Presentation is loading. Please wait.

Presentation is loading. Please wait.

An affordable creep-resistant nickel-base alloy for power plant Franck Tancret Harry Bhadeshia.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "An affordable creep-resistant nickel-base alloy for power plant Franck Tancret Harry Bhadeshia."— Presentation transcript:

1 An affordable creep-resistant nickel-base alloy for power plant Franck Tancret Harry Bhadeshia

2 The problem Future power plant: 750°C But: Commercial superalloys are too expensive (Nb, Ta, Co, Mo…) New steels: 650°C => Use of Ni-base alloys => Design an affordable creep-resistant Ni-base alloy

3 Industrial requirements - Affordable - 100 000 h creep lifetime under 100 MPa at 750°C - Stable at service temperature - Forgeable - Weldable - Corrosion resistance - Toughness

4 Design procedure -Empirical nonlinear multiparametric modelling of mechanical properties as a function of composition and processing conditions (Gaussian processes) Based on a huge database on the properties of many existing alloys => captures trends and interactions -Phase diagram and segregation simulation (Thermo-Calc) -Processability -General metallurgy principles Materials Science & Technology, 19 (2003) Ni – 20Cr – 3.5 W – 2.3 Al – 2.1 Ti – 5 Fe – 0.4 Si – 0.07 C – 0.005 B

5 Experimental results

6 Next issue: PROCESSING  Melting and solidification (primary chemical segregation)  Forging (  ’-free temperature window)  Heat treatment (precipiation hardening…)  Welding  How modelling can be used to address these issues?  Is the designed alloy easy to process?

7 Phase diagram simulation (Thermo-Calc) forging window melting No undesirable phases at service temperature

8 Primary segregation simulation (Thermo-Calc) Scheil’s approximation:  homogeneous liquid  diffusion-free solids LIQUID T = T – 1 K SOLID(S) LIQUID  V and composition

9 Primary segregation simulation (Thermo-Calc) Simple dendrite geometrical models => composition profiles sphere cylinder plate

10 Primary segregation simulation (Thermo-Calc) EDS analysis profile

11 Primary segregation simulation (Thermo-Calc)

12 Precipitation hardening kinetics Solutionising 1175°C, WQ Isothermal heat treatments below  ’ solvus, WQ Vickers hardness

13 Precipitation hardening kinetics Diffusion-controlled growth model: 3 Ni + diffusing (Al, Ti) => Ni 3 (Al,Ti) Before ageing: solutionised  During ageing:  ’ C av

14 Precipitation hardening kinetics Diffusion-controlled growth model (Al + Ti) dN(i)dN(i-1)dN p distance from precipitate C(1) = C eq C(2)C(i-1)C(i)C(i+1)……  /  ’ interface surface S adjustable parameter

15 Precipitation hardening kinetics Diffusion-controlled growth model (Al + Ti) C d C av C eq t = 0 C d C av C eq t C d C av C eq t = 

16 Precipitation hardening kinetics Diffusion-controlled growth model (Al + Ti)

17 Precipitation hardening kinetics Diffusion-controlled growth model (Al + Ti)

18 CONCLUSIONS  Design of an affordable Ni-base alloy for power-plant  100 000 h creep lifetime under 100 MPa at 750°C  Corrosion-resistant, stable, forgeable, weldable…  Extensive use of modelling: Mechanical properties (Gaussian processes) Phase diagram simulation - Stability - Forgeability - Weldability - Age-hardening - Solidification segregation (Scheil’s model) Precipitation-hardening kinetics (diffusion model)

19 Present and future work  Multicomponent diffusion growth model  Welding  High temperature ductility / forgeability / recrystallisation…  Corrosion-resistance

Download ppt "An affordable creep-resistant nickel-base alloy for power plant Franck Tancret Harry Bhadeshia."

Similar presentations

Titanium Melts at 1670°C Density 4.51 g cm -3 80% of Ti used in aerospace Use restricted to < 400°C.

Titanium Melts at 1670°C Density 4.51 g cm -3 80% of Ti used in aerospace Use restricted to < 400°C.
EPNM 2012 Metallurgical Considerations in Hot Metalworking Bi-Metal Materials John Banker Vice President Customers & Technology Dynamic Materials Corporation.

