L. Xiuqing, R. Le-pierres, and S. J. Dewson, Heat Exchangers for the Next Generation of Nuclear Reactors, 2006.

F. Pra, P. Tochon, C. Mauget, J. Fokkens, and S. Willemsen, Promising Designs of Compact Heat Exchangers for Modular HTRs Using the Brayton Cycle, Nucl. Eng. Des, vol.238, issue.11, pp.3160-3173, 2008.

N. Bartel, M. Chen, V. P. Utgikar, X. Sun, I. Kim et al., Comparative Analysis of Compact Heat Exchangers for Application as the Intermediate Heat Exchanger for Advanced Nuclear Reactors, Ann. Nucl. Energy, vol.81, pp.143-149, 2015.

G. E. Totten, M. A. Howes, and T. Inoue, Handbook of Residual Stress and Deformation of Steel, 2002.

Z. Zhang, Y. Yang, L. Li, B. Chen, and H. Tian, Assessment of Residual Stress of 7050-T7452 Aluminum Alloy Forging Using the Contour Method, 2015.

. Sci and . Eng, , vol.644, pp.61-68

M. B. Prime, Cross-Sectional Mapping of Residual Stresses by Measuring the Surface Contour After a Cut, J. Eng. Mater. Technol, vol.123, issue.2, p.162, 2001.

M. B. Prime, M. A. Newborn, and J. A. Balog, Quenching and Cold-Work Residual Stresses in Aluminum Hand Forgings: Contour Method Measurement and FEM Prediction, Mater. Sci. Forum, pp.435-440, 2003.

M. B. Prime, R. J. Sebring, J. M. Edwards, D. J. Hughes, and P. J. Webster, Laser Surface-Contouring and Spline Data-Smoothing for Residual Stress Measurement, Exp. Mech, vol.44, issue.2, pp.176-184, 2004.

M. E. Kartal, C. D. Liljedahl, S. Gungor, L. Edwards, and M. E. Fitzpatrick, Determination of the Profile of the Complete Residual Stress Tensor in a VPPA Weld Using the Multi-Axial Contour Method, Acta Mater, vol.56, issue.16, pp.4417-4428, 2008.

P. Pagliaro, M. B. Prime, J. S. Robinson, B. Clausen, H. Swenson et al., Measuring Inaccessible Residual Stresses Using Multiple Methods and Superposition, Exp. Mech, vol.51, issue.7, pp.1123-1134, 2011.

P. Pagliaro, M. B. Prime, H. Swenson, and B. Zuccarello, Measuring Multiple Residual-Stress Components Using the Contour Method and Multiple Cuts, Exp. Mech, vol.50, issue.2, pp.187-194, 2010.

P. Pagliaro, M. B. Prime, B. Clausen, M. L. Lovato, and B. Zuccarello, Known Residual Stress Specimens Using Opposed Indentation, J. Eng. Mater. Technol, vol.131, issue.3, p.31002, 2009.

N. S. Rossini, M. Dassisti, K. Y. Benyounis, and A. G. Olabi, Methods of Measuring Residual Stresses in Components, Mater. Des, vol.35, pp.572-588, 2012.

F. Hosseinzadeh, Y. Traore, P. J. Bouchard, and O. Muránsky, Mitigating Cutting-Induced Plasticity in the Contour Method, Int. J. Solids Struct, pp.247-253, 2016.

M. R. Hill and M. D. Olson, Repeatability of the Contour Method for Residual Stress Measurement, Exp. Mech, vol.54, issue.7, pp.1269-1277, 2014.

X. Cerutti, Numerical modelling and mechanical analysis of the machining of large aeronautical parts : Machining quality improvement, 2014.
URL : https://hal.archives-ouvertes.fr/tel-01132857

V. Richter-trummer, Residual Stress Effects and Damage Tolerance Behaviour of Integral Lightweight Structures Manufactured by FSW and HSM, 2011.

G. S. Schajer, Relaxation Methods for Measuring Residual Stresses: Techniques and Opportunities, Exp. Mech, vol.50, issue.8, pp.1117-1127, 2010.

X. Huang, J. Sun, L. , and J. , Effect of Initial Residual Stress and Machining-Induced Residual Stress on the Deformation of Aluminium Alloy Plate, Stroj. Vestn. -J. Mech. Eng, vol.61, issue.2, pp.131-137, 2015.

S. Nervi and B. A. Szabó, On the Estimation of Residual Stresses by the Crack Compliance Method, Comput. Methods Appl. Mech. Eng, vol.196, pp.3577-3584, 2007.

