polymachine/dissertation
1
0
Fork 0
Code Issues Pull requests Projects Releases Packages Wiki Activity Actions
dissertation/latex/Literatur/mevec.bib
Daniel G. Mevec 1f6f668a63 remane folder
2025-07-11 12:18:23 +02:00

3703 lines
155 KiB
BibTeX
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

% Encoding: UTF-8
@InCollection{schajer2013hole,
author = {Gary S. Schajer and Philip S. Whitehead},
title = {Hole drilling and ring coring},
chapter = {2},
isbn = {9781118402832},
pages = {29--60},
crossref = {schajer2013practical},
doi = {10.1002/9781118402832.ch2},
file = {:Eigenspng/Gary S. Schajer(eds.) - Practical Residual Stress
Measurement Methods (2013, Wiley) - libgen.lc.pdf:PDF},
groups = {RS measurement},
}
@InCollection{murray2013applied,
author = {Conal E. Murray and I. Cevdet Noyan},
title = {Applied and residual stress determination using x-ray diffraction},
chapter = {6},
isbn = {9781118402832},
pages = {139--162},
crossref = {schajer2013practical},
doi = {10.1002/9781118402832.ch6},
file = {:Eigenspng/Gary S. Schajer(eds.) - Practical Residual Stress
Measurement Methods (2013, Wiley) - libgen.lc.pdf:PDF},
groups = {RS measurement},
}
@InCollection{withers2013applied,
author = {Phillip John Withers},
title = {Synchrotron {X}-ray diffraction},
chapter = {7},
editor = {Gary S. Schajer},
isbn = {9781118402832},
pages = {163--194},
crossref = {schajer2013practical},
doi = {10.1002/9781118402832.ch7},
file = {:Eigenspng/Gary S. Schajer(eds.) - Practical Residual Stress
Measurement Methods (2013, Wiley) - libgen.lc.pdf:PDF},
groups = {RS measurement},
}
@InCollection{schajer2013overview,
author = {Gary S. Schajer and Clayton O. Ruud},
title = {Overview of residual stresses and their measurement},
chapter = {1},
isbn = {9781118402832},
pages = {1--27},
crossref = {schajer2013practical},
doi = {10.1002/9781118402832.ch1},
file = {:Eigenspng/Gary S. Schajer(eds.) - Practical Residual Stress
Measurement Methods (2013, Wiley) - libgen.lc.pdf:PDF},
groups = {RS measurement},
}
@InCollection{prime2013contour,
author = {Prime, Michael B. and DeWald, Adrian T.},
title = {The contour method},
chapter = {5},
isbn = {9781118402832},
pages = {109--138},
crossref = {schajer2013practical},
doi = {10.1002/9781118402832.ch5},
file = {:Eigenspng/Gary S. Schajer(eds.) - Practical Residual Stress
Measurement Methods (2013, Wiley) - libgen.lc.pdf:PDF},
groups = {RS measurement},
}
@article{ahn2005microstructural,
author = {Ahn, S. T. and Kim, D. S. and Nam, W. J.},
journal = {Journal of Materials Processing Technology},
title = {Microstructural evolution and mechanical properties of low alloyed
steel tempered by induction heating},
year = {2005},
number = {160},
pages = {54--58},
doi = {10.1016/j.jmatprotec.2004.03.019},
groups = {State-of-the-art},
}
@phdthesis{alveszapata2016magnetic,
author = {Alves Zapata, Jos{\'{e}} Rodolfo},
school = {PSL Research University},
title = {Magnetic pulse forming processes: computational modelling and
experimental validation},
year = {2016},
type = {Mechanic of materials [physics.class-ph]},
abstract = {Magnetic pulse forming is a technology that has gained interest
in the last decades -- thanks to the increased formability it
offers for high-resistance-low weight ratio materials such as
aluminum and magnesium alloys. One major complexity of the
process lies in the design and study at the work piece level and
the interaction between the several physical aspects involved:
the electromagnetic waves as source of energy, the
thermo-mechanics controlling the strain and stress evolution, as
well as the study of fracture and damage under high-speed loading
conditions. This work is dedicated to the development of a
predictive model and computational tool able to deal with the
interaction between the electromagnetism and the thermo-mechanics
in a 3D finite elements frame work. We introduce the
computational aspects of the electromagnetism, from the selected
approach to include the geometry of the parts down to the
coupling with the electric machinery behind the process. This is
followed by the computational techniques needed to couple the
electromagnetic computation to the thermo-mechanical one with a
special focus on the problem of tracking the displacement of the
deformable part within the electromagnetic module. We also
introduce some aspects more related to the physics of the process
such as the phenomena of elastic spring-back elimination and
surface bonding (welding). In the last chapter we present the
experimental facilities available at the laboratory. A
methodology for identification of the electric parameters
defining the machinery and needed to perform the simulation is
introduced.},
file = {:Alves2016_Diss_Magnetic pulse forming process - computational
modelling.pdf:PDF},
groups = {Process Simulation},
url = {https://pastel.archives-ouvertes.fr/tel-01417196},
}
@article{bay2018modelling,
author = {F. Bay and J. Alves and J. Barlier},
journal = {International Journal of Microstructure and Materials Properties},
title = {Modelling and optimisation of electromagnetically coupled solid
manufacturing processes},
year = {2018},
number = {1/2},
pages = {16--26},
volume = {13},
doi = {10.1063/1.5008061},
groups = {Induction Heating},
}
@article{antretter2002thermo,
author = {Antretter, Thomas and Fischer, F. D. and Lube, Tanja and Tanaka,
K. and Cailletaud, G.},
journal = {Journal of Intelligent Material Systems and Structures},
title = {The thermo-mechanical response to a general loading path of a
martensitic transforming steel},
year = {2002},
pages = {811--815},
volume = {13},
doi = {10.1177/1045389X02013012006},
groups = {TRIP},
keywords = {MaterialModellierung},
ranking = {rank1},
}
@article{barglik2017influence,
author = {Jerzy Barglik and Albert Smalcerz},
journal = {COMPEL-The international journal for computation and mathematics
in electrical and electronic engineering},
title = {Influence of the magnetic permeability on modeling of induction
surface hardening},
year = {2017},
number = {2},
pages = {555--564},
volume = {36},
doi = {10.1108/COMPEL-05-2016-0240},
groups = {Induction Heating},
}
@article{bioul2005application,
author = {Bioul, F. and Dupret, F.},
journal = {IEEE Transactions on Magnetics},
title = {Application of asymptotic expansions to model two dimensional
induction heating systems. {P}art {I}: {C}alculation of
electromagnetic field distribution},
year = {2005},
number = {9},
pages = {2496--2505},
volume = {41},
doi = {10.1109/TMAG.2005.854325},
groups = {Induction},
}
@article{bioul2005applicationa,
author = {Bioul, F. and Dupret, F.},
journal = {IEEE Transactions on Magnetics},
title = {Application of asymptotic expansions to model two dimensional
induction heating systems. {P}art {II}: {C}alculation of equivalent
surface stresses and heat flux},
year = {2005},
number = {9},
pages = {2506--2514},
volume = {41},
doi = {10.1109/TMAG.2005.854324},
groups = {Induction},
}
@article{boadi2005designing,
author = {A. Boadi and Y. Tsuchida and T. Todaka and M. Enokizono},
journal = {IEEE Transactions on Magnetics},
title = {Designing of suitable construction of high-frequency induction
heating coil by using finite-element method},
year = {2005},
issn = {1941-0069},
number = {10},
pages = {4048--4050},
volume = {41},
abstract = {This paper describes the three-dimensional (3-D) modeling of an
induction heating system. To realize the suitable construction of
a high-frequency induction heating coil, numerical computations
of eddy currents and heat conduction have been carried out by
using the finite-element method (FEM) and also taking into
account the dependence of material properties on temperature. For
a high-frequency induction heating coil, which is normally
applicable for heat treatment, the tubular solenoid design is the
most appropriate due to its high coil efficiency. Coil efficiency
is that part of energy delivered to the coil, which is
transferred to the workpiece. Besides coil efficiency, the
heating pattern and the production rate are also important. As
the heating pattern reflects the coil geometry, optimal coil
design is a prerequisite to attain the desired heating. Several
modifications, such as spacing in between coil turns, the motion
of the workpiece relative to the coil, and dimensional parameters
, were carried out until optimal design was achieved.},
doi = {10.1109/TMAG.2005.854993},
groups = {Inductor design},
keywords = {induction heating;radiofrequency heating;coils;eddy
currents;heat conduction;finite element analysis;circuit
optimisation;high-frequency induction heating coil;finite element
method;3D modeling;eddy currents;heat conduction;material
properties;heat treatment;tubular solenoid design;heating
pattern;coil geometry;coil turns;Coils;Finite element
methods;Heating;Heat treatment;Eddy currents;Material
properties;Temperature
dependence;Solenoids;Production;Geometry;Finite-element method
(FEM);high-frequency;induction heating;optimized coil},
}
@inproceedings{bocher2013simulation,
author = {Bocher, P. and Mingardi, D. and Larregain, B. and Bridier, F. and
Dughiero, F. and Spezzapria, M.},
booktitle = {International Conference on Heating by Electromagnetic Sources},
title = {Simulation of fast induction surface heating and comparison with
experimental full-field surface temperature measurements},
year = {2013},
address = {Padova, Italy},
pages = {99--108},
publisher = {Servici Grafici Editoriali},
date = {21--24 May 2013},
groups = {Induction Heating, IH vs convetional},
}
@conference{boehm2014measurement,
author = {Boehm, Andreas and Hahn, Ingo},
booktitle = {Industrial Electronics Society, IECON 2014 - 40th Annual
Conference of the IEEE},
title = {Measurement of magnetic properties of steel at high temperatures},
year = {2014},
organization = {IEEE},
publisher = {IEEE},
doi = {10.1109/IECON.2014.7048579},
groups = {Magnetic Properties},
}
@article{broitman2017indentation,
author = {Broitman, Esteban},
journal = {Tribology Letters},
title = {Indentation hardness measurements at macro-, micro-, and nanoscale:
a critical overview},
year = {2017},
number = {1},
pages = {23},
volume = {65},
publisher = {Springer},
}
@article{bui2015modeling,
author = {Huy-Tien Bui and Sheng-Jye Hwang},
journal = {International Journal of Heat and Mass Transfer},
title = {Modeling a working coil coupled with magnetic flux concentrators
for barrel induction heating in an injection molding machine},
year = {2015},
pages = {16--30},
volume = {86},
doi = {10.1016/j.ijheatmasstransfer.2015.02.057},
groups = {Magnetic Properties},
keywords = {Rapid heating Coil design Coupling Magnetic flux concentrator
Induction heating linearMu},
}
@book{carslaw1959conduction,
author = {Carslaw, Horatio Scott and Jaeger, John Conrad},
publisher = {Oxford: Clarendon Press},
title = {Conduction of heat in solids},
year = {1959},
edition = {2nd ed},
groups = {State-of-the-art},
}
@book{tumanski2011handbook,
author = {Tumanski, Slawomir},
publisher = {CRC Press},
title = {Handbook of Magnetic Measurements},
year = {2011},
edition = {1st ed},
groups = {State-of-the-art},
}
@article{chan2016simpler,
author = {Timothy M. Chan},
journal = {Discrete \& Computational Geometry},
title = {A simpler linear-time algorithm for intersecting two convex
polyhedra in three dimensions},
year = {2016},
number = {4},
pages = {860--865},
volume = {56},
doi = {10.1007/s00454-016-9785-3},
groups = {Geometry Intersection},
}
@article{chazelle1992optimal,
author = {Bernard Chazelle},
journal = {SIAM Journal on Computing},
title = {An optimal algorithm for intersecting three-dimensional convex
polyhedra},
year = {1992},
number = {4},
pages = {671--696},
volume = {21},
doi = {10.1137/0221041},
groups = {Geometry Intersection},
}
@article{coupard2008residual,
author = {Coupard, Dominique and Palin-luc, Thierry and Bristiel, Philippe
and Ji, Vincent and Dumas, Christian},
journal = {Materials Science & Engineering A: Structural Materials:
Properties, Microstructure and Processing},
title = {Residual stresses in surface induction hardening of steels: {C}
omparison between experiment and simulation},
year = {2008},
number = {1-2},
pages = {328--339},
volume = {487},
doi = {10.1016/j.msea.2007.10.047},
groups = {Induction Heating},
keywords = {Verification,},
publisher = {Elsevier},
}
@Article{diluozzo2012modelling,
author = {Di Luozzo, Nicolas and Fontana, Marcelo and Arcondo, Bibiana},
journal = {Journal of Alloys and Compounds},
title = {Modelling of induction heating of carbon steel tubes: {M} athematical analysis, numerical simulation and validation},
year = {2012},
pages = {S564--S568},
volume = {536},
doi = {https://doi.org/10.1016/j.jallcom.2011.12.084},
file = {diluozzo2012_Modelling_of_induction_heating_of_carbon_steel_tubes_-_Mathematical_analysis_numerical_simulation_and_validation.pdf:Simulating_Induction
\\
diluozzo2012_Modelling_of_induction_heating_of_carbon_steel_tubes_-_Mathematical_analysis_numerical_simulation_and_validation.pdf:PDF},
groups = {Induction Heating},
publisher = {Elsevier},
}
@article{drobenko2007mathematical,
author = {Drobenko, B. and Hachkevych, O. and Kournyts'kyi, T.},
journal = {International Journal of Heat and Mass Transfer},
title = {A mathematical simulation of high temperature induction heating of
electroconductive solids},
year = {2007},
pages = {616--624},
volume = {50},
doi = {10.1016/j.ijheatmasstransfer.2006.07.013},
groups = {Induction Heating},
}
@article{dolezel2005continual,
author = {Dole{\vz}el, Ivo and Barglik, Jerzy and Bohu{\vs}, Ulrych},
journal = {Journal of Materials Processing Technology},
title = {Continual induction hardening of axi-symmetric bodies},
year = {2005},
pages = {269--275},
volume = {161},
doi = {10.1016/j.jmatprotec.2004.07.035},
groups = {Induction Heating},
keywords = {Analytisch},
}
@InProceedings{drexler2015yield,
author = {Drexler, A. and Maderbacher, H. and Povodon-Karadeniz, E. and G{\" {a}}nser, H.-P. and Ecker, W. and Oberwinkler, B. and Fischersworring-Bunk, A.},
booktitle = {European Conference on Heat Treatment 2015 and 22nd IFHTSE Congress - Heat Treatment and Surface Engineering from Tradition to Innovation},
title = {Yield stress evolution in {I}nconel 718 samples under standard heat treatment process conditions of turbine disks},
year = {2015},
url = {https://www.researchgate.net/profile/Andreas_Drexler/publication/277871441_Yield_stress_evolution_in_Inconel_718_samples_under_standard_heat_treatment_process_conditions_of_turbine_disks/links/56ab589408ae8f3865698046.pdf},
}
@article{eggbauer2019situ,
author = {Eggbauer, Annika and Lukas, Marina and Ressel, Gerald and Prevedel
, Petri and Mendez-Martin, Francisca and Keckes, Jozef and Stark,
Andreas and Ebner, Reinhold},
journal = {Journal of Materials Science},
title = {In situ analysis of the effect of high heating rates and initial
microstructure on the formation and homogeneity of austenite},
year = {2019},
number = {12},
pages = {9197--9212},
volume = {54},
doi = {10.1007/s10853-019-03527-3},
groups = {Own},
publisher = {Springer},
url = {https://doi.org/10.1007/s10853-019-03527-3},
}
@inproceedings{esl2013efficient,
author = {E{\ss}l, Werner and Antretter, Thomas and Parteder, Erik},
booktitle = {Key Engineering Materials},
title = {An efficient algorithm for modeling the thermo-mechanical material
response of heavy steel plates during accelerated cooling},
year = {2013},
organization = {Trans Tech Publ},
pages = {749--763},
volume = {554},
doi = {10.4028/www.scientific.net/KEM.554-557.749},
groups = {Material Modeling},
}
@InProceedings{ferguson2013modeling,
author = {Ferguson, L. and Li, Z. and Nemkov, V. and Goldstein, R. and Jackowski, J. and Fett, G.},
booktitle = {International Conference on Heating by Electromagnetic Sources},
title = {Modeling stress and distortion of full-float truck axle during induction hardening process},
year = {2013},
address = {Padova, Italy},
pages = {109--116},
publisher = {Servici Grafici Editoriali},
date = {21-24 May 2013},
groups = {Induction Heating},
url = {https://fluxtrol.com/inc/pdf/MODELING-STRESS-AND-DISTORTION-OF-FULL-FLOAT-TRUCK-AXLE-DURING-INDUCTION-HARDENING-PROCESS.pdf},
}
@article{fiorillo2014international,
author = {Fiorillo, F. and Beatrice, C. and Son, D. and Ahnlers, Franz Josef
and Groessinger, R. and Albertini, F. and Liu, J. P. and Lin, A.
