Improvement
of the process flexibility on the iron ore sintering by designing of
composite granulation & bed structure
|
|
1 9:30∼9:55
|
Technologies for high productivity and high quality
of sinter at Kobe Steel,Kakogawa works
|
··· 718
|
T.Maki
|
|
2 10:05∼10:30
|
Effect of particle size and gangue mineral on
strength of granulated particle by tumbling granulation
|
··· 722
|
T.Maeda
|
|
3 10:30∼10:55
|
Analysis of particles motion in a continuous drum
type granulator by DEM
|
··· 726
|
J.Kano
|
|
4 10:55∼11:20
|
Design of the large and dense green ball for sinter
mixture
|
··· 730
|
T.Kawaguchi
|
|
5 12:30∼12:55
|
Outline of sintering reaction research in mosaic
embedding iron ore sintering process
|
··· 734
|
N.Oyama
|
|
6 12:55∼13:20
|
Granule design for the sintering with less amount
of liquid phase formation
|
··· 738
|
T.Otomo
|
|
7 13:20∼13:45
|
Penetration behavior and interfacial reaction
between calcium ferrite melts and sintered hematite
|
··· 742
|
K.Nakashima
|
|
8 13:45∼14:10
|
Texture structure and reduction behavior of
composite iron ore sinter
|
··· 745
|
H.Ono-Nakazato
|
|
9 14:10∼14:35
|
SFCA phase in the sintered ore for the iron making
process
|
··· 749
|
K.Sugiyama
|
|
10 14:55∼15:20
|
Apparent thermal diffusivity of sintered ore during
sintering process
|
··· 753
|
H.Shibata
|
|
11 15:20∼15:45
|
Heat transfer analysis of the mosaic embedding iron
ore sintering (MEBIOS) process
|
··· 756
|
N.Hayashi
|
|
12 15:45∼16:10
|
Numerical simulation of air and particle motions
and agglomeration processes in sintering beds
|
··· 760
|
T.Umekage
|
|
13 16:10∼16:35
|
Progress of numerical simulation for MEBIOS
|
··· 764
|
M.Nakano
|
|
Innovative development of refining
processes in steelmaking by multi phase fluxes
|
|
14 9:10∼9:40
|
Thermochemistry of heterogeneous CaO-SiO2-P2O5-FeO
slags for phosphorous removal
|
··· 768
|
M.Hasegawa
|
|
15 9:40∼10:10
|
Phosphorus distribution equilibrium between liquid
iron and two-liquid slag
|
··· 772
|
T.Miki
|
|
16 10:10∼10:40
|
Interfacial reaction mechanisms of
dephosphorization by the FeOx-CaO-SiO2-P2O5 multi-phase flux
|
··· 776
|
H.Matsuura
|
|
17 10:50∼11:20
|
Growth process of crystal formed in
dephosphorization slag
|
··· 780
|
Y.Kashiwaya
|
|
18 11:20∼11:50
|
Influence of crystallization of dicalcium silicate
on hot metal dephosphorization
|
··· 784
|
K.Miyamoto
|
|
19 13:00∼13:30
|
The behavior of phosphorous in the lime containing
multi-phase flux
|
··· 788
|
K.Ito
|
|
20 13:30∼14:00
|
Analysis of reaction behavior using a simulation
model of hot metal dephospgorization by multiphase slag
|
··· 791
|
S.Kitamura
|
|
21 14:00∼14:30
|
Application of capillary refining to De-S of liquid
Fe
|
··· 795
|
T.Tanaka
|
|
22 14:40∼15:10
|
Effects of flux composition on desulfurization
efficiency of hot metal with mechanical stirring
|
··· 798
|
N.Kikuchi
|
|
23 15:10∼15:40
|
Viscosity evaluation of multi-phase fluxes
|
··· 802
|
S.Sukenaga
|
|
24 15:40∼16:10
|
Thermal conductivity measurements and prediction
for molten fluxes containing solid CaO phase
|
··· 806
|
Y.Kobayashi
|
|
Various problems in the mold flux
|
|
25 8:40∼9:20
|
(Keynote Lecture)Mould fluxes and their relation to
defects and operational problems
|
··· 809
|
