CRANFIELD UNIVERSITY ADRIANA ENCINAS-OROPESA A STUDY OF HOT CORROSION OF SINGLE CRYSTAL SUPERALLOYS COATINGS. AND PLATINUM-ALUMINIDE 100,5 AND MANUFACTURING SCHOOL OF INDUSTRIAL SCIENCE Ph. D. THESIS CRANFIELD UNIVERSITY SCHOOL OF INDUSTRIAL AND MANUFACTURING SCIENCE Ph. D. THESES ACADEMIC YEAR 2005 ADRIANA ENCINAS-OROPESA A STUDY OF HOT CORROSION OF SINGLE CRYSTAL SUPERALLOYS AND PLATINUM-ALUMINIDE COATINGS. SUPERVISORS: Professor J. R. Nicholls, Dr. N. J. Simms October 2005 @Cranfield University, 2005. All No be rights reserved. part of this publication may reproduced without the written perrnýission of the copyright holder. W" ji! iaw inspiration for their wi on in detMhýnation,, Sor Juana to the rom women `*y eciaýyV, otber. to Acknowledgments The like her European to to the author would express gratitude Commission for funding Advanced Long Life the this the of work under Turbine Coating Systems (ALLBATROS), ENK5- project contract number CT2000-00081 the European Coal Steel Community (ECSC) and and with 7220-PR/053. project number I have had in both the the pleasure of working a very nice environment, National High Temperature Surface Engineering Power Generation the and Technology Centre, I for help, kindly where anybody asked someone always helped I learning the me. greatly appreciate patience shown on my slow English language I However, I like the to process of ever since started. would I have bothered thank the the especially people most: John Nicholls for believing in by Professor the me giving me in his to this thorough opportunity work project, guidance and constructive discussions. Dr Nigel Simms, had time for doubts, for his who always my guidance for I have leamt I the things and all since started working with and support him. John Oakey, Boýa Arias, Paul Kilgallon, Andrew Potter, Steve Nigel Legrave, Jim Norton, helped Mabbutt, all of whom me at some point of Rachel Newton, her help during the this work. who always offered (and this part of project always ended up weighing samples), experimentation Grasa-Adiego Gemma the time to to who made and effort study and explain looked impossible Peter West to understand, and who often was me what I for time this thesis. with my work so could make overloaded Tim Pryor, taught helped the laborious who me and me with set up of in laboratory, keep the to them time them the start on and going. experiments Andrew Dyer, taught to the to who me prepare samples correctly and make (and for fixing the use of equipment my mistakes). proper Suzie Chadwick in for her the time computer centre nice support every because I The kind ladies I the the messed up my work on computer. of panic help find information just library to that who me often, was under my nose and for her in Procite Heather the to support use. The Community Development Centre, Margaret Lynn, for and making life lovely difficult those easier and all gestures of support and care on and happy times... I like have had this to thank those would opportunity people who a influence during formation, they great my academic/professional since provide the to the Professor Cristina Oliviera me with means cope with unknown: who taught to "organize thoughts, to think... " Don Julio Giovine me my not who "engineering be ingenious " Cuco Navajas taught me that means... to and who "... do I have?... "... told the the t me what and qualite of executan I to friends I have hours am also very grateful my with whom spend hours fun, have been happy for those and of reflexion, adventure and whom I thank them me, and will personally. in To brothers, Armando Alberto in my my y whom retrospective, has both because Atlantic there the nicest memories, you are always and ... bond made our closer and stronger... To father; for being his my my maestro and example, advice, support and encouragement. love, To friend, Isidro for his care and mi greatest unconditional ... because I feel lucky have in life for support... very to coincided and sharing life my with you... And little "moon light "... Itzel, for to those my all extraordinary feelings day... you give me with your smile every Sincerely Adriana Encinas Oropesa Abstract At the time, for (e. present combined cycle systems power generation g. IGCC), increased lower offer efficiency of power generation and C02, SOxg, NO,,, being environmental emissions, specifically and as well as fossil fuels. Economic factors, to the the adaptable most such as cost of be Materials influence lifetime in the the materials must considered. service Solid fuels like biomass required operational environment. coal and produce different that, combustion environments containing a range of contaminants they their when reach melting points, may cause accelerated corrosion, directly life the time the turbine affecting service of gas constructional This is known Hot Corrosion. materials. accelerated corrosion as The develop, influence this to the aim of study was an understanding of factors hot these turbine of environmental on rate of corrosion of modem i. CMSX4 SC2 both the the materials, e. single crystal alloys uncoated and , PtAl that for turbine blade in coated are needed a gas and vanes operating a hot in lGCC range of corrosion environments expected an plant. To this laboratory tests achieve aim, a series of corrosion was planned in industrial high to the temperature simulate same corrosion environment as Following for testing, turbine operation. established procedures corrosion gas in furnace to samples were exposed a controlled atmosphere a mix of gases (air/SO241CI) 50 100h duration. Each time with a cyclic exposure of and/or be to to cycle, samples were removed recoated with an alkali salt mixture a 500h 1000h. Cross by time total exposure of and or sections were examined SEM/EDX to identify the hot To the mode of corrosion attack. quantify rate of this corrosion, samples were measured pre-exposure and post-exposure, and data was statistically assessed. corrosion from data, life Finally, this quantitative prediction models were developed to describe/predict the hot the onset of corrosion and corrosion rates different deposition fluxes, both under gas compositions, and various observed I II hot in incubation typical type type temperatures terms at and corrosion of Separate have been developed for the two periods. models and propagation CMSX4 SC2, in both the single crystals superalloys: and uncoated and The fit defined by platinum aluminide coated condition. goodness of as the from 0.88 0.99 for to the regression coefficient varies propagation models at 700 900'C. The incubation 7001C but less and models are as precise at precise 9001C 0.78-0.94. at with regression coefficients of I Table Contents of INTRODUCTION 1 .......................................................................... 