and Patroni, E. and Shull, R. and Thomas, O. and Hall, M. J.},
journal = {International Journal of Applied Electromagnetics and Mechanics},
title = {International comparison of measurement of hard magnets with the
vibrating sample magnetometer},
year = {2014},
pages = {245--252},
volume = {44},
doi = {10.3233/JAE-141786},
groups = {Magnetic Properties},
}
@article{fisk2018modeling,
author = {M. Fisk and L.-E. Lindgren and W. Datchary and V. Deshmukh},
journal = {Finite Elements in Analysis and Design},
title = {Modelling of induction hardening in low alloy steels},
year = {2018},
pages = {61--75},
volume = {144},
abstract = {Induction hardening is a useful method for improving resistance
to surface indentation, fatigue and wear that is favoured in
comparison with through hardening, which may lack necessary
toughness. The process itself involves fast heating by induction
with subsequent quenching, creating a martensitic layer at the
surface of the workpiece. In the present work, we demonstrate how
to simulate the process of induction hardening using a commercial
finite element software package with focuses on validation of the
electromagnetic and thermal parts, together with evolution of the
microstructure. Experiments have been carried out using fifteen
workpieces that have been heated using three different heating
rates and five different peak temperatures resulting in different
microstructures. It is found that the microstructure and
hardening depth is affected by the heating rate and peak
temperature. The agreement between the experimental and simulated
results is good. Also, it is demonstrated that the critical
equilibrium temperatures for phase transformation is important
for good agreement between the simulated and experimental
hardening depth. The developed simulation technique predicts the
hardness and microstructure sufficiently well for design and the
development of induction hardening processes.},
doi = {10.1016/j.finel.2018.03.002.},
file = {:Fisk (2018) - Modelling of Induction Hardening in Low Alloy
Steels.pdf:PDF},
groups = {Induction Heating},
keywords = {Induction heating, Austenite, Martensite, Ferromagnetism, AISI
4150, 50CrMo4,},
ranking = {rank4},
relevance = {relevant},
url = {http://www.sciencedirect.com/science/article/pii/S0168874X17307564},
}
@Article{gleim2015nonlinear,
author = {Tobias Gleim and Bettina Schr{\"{o}}der and Detlef Kuhl},
journal = {Archive of Applied Mechanics},
title = {Nonlinear thermo-electromagnetic analysis of inductive heating processes},
year = {2015},
number = {8},
pages = {1055--1073},
volume = {85},
doi = {10.1007/s00419-014-0968-1},
file = {:Simulating_Induction/Gleim2015_Article_NonlinearThermo-electromagneti.pdf:PDF},
groups = {Magnetic Properties},
}
@article{grum2001review,
author = {Grum, Janez},
journal = {Journal of Materials Processing Technology},
title = {A review of the influence of grinding conditions on resulting
residual stresses after induction surface hardening and grinding},
year = {2001},
number = {3},
pages = {212--226},
volume = {114},
doi = {10.1016/S0924-0136(01)00562-3},
groups = {residual stress},
publisher = {Elsevier},
}
@article{grum2007overview,
author = {Grum, Janez},
journal = {International Journal of Materials and Product Technology},
title = {Overview of residual stresses after induction surface hardening},
year = {2007},
number = {1-4},
pages = {9--42},
volume = {29},
doi = {10.1504/IJMPT.2007.013129},
groups = {residual stress},
publisher = {Inderscience Publishers},
}
@article{grum2007influence,
author = {Grum, Janez},
journal = {International Journal of Materials and Product Technology},
title = {Influence of induction surface heating and quenching on residual
stress profiles, followed by grinding},
year = {2007},
number = {1-4},
pages = {211--227},
volume = {29},
doi = {10.1504/IJMPT.2007.013136},
groups = {residual stress},
publisher = {Inderscience Publishers},
}
@article{hameyer1999classification,
author = {Hameyer, Kay and Driesen, Johan and De Gersem, Herbert and Belmans
, Ronnie},
journal = {IEEE Transactions on Magnetics},
title = {The classification of coupled field problems},
year = {1999},
month = may,
number = {3},
pages = {1618--1621},
volume = {35},
doi = {10.1109/20.767304},
groups = {State-of-the-art},
}
@article{holmberg2016residual,
author = {Jonas Holmberg and Axel Steuwer and Albin Sormvinter and Hans
Kristoffersen and Merja Haakanen and Johan Berglung},
journal = {Materials Science & Engineering A: Structural Materials:
Properties, Microstructure and Processing},
title = {Residual stress state in an induction hardened steel bar determined
by synchrotron- and neutron diffraction compared to results from
lab-{XRD}},
year = {2016},
pages = {199--207},
volume = {667},
doi = {10.1016/j.msea.2016.04.075},
file = {:Holmeberg2016a_Residual stress state in an induction hardened steel
bar determined by synchrotron-and neutron diffraction compared to
results from lab-XRD.pdf:PDF},
groups = {RS measurement},
}
@article{hoemberg2015analysis,
author = {H{\"o}mberg, Dietmar and Petzold, Thomas and Rocca, Elisabetta},
journal = {Nonlinear Analysis: Real World Applications},
title = {Analysis and simulations of multifrequency induction hardening},
year = {2015},
pages = {84--97},
volume = {22},
doi = {10.1016/j.nonrwa.2014.07.007},
groups = {Induction Heating},
publisher = {Elsevier},
}
@article{hoemberg2016simulation,
author = {H{\"o}mberg, Dietmar and Liu, Qingzhe and Montalvo-Urquizo,
Jonathan and Nadolski, Dawid and Petzold, Thomas and Schmidt,
Alfred and Schulz, Alwin},
journal = {Finite Elements in Analysis and Design},
title = {Simulation of multi-frequency-induction-hardening including phase
transitions and mechanical effects},
year = {2016},
pages = {86--100},
volume = {121},
doi = {10.1016/j.finel.2016.07.012},
groups = {Induction Heating},
publisher = {Elsevier},
}
@InProceedings{hornbach1995x,
author = {Hornbach, Douglas J. and Prev{\'e}y, Paul S. and Mason, Perry W.},
booktitle = {Proceedings of the First International Conference on Hardened Gears and Critical Components, Gear Research Institute},
title = {X-ray diffraction characterization of the residual stress and hardness distributions in induction hardened gears},
year = {1995},
address = {Gear Research Institute, Indianapolis, IN, USA},
organization = {Citeseer},
pages = {69--76},
date = {15-17 May 1995},
groups = {RS measurement},
url = {http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.327.4245&rep=rep1&type=pdf},
}
@book{nacke2016induction,
editor = {Bernhard Nacke and Egbert Baake},
publisher = {Vulkan Verlag},
title = {{Induction Heating: Heating | Hardening | Annealing | Brazing |
Welding}},
year = {2016},
isbn = {978-3-8027-2391-9},
groups = {State-of-the-art},
}
@article{ionita2009correction,
author = {Ionita, Valentin and Cazacu, Emil},
journal = {IEEE Transactions on Magnetics},
title = {Correction of measured magnetization curves using finite element
method},
year = {2009},
month = mar,
number = {3},
pages = {1174--1177},
volume = {45},
doi = {10.1109/TMAG.2009.2012673},
groups = {Magnetic Properties},
}
@article{istardi2011induction,
author = {Istardi, Didi and Triwinarko, Andy},
journal = {Telkomnika},
title = {Induction heating process design using {COMSOL}\textregistered
multiphysics software},
year = {2011},
month = aug,
number = {2},
pages = {327--334},
volume = {9},
groups = {Induction Heating},
url = {http://www.jogjapress.com/index.php/TELKOMNIKA/article/view/1321},
}
@Article{james2007residual,
author = {James, M. N. and Hughes, D. J. and Chen, Z. and Lombard, H. and Hattingh, D. G. and Asquith, D. and Yates, J. R. and Webster, P. J.},
journal = {Engineering Failure Analysis},
title = {Residual stresses and fatigue performance},
year = {2007},
number = {2},
pages = {384--395},
volume = {14},
doi = {10.1016/j.engfailanal.2006.02.011},
groups = {residual stress, Own},
publisher = {Elsevier},
}
@article{kagimoto2010effect,
author = {Kagimoto, Hiroyuki and Miyagi, Daisuke and Takahashi, Norio and
Uchida, Naoki and Kawanaka, Keiji},
journal = {IEEE Transactions on Magnetics},
title = {Effect of temperature dependence of magnetic properties on heating
characteristics of induction heater},
year = {2010},
month = aug,
number = {8},
pages = {3018--3021},
volume = {46},
doi = {10.1109/TMAG.2010.2046145},
groups = {Inductor design},
}
@inproceedings{kaltenbrunner2016influence,
author = {Kaltenbrunner, T. and Antretter, T. and Ecker, W. and Kaiser, R.
and G{\"{a}}nser, H.-P. and Parteder, E.},
booktitle = {10th International Rolling Conference},
title = {Influence of the levelling process on the mechanical properties of
heavy steel plates},
year = {2016},
address = {Graz},
groups = {Own},
}
@inproceedings{kaltenbrunner2017experimental,
author = {Kaltenbrunner, Thomas and Ecker, Werner and Antretter, Thomas and
Kaiser, Robert and Parteder, Erik and Egger, Rupert},
booktitle = {AIP Conference Proceedings},
title = {Experimental and computational approach to evaluate the effect of
leveling on the change of tensile properites of heavy steel plates},
year = {2017},
number = {1},
organization = {AIP Publishing},
pages = {160006},
volume = {1896},
doi = {10.1063/1.5008181},
groups = {Own},
}
@article{katoh1999study,
author = {Katoh, Mitsuaki and Nishio, Kazumasa and Yamaguchi, Tomiko},
journal = {NDT\&E International},
title = {Study on demagnetizing field in coil method using {FEM}},
year = {1999},
month = apr,
number = {3},
pages = {147--152},
volume = {32},
doi = {10.1016/S0963-8695(98)00065-6},
groups = {magnetics},
}
@Article{kielhorn2017simulation,
author = {Kielhorn, Lars and R{\"u}berg, Thomas and Zechner, J{\"{u}}rgen},
journal = {COMPEL-The international journal for computation and mathematics in electrical and electronic engineering},
title = {Simulation of electrical machines -- a {FEM}--{BEM} coupling scheme},
year = {2017},
month = sep,
number = {5},
pages = {1540--1551},
volume = {36},
abstract = {Electrical machines commonly consist of moving and stationary
parts. The field simulation of such devices can be very demanding
if the underlying numerical scheme is solely based on a domain
discretization, such as in case of the Finite Element Method
(FEM). Here, a coupling scheme based on FEM together with
Boundary Element Methods (BEM) is presented that neither hinges
on re-meshing techniques nor deals with a special treatment of
sliding interfaces. While the numerics are certainly more
involved the reward is obvious: The modeling costs decrease and
the application engineer is provided with an easy-to-use,
versatile, and accurate simulation tool.},
doi = {10.1108/COMPEL-02-2017-0061},
file = {:Kielhorn2017_FEMBEM_coupling.pdf:PDF},
groups = {FEM},
ranking = {rank1},
}
@MastersThesis{klausen2018treatise,
author = {Kristj{\'a}n {\'O}ttar Klausen},
school = {Faculty of Physical Sciences, University of Iceland},
title = {A treatise on the magnetic vector potential},
year = {2018},
groups = {State-of-the-art},
url = {https://skemman.is/bitstream/1946/29521/3/KOK_MagneticVectorPotential.pdf},
}
@InCollection{koutschan2011numerical,
author = {Koutschan, Christoph and Lehrenfeld, Christoph and Sch{\"o}berl, Joachim},
booktitle = {Numerical and symbolic scientific computing: progress and prospects},
publisher = {Springer Wien},
title = {Computer algebra meets finite elements: an efficient implementation of maxwell's equations},
year = {2011},
editor = {Langer, Ulrich and Paule, Peter},
pages = {105--121},
doi = {10.1007/978-3-7091-0794-2_6},
groups = {FEM},
keywords = {Analytisch},
}
@Article{kozeschnik2004modified,
author = {Kozeschnik, E. and Svoboda, J. and Fischer, F. D.},
journal = {Calphad - Computer Coupling of Phase Diagrams and Thermochemistry},
title = {Modified evolution equations for the precipitation kinetics of complex phases in multi-component systems},
year = {2004},
number = {4},
pages = {379--382},
volume = {28},
doi = {10.1016/j.calphad.2004.11.003},
groups = {Own, Phase Transformations},
publisher = {Elsevier},
}
@article{kozeschnik2006shape,
author = {Kozeschnik, E. and Svoboda, J. and Fischer, F. D.},
journal = {Materials Science & Engineering A: Structural Materials:
Properties, Microstructure and Processing},
title = {Shape factors in modeling of precipitation},
year = {2006},
number = {1-2},
pages = {68--72},
volume = {441},
doi = {10.1016/j.msea.2006.08.088},
groups = {Own, Phase Transformations},
publisher = {Elsevier},
}
@inproceedings{kozeschnik2007computer,
author = {Kozeschnik, Ernst and Sonderegger, Bernhard and Holzer, Ivan and
Rajek, Joachim and Cerjak, Horst},
booktitle = {Materials science forum},
title = {Computer simulation of the precipitate evolution during industrial
heat treatment of complex alloys},
year = {2007},
organization = {Trans Tech Publ},
pages = {2431--2436},
volume = {539},
doi = {10.4028/www.scientific.net/MSF.539-543.2431},
groups = {Own, Process Simulation},
}
@article{kranjc2010numerical,
author = {Kranjc, Matej and Zupanic, Anze and Miklavcic, Damijan and Jarn,
Tomaz},
journal = {International Journal of Heat and Mass Transfer},
title = {Numerical analysis and thermographic investigation of indction
heating},
year = {2010},
pages = {3585--3591},
volume = {53},
doi = {10.1016/j.ijheatmasstransfer.2010.04.030},
groups = {Induction Heating},
}
@article{kristoffersen2001influence,
author = {Kristoffersen, H. and Vomacka, P.},
journal = {Materials \& Design},
title = {Influence of process parameters for induction hardening on residual
stresses},
year = {2001},
number = {8},
pages = {637--644},
volume = {22},
doi = {10.1016/S0261-3069(01)00033-4},
groups = {residual stress},
publisher = {Elsevier},
}
@article{kumar2015parallel,
author = {Sushil Kumar and Lionel Fourment and Simon Guerdoux},
journal = {Finite Elements in Analysis and Design},
title = {Parallel, second-order and consistent remeshing transfer operators
forevolving meshes with superconvergence property on surfaceand
volume},
year = {2015},
pages = {70--84},
volume = {93},
abstract = {This paper investigates several field transfer techniques that
can be used to remap data between three-dimensional unstructured
meshes, either after full remeshing of the computational domain
or after mesh regularization resulting from an ALE (Arbitrary
Lagrangian or Eulerian) formulation. The transfer is focused on
state (or secondary) variables that are piecewise discontinuous
and consequently only defined at integration points. The proposed
methods are derived from recovery techniques that have initially
been developed by Zienkiwicz et al. in the frame of error
estimation. Obtaining a higher order interpolation with the
recovered fields allows reducing the inescapable diffusion error
resulting from the projection on the new mesh. Several variants
of the method are investigated: (a) either based on nodal patches
or on element patches, (b) by enforcing the balance equation in a
weak sense or in a strong sense or not, (c) by using first or
second interpolation orders. A special attention is paid to the
accuracy of the transfer operators for surface values, which can
play a first order role in several mechanical problems. In order
to take into account the constraint due to parallel calculations,
a new iterative approach is proposed. All methods are evaluated
and compared on analytical tests functions, both for the ALE
formulation and for full remeshings, before being applied to an
actual metal forming problem. In all studied examples, in
addition to improved accuracy, higher order convergence rates are
observed both for volume and surface values, so providing quite
accurate transfer operators for various applications.},
doi = {http://dx.doi.org/10.1016/j.finel.2014.09.002},
groups = {FEM},
url = {http://dx.doi.org/10.1016/j.finel.2014.09.002},
}
@article{kurose20093,
author = {Kurose, Hiroaki and Miyagi, Daisuke and Takahashi, Norio and
Uchida, Naoki and Kawanaka, Keiji},
journal = {IEEE Transactions on Magnetics},
title = {{3--D} eddy current analysis of induction heating apparatus
considering heat emission, heat conduction, and temperature
dependence of magnetic characteristics},
year = {2009},
month = mar,
number = {3},
pages = {1847--1850},
volume = {45},
doi = {10.1109/TMAG.2009.2012829},
groups = {magnetics, Induction Heating},
}
@article{labridis1988finite,
author = {Dimitris Labridis and Petros Dokopoulos},
journal = {IEEE Transactions on Power Delivery},
title = {Finite element comuptation of field, losses, and forces in a
three-phase gas cable with non-symmetrical conductor arrangement},
year = {1988},
number = {4},
pages = {1326--1333},
volume = {3},
doi = {10.1109/61.193927},
file = {:Simulating_Induction/Labridis1988_Finite element computation of
field, losses and forces in a three-phase gas cable with
nonsymmetrical conductor arrangement.pdf:PDF},
groups = {Induction},
keywords = {MaterialModellierung},
}
@article{labridis1989calculation,
author = {Dimitris Labridis and Petros Dokopoulos},
journal = {IEEE Transactions on Magnetics},
title = {Calculation of eddy current losses in nonlinear ferromagnetic
materials},
year = {1989},
number = {3},
pages = {2665--2669},
volume = {25},
doi = {10.1109/20.24506},
file = {:Simulating_Induction/Labridis1989_Calculation of Eddy Current
