Titanium Alloys Modelling of Microstructure Properties and Applications 1st Edition by Sha And Malinov 1845693756 9781845693756
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Product details:
ISBN 10: 1845693756
ISBN 13: 9781845693756
Authors: W. Sha, S. Malinov
Given their growing importance in the aerospace, automotive, sports and medical sectors, modelling the microstructure and properties of titanium and its alloys is a vital part of research into the development of new applications. This is the first time a book has been dedicated to modelling techniques for titanium.
Titanium Alloys 1st Table of contents:
1 Introduction to titanium alloys
1.1 Introduction
1.2 Conventional titanium alloys
1.3 Titanium aluminides
1.4 Modelling
1.5 References
Part I Experimental techniques
2 Microscopy
2.1 High temperature microscopy of surface oxidation and transformations
2.2 Gamma titanium aluminide
2.3 Transmission electron microscopy of microstructural evolution
2.4 References
3 Synchrotron radiation X-ray diffraction
3.1 Introduction
3.2 Measurements at room temperature
3.3 Measurements at elevated temperatures
3.4 Gamma titanium aluminide
3.5 References
4 Differential scanning calorimetry and property measurements
4.1 Phase and structural transformations
4.2 Mechanical properties of β21s alloy
4.3 Effects of hydrogen penetration
4.4 References
Part II Physical models
5 Thermodynamic modelling
5.1 Introduction
5.2 Conventional titanium alloys
5.3 Titanium aluminides
5.4 References
6 The Johnson–Mehl–Avrami method: isothermal transformation kinetics
6.1 Introduction
6.2 Resistivity experiments
6.3 Metallography
6.4 X-ray diffraction
6.5 Additional ageing
6.6 Thermodynamic equilibria
6.7 Kinetics of the transformation
6.8 Time–temperature–transformation diagrams
6.9 Summary
6.10 References
7 The Johnson–Mehl–Avrami method adapted to continuous cooling
7.1 Introduction
7.2 Interpretation of calorimetry data
7.3 X-ray diffraction
7.4 Microstructure and hardness
7.5 Calculation of continuous-cooling transformation diagrams
7.6 Calculation of transformation kinetics
7.7 Simulation and monitoring of transformations on continuous cooling
7.8 Summary
7.9 References
8 Finite element method: morphology of β to α phase transformation
8.1 Introduction
8.2 Experimental and modelling methodology
8.3 Experimental observation of the morphology of the phase transformation
8.4 Mathematical formulation in the model for the microstructure of Ti-6Al-4V
8.5 The 1-D model
8.6 The 2-D model
8.7 Summary of the models for Ti-6Al-4V
8.8 Extending to other alloys
8.9 Summary
8.10 References
9 Phase-field method: lamellar structure formation in γ-TiAl
9.1 Introduction
9.2 Mathematical formulation
9.3 Computer simulation of lamellar structure formation in γ-TiAl
9.4 Summary
9.5 References
10 Cellular automata method for microstructural evolution modelling
10.1 Introduction
10.2 Microstructural evolution of Ti-6Al-4V during thermomechanical processing
10.3 The simulation model
10.4 Simulated microstructural evolution during dynamic recrystallisation
10.5 Simulated flow stress–strain behaviour
10.6 Summary of the simulation method and its capabilities
10.7 References
11 Crystallographic and fracture behaviour of titanium aluminide
11.1 Introduction
11.2 Single crystal characteristic
11.3 Crack path analyses
11.4 Transmission electron microscopy
11.5 A model for microcracks nucleation in basal slip
11.6 Summary
11.7 References
12 Atomistic simulations of interfaces and dislocations relevant to TiAl
12.1 Introduction
12.2 Tasks
12.3 Computational procedure
12.4 Choice of interatomic potential
12.5 References
Part III Neural network models
13 Neural network method
13.1 Introduction
13.2 Software description
13.3 Use of the software
13.4 Upgrading the software system
13.5 Summary
13.6 References
14 Neural network models and applications in phase transformation studies
14.1 β-transus temperature
14.2 Time–temperature–transformation diagrams
14.3 An example of MatLab program code for neural network training
14.4 References
15 Neural network models and applications in property studies
15.1 Correlation between processing parameters and mechanical properties
15.2 Fatigue stress life (S-N) diagrams
15.3 Mechanical properties of gamma-based titanium aluminides
15.4 Reference
15.5 Appendix
Part IV Surface engineering products
16 Surface gas nitriding: phase composition and microstructure
16.1 Introduction
16.2 Near-α Ti-8Al-1Mo-1V
16.3Near-α Ti-6Al-2Sn-4Zr-2Mo
16.4 α + β Ti-6Al-4V
16.5 Near-β Ti-10V-2Fe-3Al
16.6 β21s
16.7 Timetal 205
16.8 Ti–Al
16.9 Summary of the effect of the parameters of gas nitriding on the microstructure
16.10 References
17 Surface gas nitriding: mechanical properties, morphology, corrosion
17.1 Hardness evolution
17.2 Tensile properties and fatigue performance after nitriding
17.3 Surface morphology and roughness of Ti-6Al-2Sn-4Zr-2Mo after nitriding
17.4 Corrosion behaviour
17.5 References
18 Nitriding: modelling of hardness profiles and the kinetics
18.1 Artificial neural network modelling of microhardness profiles
18.2 Kinetics of gas nitriding
18.3 References
19 Aluminising: fabrication of Al and Ti–Al coatings by mechanical alloying
19.1 Introduction
19.2 As-synthesised state
19.3 Annealing treatment of aluminium coating
19.4 Annealing treatment of the titanium/aluminium coating
19.5 Summary
19.6 References
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Tags: Titanium Alloys, Modelling, Microstructure Properties, Applications, Sha, Malinov