B. Ekmekçi, N. Ekmekçi, A. E. Tekkaya, and A. Erden, RESIDUAL STRESS MEASUREMENT WITH LAYER REMOVAL METHOD, Proc. First Cappadocia Int. Mech. Eng. Symp, p.9, 2004.

S. Dreier and B. Denkena, Determination of Residual Stresses in Plate Material by Layer Removal with Machine-Integrated Measurement, Procedia CIRP, vol.24, pp.103-107, 2014.

F. Hospers and L. B. Vogelesang, Determination of Residual Stresses in Aluminum-Alloy Sheet Material: In Method Described by the Authors, Thin Layers Are Removed by Chemical Etching, Which Induces an Increasing Curvature of the Sheet. The Initial Distribution of the Residual Stress Is Derived from Curvature Measurements, Exp. Mech, vol.15, issue.3, pp.107-110, 1975.

I. C. Noyan, J. B. Cohen, J. B. Cohen, and J. B. Cohen, Residual Stress: Measurement by Diffraction and Interpretation, 1987.

K. Moussaoui, S. Segonds, W. Rubio, and M. Mousseigne, Studying the Measurement by X-Ray Diffraction of Residual Stresses in Ti6Al4V Titanium Alloy, Mater. Sci. Eng. A, vol.667, pp.340-348, 2016.
URL : https://hal.archives-ouvertes.fr/hal-01950787

D. A. Tanner, R. , and J. S. , Residual Stress Prediction and Determination in 7010 Aluminum Alloy Forgings, Exp. Mech, vol.40, issue.1, pp.75-82, 2000.

J. S. Robinson, S. Hossain, C. E. Truman, A. M. Paradowska, D. J. Hughes et al., Residual Stress in 7449 Aluminium Alloy Forgings, Mater. Sci. Eng. A, vol.527, pp.2603-2612, 2010.

J. S. Robinson, D. A. Tanner, C. E. Truman, and R. C. Wimpory, Measurement and Prediction of Machining Induced Redistribution of Residual Stress in the Aluminium Alloy 7449, Exp. Mech, vol.51, issue.6, pp.981-993, 2011.

P. Rangaswamy, M. L. Griffith, M. B. Prime, T. M. Holden, R. B. Rogge et al., Residual Stresses in LENS® Components Using Neutron Diffraction and Contour Method, Mater. Sci. Eng. A, vol.399, issue.1-2, pp.72-83, 2005.

F. A. Fernandes, L. C. Casteletti, G. E. Totten, and J. Gallego, Decomposition of Expanded Austenite in AISI 316L Stainless Steel Nitrided at 723K, Int. Heat Treat. Surf. Eng, vol.6, issue.3, pp.103-106, 2012.

W. Jiang, Y. Luo, B. Wang, W. Woo, and S. T. Tu, Neutron Diffraction Measurement and Numerical Simulation to Study the Effect of Repair Depth on Residual Stress in 316L Stainless Steel Repair Weld, J. Press. Vessel Technol, vol.137, issue.4, p.41406, 2015.

S. Pratihar, M. Turski, L. Edwards, and P. J. Bouchard, Neutron Diffraction Residual Stress Measurements in a 316L Stainless Steel Bead-on-Plate Weld Specimen, Int. J. Press. Vessels Pip, vol.86, issue.1, pp.13-19, 2009.

A. I. Committee, Properties and Selection: Irons, Steels, and High-Performance Alloys, 1990.

N. Bouquet, P. Sallamand, Y. Bienvenu, M. Tech, F. Valdivieso et al., Etude de la formation des joints soudés par diffusion : Application aux échangeurs de chaleur compacts, 2014.

H. Sassoulas, Traitements thermiques des aciers inoxydables, p.27, 2016.

L. Vanoverberghe, Anticipation des déformations lors du traitement thermique de pignons de boîtes de vitesses, 2008.

J. Barralis, L. Castex, and G. Maeder, Précontraintes et traitements superficiels, p.54, 1999.

L. Jubin, Influence des traitements thermiques de détensionnement et de stabilisation sur les structures en acier inoxydable austénitique (comparaison entre traitements à haute et basse température), 2003.