Losses in Nonlinear Ferromagnetic Materials.pdf:PDF},
groups = {Induction},
keywords = {MaterialModellierung},
}
@article{labridis1992finite,
author = {Dimitris Labridis and Petros Dokopoulos},
journal = {IEEE Transactions on Power Delivery},
title = {Finite element computation of eddy current losses in nonlinear
sheaths of three-phase power cables},
year = {1992},
number = {3},
pages = {1060--1067},
volume = {7},
doi = {10.1109/61.141814},
file = {:Simulating_Induction/Labridis1992_Finite element computation of
eddy current losses in nonlinear ferromagnetic sheaths of three-phase
power cables.pdf:PDF},
groups = {Induction},
keywords = {MaterialModellierung},
}
@article{landek2004computer,
author = {Landek, Darko and Cajner, Franjo and Filetin, Tomislav},
journal = {Journal de Physique IV (Proceedings)},
title = {Computer simulation of induction surface hardening axially
symmetric workpieces},
year = {2004},
month = dec,
pages = {499--506},
volume = {120},
doi = {10.1051/jp4:2004120057},
groups = {Induction Heating},
}
@article{lavers2008state,
author = {Lavers, J. D.},
journal = {COMPEL-The international journal for computation and mathematics
in electrical and electronic engineering},
title = {State of the art of numerical modeling for induction processes},
year = {2008},
number = {2},
pages = {335--349},
volume = {27},
doi = {10.1108/03321640810847625},
groups = {FEM},
ranking = {rank2},
}
@article{li2016non,
author = {Li, Huiping and Gai, Kang and He, Lianfang and Zhang, Chunzhi and
Cui, Hongzhi and Li, Musen},
journal = {Materials \& Design},
title = {Non-isothermal phase-transformation kinetics model for evaluating
the austenization of {55CrMo} steel based on {Johnson--Mehl--Avrami}
equation},
year = {2016},
pages = {731--741},
volume = {92},
doi = {10.1016/j.matdes.2015.12.110},
groups = {Phase Transformations},
keywords = {MaterialModellierung},
publisher = {Elsevier},
}
@phdthesis{lundquist2001harmonic,
author = {Lundquist, Johan},
school = {Chalmers University of Technology},
title = {On harmonic distortion in power systems},
year = {2001},
}
@inproceedings{markegard2007optimized,
author = {Markeg{\aa}rd, Leif and Kristoffersen, H.},
booktitle = {Swedish Suppliers of Heat Treatment Equipment Conference},
title = {Optimized properties of car components--an explanation of how
residual stress is created during surface hardening},
year = {2007},
address = {Eskilstuna, Sweden},
date = {13-14 September 2007},
groups = {residual stress},
}
@article{martinsegura2012simulation,
author = {Mart{\'i}n-Segura, Guillermo and Ferrater-Sim{\'o}n, Coia and L{\'
o}pez-Mestre, Joaquim and Montesinos-Miracle, Daniel and Bergas-Jan
{\'e}, Joan},
journal = {COMPEL-The international journal for computation and mathematics
in electrical and electronic engineering},
title = {Simulation of an induction hardening system during {Curie}
temperature transition considering converter's performance},
year = {2012},
number = {1},
pages = {396--411},
volume = {32},
doi = {10.1108/03321641311293957},
groups = {Induction Heating},
publisher = {Emerald Group Publishing Limited},
}
@article{mevec2019getting,
author = {Mevec, Daniel and Raninger, Peter and Prevedel, Petri and J{\'a}
szfi, Vince and Antretter, Thomas},
journal = {HTM - Journal of Heat Treatment and Materials},
title = {Getting to know your own induction furnace: {B}asic principles to
guarantee meaningful simulations},
year = {2019},
number = {4},
pages = {267--276},
volume = {74},
doi = {https://doi.org/10.3139/105.110389},
file = {:Mevec2019-Getting to Know Your Induction Furnace.pdf:PDF},
groups = {Own},
publisher = {Carl Hanser Verlag},
}
@inproceedings{mevec2019den,
author = {Mevec, Daniel and Raninger, Peter and Prevedel, Petri and J{\'{a}}
szfi, Vinze and Antretter, Thomas},
booktitle = {ASMET Werkstofftechniktagung \& 31. H{\"{a}}rtereitagung 2019},
title = {Den eigenen {I}nduktionsofen kennenlernen: {G}rundlagen zur {G}ew{
\"{a}}hrleistung aussagekr{\"{a}}ftiger {S}imulationen},
year = {2019},
pages = {137--146},
publisher = {ASMET - Austrian Society for Metallurgy and Materials},
groups = {Own},
ranking = {rank1},
}
@article{moreno2012analysis,
author = {Moreno, J. M. D{\'\i}az and V{\'a}zquez, C. Garc{\'\i}a and
Montesinos, M. T. Gonz{\'a}lez and Gallego, F. Orteg{\'o}n},
journal = {Journal of Computational and Applied Mathematics},
title = {Analysis and numerical simulation of an induction--conduction model
arising in steel heat treating},
year = {2012},
number = {12},
pages = {3007--3015},
volume = {236},
doi = {10.1016/j.cam.2011.04.007},
groups = {Induction Heating},
publisher = {Elsevier},
}
@article{morishita2001examination,
author = {Morishita, Masayuki and Takahashi, Norio and Miyagi, Daisuke and
Nakano, Masanori},
journal = {Przeglad Elektrotechniczny (Electrical Review)},
title = {Examination of magnetic properties of several magnetic materials at
high temperature},
year = {2001},
number = {9b},
pages = {106--110},
volume = {87},
groups = {Magnetic Properties},
url = {http://www.pe.org.pl/articles/2011/9b/25.pdf},
}
@article{nerg1999dynamic,
author = {Nerg, J. and Tolsa, K. and Silventoinen, P. and Partanen, J. and
Pyrh{\"o}nen, J.},
journal = {IEEE Transactions on Magnetics},
title = {A dynamic model for the simulation of induction heating devices},
year = {1999},
month = sep,
number = {5},
pages = {3592--3594},
volume = {33},
doi = {10.1109/20.800600},
groups = {Induction Heating},
}
@article{paoli1998time,
author = {Paoli, Gerhard and B\'ir\'o, Oszk\'ar},
journal = {COMPEL-The international journal for computation and mathematics
in electrical and electronic engineering},
title = {Time harmonic eddy currents in non-linear media},
year = {1998},
number = {5/6},
pages = {567--575},
volume = {17},
comment = {Details 3D Flux Magnitude},
doi = {10.1108/03321649810220865},
file = {:Paoli1998.pdf:PDF},
groups = {magnetics},
}
@article{pugh2011demagnetizing,
author = {Pugh, B. K. and Kramer, D. P. and Chen, C. H.},
journal = {IEEE Transactions on Magnetics},
title = {Demagnetizing factors for various geometries precisely determined
iusing {3--D} eelectromagnetic field simulation},
year = {2011},
month = sep,
number = {10},
pages = {4100--4103},
volume = {47},
doi = {10.1109/TMAG.2011.2157994},
groups = {magnetics,},
}
@article{rhein2015dynamische,
author = {Rhein, S{\"o}nke and Utz, Tilman and Graichen, Knut},
journal = {at - Automatisierungstechnik},
title = {Dynamische {O}pimierung von {M}ultiphysik-{P}roblemen am {B}eispiel
induktiver {H}eizvorg{\"a}nge},
year = {2015},
number = {9},
pages = {713--726},
volume = {63},
doi = {10.1515/auto-2015-0029},
file = {:Simulating_Induction/Rhein2015_Dynamische Optimierung von
Multiphysik-Problemen am Beispiel induktiver Heizvorgänge.pdf:PDF},
groups = {FEM},
}
@book{rudnev2014asm,
editor = {Valery Rudnev and George Totten},
publisher = {A S M International},
title = {{ASM} handbook volume {4C}: induction heating and heat treatment},
year = {2014},
isbn = {978-1-62708-012-5},
groups = {State-of-the-art},
}
@Book{rudnev2017handbook,
author = {Rudnev, Valery and Loveless, Don and Cook, Raymond and Black, Micah},
editor = {Marcel Dekker},
publisher = {CRC Press},
title = {Handbook of induction heating},
year = {2017},
address = {New York, NY, USA},
edition = {second},
isbn = {9781466553972},
month = jul,
doi = {10.1201/9781315117485},
groups = {State-of-the-art},
}
@article{sackl2014induction,
author = {Sackl, Stephanie and Leitner, Harald and Zuber, Michael and
Clemens, Helmut and Primig, Sophie},
journal = {Metallurgical and Materials Transactions A: Physical Metallurgy
and Materials Science},
title = {Induction hardening vs conventional hardening of a heat treatable
steel},
year = {2014},
number = {12},
pages = {5657--5666},
volume = {45},
doi = {10.1007/s11661-014-2518-4},
groups = {IH vs convetional},
publisher = {Springer},
}
@article{sackl2016induction,
author = {Sackl, Stephanie and Zuber, Michael and Clemens, Helmut and Primig
, Sophie},
journal = {Metallurgical and Materials Transactions A: Physical Metallurgy
and Materials Science},
title = {Induction tempering vs conventional tempering of a heat-treatable
steel},
year = {2016},
number = {7},
pages = {3694--3702},
volume = {47},
doi = {10.1007/s11661-016-3534-3},
groups = {IH vs convetional},
publisher = {Springer},
}
@article{sadeghipour1996computer,
author = {Sadeghipour, K. and Dopkin, J. A. and Li, K.},
journal = {Computers in Industry},
title = {A computer aided finite element/experimental analysis of induction
heating process of steel},
year = {1996},
issn = {0166-3615},
number = {3},
pages = {195--205},
volume = {28},
abstract = {The characteristics of steels during electroplating or induction
heating are very complex. Induction heat-treating of steel has
become increasingly important as a means of reducing cost and
improving the quality of carbon steel components. The use of high
frequency (40 to 200kHz) offers many advantages, but tooling and
cycle optimization is complex and time consuming. Approximate
analytical methods suitable for low-frequency approximations are
not sufficient for the low-frequency domain and the fact that
important material properties change drastically with temperature
makes more exact analysis methods very difficult to implement.
Therefore, a powerful computer aided numerical tool (i.e., finite
element analysis) is selected to numerically model an induction
heating process. A general-purpose finite element program was
employed to simulate and analyze the above problem. The
combination of magnetic and thermal routines, within the package,
enabled us to complete the task. A coupling method between the
two magnetic and thermal routines was also developed and
implemented. This was done to incorporate the change in the
material properties due to the change in temperature. For the
sake of comparison and verification, a high-frequency induction
heating experiment was set up and a series of tests was
performed. The finite element results were evaluated and compared
with the experimental results. The effect of the time duration
size (time step) for coupling between the magnetic and thermal
analyses was also studied. Particular attention was given to the
coupling procedure after the Curie temperature was reached. The
skin effect was studied and demonstrated in the numerical model.
A discussion of induced power density profile and transient
temperature distribution is also presented. The accuracy and
efficiency of the numerical models are demonstrated and
appreciated. This tool is therefore proposed to be a powerful
alternative prior to the actual induction heating process.},
doi = {https://doi.org/10.1016/0166-3615(95)00072-0},
file = {:Simulating_Induction/sadeghipour1996computer.pdf:PDF},
groups = {Induction Heating},
keywords = {Finite element analysis, Induction heating, Surface hardening},
url = {http://www.sciencedirect.com/science/article/pii/0166361595000720},
}
@article{savaria2012computational,
author = {Savaria, Vincent and Bridier, Florent and Bocher, Philippe},
journal = {International Journal of Mechanical Sciences},
title = {Computational quantification and correction of the errors induced
by layer removal for subsurface residual stress measurements},
year = {2012},
number = {1},
pages = {184--195},
volume = {64},
doi = {10.1016/j.ijmecsci.2012.07.003},
groups = {RS measurement},
publisher = {Elsevier},
}
@article{savaria2015measurement,
author = {Savaria, Vincent and Monajati, Hossein and Bridier, Florent and
Bocher, Philippe},
journal = {Journal of Materials Processing Technology},
title = {Measurement and correction of residual stress gradients in
aeronautical gears after various induction surface hardening
treatments},
year = {2015},
pages = {113--123},
volume = {220},
doi = {10.1016/j.jmatprotec.2014.12.009},
groups = {RS measurement},
publisher = {Elsevier},
}
@InProceedings{schemmel2014modelling,
author = {Schemmel, Manuel and Prevedel, Petri and Sch{\"o}ngrundner, Ronald and Ecker, Werner and Antretter, Thomas},
booktitle = {Proceedings -- European Conference on Heat Treatment and 21st IFHTSE Congress},
title = {Modelling of phase transformations and residual stress formation in hot-work tool steel components},
year = {2014},
pages = {285--292},
groups = {Material Modeling},
keywords = {MaterialModellierung},
ranking = {rank1},
url = {https://www.researchgate.net/profile/Petri_Prevedel/publication/264598708_Modelling_of_phase_transformations_and_residual_stress_formation_in_hot-work_tool_steel_components/links/56a2051008ae24f6270452a1.pdf},
}
@article{schemmel2015size,
author = {Schemmel, Manuel and Prevedel, Petri and Sch{\"o}ngrundner, Ronald
and Ecker, Werner and Antretter, Thomas},
journal = {Advances in Materials Science and Engineering},
title = {Size effects in residual stress formation during quenching of
cylinders made of hot-work tool steel},
year = {2015},
volume = {2015},
doi = {10.1155/2015/678056},
file = {:phasen/Schemmel2015_Size Effects in Residual Stress Formation
during Quenching of Cylinders Made of Hot-Work Tool Steel.pdf:PDF},
groups = {Material Modeling},
keywords = {MaterialModellierung},
publisher = {Hindawi},
ranking = {rank1},
}
@book{schwenk2012numerische,
author = {Schwenk, Maximilian},
publisher = {KIT, Fakult{\"{a}}t f{\"{u}}r Maschinenbau (MACH), Institut f{
\"{u}}r Angewandte Materialien-Werkstoffkunde (IAM-WK)},
title = {Numerische {M}odellierung der induktiven {E}in-und {Z}
weifrequenzrandschichth{\"a}rtung},
year = {2012},
isbn = {978-3-86644-929-9},
doi = {10.5445/KSP/1000030463},
file = {:Schwenk2012a_Numerische Modellierung der induktiven Ein- und
Zweifrequenzrandschichthärtung.pdf:PDF},
groups = {Material Modeling},
}
@inproceedings{shan2014determination,
author = {Shan, Yao V. and Svoboda, Ji{\v{r}}{\'\i} and Fischer, Franz
Dieter and Kozeschnik, E.},
booktitle = {Advanced Materials Research},
title = {Determination of substitutional-interstitial interaction from
chemical potentials of interstitials in the steel matrix},
year = {2014},
organization = {Trans Tech Publ},
pages = {645--650},
volume = {922},
doi = {10.4028/www.scientific.net/AMR.922.645},
}
@article{shmilovitz2005definition,
author = {Shmilovitz, Doron},
journal = {IEEE Transactions on Power Delivery},
title = {On the definition of total harmonic distortion and its effect on
measurement interpretation},
year = {2005},
month = jan,
number = {1},
pages = {526--528},
volume = {20},
doi = {10.1109/TPWRD.2004.839744},
groups = {measurement},
keywords = {signal processing},
}
@article{song2016coupled,
author = {Song, Min Churl and Moon, Young Hoon},
journal = {Applied Thermal Engineering},
title = {Coupled electromagnetic and thermal analysis of induction heating
for the forging of marine crankshafts},
year = {2016},
pages = {98--109},
volume = {98},
doi = {10.1016/j.applthermaleng.2015.11.129},
groups = {IH Crankshafts},
publisher = {Elsevier},
}
@article{sun2018numerical,
author = {Jianliang Sun and Shuo Li and Chouwu Qiu and Yan Peng},
journal = {Applied Thermal Engineering},
title = {Numerical and experimental investigation of induction heating
process of heavy cylinder},
year = {2018},
issn = {1359-4311},
pages = {341--352},
volume = {134},
abstract = {In this work, the induction heating of heavy cylinder is
numerically and experimentally studied. The
electromagnetic-temperature-stress multi-field coupling
simulation are performed, using the ANSYS software in order to
investigated the induction heating process of heavy cylinder,
simulation results show that the end of heavy cylinder would be
overheating and burning because of the acute angle effect and the
high magnetic flux density when the rectangular coil is used. And
then, the acute angle effect problem of heavy cylinder in the
induction heating process is investigated, a solution of welding
heat treatment ring at the end of the heavy cylinder and adding
the magnetizer at the end of coil is proposed, and the acute
angle effect can be eliminated. Furthermore, the heating effects
of heavy cylinder by traditional heating method and induction
heating method proposed are compared, simulation results show
that the heating efficiency and the energy saving of induction
heating are improved greatly. Finally, the heat treatment
experiment of heavy cylinder material based on induction heating
is investigated, experiment results show that the mechanical
properties of the heavy cylinder can meet the application
requirements.},
doi = {https://doi.org/10.1016/j.applthermaleng.2018.01.101},
groups = {Induction Heating, IH vs convetional},
keywords = {Heavy cylinder, Induction heating, Acute angle effect, Rapid
heat treatment},
url = {http://www.sciencedirect.com/science/article/pii/S1359431117353474},
}
@article{svoboda2014determination,
author = {Svoboda, J. and Shan, Y. V. and Kozeschnik, E. and Fischer, F. D.},
journal = {Modelling and Simulation in Materials Science and Engineering},
title = {Determination of depths of multiple traps for interstitials and
their influence on diffusion kinetics},
year = {2014},
number = {6},
pages = {065015},
volume = {22},
doi = {10.1088/0965-0393/22/6/065015},
publisher = {IOP Publishing},
}
@article{svoboda2015kinetics,
author = {Svoboda, J. and Zickler, G. A. and Kozeschnik, E. and Fischer, F.
