Lecture No |
Title |
Page |
Speaker |
Control of reduction equilibrium in blast furnace through vicinity
arrangement of iron ore and carbon
|
D1
|
Achievement of
low reducing agent rate operation of blast furnace by controlling size of
coke mixed in ore layer
|
······1
|
K.Miyagawa
|
D2
|
Reduction of
reducing agent rate with carbon iron composite
|
······5
|
T.Sato
|
D3
|
Bonding energy of
carbon implanted into hematite
|
······9
|
Y.Kashiwaya
|
D4
|
Design of iron ore/carbon
composite for increasing iron reduction rate
|
······13
|
K.Miura
|
D5
|
Lowering the
reduction temperature of iron oxide in the coal/iron ore composite
|
······17
|
T.Murakami
|
D6
|
Blast furnace simulated
reaction behavior of a packed bed mixed with iron ore pellets and coal
composite iron ore hot briquettes
|
······21
|
S.Hayashi
|
D7
|
(ISIJ Research Promotion Grant)
Reaction model of
carbon iron-ore composite and reduction behavior in blast furnace
|
······25
|
T.Ariyama
|
D8
|
Softening-melting
properties and reactivity of carbon-iron composite
|
······29
|
K.Sunahara
|
D9
|
Slag design with the
aim of the low-temperature and rate-enhancement of the carburization reaction
|
······33
|
H.Ono-Nakazato
|
D10
|
Carburization
mechanism of reduced iron in coal and iron ore composite
|
······35
|
T.Miki
|
D11
|
(ISIJ Research Promotion Grant)
Effects of
melting temperature and amount of slag on slag-metal separation behavior
|
······39
|
K.Ohno
|
D12
|
Physical property
measurements of blast furnace type slags
|
······43
|
S.Sukenaga
|
Fundamentals and applications
of multi-phase flow analysis
|
D13
|
Computation of
MHD convection with a modeling of the Hartmann layer
|
······47
|
T.Tagawa
|
D14
|
Tensor-valued
surface tension model for interface capturing method
|
······51
|
K.Ueno
|
D15
|
(Invited Lecture)
Numerical
analysis of violent free-surface flows
|
······55
|
T.Himeno
|
D16
|
High-Precision
analysis of fluid flow with free surface
|
······58
|
K.Takatani
|
D17
|
(Invited Lecture)
CFD analysis for
moving boundary problems by generalized porosity method
|
······62
|
M.Sakata
|
D18
|
Hybrid
multiphase-flow simulation of bubble-driven flow in complex geometry using an
immersed boundary apporach
|
······66
|
M.Tanaka
|
D19
|
(Invited Lecture)
Car-body design
tools in painting process
|
······69
|
H.Tominaga
|
D20
|
Flow pattern
transition phenomena induced by channel miniaturization in gas-liquid
two-phase flow
|
······73
|
T.Kumagai
|
D21
|
Production of
mono-disperse metal particles from liquid jet with electromagnetic force
|
······76
|
S.Shimasaki
|
D22
|
Development of
manufacturing technology for high quality solar silicon ingots
|
······79
|
S.Nara
|
D23
|
Thermal and fluid
simulation of molten steel in steelmaking process and unsteady thermal
modeling
|
······83
|
T.Nakaoka
|
D24
|
(Nishiyama Commemorative Prize)
Steel sheet
process development based on numerical simulation
|
······85
|
T.Ishii
|
Social Engineering
on Iron and Steel Industry
|
Lecture No |
Title |
Page |
Speaker |
D25
|
Evaluation method
of metal resource recyclability based on thermodynamic analysis for materials
strategy
|
······217
|
K.Nakajima
|
D26
|
Material flow
analysis on the manganese associated with iron and steel cycle
|
······219
|
K.Matsubae-Yokoyama
|
D27
|
(ISIJ Young Researcher Award)
Substance flows
associated with steel cycle:a case study on Cr
|
|
I.Daigo
|
D28
|
Estimation of
future steel stock and flow in East Asia
|
······221
|
E.Kakiuchi
|
D29
|
Method of
analysis to calculate copper in-use stock in East-Asia
|
······222
|
R.Terakado
|
D30
|
Estimation of
resources in long-term supply-demand model of metals
|
······223
|
S.Murakami
|
D31
|
Material flow of
platinum for automobile in Japan
|
······225
|
S.Ita
|
D32
|
Utilization and
recycling of plastic materials in automobile
|
······228
|
M.Hirao
|
D33
|
Visualization of