Kenneth C
Mills
|
|
|
26 9:20∼9:45
|
Analysis of solidification of steel on the molten
mold flux
|
··· 813
|
H.Esaka
|
|
|
27 9:45∼10:10
|
Thermophysical properties controlling heat transfer
in mould flux
|
··· 816
|
H.Toyota
|
|
|
28 10:20∼10:45
|
Mechanism of heat transfer through mold flux in
continuous casting mold
|
··· 818
|
H.Shibata
|
|
|
29 10:45∼11:10
|
Mold flux design in terms of crystallization
control
|
··· 822
|
M.Hanao
|
|
|
30 11:10∼11:35
|
Melilite crystallization of high basicity and high
viscosity mold flux
(Development of new crystallized mold flux-3)
|
··· 826
|
Y.Tsukaguchi
|
|
|
31 11:35∼12:00
|
Water model experiment on the behavior of an argon
bubble rising near the poorly wetted immersion nozzle
|
··· 830
|
M.Iguchi
|
|
|
32 13:00∼13:25
|
Development of mold powder of non-Newtonian fluid
for prevention of entrapment into molten steel
|
··· 834
|
K.Tsutsumi
|
|
|
33 13:25∼13:50
|
Structure and thermodynamics of CaO-SiO2-CaF2 melts
|
··· 836
|
M.Hayashi
|
|
|
34 13:50∼14:15
|
Viscosity evaluation of calcium silicate based
multi-phase fluxes
|
··· 837
|
S.Sukenaga
|
|
|
35 14:25∼14:50
|
Prevention of surface defects for leaded
free-cutting steels
|
··· 840
|
I.Takasu
|
|
|
36 14:50∼15:15
|
Mould lubrication and control of initial
solidification associated with continuous casting of steel(Review)
|
··· 844
|
T.Kajitani
|
|
|
Instrumentation, Control and System
Engineering
Lecture No Title Page Speaker
|
|
|
|
|
|
|
|
|
|
37 9:00∼9:30
|
Agent-based emergent synthesis of "field
force" in steel plant
-A framework for designing an agent of experienced personnel-
|
··· 1094
|
H.Tamaki
|
|
38 9:30∼10:00
|
Agent based simulation of hot strip rolling for
operation support
|
··· 1098
|
M.Konishi
|
|
39 10:15∼10:45
|
Agent-based planning in iron and steel production
-Modeling of expert in steel making process-
|
··· 1102
|
N.Fujii
|
|
40 10:45∼11:15
|
Decision making support for business strategies by
using agent based simulation
|
··· 1106
|
I.Hatono
|
|
Advanced statistical modeling
technique and its application to steel production process
|
|
41 13:10∼13:50
|
(Invited Lecture)Statistical modeling and
probabilistic inference using bayesian networks
|
··· 1110
|
Y.Motomura
|
|
42 13:50∼14:20
|
Development of the visualization system and large
database modeling of the blast furnace operation data
|
··· 1114
|
S.Matsuzaki
|
|
43 14:20∼14:50
|
Variational Bayes method for state-space models
|
··· 1118
|
K.Fujimoto
|
|
44 15:05∼15:45
|
(Invited Lecture)Pattern recognition by boosting
method
|
··· 1122
|
T.Takenouchi
|
|
45 15:45∼16:15
|
New automatic defect classification technique for
surface inspection systems
|
··· 1126
|
T.Hirata
|
|
46 16:15∼16:45
|
Robust optimization via randomized algorithms
|
··· 1130
|
Y.Fujisaki
|
|
Processing for Quality Products
Lecture No Title Page Speaker
|
|
The frontiers of the cooling
technology
|
|
47 10:05∼10:35
|
Effects of parameters on cooling curves
|
··· 1150
|
H.Ohkubo
|
|
48 10:35∼11:05
|
Effect of plate moving velocity on cooling
characteristics of laminar water flow for hot plate
|
··· 1151
|
Y.Haraguchi
|
|
49 11:05∼11:25
|
Effect of water temperature on characteristics of
heat transfer in spray cooling
|
··· 1153
|
N.Nakata