D.},
journal = {Philosophical Magazine Letters},
title = {Kinetics of interstitial segregation in {C}ottrell atmospheres and
grain boundaries},
year = {2015},
number = {9},
pages = {458--465},
volume = {95},
doi = {10.1080/09500839.2015.1087652},
publisher = {Taylor \& Francis},
}
@article{takahashi2010examination,
author = {Takahashi, Norio and Morishita, Masayuki and Miyagi, Daisuke and
Nakano, Masanori},
journal = {IEEE Transactions on Magnetics},
title = {Examination of magnetic properties of magnetic materials at high
temperature using a ring specimen},
year = {2010},
month = feb,
number = {2},
pages = {548--551},
volume = {46},
doi = {10.1109/TMAG.2009.2033122},
groups = {Magnetic Properties},
}
@article{takahashi2011comparison,
author = {Takahashi, Norio and Morishita, Masayuki and Miyagi, Daisuke and
Nakano, Masanori},
journal = {IEEE Transactions on Magnetics},
title = {Comparison of magnetic properties of magnetic material at high
temperature},
year = {2011},
month = oct,
number = {10},
pages = {4352--4355},
volume = {47},
doi = {10.1109/TMAG.2011.2158517},
groups = {Magnetic Properties},
}
@article{tong2018numerical,
author = {Daming Tong and Jianfeng Gu and Fan Yang},
journal = {Journal of Materials Processing Technology},
title = {Numerical simulation on induction heat treatment process of a shaft
part: {I}nvolving induction hardening and tempering},
year = {2018},
volume = {262},
doi = {10.1016/j.jmatprotec.2018.06.043},
file = {:Simulating_Induction/tong2018numerical.pdf:PDF},
groups = {Induction Heating},
}
@inproceedings{vieweg2016induction,
author = {Vieweg, Annika and Ressel, Gerald and Prevedel, Petri and Raninger
, Peter and Panzenb{\"o}ck, Michael and Marsoner, Stefan and Ebner,
Reinhold},
booktitle = {IOP Conference Series: Materials Science and Engineering},
title = {Induction hardening: {D}ifferences to a conventional heat treatment
process and optimization of its parameters},
year = {2016},
number = {1},
organization = {IOP Publishing},
pages = {012019},
volume = {119},
doi = {10.1088/1757-899X/119/1/012019},
groups = {IH vs convetional, Own},
}
@article{vieweg2017experimental,
author = {Vieweg, Annika and Raninger, P. and Prevedel, P. and Ressel, G.
and Ecker, W. and Marsoner, S. and Ebner, R.},
journal = {HTM - Journal of Heat Treatment and Materials},
title = {Experimental and numerical analysis of the inductive tempering of a
{QT}-steel},
year = {2017},
number = {4},
pages = {199--204},
volume = {72},
doi = {https://doi.org/10.3139/105.110328},
file = {:Vieweg2017_Inductive Tempering of a QT-Steel.pdf:PDF},
groups = {Own},
publisher = {Carl Hanser Verlag Kolbergerstrasse 22, Postfach 86 04 20,
D-81679 Munich},
}
@unpublished{vieweginfluences,
author = {Vieweg, Annika},
note = {Submitted to Metallurgical and Materials Transactions A: Physical
Metallurgy and Materials Science},
title = {Influences of continuous austenitizing treatments and different
prior microstructures of the austenitic and martensitic state of a {
50CrMo4} steel},
groups = {Own},
}
@article{vieweg2017phase,
author = {Vieweg, Annika},
journal = {Materials and Design},
title = {Phase evolution and carbon redistribution during continuous
tempering of martensite studied with high resolution techniques},
year = {2017},
month = dec,
note = {Quelle für Martensit Start Temperatur},
pages = {214--222},
volume = {136},
doi = {10.1016/j.matdes.2017.09.065},
file = {:Vieweg2017phase_evolution.pdf:PDF},
groups = {Own},
}
@article{vieweg2017effects,
author = {Vieweg, Annika and Ressel, Georg and Prevedel, Petri and Marsoner,
Stefan and Ebner, R.},
journal = {HTM - Journal of Heat Treatment and Materials},
title = {Effects of the inductive hardening process on the martensitic
structure of a {50CrMo4} steel},
year = {2017},
number = {1},
pages = {3--9},
volume = {72},
doi = {10.3139/105.110308},
file = {:Vieweg2017_Effects of the Inductive Hardening Process.pdf:PDF},
groups = {Own},
publisher = {Carl Hanser Verlag},
}
@article{webster2001residual,
author = {Webster, G. A. and Ezeilo, A. N.},
journal = {International Journal of Fatigue},
title = {Residual stress distributions and their influence on fatigue
lifetimes},
year = {2001},
month = sep,
pages = {375--383},
volume = {23},
doi = {10.1016/S0142-1123(01)00133-5},
groups = {residual stress},
publisher = {Elsevier},
}
@article{zgraja2003computer,
author = {Zgraja, Jerzy and Bereza, Jerzy},
journal = {COMPEL-The international journal for computation and mathematics
in electrical and electronic engineering},
title = {Computer simulation of induction heating system with series
inverter},
year = {2003},
number = {1},
pages = {48--57},
volume = {22},
doi = {10.1108/03321640310452015},
file = {:Simulating_Induction/zu lesen/Zgraja2003_Computer simulatioon of
iduction system with series inverter.pdf:PDF},
groups = {Induction Heating},
}
@article{zhang2014fast,
author = {Zhang, Richard Y. and White Jacob, K. and Kassakian John, G.},
journal = {IEEE Transactions on Magnetics},
title = {Fast simulation of complicated {3--D} structure above lossy
magnetic media},
year = {2014},
month = oct,
number = {10},
pages = {1--16},
volume = {50},
doi = {10.1109/TMAG.2014.2323933},
groups = {magnetics},
}
@article{diez2015rational,
author = {Diez, Patrick and Webb, J. P.},
journal = {IEEE Transactions on Magnetics},
title = {A rational approach to {$B$--$H$} curve representation},
year = {2015},
number = {3},
pages = {1--4},
volume = {52},
doi = {10.1109/TMAG.2015.2488360},
file = {:Diez_2015_-_Raional_BH_Curve_Representation.pdf:PDF},
groups = {Induction},
keywords = {MaterialModellierung},
publisher = {IEEE},
related = {fischer1956die,trutt1968representation},
}
@article{fischer1956die,
author = {Fischer, Johannes and Moser, Herbert},
journal = {Archiv f{\"u}r Elektrotechnik},
title = {Die {N}achbildung von {M}agnetisierungskurven durch einfache
algebraische oder transzendente {F}unktionen},
year = {1956},
number = {5},
pages = {286--299},
volume = {42},
doi = {10.1007/BF01407417},
file = {:fischer1956.pdf:PDF},
groups = {Induction},
keywords = {MaterialModellierung},
publisher = {Springer},
}
@article{trutt1968representation,
author = {F. C. Trutt and E. A. Erdelyi and R. E. Hopkins},
journal = {IEEE Transactions on Power Apparatus and Systems},
title = {Representation of the magnetization characteristic of {DC} machines
for computer use},
year = {1968},
number = {3},
pages = {665--669},
volume = {PAS-87},
doi = {10.1109/TPAS.1968.292178},
file = {:trutt1968.pdf:PDF},
groups = {Induction},
keywords = {MaterialModellierung},
}
@article{silva2009exact,
author = {Silva, Gustavo H. C. and Le Riche, Rodolphe and Molimard, J{\'e}r{
\^o}me and Vautrin, Alain},
journal = {European Journal of Computational Mechanics/Revue Europ{\'e}enne
de M{\'e}canique Num{\'e}rique},
title = {Exact and efficient interpolation using finite elements shape
functions},
year = {2009},
number = {3-4},
pages = {307--331},
volume = {18},
doi = {10.3166/ejcm.18.307-331},
file = {:Intersection-Algorithms/Silva2007_-_exact_interpolation.pdf:PDF},
groups = {Geometry Intersection},
publisher = {Taylor \& Francis},
}
@article{avrami1940kinetics,
author = {Avrami, Melvin},
journal = {The Journal of Chemical Physics},
title = {Kinetics of phase change. {II} transformation-time relations for
random distribution of nuclei},
year = {1940},
number = {2},
pages = {212--224},
volume = {8},
doi = {10.1063/1.1750631},
file = {:phasen/avrami1940.pdf:PDF},
groups = {Phase Transformations},
keywords = {MaterialModellierung},
publisher = {American Institute of Physics},
}
@article{avrami1939kinetics,
author = {Avrami, Melvin},
journal = {The Journal of Chemical Physics},
title = {Kinetics of phase change. {I} general theory},
year = {1939},
number = {12},
pages = {1103--1112},
volume = {7},
doi = {10.1063/1.1750380},
file = {:phasen/avrami1939.pdf:PDF},
groups = {Modeling, Phase Transformations},
keywords = {MaterialModellierung},
publisher = {American Institute of Physics},
}
@article{avrami1941kinetics,
author = {Avrami, Melvin},
journal = {The Journal of Chemical Physics},
title = {Kinetics of phase change. {III} granulation, phase change, and
microstructure},
year = {1941},
number = {2},
pages = {177--184},
volume = {9},
doi = {10.1063/1.1750872},
file = {:phasen/avrami1941.pdf:PDF},
groups = {Phase Transformations},
keywords = {MaterialModellierung},
publisher = {American Institute of Physics},
}
@article{scheil1935anlaufzeit,
author = {Scheil, Erich},
journal = {Archiv f{\"u}r das Eisenh{\"u}ttenwesen},
title = {Anlaufzeit der austenitumwandlung},
year = {1935},
number = {12},
pages = {565--567},
volume = {8},
doi = {10.1002/srin.193500186},
file = {:phasen/Scheil1935_Anlaufzeit der Austenitumwandlung.pdf:PDF},
groups = {Phase Transformations},
publisher = {Wiley Online Library},
}
@Article{clarke2020perspectives,
author = {Clarke, A. J. and Klemm-Toole, J. and Clarke, K. D. and Coughlin, D. R. and Pierce, D. T. and Euser, V. K. and Poplawsky, J. D. and Clausen, B. and Brown, D. and Almer, J. and others},
journal = {Metallurgical and Materials Transactions A},
title = {Perspectives on quenching and tempering 4340 steel},
year = {2020},
pages = {1--22},
doi = {10.1007/s11661-020-05972-1},
file = {:Clarke2020_Perspectives-on-Quenching-and-Tempering-4340-Steel.pdf:PDF},
publisher = {Springer},
}
@article{mevec2020posteriori,
author = {Mevec, Daniel G. and Raninger, Peter and Prevedel, Petri and J{\'a
}szfi, Vince},
journal = {Scientific Reports},
title = {A posteriori reconstruction of the temperature distribution in
surface hardened tempering steel},
year = {2020},
number = {1},
pages = {1--8},
volume = {10},
doi = {10.1038/s41598-020-63328-6},
groups = {Own},
publisher = {Nature Publishing Group},
}
@article{baldan2020improving,
author = {Baldan, M. and Stolte, M. H. and Nacke, B. and Nürnberger, F.},
journal = {IEEE Transactions on Magnetics},
title = {Improving the accuracy of {FE} simulations of induction tempering
toward a microstructure-dependent electromagnetic model},
year = {2020},
number = {10},
pages = {1-9},
volume = {56},
doi = {10.1109/TMAG.2020.3013562},
file = {:Simulating_Induction/Baldan2020_Improving the accuracy of FE
simulations of induction tempering towards a microstructure-dependent
electromagnetic mode.pdf:PDF},
groups = {Induction Heating},
}
@article{mcmeekin2017improving,
author = {McMeekin, Kevin and Sirois, Fr{\'e}d{\'e}ric and Tousignant,
Maxime and Bocher, Philippe},
journal = {COMPEL-The international journal for computation and mathematics
in electrical and electronic engineering},
title = {Improving the accuracy of time-harmonic fe simulations in induction
heating applications},
year = {2017},
doi = {10.1108/COMPEL-05-2016-0203},
file = {:Simulating_Induction/McMeekin2017.pdf:PDF},
groups = {FEM},
publisher = {Emerald Publishing Limited},
}
@article{dibarba2017benchmark,
author = {Di Barba, Paolo and Mognaschi, Maria Evelina and Lowther, D. A.
and Dughiero, Fabrizio and Forzan, Michele and Lupi, S. and Sieni,
Elisabetta},
journal = {International Journal of Applied Electromagnetics and Mechanics},
title = {A benchmark problem of induction heating analysis},
year = {2017},
number = {S1},
pages = {S139--S149},
volume = {53},
doi = {10.3233/JAE-162249},
file = {:Simulating_Induction/dibarba2016.pdf:PDF},
groups = {FEM},
publisher = {IOS Press},
}
@incollection{arimoto2016thermally,
author = {Arimoto, Kyozo},
booktitle = {Encyclopedia of Iron, Steel, and Their Alloys (Online Version)},
publisher = {CRC Press},
title = {Thermally-processed steels: residual stresses and distortion},
year = {2016},
pages = {3605--3633},
doi = {10.1081/E-EISA-120049221},
file = {:Eigenspng/arimoto2016_thermally_Processed Steels_ Residual Stresses
and Distortion.pdf:PDF},
groups = {residual stress},
}
@inproceedings{schell2008high,
author = {Schell, Norbert and Martins, Ren{\'e} V. and Beckmann, Felix and
Ruhnau, Hans Ulrich and Kiehn, R{\"u}diger and Schreyer, Andreas},
booktitle = {Materials Science Forum},
title = {The high energy materials science beamline at {PETRA III}},
year = {2008},
organization = {Trans Tech Publ},
pages = {261--266},
volume = {571},
groups = {measurement},
}
@online{fit2d,
title = {The fit2d home page},
url = {https://www.esrf.eu/computing/scientific/FIT2D/},
urldate = {2020-11-30},
}
@article{david1986powder,
author = {David, W. I. F.},
journal = {Journal of applied crystallography},
title = {Powder diffraction peak shapes. {P}arameterization of the pseudo-{
Voigt} as a {Voigt} function},
year = {1986},
number = {1},
pages = {63--64},
volume = {19},
doi = {10.1107/S0021889886089999},
groups = {RS measurement},
publisher = {International Union of Crystallography},
}
@article{eck2014using,
author = {Eck, Sven and Prevedel, Petri and Marsoner, Stefan and Ecker,
Werner and Illmeier, M.},
journal = {Journal of materials engineering and performance},
title = {Using finite element simulation to optimize the heat treatment of
tire protection chains},
year = {2014},
number = {4},
pages = {1288--1295},
volume = {23},
doi = {10.1007/s11665-013-0854-y},
file = {:Eigenspng/2014_Sven Eck_Using Finite Element Simulation to Optimize
the Heat Treatment of Tire Protection Chains_JMEP.pdf:PDF},
groups = {Process Simulation, TRIP},
publisher = {Springer},
}
@article{leuning2019correlation,
author = {Leuning, N. and Steentjes, S. and Heller, M. and Korte-Kerzel, S.
and Hameyer, K.},
journal = {Journal of Magnetism and Magnetic Materials},
title = {On the correlation of crystallographic macro-texture and magnetic
magnetization anisotropy in non-oriented electrical steel},
year = {2019},
pages = {165485},
volume = {490},
comment = {Zeigt dass (in Elektrostahl) die Magnetische Sättigung von der
Chemie und nicht der Mikrostruktur abhängt!},
doi = {10.1016/j.jmmm.2019.165485},
file = {:Magnetometrie/Leuning2019_On the correlation of crystallographic
macro-texture and magnetic magnetization anisotropy in non-oriented
electrical steel.pdf:PDF},
groups = {Induction},
publisher = {Elsevier},
}
@article{todt2018gradient,
author = {J. Todt and J. Keckes and G. Winter and P. Staron and A.