R. Wawszczak, A. Baczma?ski, M. Marciszko, M. Wróbel, T. Czeppe et al., Evolution of Microstructure and Residual Stress during Annealing of Austenitic and Ferritic Steels, Mater. Charact, vol.112, pp.238-251, 2016.
URL : https://hal.archives-ouvertes.fr/hal-02270676

A. I. Committee and J. Douthett, ASM Handbook: Heat Treating, 1991.

X. Cerutti, K. Mocellin, S. Hassini, B. Blaysat, and E. Duc, Methodology for Aluminium Part Machining Quality Improvement Considering Mechanical Properties and Process Conditions, CIRP J. Manuf. Sci. Technol, vol.18, pp.18-38, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01446181

Y. Yang, M. Li, and K. R. Li, Comparison and Analysis of Main Effect Elements of Machining Distortion for Aluminum Alloy and Titanium Alloy Aircraft Monolithic Component, Int. J. Adv. Manuf. Technol, vol.70, pp.1803-1811, 2014.

V. Richter-trummer, D. Koch, A. Witte, J. F. Santos, and P. Castro,

S. T. , Methodology for Prediction of Distortion of Workpieces Manufactured by High Speed Machining Based on an Accurate Through-the-Thickness Residual Stress Determination, Int. J. Adv. Manuf. Technol, vol.68, pp.2271-2281, 2013.

Y. Javadi, M. C. Smith, K. Venkata, N. Naveed, A. N. Forsey et al.,

P. J. Bouchard, H. C. Dey, A. K. Bhaduri, and S. Mahadevan, Residual Stress Measurement, 2017.

, Austenitic Stainless Steel 316L(N) and Ferritic Steel P91, vol.154, pp.41-57

M. Hofmann, W. Gan, and J. Rebelo-kornmeier, STRESS-SPEC: Materials Science Diffractometer, J. Large-Scale Res. Facil. JLSRF, p.1, 2015.

H. Brokmeier, W. M. Gan, C. Randau, M. Völler, J. Rebelo-kornmeier et al., Texture Analysis at Neutron Diffractometer STRESS-SPEC, Nucl. Instrum. Methods Phys. Res. A, vol.642, pp.87-92, 2011.

J. Rebelo-kornmeier, M. Hofmann, W. M. Gan, C. Randau, K. Braun et al., New Developments of the Materials Science Diffractometer STRESS-SPEC, vol.905, pp.151-156, 2017.

S. Hassini, Qualification multi-critères des gammes d'usinage: application aux pièces de structure aéronautique en alliage Airware®, 2015.

L. Liu, J. Sun, W. Chen, and P. Sun, Study on the Machining Distortion of Aluminum Alloy Parts Induced by Forging Residual Stresses, Proc. Inst. Mech, 2017.

. Eng, Part B J. Eng. Manuf, vol.231, issue.4, pp.618-627

M. A. Mannan and J. P. Sollie, A Force-Controlled Clamping Element for Intelligent Fixturing, CIRP Ann, vol.46, issue.1, pp.265-268, 1997.

J. K. Rai and P. Xirouchakis, Finite Element Method Based Machining Simulation Environment for Analyzing Part Errors Induced during Milling of Thin-Walled Components, Int. J. Mach. Tools Manuf, vol.48, issue.6, pp.629-643, 2008.

J. K. Rai and P. Xirouchakis, FEM-Based Prediction of Workpiece Transient Temperature Distribution and Deformations during Milling, Int. J. Adv. Manuf. Technol, vol.42, pp.429-449, 2009.

N. H. Wu and K. C. Chan, A Genetic Algorithm Based Approach to Optimal Fixture Configuration, Comput. Ind. Eng, vol.31, pp.919-924, 1996.

Y. Kang, Y. Rong, J. Yang, and W. Ma, Computer-aided Fixture Design Verification, Assem. Autom, vol.22, issue.4, pp.350-359, 2002.

A. Raghu and S. N. Melkote, Analysis of the Effects of Fixture Clamping Sequence on Part Location Errors, Int. J. Mach. Tools Manuf, vol.44, issue.4, pp.373-382, 2004.

J. R. Boerma and H. J. Kals, Fixture Design with FIXES: The Automatic Selection of Positioning, Clamping and Support Features for Prismatic Parts, CIRP Ann, vol.38, issue.1, pp.399-402, 1989.

, NF E25-030-2, Fixations -Assemblages Vissés à Filetage Métrique ISO -Partie 2, p.4, 2014.

G. Charrondière, École nationale supérieure d'arts et métiers, 2018.

, NF E66-520, Domaine de Fonctionnement Des Outils Coupants -Couple Outil-Matière, p.4, 1997.

O. Fergani, A. Mamedov, I. Lazoglu, J. G. Yang, and S. Y. Liang, Prediction of Residual Stress Induced Distortions in Micro-Milling of Al7050 Thin Plate, Appl. Mech. Mater, 2014.