|
|
50 11:25∼11:50
|
Cooling technology in steel making process
|
··· 1155
|
Y.Serizawa
|
|
51 13:00∼13:30
|
(Invited Lecture)Effect of contact angle on water
drop evaporation on heated surface
|
··· 1159
|
Y.Takata
|
|
52 13:30∼14:00
|
(Invited Lecture)Study on extinction of
liquid-solid contact and surface wettability during cooling by boiling
|
··· 1161
|
N.Nagai
|
|
53 14:00∼14:30
|
(Invited Lecture)Characteristics of wetting
temperature during cooling with spray
|
··· 1164
|
Y.Mitsutake
|
|
54 14:30∼15:00
|
(Invited Lecture)Current rewetting model and its
problems
|
··· 1167
|
H.Ohtake
|
|
55 15:00∼15:30
|
(Invited Lecture)An analysis of thermally couple
problem using pseudo-compressibility method
|
··· 1169
|
H.Kamegaya
|
|
56 15:30∼16:00
|
3-d numerical simulation of a free surface liquid
jet impinging on a solid substrate
|
··· 1170
|
H.Fujimoto
|
|
Microstructure and Properties of
Materials
Lecture No Title Page Speaker
|
|
Effects of biofilm on the materials
surface characteristics
|
|
57 13:10∼13:30
|
Microbial adhesion behavior on various metal
surfaces
|
··· 1236
|
K.Kittaka
|
|
58 13:30∼13:50
|
Interaction between pseudo-sensitized stainless
steel surfaces and protein
|
··· 1238
|
S.Fukuzaki
|
|
59 13:50∼14:10
|
The characteristics of biofilm polymer
|
··· 1242
|
H.Morisaki
|
|
60 14:10∼14:30
|
Formation of Tin-silver films on steels through
heat-treatment alloying process and their ability to inhibit the growth of
biofilm
|
··· 1244
|
H.Kanematsu
|
|
61 14:30∼14:50
|
Inhibition of biofilm formation on metal surface
using electrodeposited biofunctional molecule
|
··· 1247
|
Y.Tanaka
|
|
62 14:50∼15:10
|
Physical properties, antibacterial efficacy and biodegradation
characteristics of chitosan films
|
··· 1251
|
T.Nakashima
|
|
63 15:30∼16:00
|
(Invited Lecture)Biofilms adhesion and microbially
influenced corrosion of anti-bacterial SUS304AB exposed to dam water
|
··· 1255
|
T.Anzai
|
|
64 16:00∼16:20
|
Investigation of microbiologically influenced
corrosion in anaerobic environments
|
··· 1257
|
K.Ito
|
|
65 16:20∼16:40
|
Analysis of microbiologically influenced corrosion
and biofilm formed in water solved natural gas plant
|
··· 1259
|
Y.Tanji
|
|
Recent advancement of research
& development on hydrogen energy related structural materials
|
|
66 9:55∼10:20
|
(Keynote Lecture)Technical standards study for fuel
cell vehicle commercialization and expectation
to metal material research
|
··· 1261
|
H.Tamura
|
|
67 10:20∼10:50
|
(Keynote Lecture)Hydrogen embrittlement of
austenitic stainless steels
|
··· 1265
|
M.Nagumo
|
|
68 11:00∼11:25
|
Evaluation of hydrogen gas embrittlement of metals
in 210MPa hydrogen
|
··· 1269
|
S.Fukuyama
|
|
69 11:25∼11:50
|
Effect of high pressure gaseous hydrogen on the
tensile properties of four types of stainless steels
|
··· 1273
|
H.Nakagawa
|
|
70 13:00∼13:25
|
Analysis of deformation behavior of commercially
pure titanium in liquid hydrogen by computer simulation
|
··· 1277
|
K.Shibata
|
|
71 13:25∼13:50
|
Effect of high-pressure hydrogen on fatigue
properties at low temperatures of austenitic stainless
steels by the simple testing method
|
··· 1281
|
T.Ogata
|
|
72 14:00∼14:25
|
Fatigue crack growth of SUS304L stainless steel in