Hohenwarter},
journal = {Scripta Materialia},
title = {Gradient residual strain and stress distributions in a high
pressure torsion deformed iron disk revealed by high energy x-ray
diffraction},
year = {2018},
issn = {1359-6462},
pages = {178-181},
volume = {146},
abstract = {High energy X-ray diffraction is used to investigate for the
first time the distribution of residual X-ray elastic stresses
inside a high pressure torsion (HPT) deformed iron disk with a
diameter and thickness of ~30 and ~8mm, respectively. In the
experiment, a dedicated conical slit system restricts the
diffraction gauge volume in three dimensions to ~0.45mm3, which
is then used to scan the bulk sample cross-section in a
non-invasive manner. Pronounced residuals stress gradients with
maximal tensile stresses of ~200MPa are observed along radial and
tangential directions and are correlated to the deformation
gradient arising from HPT.},
doi = {https://doi.org/10.1016/j.scriptamat.2017.11.037},
file = {:Eigenspng/Todt2018gradient.pdf:PDF},
groups = {RS measurement},
keywords = {High-pressure torsion, Ultrafine grained microstructure, Iron,
Synchrotron radiation, Residual stresses},
url = {https://www.sciencedirect.com/science/article/pii/S1359646217306760},
}
@article{pickering2013macrosegregation,
author = {Pickering, Edward John},
journal = {ISIJ international},
title = {Macrosegregation in steel ingots: the applicability of modelling
and characterisation techniques},
year = {2013},
number = {6},
pages = {935--949},
volume = {53},
doi = {https://doi.org/10.2355/isijinternational.53.935},
publisher = {The Iron and Steel Institute of Japan},
}
@book{cain1984hardening,
author = {Tubal Cain},
publisher = {Argus Books Ltd},
title = {Hardening, tempering and heat treatment},
year = {1984},
address = {UK},
isbn = {978-0852428375},
groups = {State-of-the-art},
}
@manual{2010holedrilling,
title = {Measurement of residual stresses by the hole-drilling strain gage
method},
month = nov,
organization = {Vishay Precision Group},
year = {2010},
file = {:Eigenspng/Measurement of Residual Stresses by the Hole-Drilling
Strain Gage Method.pdf:PDF},
groups = {RS measurement},
url = {http://www.vishaypg.com/docs/11053/tn503.pdf},
}
@Collection{schajer2013practical,
doi = {10.1002/9781118402832},
edition = {1st ed},
editor = {Schajer, Gary S.},
groups = {RS measurement},
isbn = {9781118342374},
publisher = {John Wiley \& Sons},
title = {Practical residual stress measurement methods},
year = {2013},
}
@article{mathar1934determination,
author = {Mathar, Josef},
journal = {Trans. ASME},
title = {Determination of initial stresses by measuring the deformation
around drilled holes},
year = {1934},
number = {4},
pages = {249--254},
volume = {56},
groups = {RS measurement},
}
@article{sachs1927detection,
author = {Sachs, G.},
journal = {Zeitschift f\"ur Metallkunde},
title = {The detection of internal stresses in rods and tubes},
year = {1927},
pages = {352--357},
volume = {19},
groups = {RS measurement},
}
@article{hattori1929cause,
author = {Hattori, D.},
journal = {Sci. Rep. Tohoku Imp. Univ., Ser},
title = {On the cause of quenching deformation in tool steels},
year = {1929},
pages = {665--698},
volume = {1},
groups = {residual stress},
}
@article{drexler2017finite,
author = {Drexler, Andreas and Ecker, Werner and Hessert, Roland and
Oberwinkler, Bernd and Gänser, Hans-Peter and Keckes, Jozef and
Hofmann, Michael and Fischersworring-Bunk, Andreas},
journal = {AIP Conference Proceedings},
title = {Finite element modeling of the residual stress evolution in forged
and direct-aged alloy 718 turbine disks during manufacturing and its
experimental validation},
year = {2017},
number = {1},
pages = {070001},
volume = {1896},
doi = {10.1063/1.5008076},
eprint = {https://aip.scitation.org/doi/pdf/10.1063/1.5008076},
groups = {Process Simulation, residual stress},
url = {https://aip.scitation.org/doi/abs/10.1063/1.5008076},
}
@book{bhadeshia2006steels,
author = {Bhadeshia, Harshad Kumar Dharamshi Hansraj and Honeycombe, Robert},
publisher = {Butterworth-Heinemann},
title = {Steels: microstructure and properties},
year = {2006},
edition = {3rd ed},
file = {:Harry Bhadeshia, Robert Honeycombe - Steels_ Microstructure and
Properties, Third Edition (2006) - libgen.lc.pdf:PDF},
groups = {State-of-the-art},
}
@Article{sorger2019local,
author = {Sorger, Gon{\c{c}}alo and Vila{\c{c}}a, Pedro and Santos, Telmo G.},
journal = {Scientific reports},
title = {Local magnetic flux density measurements for temperature control of transient and non-homogeneous processing of steels},
year = {2019},
number = {1},
pages = {1--11},
volume = {9},
doi = {10.1038/s41598-019-54503-5},
file = {:Magnetometrie/sorger2019local - Local Magnetic Flux Density
Measurements for Temperature Control of Transient and Non Homogeneous
Processing of Steels.PDF:PDF},
publisher = {Nature Publishing Group},
}
@article{gomes2010correlation,
author = {Gomes, E. and Schneider, J. and Verbeken, K. and Barros, J. and
Houbaert, Y.},
journal = {IEEE Transactions on Magnetics},
title = {Correlation between microstructure, texture, and magnetic induction
in nonoriented electrical steels},
year = {2010},
number = {2},
pages = {310--313},
volume = {46},
doi = {10.1109/TMAG.2009.2032425},
}
@article{barros2008correlation,
author = {J. Barros and J. Schneider and K. Verbeken and Y. Houbaert},
journal = {Journal of Magnetism and Magnetic Materials},
title = {On the correlation between microstructure and magnetic losses in
electrical steel},
year = {2008},
issn = {0304-8853},
note = {Proceedings of the 18th International Symposium on Soft Magnetic
Materials},
number = {20},
pages = {2490--2493},
volume = {320},
doi = {https://doi.org/10.1016/j.jmmm.2008.04.056},
file = {:barros2008correlation.pdf:PDF},
keywords = {Magnetic loss, Magnetic texture, Grain size, Electrical steel},
url = {https://www.sciencedirect.com/science/article/pii/S0304885308003909},
}
@book{fiorillo2004characterization,
author = {Fiorillo, Fausto},
publisher = {Academic Press},
title = {Characterization and measurement of magnetic materials},
year = {2004},
isbn = {978-0-12-257251-7},
doi = {10.1016/B978-0-12-257251-7.X5000-X},
file = {:Magnetometrie/Fausto Fiorillo - Characterization and Measurement of
Magnetic Materials (Electromagnetism)-Academic Press (2005).pdf:PDF},
groups = {Magnetic Properties},
}
@article{saunders2016validated,
author = {Saunders, Robert N. and Boyd, James G. and Hartl, Darren J. and
Brown, Jonathan K. and Calkins, Frederick T. and Lagoudas, Dimitris
C.},
journal = {Smart Materials and Structures},
title = {A validated model for induction heating of shape memory alloy
actuators},
year = {2016},
number = {4},
pages = {045022},
volume = {25},
abstract = {Shape memory alloy (SMA) actuators deliver high forces while
being compact and reliable, making them ideal for consideration
in aerospace applications. One disadvantage of these thermally
driven actuators is their slow cyclic time response compared to
conventional actuators. Induction heating has recently been
proposed to quickly heat SMA components. However efforts to date
have been purely empirical. The present work approachs this
problem in a computational manner by developing a finite element
model of induction heating in which the time-harmonic
electromagnetic equations are solved for the Joule heat power
field, the energy equation is solved for the temperature field,
and the linear momentum equations are solved to find the stress,
displacement, and internal state variable fields. The combined
model was implemented in Abaqus using a Python script approach
and applied to SMA torque tube and beam actuators. The model has
also been used to examine magnetic flux concentrators to improve
the induction systems performance. Induction heating experiments
were performed using the SMA torque tube, and the model agreed
well with the experiments.},
doi = {10.1088/0964-1726/25/4/045022},
groups = {Induction Heating},
publisher = {{IOP} Publishing},
url = {https://doi.org/10.1088/0964-1726/25/4/045022},
}
@article{brand2015authorship,
author = {Brand, Amy and Allen, Liz and Altman, Micah and Hlava, Marjorie
and Scott, Jo},
journal = {Learned Publishing},
title = {Beyond authorship: attribution, contribution, collaboration, and
credit},
year = {2015},
number = {2},
pages = {151-155},
volume = {28},
abstract = {As the number of authors on scientific publications increases,
ordered lists of author names are proving inadequate for the
purposes of attribution and credit. A multi-stakeholder group has
produced a contributor role taxonomy for use in scientific
publications. Identifying specific contributions to published
research will lead to appropriate credit, fewer author disputes,
and fewer disincentives to collaboration and the sharing of data
and code.},
doi = {https://doi.org/10.1087/20150211},
eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1087/20150211},
keywords = {credit},
url = {https://onlinelibrary.wiley.com/doi/abs/10.1087/20150211},
}
@article{allen2019credit,
author = {Allen, Liz and OConnell, Alison and Kiermer, Veronique},
journal = {Learned Publishing},
title = {How can we ensure visibility and diversity in research
contributions? How the {C}ontributor {R}ole {T}axonomy {(CRediT)} is
helping the shift from authorship to contributorship},
year = {2019},
number = {1},
pages = {71-74},
volume = {32},
doi = {https://doi.org/10.1002/leap.1210},
eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/leap.1210},
keywords = {credit},
url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/leap.1210},
}
@article{keckes201830,
author = {J. Keckes and R. Daniel and J. Todt and J. Zalesak and B. Sartory
and S. Braun and J. Gluch and M. Rosenthal and M. Burghammer and C.
Mitterer and S. Niese and A. Kubec},
journal = {Acta Materialia},
title = {30 nm X-ray focusing correlates oscillatory stress, texture and
structural defect gradients across multilayered TiN-SiOx thin film},
year = {2018},
issn = {1359-6454},
pages = {862-873},
volume = {144},
abstract = {Resolving depth gradients of microstructure and residual
stresses within individual sublayers of multilayered thin films
and understanding their origin as well as their influence on
functional properties are challenging tasks. In this work, a
newly developed synchrotron focusing setup based on Multilayer
Laue Lenses, providing an X-ray beam diameter of 30 nm, is used
to characterize the cross-sectional properties of a 2.9 μm thick
sculptured multilayered TiN-SiOx film, which consists of twelve
230 nm thick nano-crystalline TiN sublayers of zigzag columnar
grain morphology separated by eleven amorphous SiOx sublayers,
both prepared by oblique magnetron sputtering on a Si(100)
substrate. The X-ray nano-diffraction analysis of the TiN
sublayers reveals (i) an oscillatory variation of compressive
residual stresses across the film ranging between 1.8 and 0.25
GPa, (ii) the presence of <100> fiber textures with three
different fiber axis orientations, which abruptly change between
the individual sublayers, and (iii) gradually decreasing
densities of structural defects within every TiN sublayer,
exhibiting a sawtooth-like depth-profile across the film. The
near-substrate TiN sublayer shows the highest compressive stress
reaching 1.8 GPa, a unique texture and the largest density of
defects among all sublayers, which indicates diverse nucleation
mechanisms of TiN on the native Si oxide and on the SiOx
sublayers. The results demonstrate that the average stress state
and the microstructure within the individual TiN sublayers can be
influenced effectively by the applied deposition conditions,
although self-organization processes during the sublayers'
evolution give rise to the occurrence of qualitatively similar
gradual trends, which differ in intensity and which were
characterized also by complementary laboratory X-ray diffraction,
as well as scanning and transmission electron microscopies.
Finally, the presented results document that the novel X-ray
nano-probe approach allows for the characterization of nano-scale
gradients within individual microstructural features of
polycrystalline thin films and pioneers the way for
knowledge-based synthesis of thin films with predefined
cross-sectional microstructure and property gradients.},
doi = {https://doi.org/10.1016/j.actamat.2017.11.049},
file = {:Eigenspng/keckes201830.pdf:PDF},
groups = {RS measurement},
keywords = {Thin film, Microstructure, Residual stress, X-ray,
Nanodiffraction},
url = {https://www.sciencedirect.com/science/article/pii/S1359645417309928},
}
@article{bodner2021correlative,
author = {Bodner, S. C. and Meindlhumer, M. and Ziegelwanger, T. and
Winklmayr, H. and Hatzenbichler, T. and Schindelbacher, C. and
Sartory, B. and Krobath, M. and Ecker, W. and Schell, N. and Keckes
, J.},
journal = {Journal of Materials Research and Technology},
title = {Correlative cross-sectional characterization of nitrided,
carburized and shot-peened steels: synchrotron micro-{X}-ray
diffraction analysis of stress, microstructure and phase gradients},
year = {2021},
issn = {2238-7854},
pages = {1396-1410},
volume = {11},
abstract = {Mechanical properties of case modified steels depend decisively
on the near-surface gradients of residual stresses,
microstructures, phases and chemical composition, which are
generated by the empirically well-established case-hardening
techniques. Currently, however, to obtain the correlation between
near-surface structureproperty gradients, applied hardening
process parameters and steels overall performance is a very
challenging task. In this work, high-energy synchrotron
cross-sectional X-ray diffraction (CSmicroXRD) using a pencil
beam cross-section of 20 × 500 μm2 and complementary analytical
techniques are used to characterize the surface-to-bulk gradient
of (i) a plasma nitrided steel W300, (ii) a carburized case
hardening steel (grade 18CrNiMo7-6) and (iii) a shot-peened high
strength steel, type 300M. CSmicroXRD analysis reveals complex
gradients of martensite and austenite phases, residual stresses
in both phases, crystallographic texture and the evolution of
diffraction peak broadening with a spatial resolution of ~20 μm.
These parameters are correlated with the gradients of hardness,
morphology-microstructure and with the changes in N and C
concentrations and/or retained austenite formation/depletion in
all three model samples. Finally, the correlative micro-analytics
approach indicates the complexity of near surface
structure-property relationships as well as the importance of
innovative cross-sectional characterization, which allows for
assessing gradual near-surface physical and/or chemical changes
accompanying thermo-chemical and mechanical surface treatments.},
doi = {https://doi.org/10.1016/j.jmrt.2021.01.099},
file = {:Eigenspng/bodner2021correlative.pdf:PDF},
groups = {RS measurement},
keywords = {Cross-section analysis, Synchrotron micro-XRD, Near-surface
characterization, Case-hardening, Low-pressure-plasma nitriding,
Shot-peening},
url = {https://www.sciencedirect.com/science/article/pii/S2238785421000995},
}
@article{kieffer2013pyfai,
author = {J{\'e}r{\^o}me Kieffer and Dimitrios Karkoulis},
journal = {Journal of Physics: Conference Series},
title = {{PyFAI}, a versatile library for azimuthal regrouping},
year = {2013},
month = {mar},
number = {20},
pages = {202012},
volume = {425},
abstract = {2D area detectors like CCD or pixel detectors have become
popular in the last 15 years for diffraction experiments (e.g.
for WAXS, SAXS, single crystal and powder diffraction (XRPD)).
