposed in vacuum or exposed 
prior to machining showed no fatigue debit. 
Ø Confirms debits observed for prior exposures in air are 
from environmental attack, not overaging during exposure. 
•  Tests on specimens, pre-exposed at 815°C 2020 h 
and where the oxide and subscale were removed 
mechanically showed a marginal improvement (3X) 
in mean fatigue life compared to 815°C 2020h tests. 
•  When the M23C carbide dissolution layer was 
removed, a near full recovery was observed.  
•  The absence of carbides make GBs weak; layer 
removal tests establish that GB strength is 
important to crack initiation mechanism. 
None	  
99 % 
Debit 
Nearly full 
recovery 
20% Debit 
 
3) M23C6  
Dissolution 
 Layer removed 
2) Scale +  
Subscale  
removed  
97 %  
Debit 
Multiple  
intergranular 
initiations 
Single  
transgranular 
initiation 
Side view of fracture  
surface 
NLCF testing at 704 °C 
σmax=855 MPa, R(σ)= 0.05, 0.333 Hz 
815°C  2020 h in air 
1)  As-exposed   
        surface 
3 2 1 
45k	  
Scale + Subscale  Removed  M23C6 Dissolution Layer Removed 
0.4k	   1.3k	   36k	  
Slight	  
Moderate	  
Aggressive	  
Intergranular	  
Propaga0on	  
•  Prior exposures in air significantly 
affect fatigue life.  
•  Debit is caused by damage at the 
surface not exposure temperature; 
as tests on moderate conditions 
produce equivalent lives.  
Overload	  
Extends well 
beyond surface 
damage 
Initiation sites 
Aggressive	  Avg. γ’-Dissolution Depth (µm) 
National Aeronautics and Space Administration 
www.nasa.gov 
Uncoated ME3: microstructural variation trends differ from time1/2 
                Only Al2O3 penetration follows a parabolic growth trend     
                                                       Activation energy, Q, observed for scale thickness 
          for other disk alloys:  250 – 300 kJ/mol 
! 
k = k0 exp("Q /RT)
      Scale Thickness          <         Al2O3 penetration    <             Denuded Zone  
Average Scale Thickness (um) Average Al2O3 Penetration (um) Average Denuded Zone (um) 
Time (h) Time (h) Time (h) 
k(704)=0.0077 ± 0.0018 um3/h 
k(760)=0.0031 ± 0.0006 um3/h 
k(815)=0.0190 ± 0.0026 um3/h 
k(704)upper=0.005 ± 0.004 um2/h 
k(760)=0.0142 ± 0.0011 um2/h 
k(815)=0.052 ± 0.004 um2/h 
k(704)=0.019 ± 0.0010 um3/h 
k(760)=0.076 ± 0.020 um3/h 
k(815)=0.510 ± 0.008 um3/h 
! 
y = k" t( )n
n= 1/3 
n= 1/3 n= 1/2 
704 °C 
760 °C 
815 °C 
704 °C 
760 °C 
815 °C 
704 °C 
760 °C 
815 °C 
Select conditions for notched fatigue tests 
Time (h) Time (h) Time (h) 
Avg. Scale Thickness µ ) Avg. Al2O3 Pen tration (µ ) 
Measure feature sizes over time & temperature space from cross sections 
Slight exposures              Scale thickness < 0.6 µm:  704 °C for 100 h, 704 °C for 440 h  
Moderate exposures    Invariant of temp.: Scale thickness ~1 µm & Al2O3 depths ~ 3 µm 
          815 °C for 100 h, 760 °C for 440 h, 704 °C for 2,020 h  
Aggressive exposures   Scale thickness > 1.8 µm:  815 °C for 440 h, 815 °C for 2,020 h  
 