EPNM 2012 Metallurgical Considerations in Hot Metalworking Bi-Metal Materials John Banker Vice President Customers & Technology Dynamic Materials Corporation.
Acero 2000 PHYSICAL METALLURGY AND THERMAL PROCESSING OF STEEL

Acero 2000 PHYSICAL METALLURGY AND THERMAL PROCESSING OF STEEL
MatSE 259 Exam 1 Review Session 1.Exam structure – 25 questions, 1 mark each 2.Do NOT forget to write your student I.D. on the answer sheet 3.Exams are.

MatSE 259 Exam 1 Review Session 1.Exam structure – 25 questions, 1 mark each 2.Do NOT forget to write your student I.D. on the answer sheet 3.Exams are.
DICTRA Mobility Database for Zr alloys C. Toffolon-Masclet, C. Desgranges and J.C. Brachet CEA Saclay, France C. Toffolon-Masclet et al., CALPHAD XLI,

DICTRA Mobility Database for Zr alloys C. Toffolon-Masclet, C. Desgranges and J.C. Brachet CEA Saclay, France C. Toffolon-Masclet et al., CALPHAD XLI,
PART 2 : HEAT TREATMENT. ALLOY SYSTEMS STEELS ALUMINUM ALLOYS TITANIUM ALLOYS NICKEL BASE SUPERALLOYS.

PART 2 : HEAT TREATMENT. ALLOY SYSTEMS STEELS ALUMINUM ALLOYS TITANIUM ALLOYS NICKEL BASE SUPERALLOYS.
Chapter 10 Phase Transformations in Metals (1)

Chapter 10 Phase Transformations in Metals (1)
Slides on CAST IRONS provided by Prof. Krishanu Biswas

Slides on CAST IRONS provided by Prof. Krishanu Biswas
NC State University Department of Materials Science and Engineering1 MSE 440/540: Processing of Metallic Materials Instructors: Yuntian Zhu/Suveen Mathaudhu.

NC State University Department of Materials Science and Engineering1 MSE 440/540: Processing of Metallic Materials Instructors: Yuntian Zhu/Suveen Mathaudhu.
Properties and Applications

Properties and Applications
Powder Production through Atomization & Chemical Reactions N. Ashgriz Centre for Advanced Coating Technologies Department of Mechanical & Industrial Engineering.

Powder Production through Atomization & Chemical Reactions N. Ashgriz Centre for Advanced Coating Technologies Department of Mechanical & Industrial Engineering.
Mechanical & Aerospace Engineering West Virginia University Strengthening by Phase Transformation.

Mechanical & Aerospace Engineering West Virginia University Strengthening by Phase Transformation.
Nickel to Stainless Dissimilar Metal Welding

Nickel to Stainless Dissimilar Metal Welding
1 Journées d ’Automne 2001 Structural Materials for Hybrid System Paris, 29-31 octobre 2001 O. Danylova 1, Y. de Carlan 2, D. Hamon 2, J-C. Brachet 2,

1 Journées d ’Automne 2001 Structural Materials for Hybrid System Paris, octobre 2001 O. Danylova 1, Y. de Carlan 2, D. Hamon 2, J-C. Brachet 2,
Advanced Materials 2: Phase transformations 1.Introduction 2.Microscopic Interactions 3.Cooperativity 4.Universal aspects of phase transitions 5.Landau.

Advanced Materials 2: Phase transformations 1.Introduction 2.Microscopic Interactions 3.Cooperativity 4.Universal aspects of phase transitions 5.Landau.
Welding Metallurgy 2.

Welding Metallurgy 2.
Neural Networks www.msm.cam.ac.uk/phase-trans.

Neural Networks
Solidification and Grain Size Strengthening

Solidification and Grain Size Strengthening
University of Cambridge Stéphane Forsik 5 th June 2006 Neural network: A set of four case studies.

University of Cambridge Stéphane Forsik 5 th June 2006 Neural network: A set of four case studies.
Materials for fusion power plants Stéphane Forsik - Phase Transformations and Complex Properties Group www.msm.cam.ac.uk/phase-trans FUSION POWER PLANT.

Materials for fusion power plants Stéphane Forsik - Phase Transformations and Complex Properties Group FUSION POWER PLANT.

Similar presentations

Ads by Google