O. Fergani, I. Lazoglu, A. Mkaddem, M. El-mansori, and S. Y. Liang, Analytical Modeling of Residual Stress and the Induced Deflection of a Milled Thin Plate, Int. J. Adv. Manuf. Technol, vol.75, issue.1-4, pp.455-463, 2014.

B. Toubhans, F. Viprey, G. Fromentin, and H. Karaouni, Prediction of Form Error during Face Turning on Flexible Inconel 718 Workpiece, Procedia CIRP, vol.82, pp.290-295, 2019.
URL : https://hal.archives-ouvertes.fr/hal-02177246

L. D'alvise, D. Chantzis, B. Schoinochoritis, and K. Salonitis, Modelling of Part Distortion Due to Residual Stresses Relaxation: An AerOnautical Case Study, Procedia CIRP, vol.31, pp.447-452, 2015.

A. R. Khoei, Extended Finite Element Method: Theory and Applications, 2015.

S. Osher and J. A. Sethian, Fronts Propagating with Curvature-Dependent Speed: Algorithms Based on Hamilton-Jacobi Formulations, J. Comput. Phys, vol.79, issue.1, pp.12-49, 1988.

F. Poulhaon, M. Rauch, A. Leygue, J. Y. Hascoet, and F. Chinesta, Online Prediction of Machining Distortion of Aeronautical Parts Caused by Re-Equilibration of Residual Stresses, Key Eng. Mater, pp.1327-1335, 2014.

S. P. Wang, A New Approach For FEM Simulation of NC Machining Processes, AIP Conference Proceedings, pp.1371-1376, 2004.

Y. Bi, Q. Cheng, H. Dong, and Y. Ke, Machining Distortion Prediction of Aerospace Monolithic Components, J. Zhejiang Univ.-Sci. A, vol.10, issue.5, pp.661-668, 2009.

H. Dong and Y. Ke, Study on Machining Deformation of Aircraft Monolithic Component by FEM and Experiment, Chin. J. Aeronaut, vol.19, issue.3, pp.247-254, 2006.

W. Li, L. Ma, M. Wan, J. Peng, and B. Meng, Modeling and Simulation of Machining Distortion of Pre-Bent Aluminum Alloy Plate, J. Mater. Process. Technol, vol.258, pp.189-199, 2018.

H. Karaouni, B. Souvestre, A. , and Y. , Machining Advanced Simulation: Distortion Prediction of Prestressed Machined Parts in NCSIMUL Environment, p.6, 2010.

X. Huang, J. Sun, L. , and J. , Finite Element Simulation and Experimental Investigation on the Residual Stress-Related Monolithic Component Deformation, Int. J. Adv. Manuf. Technol, vol.77, pp.1035-1041, 2015.

R. A. Izamshah, R. Mo, J. Ding, and S. L. , Finite Element Analysis of Machining Thin-Wall Parts, Key Eng. Mater, vol.458, pp.283-288, 2010.

L. Masset and J. Debongnie, Machining Processes Simulation: Specific Finite Element Aspects, J. Comput. Appl. Math, vol.168, pp.309-320, 2004.

K. Ma, R. Goetz, and S. K. Srivatsa, Modeling of Residual Stress and Machining Distortion in Aerospace Components (PREPRINT):, Defense Technical Information Center, 2010.

J. Li, W. , and S. , Distortion Caused by Residual Stresses in Machining Aeronautical Aluminum Alloy Parts: Recent Advances, Int. J. Adv. Manuf. Technol, vol.89, issue.1-4, pp.997-1012, 2017.

Y. Yang, M. Li, and K. R. Li, Comparison and Analysis of Main Effect Elements of Machining Distortion for Aluminum Alloy and Titanium Alloy Aircraft Monolithic Component, Int. J. Adv. Manuf. Technol, vol.70, pp.1803-1811, 2014.

T. D. Marusich, S. Usui, and K. J. Marusich, Finite Element Modeling of Part Distortion, Intelligent Robotics and Applications, pp.329-338, 2008.

A. Brosse, P. Naisson, H. Hamdi, and J. M. Bergheau, Temperature Measurement and Heat Flux Characterization in Grinding Using Thermography, J. Mater. Process. Technol, vol.201, pp.590-595, 2008.

P. Hervé, Mesure de l'émissivité thermique, p.16, 2005.

N. Barnier and P. Brisset, Optimisation par algorithme génétique sous contraintes, p.24

H. S. Hasan, M. J. Peet, J. M. Jalil, and H. K. Bhadeshia, Heat Transfer Coefficients during Quenching of Steels, Heat Mass Transf, vol.47, issue.3, pp.315-321, 2011.

H. S. Hasan, University of Technology in a partial fulfilment of the requirements, 2009.