These detectors have a large sensitive area of millions of pixels
with high spatial resolution. The software package pyFAI has been
designed to reduce SAXS, WAXS and XRPD images taken with those
detectors into 1D curves (azimuthal integration) usable by other
software for in-depth analysis such as Rietveld refinement, or 2D
images (a radial transformation named caking). As a library, the
aim of pyFAI is to be integrated into other tools like PyMca or
EDNA with a clean pythonic interface. However pyFAI features also
command line tools for batch processing, converting data into
q-space (q being the momentum transfer) or 2θ-space (θ being the
Bragg angle) and a calibration graphical interface for optimizing
the geometry of the experiment using the Debye-Scherrer rings of
a reference sample. PyFAI shares the geometry definition of SPD
but can directly import geometries determined by the software
FIT2D. PyFAI has been designed to work with any kind of detector
and geometry (transmission or reflection) and relies on FabIO, a
library able to read more than 20 image formats produced by
detectors from 12 different manufacturers. During the
transformation from cartesian space (x,y) to polar space (2θ, χ),
both local and total intensities are conserved in order to obtain
accurate quantitative results. Technical details on how this
integration is implemented and how it has been ported to native
code and parallelized on graphic cards are discussed in this
paper.},
doi = {10.1088/1742-6596/425/20/202012},
groups = {measurement},
publisher = {{IOP} Publishing},
url = {https://doi.org/10.1088/1742-6596/425/20/202012},
}
@misc{abaqus2021,
author = {{Dassault Syst\'emes Simulia Corp.}},
title = {Abaqus analysis user's manual, v.2021},
date = {2021-12-06},
groups = {Norms and Reference Work},
}
@phdthesis{eggbauer2018inductive,
author = {Eggbauer, Annika},
school = {University of Leoben},
title = {Inductive heat treatment of a {50CrMo4} steel-evolution of
microstructure and mechanical properties},
year = {2018},
groups = {Own},
}
@techreport{en821-3,
author = {{DIN EN 821-3:2005-04}},
institution = {Deutsches Institut für Normung},
title = {Advanced technical ceramics - Monolithic ceramics - Thermo-physical
properties - Part 3: Determination of specific heat capacity},
year = {2005},
doi = {https://dx.doi.org/10.31030/9611761},
groups = {Norms and Reference Work},
}
@techreport{en821-2,
author = {{BS EN 821-2:1997-11-15}},
institution = {British Standards Institution},
title = {Advanced technical ceramics. Monolithic ceramics. Thermo-physical
properties. Determination of thermal diffusivity by the laser flash
(or heat pulse) method},
year = {1997},
groups = {Norms and Reference Work},
}
@techreport{din51045-1,
author = {{DIN 51045-1:2005-08}},
institution = {Deutsches Institut für Normung},
title = {Determination of the thermal expansion of solids - Part 1: Basic
rules},
year = {2005},
doi = {https://dx.doi.org/10.31030/9636919},
groups = {Norms and Reference Work},
}
@techreport{en993-1,
author = {{DIN EN 993-1}},
institution = {Deutsches Institut für Normung},
title = {Methods of test for dense shaped refractory products - Part 1:
Determination of bulk density, apparent porosity and true porosity},
year = {1995},
groups = {Norms and Reference Work},
}
@unpublished{jaszfi2022indirect,
author = {Vince J{\'a}szfi and Peter Raninger and Johann M. Riedler and
Petri Prevedel and Daniel G. Mevec and John Wilson and Reinhold
Ebner},
title = {Indirect yoke-based {B-H} hysteresis measurement method determining
the magnetic properties of macroscopic ferromagnetic samples part {I
}: room temperature},
year = {2022},
groups = {Own},
journal = {Journal of Magnetism and Magnetic Materials},
}
@article{jaszfi2019influence,
author = {J{\'a}szfi, V. and Prevedel, P. and Eggbauer, A. and Godai, Y. and
Raninger, P. and Mevec, D. and Panzenb{\"o}ck, M. and Ebner, R.},
journal = {HTM Journal of Heat Treatment and Materials},
title = {Influence of the parameters of induction heat treatment on the
mechanical properties of {50CrMo4}},
year = {2019},
number = {6},
pages = {366--379},
volume = {74},
doi = {10.3139/105.110398},
groups = {Own},
publisher = {De Gruyter},
url = {https://doi.org/10.3139/105.110398},
}
@book{bathe2006finite,
author = {Bathe, Klaus-J{\"u}rgen},
title = {Finite element procedures},
year = {2006},
address = {Watertown, MA, USA},
groups = {FEM},
}
@misc{abaqus2018,
author = {{Dassault Syst\'emes Simulia Corp.}},
title = {Abaqus analysis user's manual, v.2018},
date = {2019-01-24},
groups = {Norms and Reference Work},
}
@article{jaszfi2022residual,
author = {Jaszfi, Vince and Prevedel, Petri and Raninger, Peter and Todt,
Juraj and Mevec, Daniel G. and Godai, Yves and Maawad, Emad and
Ebner, Reinhold},
journal = {submitted},
title = {Residual stress distribution of a locally and inductively quenched
and tempered {50CrMo4} steel analysed by synchrotron transmission
techniques},
year = {2022},
groups = {Own},
}
@article{biro1999edge,
author = {Oszk\'ar B\'ir\'o},
journal = {Computer Methods in Applied Mechanics and Engineering},
title = {Edge element formulations of eddy current problems},
year = {1999},
issn = {0045-7825},
number = {3},
pages = {391-405},
volume = {169},
abstract = {Various formulations of eddy current problems in terms of scalar
and vector potentials are reviewed in the paper. The vector
potentials are approximated by edge finite elements and the
scalar potentials by nodal ones. The formulations are ungauged,
leading, in most cases, to singular finite element equations
systems. Special attention is paid to ensuring that the
right-hand sides of the equations systems are consistent. The
resulting numerical schemes prove to be as robust as the
corresponding Coulomb gauged approaches realized by nodal
elements.},
doi = {https://doi.org/10.1016/S0045-7825(98)00165-0},
file = {:Simulating_Induction/biro1999edge.pdf:PDF},
groups = {FEM},
url = {https://www.sciencedirect.com/science/article/pii/S0045782598001650},
}
@inproceedings{bose2014recent,
author = {Bose, K. and Govindarajan, S. M. and Gundu, K. M.},
booktitle = {Proceedings of the 10th World Congress on Computational
Mechanics},
title = {Recent advances towards solving electromagnetic problems in
commercial finite element software package {Abaqus}},
year = {2014},
pages = {3439--3455},
publisher = {S\~ao Paulo: Blucher},
doi = {10.5151/meceng-wccm2012-19370},
file = {:Simulating_Induction/bose2014recent.pdf:PDF},
groups = {FEM},
}
@article{choi2018predicting,
author = {Choi, Jin-Kyu and Park, Kwan-Seok and Lee, Seok-Soon},
journal = {Journal of Mechanical Science and Technology},
title = {Predicting the hardening depth of a sprocket by finite element
analysis and its experimental validation for an induction hardening
process},
year = {2018},
number = {3},
pages = {1235--1241},
volume = {32},
doi = {10.1007/s12206-018-0227-4},
file = {:Simulating_Induction/choi2018predicting.pdf:PDF},
groups = {Induction Heating},
publisher = {Springer},
}
@article{tong2017numerical,
author = {Tong, Daming and Gu, Jianfeng and Totten, George Edward},
journal = {Modelling and Simulation in Materials Science and Engineering},
title = {Numerical simulation of induction hardening of a cylindrical part
based on multi-physics coupling},
year = {2017},
number = {3},
pages = {035009},
volume = {25},
doi = {10.1088/1361-651X/aa5f7c},
file = {:Simulating_Induction/tong2017numerical.pdf:PDF},
groups = {Induction Heating},
publisher = {IOP Publishing},
}
@article{brunbauer2019residual,
author = {Silvia Brunbauer and Gerald Winter and Thomas Antretter and Peter
Staron and Werner Ecker},
journal = {Materials Science and Engineering: A},
title = {Residual stress and microstructure evolution in steel tubes for
different cooling conditions simulation and verification},
year = {2019},
issn = {0921-5093},
pages = {73-79},
volume = {747},
abstract = {A finite element modelling approach is applied to investigate
the evolution of residual stresses, temperature and phase
fraction during quenching of low-alloyed seamless steel tubes.
Under real-process quenching conditions, non-continuous cooling
occurs that results in a stopping and restarting transformation
front throughout the tube's radial direction. It is shown that
the simulated temperature history, transformation kinetics and
the residual stresses from the thermo-mechanical model can be
correlated with experimentally observed residual stresses and
micro-hardness investigations of produced tubes. The effect of
the discontinuous cooling was found to be negligible with respect
to residual stresses for comparable conditions, but it can cause
local self-annealing and micro-hardness drops. The combination of
outer and inner cooling of the tube influences residual stress
and micro-hardness distribution significantly.},
doi = {https://doi.org/10.1016/j.msea.2019.01.037},
file = {:Eigenspng/brunbauer2019residual.pdf:PDF},
groups = {Own},
keywords = {Simulation, Residual stresses, Phase transformation, Quenching,
Steel, Heat treatment},
url = {https://www.sciencedirect.com/science/article/pii/S0921509319300498},
}
@article{denis1992mathematical,
author = {S. Denis and D. Farias and A. Simon},
journal = {ISIJ International},
title = {Mathematical model coupling phase transformations and temperature
evolutions in steels},
year = {1992},
number = {3},
pages = {316-325},
volume = {32},
doi = {10.2355/isijinternational.32.316},
groups = {Induction Heating},
}
@article{fernandes1985mathematical,
author = {Fernandes, F. M. B. and Denis, S. and Simon, A.},
journal = {Materials Science and Technology},
title = {Mathematical model coupling phase transformation and temperature
evolution during quenching of steels},
year = {1985},
number = {10},
pages = {838--844},
volume = {1},
doi = {10.1179/mst.1985.1.10.838},
groups = {Induction Heating},
publisher = {Taylor \& Francis},
}
@article{simsir2008simulation,
author = {Caner Şimşir and C. Hakan Gür},
journal = {Journal of Materials Processing Technology},
title = {{3D} {FEM} simulation of steel quenching and investigation of the
effect of asymmetric geometry on residual stress distribution},
year = {2008},
issn = {0924-0136},
number = {1},
pages = {211-221},
volume = {207},
abstract = {During quench hardening of steel components, obtaining the
desired distribution of microstructure and residual stresses with
minimum distortion is essential in order to achieve production
goals and reliable service performance. In this study, a 3D FEM
based model, which is integrated into commercial FEA software
Msc.Marc® via user subroutines, has been developed to predict
temperature history, evolution of microstructure and internal
stresses during quenching. For experimental verification,
eccentrically drilled C60 steel cylinders were quenched from
830°C into water at 20°C. The results indicate that the model can
effectively predict the trends in the distribution of residual
stresses for 3D asymmetric components.},
doi = {https://doi.org/10.1016/j.jmatprotec.2007.12.074},
groups = {Process Simulation},
keywords = {Steel, Quenching, Simulation, Residual stress, Phase
transformation, Finite element method},
url = {https://www.sciencedirect.com/science/article/pii/S0924013607014616},
}
@book{gur2008handbook,
author = {Gur, Cemil Hakan and Pan, Jiansheng},
publisher = {CRC Press},
title = {Handbook of thermal process modeling steels},
year = {2008},
groups = {Process Simulation},
}
@mastersthesis{lindenberger2018design,
author = {Philipp Lindenberger},
school = {Montanuniversit\"{a}t Leoben},
title = {Design of an algorithm to simulate transformation induced
plasticity insteels},
year = {2018},
month = jul,
type = {Bachelor Thesis},
abstract = {The effect of transformation induced plasticity (TRIP-effect) is
used in steels to enhance ductility and tensile strength. Common
applications of TRIP-steels are in the automotive and aerospace
industry. During the phase transformation from austenite to
martensite, the macromechanical behavior changes. In this
bachelor thesis, it is the aim to build an algorithm based on the
work done by Rolf Mahnken et.al. in [1] to calculate the
macromechanical behavior of steels showing martensitic phase
transformation. To consider the possibility of implementing this
algorithm into the FEM-Software Abaqus in the future, the
algorithm was designed as strain-driven to fit into
FEM-calculations. In order to use this software also as a
stand-alone program not needing a full strain history, a
stress-driven adaption was designed and integrated. The
mathematical background for both implementations are derived in
this thesis and a design for this algorithm is discussed. An
introduction to the designed code is given in the end and the
main functions and classes are listed and described. Based on
commonly used material properties, the goal was to minimize the
error between simulated and measured data. In the end, the
simulated data is compared to experimental data obtained from [2]
with material parameters from [1] and the impact of the increment
size is evaluated.},
file = {:Bachelorarbeit_Lindenberger.pdf:PDF},
groups = {TRIP},
}
@article{noyan1983effect,
author = {I. Cevdet Noyan},
journal = {Metallurgical Transactions A},
title = {Effect of gradients in multi-axial stress states on residual stress
measurements with x-rays},
year = {1983},
pages = {249-258},
volume = {14},
file = {:noyan1983effect.pdf:PDF},
groups = {RS measurement},
}
@book{he2009twodimensional,
author = {Bob B. He},
publisher = {John Wiley & Sons},
title = {Two-dimensional x-ray diffraction},
year = {2009},
doi = {10.1002/9780470502648},
groups = {measurement},
}
@article{moore1958mathematical,
author = {Moore, Marcia G. and Evans, W. Price},
journal = {SAE International},
title = {Mathematical correction for stress in removed layers in x-ray
diffraction residual stress analysis},
year = {1958},
doi = {10.4271/580035},
file = {:Eigenspng/moore1958mathematical.pdf:PDF},
groups = {RS measurement},
}
@article{withers2004depth2,
author = {Withers, Philip John},
journal = {Journal of Applied Crystallography},
title = {Depth capabilities of neutron and synchrotron diffraction strain
measurement instruments. {II. P}ractical implications},
year = {2004},
month = aug,
number = {4},
pages = {607--612},
volume = {37},
abstract = {In part I [Withers (2004). {\it J. Appl. Cryst.} {\bf 37}, 596{
--}606], a framework was presented for estimating the maximum
feasible penetration length for neutron and synchrotron X-ray
strain measurement. This calculation reflected the attenuation
and scattering capability of the material under examination, the
incident flux and detector arrangement, the likely background
signal, the required strain measurement accuracy, the sampling
volume, and the diffracting geometry. In the present paper (part
II), preliminary calibration data acquired for a very wide range
of neutron and synchrotron sources are presented. This database
is used to explore the implications of the framework for
delineating those conditions under which a specific instrument
can provide useful information within a feasible timescale, in
order to identify the most appropriate radiation, energy and
instrumental configuration for undertaking measurements in
transmission and reflection as a function of depth, and to
establish guiding principles for improving the performance of
existing instruments.},
doi = {10.1107/S0021889804012750},
file = {:Eigenspng/withers2004depth2.pdf:PDF},
groups = {RS measurement},
keywords = {residual strain, neutron diffraction, synchrotron diffraction,
penetration depth, residual stress},
url = {https://doi.org/10.1107/S0021889804012750},
}
@article{withers2004depth1,
author = {Withers, Philip John},
journal = {Journal of Applied Crystallography},
title = {Depth capabilities of neutron and synchrotron diffraction strain
measurement instruments. {I. T}he maximum feasible path length},
year = {2004},
month = aug,
number = {4},
pages = {596--606},
volume = {37},
abstract = {In this paper an algorithm is presented for estimating the
maximum feasible penetration path length for neutron and
synchrotron X-ray strain measurement instruments. This reflects
the attenuation and scattering capability of the material under
examination, the incident flux and detector arrangement, the
likely background signal, the required strain measurement
accuracy, the sampling volume and the diffracting geometry. Its
validity and generality is examined through a consideration of
data collected using a number of instruments on a variety of
materials. Two criteria for the maximum feasible path length are
examined: one based on the maximum acquisition time, the other
based on the minimum acceptable peak height to background ratio.
As demonstrated in the companion paper [part II: Withers (2004).
{\it J. Appl. Cryst.} {\bf 37}, 607{--}612], the algorithm can be
used to delineate those conditions under which neutron and
synchrotron X-ray radiations can provide useful information and
to identify which is most suited to any particular measurement
task.},
doi = {10.1107/S0021889804012737},
file = {:Eigenspng/withers2004depth1.pdf:PDF},
groups = {RS measurement},
keywords = {residual strain, residual stress, neutron diffraction,
synchrotron diffraction, penetration depth},
url = {https://doi.org/10.1107/S0021889804012737},
}
@book{noyan1987residual,
author = {Noyan, Ismail C. and Cohen, Jerome B.},
publisher = {Springer},
title = {Residual stress: measurement by diffraction and interpretation},
year = {1987},
file = {:Eigenspng/noyan1987residual.pdf:PDF},
groups = {RS measurement},
}
@article{doelle1979influence,
author = {D\"{o}lle, H.},
journal = {Journal of Applied Crystallography},
title = {The influence of multiaxial stress states, stress gradients and
elastic anisotropy on the evaluation of residual stresses by x-rays},
year = {1979},
month = {Dec},
number = {6},
pages = {489--501},
volume = {12},
abstract = {In recent years, nonlinear {\it d versus} sin${\sp 2}$ {\it {$
\psi$}} distributions have been observed in stressed materials
which cannot be explained by the classical fundamentals of X-ray
stress measurement, {\it d} is the interplanar spacing measured
and {\it {$\psi$}} is the angle between the surface normal of the
sample and the measuring direction. This paper reviews treatments
for these nonlinear distributions, including stress gradients,
shear stresses and anisotropic X-ray elastic constants. Methods
for the evaluation of stresses are reported, and recommendations
are given for the practical application of X-ray stress
measurement.},
doi = {10.1107/S0021889879013169},
file = {:Eigenspng/doelle1979influence.pdf:PDF},
groups = {RS measurement},
url = {https://doi.org/10.1107/S0021889879013169},
}
@article{withers2001residual2,
author = {Withers, Philip John and Bhadeshia, Harshad Kumar Dharamshi
Hansraj},
journal = {Materials Science and Technology},
title = {Residual stress. {P}art 2 -- nature and origins},
year = {2001},
number = {4},
pages = {366-375},
volume = {17},
doi = {10.1179/026708301101510087},
file = {:Eigenspng/withers2001residual2.pdf:PDF},
groups = {residual stress},
publisher = {Taylor & Francis},
}
@article{withers2001residual1,
author = {Withers, Philip John and Bhadeshia, Harshad Kumar Dharamshi
Hansraj},
journal = {Materials Science and Technology},
title = {Residual stress. {P}art 1 -- measurement techniques},
year = {2001},
number = {4},
pages = {355-365},
volume = {17},
doi = {10.1179/026708301101509980},
file = {:Eigenspng/withers2001residual1.pdf:PDF},
groups = {residual stress},
publisher = {Taylor & Francis},
}
@article{prime2014beyond,
author = {Prime, Michael B. and Steinzig, Michael L.},
journal = {Advanced Materials Research},
title = {Beyond the streetlight effect: a united future for relaxation and
diffraction methods for residual stress measurement},
year = {2014},
pages = {234--242},
volume = {996},
doi = {10.4028/www.scientific.net/AMR.996.234},
file = {:Eigenspng/prime2014beyond.pdf:PDF},
groups = {RS measurement},
}
@article{leitner2020model,
author = {Leitner, Silvia and Winter, Gerald and Klarner, Jürgen and
Antretter, Thomas and Ecker, Werner},
journal = {Materials},
title = {Model-based residual stress design in multiphase seamless steel
tubes},
year = {2020},
issn = {1996-1944},
number = {2},
volume = {13},
abstract = {Residual stresses in quenched seamless steel tubes highly depend
on the cooling conditions to which the tubes have been subjected.