inter-sectoral material flow based on triangularization of input-output table
|
······229
|
Y.Kondo
|
Instrumentation, Control
and System Engineering
|
Lecture No |
Title |
Page |
Speaker |
Research
activities in the research group on "Novel steel process control based
on |
D34
|
Modeling and problem
formulation for bimodal coiler control problem
|
······323
|
S.Masuda
|
D35
|
Design case study
for bimodal coiler control problem
|
······326
|
M.Hirata
|
D36
|
Thickness control
for cold tandem mill by nonlinear receding horizon control
|
······330
|
T.Ohtsuka
|
D37
|
Simultaneous
optimization of charging scheduling and heating control in reheating furnace
|
······334
|
S.Fujii
|
D38
|
Simulator based
design of secondary cooling zone control in continuous casting
|
······338
|
Y.Fujisaki
|
Processing for Quality
Products
|
Lecture No |
Title |
Page |
Speaker |
Recent development of rolling equipments and control technologies
|
D39
|
The latest
process control technology of hot-rolling
|
······350
|
N.Kubo
|
D40
|
Development of
flying gauge press
|
······354
|
Y.Dodo
|
D41
|
Reducing of
impact force at threading of strip head end and mill vibration with mill
stabilizer device, and application to production line
|
······358
|
H.Furumoto
|
D42
|
(Invited Lecture)
Development of
rolling reduction control technology to prevent slip when it rolled the
ultrahigh-intensity strip front
|
······362
|
M.Sugahara
|
D43
|
Control apparatus
in recent flat rolling line
|
······366
|
H.Honjo
|
D44
|
Precise control
method for strip flatness in cluster-type rolling mill
|
······370
|
J.Tateno.
|
D45
|
Runout table
cooling control technology in hot strip mill
|
······374
|
H.Tachibana
|
D46
|
Rolling set-up system
for steel plates through Just-In-Time modeling
|
······378
|
H.Shigemori
|
Fracture
of steel tube and its numerical simulation: current status and problems
|
D47
|
(Invited Lecture)
Effect of
processing temperature on ductile fracture
|
······382
|
T.Kawabe
|
D48
|
Formability
evaluation in tube hydroforming
|
······386
|
K.Sato
|
D49
|
Prediction method
for propagation and arrest of running shear fracture in natural gas pipelines
by HLP committee
|
······390
|
T.Kubo
|
D50
|
(Invited Lecture)
Development of 3D
finite element simulation system for burst phenomenon of pipeline containing
high pressure liquid natural gas
|
······394
|
S.Yoshimura
|
D51
|
Fracture propagation
and arrest in high pressure gas transmission pipeline by ultra high strength
line pipes
|
······398
|
H.Makino
|
D52
|
Crack propagation
behavior analyses of simulation model for ductile crack propagation in high-pressure
gas pipelines coupling gas-decompression and dynamic fracture
|
······402
|
K.Misawa
|
New technological development
of roll and lubricant
|
D53
|
Influence of
plate-out oil film on lubrication characteristics in cold rolling
|
······406
|
N.Fujita
|
D54
|
Environmental
performance of new synthetic cold rolling fluid
|
······410
|
Y.Furugori
|
D55
|
Effects of
emulsion behavior on rolling force in aluminium cold rolling
|
······413
|
H.Ohta
|
D56
|
Coefficient of friction
and lubrication model in hot sheet rolling
|
······417
|
Y.Nakata
|
D57
|
Characteristics
of water soluble colloidal lubricants with solid lubricant and inorganic
compound
|
······421
|
K.Noro
|
D58
|
Development of
composite-type WC rolls
|
······425
|
H.Tomita
|
D59
|
Characteristics
of wear on fiber reinforced metal at high temperature
|
······429
|
T.Inoue
|
Microstructure and Properties
of Materials
|
Lecture No |
Title |
Page |
Speaker |
Fundamentals and novel approaches for new demands on mechanical properties of steels
|
D60
|
Inhomogeneous deformation and work-hardening
|
······457
|
K.Higashida
|
D61
|
Effect of microstructure
on work hardening properties of austenitic stainless steels
|
······459
|
Y.Hideshima
|
D62
|
Effect of warm
pre-rolling on tensile deformation behavior in high nitrogen austenitic