2 LITERATURE REVIEW 4 ............................................................... 2.1 Power Generation Systems 4 ................. . .............. ......................... ................. . ...... 2.2 Contaminants in Coal/biomass Fired Gas Turbine 8 a . ............. . .......... . .............. 2.3 Materials Impact the Industrial Gas Turbines 11 on ........ . ...................... . ........... 2.3.1 Introduction 11 ......................................................................................................... 2.3.2 Superalloys 12 .......................................................................................................... 2.3.3 Nickel-Base Superalloys 12 ..................................................................................... 2.3.4 Chemical 13 composition ......................................................................................... 2.3.5 Structure Microstructure 14 and ............................................................................... 2.3.6 Effects Alloying Elements 17 of .............................................................................. 2.4 High Temperature Oxidation 19 .............................. . .......... .................................. 2.4.1 Introduction 19 ......................................................................................................... 2.4.2 Thermodynamics Oxidation 19 of ........................................................................... 2.4.3 Kinetics Oxidation: Oxide Scale Formation Grown 21 of and ................................ 25 2.4.4 Transport mechanisms ........................................................................................ 2.5 High Temperature Corrosion 26 ... . ....... . ... . ............................. . ............... . ........... 2.5.1 Introduction 26 ......................................................................................................... 2.5.2 Hot Corrosion 26 ...................................................................................................... 2.5.3 Hot Corrosion Degradation Sequence 27 ................................................................. 2.5.4 The Initiation Stage Hot Corrosion Attack 29 of ..................................................... 33 2.5.5 Hot Corrosion: Type I Type 11 and ...................................................................... 35 2.5.6 The Propagation Stage Hot Corrosion of ............................................................ 2.5.7 Thermodynamics 36 ................................................................................................. 2.5.8 Basic Fluxing 40 ...................................................................................................... 2.5.9 Acid Fluxing 43 ....................................................................................................... 2.5.10 Salt Component-Induced Hot Corrosion 49 ........................................................ 2.5.11 Effect Chlorine Species Hot Corrosion 50 of on ................................................. 2.6 Protective Coatings 54 ................................................................................................ 2.6.1 Introduction 54 ......................................................................................................... 2.6.2 Coating Requirements 54 ......................................................................................... 2.6.3 High Temperature Coatings 56 ................................................................................ 2.6.4 Alurninising 59 ......................................................................................................... 2.6.5 Modified Aluminide Coatings 60 ............................................................................. 2.6.6 Platinum Aluminide Coatings 60 ............................................................................. 2.6.7 Microstructure PtAl Modified Coatings 62 of ......................................................... 2.6.8 Overlay Coatings 63 ................................................................................................. 2.6.9 Oxidation Hot Corrosion Coatings 65 and of ........................................................... 2.7 Application Statistics to High Temperature Corrosion 67 of .................................. 3 EXPERIMENTAL PROCEDURES 68 ............................................. 3.1 Introduction 68 ............................................................................................................ ii 70 3.2 Materials . .................... ........................................................................................... 71 3.3 Corrosion Furnaces Environment and ....................................................... ...... .. 3.4 Corrosion Testing: Deposit Re-coat Test Method in Controlled Atmosphere 72 Furnaces ................................................................................................................................ 75 3.5 Metrology . .................... .......................................................................................... 77 3.6 Specimen Manufacture .......................................................................................... 77 3.7 Pre-exposure Metrology ........................................................................................ 79 3.8 Post-exposure Sample Preparation ....................................................................... 80 3.9 Post- Metrology exposure ........................................ . ............................................ 82 4 RESULTS ...................................................................................... 82 4.1 Introduction ............................................................................................................ 82 4.2 Mass Change ........................................................................................................... 83 data (Phase 1) 4.2.1 Mass change ................................................................................. 83 4.2.1.1 Uncoated IN738 LC 700* C: at ............................................................................................................. 85 4.2.1.2 Platinum aluminised coated IN738 LC: ................................................................................................ 88 4.2.1.3 Uncoated CMSX-4 at 700*C: ............................................................................................................... 