The design aspect of how to use controlled cooling strategies in
multiphase steel tubes to achieve certain residual stress and
phase configurations is discussed. In an experimentally validated
finite element (FE) model considering a coupled evolution of
martensite and bainite, three cooling strategies are tested for a
low-alloyed 0.25 wt.% C steel tube. The strategies are (i)
external cooling only, (ii) internal and external cooling for low
residual stresses in a mainly martensitic tube, and (iii)
internal and external cooling with low cooling rate for a mainly
bainitic tube. The strategies represent design cases, where low
residual stresses with different phase compositions are provoked,
in order to show the potential of numerical analysis for residual
stress and property design. It can be concluded that, for the
investigated steel class, intense external cooling leads to a
characteristic residual stress profile regardless of the
dimension. A combination of external and internal cooling allows
a more flexible design of residual stress and phase distribution
by choosing different cooling parameters (i.e., water amount and
cooling times). In general, lower cooling rates lead to lower
thermal misfit strains, and thus less plasticity and lower
residual stresses.},
doi = {10.3390/ma13020439},
file = {:Eigenspng/leitner2020model.pdf:PDF},
groups = {Process Simulation},
url = {https://www.mdpi.com/1996-1944/13/2/439},
}
@Article{gaenser2019residual,
author = {Hans-Peter G\"{a}nser and P. Angerer and T. Klünsner},
journal = {International Journal of Refractory Metals and Hard Materials},
title = {Residual stress depth profiling of a coated {WC-Co} hardmetal part {II} of {II}: {R}egression methods for stress depth profile reconstruction from diffraction data},
year = {2019},
issn = {0263-4368},
pages = {324--328},
volume = {82},
abstract = {Reconstruction of residual stress depth profiles from
diffraction data depends crucially on the underlying assumptions
regarding X-ray elastic constants, stress state, and generic
shape of the stress depth profile. This article addresses two
issues: first, how to account for X-ray elastic constants varying
according to different crystallographic planes by rearranging the
underlying equation system such that it becomes amenable to
linear regression again; second, how to construct the residual
stress depth profile via inverse Laplace transformation of a
piecewise linear approximation function, thereby obtaining
maximum flexibility in the description of the generic shape of
the profile. The methods are discussed by means of typical
examples.},
doi = {https://doi.org/10.1016/j.ijrmhm.2019.05.002},
file = {:Eigenspng/gaenser2019residual.pdf:PDF},
groups = {RS measurement},
keywords = {X-ray diffraction, Residual stress, Depth profile, EP-GIXD method, Stress profile reconstruction, Regression, Regularization},
url = {https://www.sciencedirect.com/science/article/pii/S0263436818308011},
}
@article{angerer2019residual,
author = {P. Angerer and T. Kl\"{u}nsner and M. Morstein and H.-P. G\"{a}
nser},
journal = {International Journal of Refractory Metals and Hard Materials},
title = {Residual stress depth profiling of a coated {WC-Co} hardmetal -
part {I} of {II}: {E}qui-penetration grazing incidence x-ray
diffraction (ep-gixd) method},
year = {2019},
issn = {0263-4368},
pages = {104943},
volume = {83},
abstract = {The damage behavior of hard coated structures such as used for
metalworking tools is influenced by residual stresses since they
are superimposed with the load stresses that arise in
application. Information on the depth gradient of these residual
stresses in a coating's substrate is crucial to understand the
evolution of damage in the substrate-coating composite. In the
current work, the equi-penetration grazing incidence X-ray
diffraction (EP-GIXD) method was adapted for the determination of
the residual stress depth profile in the WC-Co hardmetal
substrate below an AlCrN-based hard coating. The limits of this
method in terms of coating thickness, up to which the EP-GIXD
method is applicable to determine the residual stress state in
the substrate, were investigated by recording the X-ray
absorption in the hard coating in rocking curves. To this end,
the diffraction intensity was recorded as a function of the path
length in the coating that depends on the incident angle of the
X-rays. Subsequently, the obtained residual stress profile was
determined as a function of various mean penetration depths
selected via the variation of the angle of incidence. The EP-GIXD
method facilitates a significant reduction of experimental effort
compared to e.g. synchrotron-based approaches for the future
study of the residual stress state of substrates in
substrate-coating composite structures.},
doi = {https://doi.org/10.1016/j.ijrmhm.2019.04.010},
file = {:Eigenspng/angerer2019residual.pdf:PDF},
groups = {RS measurement},
keywords = {X-ray diffraction, Residual stress, Depth profile,
Equi-penetration grazing incidence X-ray diffraction method,
WC-Co hardmetal, AlCrTiN hard coating},
url = {https://www.sciencedirect.com/science/article/pii/S026343681830800X},
}
@article{fernandes2014determination,
author = {Fernandes, Frederico Augusto Pires and Christiansen, Thomas L. and
Somers, Marcel A. J.},
journal = {Advanced Materials Research},
title = {Determination of stress profiles in expanded austenite by combining
successive layer removal and {GI-XRD}},
year = {2014},
month = {10},
pages = {155--161},
volume = {996},
abstract = {The present work deals with the evaluation of the
residual-stress profile in expanded-austenite by successive
removal steps using GI-XRD. Preliminary results indicate stresses
of several GPa's from 111 and 200 diffraction lines. These
stresses appear largest for the 200 reflection. The strain-free
lattice parameter decayed smoothly with depth, while for the
compressive stress a maximum value is observed at some depth
below the surface. Additionally a good agreement was found
between the nitrogen profile determined with GDOES analysis and
the strain-free lattice parameter from XRD.},
doi = {10.4028/www.scientific.net/AMR.996.155},
file = {:Eigenspng/fernandes2014determination.pdf:PDF},
groups = {RS measurement},
keywords = {Expanded Austenite, Grazing Incidence, Stress Analysis, Gas
Nitriding, X-Ray Diffraction (XRD), Low Temperature Surface
Hardening},
}
@article{liu2020xrd,
author = {Liu, Hongfei and Wei, Yuefan and Tan, Chee Kiang Ivan and Ardi,
Dennise T. and Tan, Dennis C. C. and Lee, Coryl J. J.},
journal = {Materials Characterization},
title = {{XRD} and {EBSD} studies of severe shot peening induced martensite
transformation and grain refinements in austenitic stainless steel},
year = {2020},
issn = {1044-5803},
pages = {110574},
volume = {168},
abstract = {Effects of severe shot peening (SSP) on the phase transformation
and grain refinements of stainless steel 304 have been studied,
driven by potential performance improvements via grain
refinements in advanced surface enhancements, by employing X-ray
diffraction (XRD) and electron backscatter diffraction (EBSD).
XRD measurements reveal a monotonic increase in martensite
transformations (MT) when the shot peening coverage (SPC) is
increased from 100% to 1500% and the increase exhibits a strong
correlation with that of the compressive residual stress (CRS).
They also reveal that the maximum MT locates under the processed
surface and shifts deeper into the material when the SPC is
increased. This variation trend, except for the different
locations in depth, is similar to that of the maximum CRS. The
depth-dependence of MT measured by XRD is consistent with that
measured by EBSD at a scanning step of 0.3 μm; however,
discrepancies are observed when either increasing or decreasing
the scanning step by about one order of magnitude. The
discrepancies are attributable to the SSP-induced grain
refinements, which exhibit a monotonic decrease as a function of
the depth under the peened surface, while the severely refined
grains are most dominated by martensite.},
doi = {https://doi.org/10.1016/j.matchar.2020.110574},
groups = {RS measurement},
keywords = {Shot peening, Stainless steel 304, Phase transformation, Grain
refinement, XRD, EBSD},
url = {https://www.sciencedirect.com/science/article/pii/S1044580320320453},
}
@mastersthesis{england2000measurement,
author = {England, Roger D.},
school = {University of Cincinnati},
title = {Measurement of residual stresses in diesel components using x-ray,
synchrotron, and neutron diffraction},
year = {2000},
groups = {RS measurement},
}
@techreport{iso6507-2,
author = {{ISO 6507-2:2018(en)}},
institution = {International Organization for Standardization},
title = {{Metallic materials -- Vickers hardness test -- Part 2:
Verification and calibration of testing machines}},
year = {2018},
address = {Geneva, CH},
month = mar,
type = {Standard},
groups = {Norms and Reference Work},
volume = {2000},
}
@techreport{iso13586,
author = {{ISO 13586:2000(E)}},
institution = {International Organization for Standardization},
title = {{Plastics -- Determination of fracture toughness -- Linear elastic
fracture mechanics ({LEFM}) approach}},
year = {2000},
address = {Geneva, CH},
month = mar,
type = {Standard},
groups = {Norms and Reference Work},
volume = {2000},
}
@techreport{iso6507-1,
author = {{ISO 6507-1:2018(en)}},
institution = {International Organization for Standardization},
title = {{Metallic materials -- Vickers hardness test -- Part 1: Test method
}},
year = {2018},
address = {Geneva, CH},
month = mar,
type = {Standard},
groups = {Norms and Reference Work},
volume = {2000},
}
@techreport{iso6507-3,
author = {{ISO 6507-3:2018(en)}},
institution = {International Organization for Standardization},
title = {{Metallic materials -- Vickers hardness test -- Part 3: Calibration
of reference blocks}},
year = {2018},
address = {Geneva, CH},
month = mar,
type = {Standard},
groups = {Norms and Reference Work},
volume = {2000},
}
@techreport{iso6507-4,
author = {{ISO 6507-4:2018(en)}},
institution = {International Organization for Standardization},
title = {{Metallic materials -- Vickers hardness test -- Part 4: Tables of
hardness values}},
year = {2018},
address = {Geneva, CH},
month = mar,
type = {Standard},
groups = {Norms and Reference Work},
volume = {2000},
}
@TechReport{astme92,
author = {{ASTM E92-17}},
institution = {ASTM International},
title = {Standard test methods for vickers hardness and knoop hardness of metallic materials},
year = {2017},
address = {West Conshohocken, PA, USA},
type = {Standard},
groups = {Norms and Reference Work},
}
@techreport{astme18,
author = {{ASTM E18-20}},
institution = {ASTM International},
title = {Rockwell hardness standard test methods},
year = {2020},
address = {West Conshohocken, PA, USA},
type = {Standard},
groups = {Norms and Reference Work},
}
@article{nobre2018plasticity,
author = {Nobre, J. P. and Kornmeier, M. and Scholtes, B.},
journal = {Experimental Mechanics},
title = {Plasticity effects in the hole-drilling residual stress measurement
in peened surfaces},
year = {2018},
issn = {1741-2765},
number = {2},
pages = {369--380},
volume = {58},
doi = {10.1007/s11340-017-0352-5},
groups = {RS measurement},
}
@article{bobzin2020comparison,
author = {Bobzin, K. and Wietheger, W. and Knoch, M. A. and Schacht, A. and
Reisgen, U. and Sharma, R. and Oster, L.},
journal = {Journal of Thermal Spray Technology},
title = {Comparison of residual stress measurements conducted by x-ray
stress analysis and incremental hole drilling method},
year = {2020},
issn = {1544-1016},
number = {6},
pages = {1218--1228},
volume = {29},
doi = {10.1007/s11666-020-01056-z},
groups = {RS measurement},
}
@article{olson2018repeatability,
author = {Olson, Mitchell D. and DeWald, Adrian T. and Hill, Michael R.},
journal = {Materials Performance and Characterization},
title = {Repeatability of contour method residual stress measurements for a
range of materials, processes, and geometries},
year = {2018},
number = {4},
pages = {20170044--20170044},
volume = {7},
doi = {10.1520/MPC20170044},
groups = {RS measurement},
}
@article{peng2021residual,
author = {Yang Peng and Jun Zhao and Lan-shu Chen and Jun Dong},
journal = {Journal of Constructional Steel Research},
title = {Residual stress measurement combining blind-hole drilling and
digital image correlation approach},
year = {2021},
issn = {0143-974X},
pages = {106346},
volume = {176},
doi = {10.1016/j.jcsr.2020.106346},
groups = {RS measurement},
keywords = {Residual stress, DIC-hole drilling method, H-section beam},
}
@inproceedings{isaac2017residual,
author = {Isaac, Daulton D. and Prime, Michael B. and Arakere, Nagaraj},
booktitle = {Residual Stress, Thermomechanics \& Infrared Imaging, Hybrid
Techniques and Inverse Problems, Volume 9},
title = {Residual stress measurement of full-scale jet-engine bearing
elements using the contour method},
year = {2017},
editor = {Quinn, Simon and Balandraud, Xavier},
pages = {69--81},
publisher = {Springer International Publishing},
doi = {10.1007/978-3-319-42255-8_10},
groups = {RS measurement},
isbn = {978-3-319-42255-8},
}
@article{shim2007topology,
author = {Shim, Hokyung and Wang, Semyung and Hameyer, Kay},
journal = {IEEE Transactions on Magnetics},
title = {Topology optimization of magnetothermal systems considering eddy
current as joule heat},
year = {2007},
number = {4},
pages = {1617--1620},
volume = {43},
doi = {10.1109/TMAG.2006.892248},
groups = {Inductor design},
keywords = {topology, optimization},
}
@article{georges2004modeling,
author = {Georges, Th. and Hackmair, Ch. and Mayer, H. M. and Pyzalla, A.
and Porzner, H. and Duranton, P.},
journal = {Industrial Heating},
title = {Modeling induction heat treating of crankshafts-residual stress and
deformation that develop during heat treatment of steel parts can be
determined quantitatively using numerical simulation.},
year = {2004},
number = {8},
pages = {51--58},
volume = {71},
groups = {IH Crankshafts},
keywords = {Quenching, Crankshaft, Residual Stress, Finite Element Method
(FEM), Simulation},
timestamp = {2022-05-30},
}
@inproceedings{qin2015fem,
author = {Qin, Wen Jie and Dong, Chao},
booktitle = {Advances in Engineering Plasticity XII},
title = {{FEM} simulation of quenching process and investigation of residual
stresses of crankshafts},
year = {2015},
pages = {149--154},
publisher = {Trans Tech Publications Ltd},
series = {Key Engineering Materials},
volume = {626},
doi = {10.4028/www.scientific.net/KEM.626.149},
groups = {Crankshaft-Sim, IH Crankshafts},
keywords = {Quenching, Crankshaft, Residual Stress, Finite Element Method
(FEM), Simulation},
}
@article{grum2003analysis,
author = {Grum, Janez},
journal = {Proceedings of the Institution of Mechanical Engineers, Part D:
Journal of Automobile Engineering},
title = {Analysis of residual stresses in main crankshaft bearings after
induction surface hardening and finish grinding},
year = {2003},
number = {3},
pages = {173--182},
volume = {217},
doi = {10.1243/09544070360550282},
groups = {residual stress},
}
@article{hoemberg2003optimal,
author = {Hömberg, Dietmar and SokoLowski, Jan},
journal = {SIAM Journal on Control and Optimization},
title = {Optimal shape design of inductor coils for surface hardening},
year = {2003},
number = {3},
pages = {1087--1117},
volume = {42},
doi = {10.1137/S0363012900375822},
eprint = {10.1137/S0363012900375822},
groups = {Inductor design},
keywords = {topology, optimization,},
}
@article{schulze2020hierarchical,
author = {Schulze, Martin and Nikanorov, Alexander and Nacke, Bernard},
journal = {COMPEL - The international journal for computation and
mathematics in electrical and electronic engineering},
title = {Hierarchical shape optimization of one-sided transverse flux
heating induction coil},
year = {2020},
issn = {0332-1649},
number = {1},
pages = {73--80},
volume = {39},
doi = {10.1108/COMPEL-05-2019-0214},
groups = {Inductor design},
keywords = {topology, optimization},
}
@article{wang2019prediction,
author = {Xiaoli Wang and Qingshuai Meng and Zhou Wang and Jin Gan and Ying
Yang and Xunpeng Qin and Kai Gao and Hanlie Zhong and Man Cheng and
Xiaoyan Gan},
journal = {Surface and Coatings Technology},
title = {Prediction of the surface characteristic of 42{C}r{M}o after spot
continual induction hardening based on a novel co-simulation method},
year = {2019},
issn = {0257-8972},
pages = {252--266},
volume = {357},
doi = {10.1016/j.surfcoat.2018.09.088},
groups = {Induction Heating},
keywords = {Spot continual induction hardening, Finite element co-simulation
, Electromagnetic-thermal model, Thermal-mechanical-metallurgical
model, Residual stress distribution},
}
@article{choi2018prediction,
author = {Choi, Jin-Kyu and Park, Kwan-Seok and Lee, Seok-Soon},
journal = {International Journal of Precision Engineering and Manufacturing},
title = {Prediction of high-frequency induction hardening depth of an {AISI}
1045 specimen by finite element analysis and experiments},
year = {2018},
issn = {2005-4602},
number = {12},
pages = {1821--1827},
volume = {19},
doi = {10.1007/s12541-018-0210-0},
groups = {Induction Heating},
keywords = {cosimulation},
}
@article{akujaervi2017mapping,
author = {Akuj{\"a}rvi, Ville and Cedell, Tord and Frogner, Kenneth and
Andersson, Mats},
journal = {COMPEL - The international journal for computation and
mathematics in electrical and electronic engineering},
title = {Mapping of magnetic properties for simulations of high-temperature
electromagnetic applications},
year = {2017},
issn = {0332-1649},
number = {2},
pages = {546--554},
volume = {36},
doi = {10.1108/COMPEL-05-2016-0217},
groups = {Magnetic Properties},
}
@article{hoffmeister2012process,