. γ’- i l ti  Lay r
Statistically equivalent 
•  Static oxidation at potential service temperatures over extended 
periods was mapped for supersolvus ME3 from 704 °C to 815 °C.  
•  Cross-section evaluation uncovered complex near-surface damage, 
including extensive GB carbide dissolution.  
•  Fatigue debit reductions showed a power law correlation with total 
damage depth, that decay as (TDD)-3 and by substitution, (time)-1.  
•  Fatigue debit is independent of temperature and is caused by 
environmental surface damage from air exposure not overaging, 
while for specimens removal past carbide dissolution layer led to full 
recovery in fatigue life for aggressive prior exposures. 
•  For slight exposures, specimens failed from single surface cracks 
that initiated and propagated transgranularly, as exposures became 
more aggressive, multiple cracks initiated in surface oxide and 
propagated intergranularly for distances well beyond the total 
damage depth.  
Summary 
. 
T= Transgranular, I= Intergranular, O= Oxide failure 
Depth 
(Summation of PL fits) 
•  With excellent fits to a simple power law, 
normalized fatigue life decays with 
thickness of oxide scale, γ’-dissolution layer, 
carbide dissolution layer, and, by inference, 
total damage depth with an exponent of -3.  
•  It follows that normalized fatigue life is 
proportional to (time)-1 by substitution of 
cubic dependencies from cross sections. 
•  Removal experiments demonstrate that the 
fatigue response is governed by the total 
damage depth not individual layers. 
Aggressive exposures were found to degrade grain boundary strength 
well beyond the resulting surface damage. It is known that segregation  
of O or absence of B can can cause weak grain boundaries in similar 
nickel base superalloys [6], and therefore, it was hypothesized that 
long-range GB diffusion of these light species caused embrittlement. 
Precise measurement with atom probe tomography showed equivalent 
B, C, P and O chemistries for nondegraded and degraded grain 
boundaries, eliminating this possibility. Further work is planned. 
All atoms B C O 
Typical atom probe GB analysis from failed 
NLCF specimens at 100 µm depth  
C=0.19 ± 0.06 at.% 
B=0.98+0.14 at.% 
P=0.059 ± 0.032 at.% 
C=0.28 ± 0.10 at.% 
B=1.22 ± 0.20 at.% 
P=0.08 ± 0.04 at.% 
Intergranular  
propagation  
C
on
ce
nt
ra
tio
n 
(a
t.%
) 
GB chemistry Transgranular  
propagation 
γ' 
γ' 
γ 
98 nm x 97 nm x 152 nm – Air exposure 
	  	  	  	  	  -­‐4	  	  	  	  -­‐2	  	  	  	  	  0	  	  	  	  2	  	  	  	  	  4	  
	  	  	  	  	  -­‐4	  	  	  	  -­‐2	  	  	  	  	  0	  	  	  	  	  2	  	  	  	  	  4	  
Distance	  (nm)	  
Air 
Vacuum 
Linking existing microstructure to fatigue response 
m= -3 
Six	  prior	  exposure	  condi;ons	  in	  air	  showed	  fa;gue	  debits	  
C 
B 
P 
C 
B 
P 
y = κ ⋅LT( )m
Layer 
The effect of prior exposures on the notched fatigue behavior of disk 
superalloy ME3 
National Aeronautics and Space Administration 
Chantal K. Sudbrack1, Susan L. Draper1, Timothy T. Gorman2,*, Jack Telesman1, Tim P. Gabb1, 
David R. Hull1, Daniel E. Perea3,+ and Daniel K. Schreiber3  
 1. NASA Glenn Research Center, Cleveland OH, 2. University of Dayton, Dayton OH, 3. Pacific Northwest National Laboratory, Richland WA 
*NASA USRP Intern, +Environmental Molecular Sciences Laboratory at PNNL 
 
 
 
https://ntrs.nasa.gov/search.jsp?R=20150009927 2019-08-31T07:52:48+00:00Z


The Effect of Prior Exposures on the Notched Fatigue Behavior of Disk Superalloy ME3

The Effect of Prior Exposures on the Notched Fatigue Behavior of Disk Superalloy ME3

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