90 4.2.1.4 Platinum Aluminized coated CMSX-4 at 700*C: ................................................................................. 93 4.2.2 Mass data (Phase 2) change ................................................................................. 93 4,2.2.1 Mass change on CMSX-4 (uncoated and with a PtAl coating) ............................................................ 97 4.2.2.2 Mass change on SC2 (uncoated and with PtAl coating) ....................................................................... 10 1 4.3 Optical Microscopy . ................. .................................................................... 101 4.3.1 Damage Morphologies (Phase 1) ...................................................................... 102 4.3.2 Damage Morphologies (Phase 2) ...................................................................... 104 (Phase 3) 4.3.3 Damage morphologies ....................................................................... 119 Statistical Assessment Hot Corrosion Data 4.4 of ................................................... 121 4.4.1 Probability Analysis Phase I ............................................................................. 121 Gas 4.4.1.1 composition sensitivity ................................................................................................................ 127 4.4.1.2 Deposit composition sensitivity .......................................................................................................... 127 4.4.1.3 Temperature sensitivity ....................................................................................................................... 130 4.4.2 Probability Analysis Phase 2 ............................................................................. 130 4.4.2.1 Sensitivity to gas composition and temperature ................................................................................. 145 4.4.2.2 Sensitivity to deposition flux .............................................................................................................. 159 5 DISCUSSION .............................................................................. 159 5.1 Introduction .......................................................................................................... 5.2 Effect Varying Deposit Flux in Different Hot Corrosion Environments 161 of .... 5.3 Effect Varying the Deposit Composition 167 of ............................... . .......... . ........... 5.4 Effect Alloy Composition Different Hot Corrosion Environments 172 of .............. 5.5 Effect the Gas Composition in Different Hot Corrosion Environments 182 of ..... 194 5.6 PtAl Coatings Performance in Different Hot Corrosion Environments .......... III 211 5.7 Life Prediction Models in Hot Corrosion Environments .................................. 211 5.7.1 Incubation Models ............................................................................................. 214 5.7.2 Propagation Models .......................................................................................... 221 6 CONCLUSIONS ......................................................................... 223 FOR FUTURE WORK 7 SUGGESTIONS .................................. 224 REFERENCE LIST 239 APPENDIX IV List Figures of Figure 2.1: Primary by fuel 1990 2001 in to the consumption produce, and United Kingdom [5] 4 . .................................................................................. Figure 2.2: Historical Evolution Power Plant Efficiency [10] 5 of . ..................... Figure 2.3: Simplified flow Integrated Gasification the sheet of process of Combined Cycle Power Generation [14] 7 . .................................................. Figure 2A Variation levels S02 IS03 temperature of equilibrium Of with as in [26] 10 refereed . ........................................................................................ Figure 2.5: Equilibrium (Na + K) alkali chloride vapour concentration as function for PFBC [24] 10 temperature of gas conditions ............................ Figure 2.6: Example blade for (a) turbine of a gas power generation systems damaged (b) 12 and severely ......................................................................... Figure 2.7: Elements important in the [32]. constitution of nickel-based alloys 14 .................................................................................................................. development Figure 2.8: Panorama the of of nickel superalloy microstructure both deleterious [30] 15 showing useful and phases ..................................... in Figure 2.9: Microstructure the two this of single crystal alloys studied work: in fully heat SC2 [37] b) treated typical a) y' precipitates superalloy CMSX4, in microstructure of with y'-Nl3AI grains, embedded a 7-Ni [38] 16 matrix ................................................................................................ Figure 2.10: Schematic diagram illustrating the for Ni- oxidation mechanism [39] 17 Cr-Al alloys . ..................................................................................... 2.11: Ellingham/Richardson diagram. Standard free Figure energy of formation function temperature [45] 20 of selected oxides as a of ............... Figure 2.12: Schematic illustration the of main phenomena and part-processes in the taking place reaction of metals with single oxidant gases, e. g. 21 oxygen[50] . ............................................................................................. for high Figure 2.13: Interfacial transport temperature reactions and processes (a) (b) [49] 22 mechanisms cation mobile and anion mobile oxidation . ...... Figure 2.14: Schematic illustration the (e. thickness) of variation of x g. oxide for linear logarithmic [45] 23 time parabolic, and oxidation with ................ Figure 2.15: Order-of-magnitude for the parabolic rate constants growth of [49] 24 oxides several . .................................................................................. Figure 2.16: (a) Transport through by lattice processes scales growing diffusion. (b) Transport in in lattice terms processes growing scale of and defects, interstitial ions e. g., of metal vacancies and and of electronic holes [50] 25 and electron respectively electrons . ........................................ Figure 2.17: Binary diagram for Na2S04-K2SO4 [65] 27 equilibrium system ...... Figure 2.18: Schematic weight change versus time to illustrate that the degradation initiation of corrosion resistant systems consist on an and [6 1].............................................................................. 28 propagation stage V