author = {Hoffmeister, J\"{u}rgen and Lindgren, Lars-Erik and Fisk, Martin
and Schwenk, Maximilian and Cedell, Tord and Schulze, Volker},
journal = {Materials Performance and Characterization},
title = {Process simulation of single and dual frequency induction surface
hardening considering magnetic nonlinearity},
year = {2012},
issn = {2165-3992},
number = {1},
pages = {1--20},
volume = {1},
doi = {10.1520/MPC104374},
groups = {Induction Heating},
}
@article{bay2003numerical,
author = {Bay, F. and Labbe, V. and Favennec, Y. and Chenot, J. L.},
journal = {International Journal for Numerical Methods in Engineering},
title = {A numerical model for induction heating processes coupling
electromagnetism and thermomechanics},
year = {2003},
number = {6},
pages = {839--867},
volume = {58},
doi = {10.1002/nme.796},
eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/nme.796},
groups = {Induction Heating},
keywords = {induction heating, electromagnetic modelling, heat transfer
computations, mechanical modelling, multiphysics coupling, finite
elements},
}
@Article{klonk2016numerical,
author = {Klonk, Steffen and Bay, François},
journal = {International Journal of Microstructure and Materials Properties},
title = {Numerical analysis of computational models for induction heat treatment of complex geometrical parts},
year = {2016},
number = {1-2},
pages = {48--70},
volume = {11},
doi = {10.1504/IJMMP.2016.078050},
eprint = {https://www.inderscienceonline.com/doi/pdf/10.1504/IJMMP.2016.078050},
groups = {Inductor design},
}
@Article{areitioaurtena2021semi,
author = {Areitioaurtena, Maialen and Segurajauregi, Unai and Akuj{\"a}rvi, Ville and Fisk, Martin and Urresti, Iker and Ukar, Eneko},
journal = {Advanced Modeling and Simulation in Engineering Sciences},
title = {A semi-analytical coupled simulation approach for induction heating},
year = {2021},
issn = {2213-7467},
number = {1},
pages = {14},
volume = {8},
doi = {10.1186/s40323-021-00199-0},
groups = {Induction Heating},
}
@book{wiak2011computational,
editor = {Wiak, S{\l}awomir and Napieralska-Juszczak, Ewa},
publisher = {Springer},
title = {Computational methods for the innovative design of electrical
devices},
year = {2011},
isbn = {978-3-642-16225-1},
series = {Studies in Computational Intelligence,},
volume = {327},
doi = {10.1007/978-3-642-16225-1},
groups = {Inductor design},
}
@incollection{stumberger2011computational,
author = {{\v{S}}tumberger, Gorazd and {\v{Z}}arko, Damir and Tokic, Amir
and Dolinar, Drago},
editor = {Wiak, S{\l}awomir and Napieralska-Juszczak, Ewa},
title = {Magnetically Nonlinear Iron Core Characteristics of Transformers
Determined by Differential Evolution},
pages = {247--259},
publisher = {Springer Berlin Heidelberg},
booktitle = {Computational methods for the innovative design of electrical
devices},
year = {2011},
isbn = {978-3-642-16225-1},
doi = {10.1007/978-3-642-16225-1_14},
}
@article{nusskern2013simulation,
author = {Phillip Nusskern and J\"{u}rgen Hoffmeister and Volker Schulze},
journal = {HTM Journal of Heat Treatment and Materials},
title = {{S}imulation des {E}insatzhärtens gradiert poröser {B}auteile: {M}
aterialmodellierung},
year = {2013},
number = {6},
pages = {258--266},
volume = {68},
doi = {doi:10.3139/105.110200},
groups = {Material Modeling},
lastchecked = {2022-06-08},
}
@article{geijselaers2004thermomechanical,
author = {Geijselaers, H. J. M. and Huétink, H.},
journal = {AIP Conference Proceedings},
title = {Thermomechanical analysis with phase transformations},
year = {2004},
number = {1},
pages = {1508--1513},
volume = {712},
doi = {10.1063/1.1766742},
eprint = {https://aip.scitation.org/doi/pdf/10.1063/1.1766742},
groups = {Phase Transformations},
}
@PhdThesis{geijselaers2003numerical,
author = {Geijselaers, Hubertus J. M.},
school = {Universiteit Twente},
title = {Numerical simulation of stresses due to solid state transformations},
year = {2003},
groups = {Phase Transformations},
}
@article{bamberger1986determination,
author = {M. Bamberger and B. Prinz},
journal = {Materials Science and Technology},
title = {Determination of heat transfer coefficients during water cooling of
metals},
year = {1986},
number = {4},
pages = {410-415},
volume = {2},
doi = {10.1179/mst.1986.2.4.410},
groups = {measurement},
publisher = {Taylor & Francis},
}
@article{leblond1989mathematical,
author = {Leblond, J. B.},
journal = {International Journal of Plasticity},
title = {Mathematical modelling of transformation plasticity in steels {II}:
Coupling with strain hardening phenomena},
year = {1989},
issn = {0749-6419},
number = {6},
pages = {573-591},
volume = {5},
doi = {10.1016/0749-6419(89)90002-8},
groups = {Phase Transformations},
}
@book{orlich1954atlas,
author = {Orlich, J{\"u}rgen and Pietrzeniuk, Hans-Joachim},
publisher = {Verlag Stahleisen},
title = {Atlas zur W{\"a}rmebehandlung der St{\"a}hle},
year = {1954},
groups = {Norms and Reference Work},
}
@article{mevec2022combining,
author = {Mevec, Daniel G. and J{\'a}szfi, Vince and Prevedel, Petri and
Todt, Juraj and Maawad, Emad and Keckes, Jozef and Raninger, Peter},
journal = {Materials Today Communications},
title = {Combining hardness measurements of a heat-treated crankshaft
bearing with cross-sectional residual stress and retained austenite
distributions measured by {HEXRD}},
year = {2022},
pages = {104267},
volume = {33},
doi = {10.1016/j.mtcomm.2022.104267},
groups = {Own},
publisher = {Elsevier},
}
@book{jin2014fem,
author = {Jin, Jian-Ming},
publisher = {John Wiley \& Sons},
title = {The finite element method in electromagnetics},
year = {2014},
address = {Hoboken. New Jersey},
edition = {3rd ed},
isbn = {978-1-118-57136-1},
abstract = {Useful in analyzing electromagnetic problems in a variety of
engineering circumstances, the finite element method is a
powerful simulation technique. This book explains the method's
processes and techniques in careful, meticulous prose. It covers
not only essential finite element method theory, but also its
latest developments and applications.},
groups = {FEM},
keywords = {Finite element method, Simulation},
url = {https://search.worldcat.org/title/857370347},
}
@article{vieweg2018comparing,
author = {Vieweg, Annika and Ressel, Gerald and Raninger, Peter and Prevedel
, Petri and {Marsoner, Stefan} and Ebner, Reinhold},
journal = {Metall. Res. Technol.},
title = {Comparing fast inductive tempering and conventional tempering:
Effects on microstructure and mechanical properties},
year = {2018},
number = {4},
pages = {407},
volume = {115},
doi = {10.1051/metal/2018015},
groups = {IH vs convetional, Own},
url = {https://doi.org/10.1051/metal/2018015},
}
@techreport{astme975,
author = {{ASTM E975-13}},
institution = {ASTM International},
title = {Standard practice for x-ray determination of retained austenite in
steel with near random crystallographic orientation},
year = {2013},
address = {West Conshohocken, PA, USA},
type = {Standard},
doi = {10.1520/E0975-13},
groups = {Norms and Reference Work},
url = {www.astm.org},
}
@article{mahnken2012multiphase,
author = {R. Mahnken and M. Wolff and A. Schneidt and M. Böhm},
journal = {International Journal of Plasticity},
title = {Multi-phase transformations at large strains Thermodynamic
framework and simulation},
year = {2012},
issn = {0749-6419},
pages = {1-26},
volume = {39},
abstract = {We develop a macroscopic material model for visco-plastic
material behavior accompanied by phase transformations, which are
important phenomena in steel production processes. The model is
formulated within a thermodynamic framework at large strains, and
it will be specialized and applied to a hybrid-forming process in
steel production. Moreover, thermodynamic consistency of the
model will be proved, taking multi-phase transformations into
account. In a prototypical situation, TRIP is caused by bainitic
and martensitic transformation. The phase transformations
considered are: Transformation of the ferritic-pearlitic initial
state into austenite, forming of bainite and of martensite. The
modelling of bainite evolution takes the incubation via
nucleation into account and allows for individual evolutions of
upper and lower bainite. Furthermore, the numerical
implementation of the constitutive equations into a
finite-element program is described. Finally, in a numerical
example we investigate the material behavior of a steel shaft
subjected to thermo-mechanical loading in a hybrid-forming
process.},
doi = {https://doi.org/10.1016/j.ijplas.2012.05.009},
groups = {Phase Transformations},
keywords = {A. Phase transformation, A. Thermomechanical processes, B.
Viscoplastic material, C. Finite elements, Transformation-induced
plasticity, MaterialModellierung},
url = {https://www.sciencedirect.com/science/article/pii/S0749641912000927},
}
@article{garcia1998modelling,
author = {{Garc\'ia de Andr\'es}, C. and Caballero, F. G. and Capdevila, C.
and Bhadeshia, H. K. D. H.},
journal = {Scripta Materialia},
title = {Modelling of kinetics and dilatometric behavior of non-isothermal
pearlite-to-austenite transformation in an eutectoid steel},
year = {1998},
issn = {1359-6462},
number = {6},
pages = {791-796},
volume = {39},
doi = {https://doi.org/10.1016/S1359-6462(98)00146-8},
groups = {Phase Transformations,},
url = {https://www.sciencedirect.com/science/article/pii/S1359646298001468},
}
@article{garrett2004model,
author = {Garrett, R. P. and Xu, S. and Lin, J. and Dean, T. A.},
journal = {International Journal of Machine Tools and Manufacture},
title = {A model for predicting austenite to bainite phase transformation in
producing dual phase steels},
year = {2004},
issn = {0890-6955},
number = {7},
pages = {831-837},
volume = {44},
doi = {https://doi.org/10.1016/j.ijmachtools.2004.01.004},
groups = {Phase Transformations},
keywords = {Materials modelling, Phase transformation model, Optimisation,
Dual phase steel, Bainite transformation, MaterialModellierung},
url = {https://www.sciencedirect.com/science/article/pii/S0890695504000070},
}
@article{mahnken2011simulation,
author = {Mahnken, R. and Schneidt, A. and Tschumak, S. and Maier, H. J.},
journal = {Computational Materials Science},
title = {On the simulation of austenite to bainite phase transformation},
year = {2011},
issn = {0927-0256},
number = {6},
pages = {1823-1829},
volume = {50},
doi = {https://doi.org/10.1016/j.commatsci.2010.12.032},
groups = {Phase Transformations},
keywords = {Bainitic phase transformation, Upper and lower bainite,
Transformation plasticity, MaterialModellierung},
url = {https://www.sciencedirect.com/science/article/pii/S0927025610007032},
}
@article{koistinen1959general,
author = {Koistinen, D. P. and Marburger, R. E.},
journal = {Acta Metallurgica},
title = {A general equation prescribing the extent of the
austenite-martensite transformation in pure iron-carbon alloys and
plain carbon steels},
year = {1959},
issn = {0001-6160},
number = {1},
pages = {59-60},
volume = {7},
doi = {https://doi.org/10.1016/0001-6160(59)90170-1},
groups = {Modeling, Phase Transformations},
keywords = {MaterialModellierung},
url = {https://www.sciencedirect.com/science/article/pii/0001616059901701},
}
@article{johnson1939reaction,
author = {Johnson, W. A. and Mehl, R. F.},
journal = {Transactions of the American Institute of Mining, Metallurgical,
and Petroleum Engineers},
title = {Reaction kinetics in processes of nucleation and growth},
year = {1939},
pages = {416--458},
volume = {135},
groups = {Phase Transformations},
keywords = {MaterialModellierung},
}
@article{kolmogorov1937statistical,
author = {Kolmogorov, Andrei Nikolaevich},
journal = {Bull Acad Sci URSS (Cl Sci Math Nat)},
title = {On the statistical theory of the crystallization of metals},
year = {1937},
pages = {335},
volume = {3},
groups = {Phase Transformations},
keywords = {MaterialModellierung},
}
@article{fischer2000new,
author = {Fischer, F. D. and Reisner, G. and Werner, E. and Tanaka, K. and
Cailletaud, G. and Antretter, T.},
journal = {International Journal of Plasticity},
title = {A new view on transformation induced plasticity ({TRIP})},
year = {2000},
issn = {0749-6419},
number = {7},
pages = {723-748},
volume = {16},
abstract = {The phenomenon of transformation induced plasticity (TRIP) in
steel is reinvestigated both experimentally and theoretically.
The irreversible length change (TRIP strain) consists not only of
a plastic contribution (“GreenwoodJohnson” effect) but also of a
contribution due to the length change caused by the
transformation shear component of the martensitic variants
(orientation effect or “Magee” effect). This orientation effect,
which is fully accepted for shape memory alloys, is explained for
steels. Micromechanical investigations help to quantify the
orientation effect. Finally a proposal for a modified
constitutive law for elastic plastic phase changing materials is
presented.},
doi = {https://doi.org/10.1016/S0749-6419(99)00078-9},
groups = {TRIP},
keywords = {Phase transformation, Constitutive behaviour, Finite elements,
Mechanical testing, Transformation induced plasticity},
url = {https://www.sciencedirect.com/science/article/pii/S0749641999000789},
}
@article{mevec2024multi,
author = {Daniel G. Mevec and Peter Raninger and Vince Jászfi and Petri
Prevedel and Thomas Antretter},
journal = {Materialia},
title = {Multi-physical simulation of an inductive heat treatment process on
{50CrMo4} steel rods and validation by {HEXRD} cross-sectional
measurements},
year = {2024},
issn = {2589-1529},
pages = {102094},
volume = {34},
abstract = {A multi-physical finite element model for the induction
hardening of a 50CrMo4 steel rod was implemented in Abaqus,
including an electromagnetic, thermal, mechanical, and
metallurgical model describing the individual phenomena taking
place during the process. For induction heating, a linearization
scheme for the nonlinear permeability of steel was implemented.
The model was validated by recreating a previously published
experiment with the model and using the calculated residual
stress data as a comparison to the measured stresses. To ensure a
valid comparison, the sample preparation process and measurement
methodology were considered for the simulation and a good
agreement between the measured and calculated stress
distributions was obtained. Thus the distribution and time
evolution of several quantities such as temperature, phase
fractions and plastic strain can be examined to gain insight into
the formation of residual stresses.},
doi = {10.1016/j.mtla.2024.102094},
groups = {Own},
keywords = {Induction hardening, Phase transformation, Residual stress,
Synchrotron, High energy X-ray diffraction, Finite Element
Analysis},
url = {https://www.sciencedirect.com/science/article/pii/S2589152924000917},
}
@Article{Chung2022,
author = {Chung, D. D. L. and Xi, Xiang},
journal = {Materials Research Bulletin},
title = {A review of the colossal permittivity of electronic conductors, specifically metals and carbons},
year = {2022},
issn = {0025-5408},
pages = {111654},
volume = {148},
doi = {https://doi.org/10.1016/j.materresbull.2021.111654},
keywords = {A. metals, D. dielectric properties, D. electrical properties},
url = {https://www.sciencedirect.com/science/article/pii/S0025540821004517},
abstract = {The colossal permittivity of electronic conductors (specifically metals and carbons) is reviewed. Relative permittivity (even $10^8$) was predicted theoretically by Jonscher in 1999. The measured values that emerged in 2019 are up to $10^6$. The colossal permittivity is attributed to (i) charge-carrier polarization, and (ii) space charge polarization associated with the carrier-atom interaction at heterogeneities. Due to this interaction, the permittivity is more sensitive to the microstructure than the resistivity is, being increased by grain size reduction or cold work. The fraction of carriers that participate in the interaction under alternating current is low (up to 109 for graphite) and even lower (1016) under direct current. The fraction is higher for carbons than metals. Ferroelectric behavior was not observed in the carbons, but in tin-silver (Sn-4Ag, a metal). The colossal permittivity of electronic conductors is consistent with the dominance of the absorption loss over reflection loss in the radio-wave regime.}
}
@InBook{lourtioz2005bulk,
author = {Lourtioz, Jean-Michel and Benisty, Henri and Berger, Vincent and Gerard, Jean-Michel and Maystre, Daniel and Tchelnokov, Alexei and Pagnoux, D.},
publisher = {Springer},
chapter = {4},
title = {Photonic crystals},
year = {2005},
journal = {Towards Nanoscale Photonic Devices},
}
@Comment{jabref-meta: databaseType:bibtex;}
@Comment{jabref-meta: grouping:
0 AllEntriesGroup:;
1 StaticGroup:Geometry Intersection\;0\;0\;0x8a8a8aff\;\;\;;
1 StaticGroup:IH vs convetional\;0\;1\;0x8a8a8aff\;\;\;;
1 StaticGroup:Norms and Reference Work\;0\;1\;0x8a8a8aff\;\;\;;
1 StaticGroup:Own\;0\;0\;0x8a8a8aff\;\;\;;
1 StaticGroup:State-of-the-art\;0\;1\;0x8a8a8aff\;\;\;;
2 StaticGroup:FEM\;0\;1\;0x8a8a8aff\;\;\;;
3 StaticGroup:magnetics\;0\;0\;0x8a8a8aff\;\;\;;
2 StaticGroup:Inductor design\;0\;1\;0x8a8a8aff\;\;\;;
2 StaticGroup:Material Modeling\;0\;1\;0x8a8a8aff\;\;\;;
3 StaticGroup:Induction\;0\;1\;0x8a8a8aff\;\;\;;
3 StaticGroup:Phase Transformations\;0\;0\;0x8a8a8aff\;\;\;;
3 StaticGroup:TRIP\;0\;1\;0x8a8a8aff\;\;\;;
2 StaticGroup:measurement\;0\;1\;0x8a8a8aff\;\;\;;
3 StaticGroup:Magnetic Properties\;0\;0\;0x8a8a8aff\;\;\;;
3 StaticGroup:RS measurement\;0\;0\;0x8a8a8aff\;\;\;;
2 StaticGroup:Process Simulation\;0\;1\;0x8a8a8aff\;\;\;;
3 StaticGroup:Induction Heating\;0\;1\;0x8a8a8aff\;\;\;;
4 StaticGroup:IH Crankshafts\;0\;0\;0x8a8a8aff\;\;\;;
2 StaticGroup:residual stress\;0\;1\;0x8a8a8aff\;\;\;;
}
Reference in a new issue View git blame Copy permalink