stainless steel
|
······463
|
R.Inoue
|
D63
|
Effect of strain
aging on anisotropic work hardening
|
······466
|
K.Nagai
|
D64
|
Effect of strain
rate on dynamic strain aging for cold forging steels
|
······470
|
T.Masuda
|
D65
|
Difference in work
hardening behavior between hard and soft particles dispersion ferritic steel
|
······472
|
N.Nakada
|
D66
|
Stress-strain
relations in various multi-microstructure steels
|
······476
|
N.Tsuchida
|
D67
|
Work hardening mechanism
of pearlite steel studied by neutron diffraction and EBSD method
|
······480
|
S.Morooka
|
D68
|
Effect of dual
phase microstructure control and deformation on tensile properties os steels
for building structures
|
······484
|
S.Suzuki
|
D69
|
Effect of
solution carbon on development of deformation structure of lath martensite
with retained austenite films
|
······488
|
S.Morito
|
D70
|
Producing a fully
martensitic microstructure by hot stamping method and its mechanical
properties
|
······492
|
N.Kojima
|
D71
|
Determination of
plastic deformation behavior and material modeling of IF steel under biaxial
tension
|
······496
|
T.Kimura
|
D72
|
Effects of
anisotropic yield functions on the accuracy of forming simulations of bore
expansion
|
······500
|
K.Hashimoto
|
Process Evaluation and
Material Characterization
|
Lecture No |
Title |
Page |
Speaker |
Newly analytical method for inorganic
materials
|
D73
|
Non-destructive analysis
of deep surface on inorganic materials by quantum beam
|
······644
|
H.Yamamoto
|
D74
|
Trace element
measurement in silicon carbide
|
······645
|
H.Yamaguchi
|
D75
|
(Invited Lecture)
Thermo-analytical
characterization of chicken waste-coal blend to use as activated carbon for
capturing CO2
|
······647
|
R.Ozao
|
D76
|
(Invited Lecture)
TEM specimen
preparation using focused ion beam and removal of the damaged layer
|
······650
|
T.Kato
|
D77
|
(ISIJ Research Promotion Grant)
Evaluation test
on water purification of inorganic environmental materials using ion chromatography
|
······654
|
M.Mori
|
D78
|
Evaluation of
contaminants from experimental instruments and reagents on determination of
trace elements in inorganic materials by HR-ICP-MS
|
······655
|
T.Ashino
|
D79
|
(Invited Lecture)
Development of
particle dispersion technique for advanced analyses
|
······658
|
H.Muto
|
D80
|
(Invited Lecture)
Separation of
trace lead in iron and steel by coprecipitation with Yttrium phosphate
|
······660
|
S.Kagaya
|
D81
|
X-ray diffraction
studies for a dehydration process from Gibbsite to γ-Al2O3
|
······663
|
C.Numako
|
D82
|
(Invited Lecture)
Microstructure and
mechanical strength development of hydrothermally solidified blast furnace
slag
|
······667
|
N.Isu
|
D83
|
Analysis of trace
amounts of Fe in the sea water to investigate the effect of steelmaking slag
as the Fe-fertilizer for seaweeds
|
······670
|
M.Aimoto
|
D84
|
(Invited Lecture)
Characterization
of transformation of Green Rust to iron oxides and ferric oxyhydroxides
induced by oxidation
|
······673
|
S.Suzuki
|
Environmental and Energy Technology/Microstructure
and Properties of Materials/Processing for Quality Products
|
Lecture No |
Title |
Page |
Speaker |
Microstructure
control with Inter-process cooperation
|
D85
|
(Invited Lecture)
Possibility of steel
production by means of impurities
|
······231
|
T.Hanamura
|
D86
|
About
non-metallic inclusions in stainless steels
|
······235
|
H.Todoroki
|
D87
|
Nucleation and
growth in the CC mold of steel
|
······239
|
H.Esaka
|
D88
|
(Invited Lecture)Twin roll strip caster
|
······242
|
K.Nakayama
|
D89
|
Dissolution of
hot ductility and prevention of slab surface transverse cracking by
microstructure control
|
······246
|
T.Kato
|
D90
|
Change in composition
and structure of non-metallic inclusions by heating and rolling
|
······250
|
S.Kitamura
|
D91
|
Reduction of
center porosity in rolling and forging process
|
······254
|
M.Nakasaki
|