high pressure gaseous hydrogen
|
··· 1285
|
S.Ohmiya
|
|
73 14:25∼14:50
|
Fatigue properties and its degradation mechanism of
stainless steels in high pressure gaseous hydrogen environment
|
··· 1289
|
J.Nakamura
|
|
74 14:50∼15:15
|
Development of high strength austenitic stainless
steels containing reduced amount of nickel for hydrogen energy systems
|
··· 1293
|
M.Hatano
|
|
Structure control of
nitrogen-bearing steels and their properties
|
|
75 9:20∼9:50
|
Processing and evaluation of 6% Ni-containing high
nitrogen stainless steel
|
··· 1297
|
F.Takahashi
|
|
76 9:50∼10:20
|
Application of solution nitriding to SUS410 and its
efficacy
|
··· 1299
|
Ngo Huynh Kinh Luan
|
|
77 10:20∼10:50
|
Effect of nitrogen gas introduction temperature on
mechanical properties of high nitrogen stainless steels fabricated by metal
injection molding
|
··· 1301
|
Y.Aoyama
|
|
78 11:00∼11:30
|
Weldabilty of 1.00mass% high nitrogen steel by
friction pressure welding
|
··· 1304
|
K.Tanino
|
|
79 11:30∼12:00
|
Friction stir welding on 1mass% nitrogen containing
austenitic stainless steel
|
··· 1306
|
Y.Miyano
|
|
80 13:00∼13:30
|
Application of high nitrogen stainless steels to
bipolar plates for PEFC
|
··· 1307
|
H.Yashiro
|
|
81 13:30∼14:00
|
Effect of nitrogen addition on phase stability and
stacking fault energy in austenitic stainless steels
|
··· 1311
|
M.Ojima
|
|
82 14:00∼14:30
|
Effect of copper addition on tensile deformation behavior
of high nitrogen austenitic steel
|
··· 1313
|
T.Onomoto
|
|
83 14:40∼15:10
|
Effects of alloying elements, aging temperature and
pre-strain on the micro-structure of high nitrogen steels
|
··· 1315
|
Y.Katada
|
|
84 15:10∼15:40
|
Gradient structure control in metastable austenitic
stainless steel by solution nitriding and cold rolling
|
··· 1318
|
H.Takebe
|
|
85 15:40∼16:10
|
Grain boundary engineering of nickel-free high
nitrogen austenitic stainless steel
|
··· 1320
|
S.Sato
|
|
Process Evaluation and Material
Characterization
Lecture No Title Page Speaker
|
|
Prospect of light element
analysis in iron and steel materials
|
|
86 13:00∼13:20
|
Quantitative analysis of carbon,sulfur and nitrogen
by optical emission spectrometry
|
··· 1490
|
K.Hayashi
|
|
87 13:20∼13:40
|
The analysis of La and Ce in iron and steel using
the membrane filter
|
··· 1494
|
H.Yamaguchi
|
|
88 13:40∼14:00
|
Chemical analysis of dilute oxygen and aluminum in
iron alloys
|
··· 1496
|
T.Miki
|
|
89 14:00∼14:20
|
Improvement of laser induced breakdown spectroscopy
analysis by laser induced fluorescence spectroscopy
|
··· 1500
|
Y.Isei
|
|
90 14:20∼14:40
|
Detection of nonmetal particles in still by
laser-ablation/He microwave-induced atmospheric pressure plasma spectrometry
|
··· 1504
|
Y.Okamoto
|
|
91 14:40∼15:00
|
Non-destructive depth profiling of steel surface by
quantum beam
|
··· 1508
|
H.Yamamoto
|
|
92 15:10∼15:40
|
(Invited Lecture)Advanced chemical analysis using
computer-controlled automated flow system
|
··· 1512
|
S.Motomizu
|
|
93 15:40∼16:00
|
Development of simple, rapid and sensitive chemical
methods of analysis for iron and steel utilizing flow injection system
|
··· 1516
|
T.Yamane
|
|
94 16:00∼16:20
|
Quantitative analysis of carbon and nitrogen
dissolved in �� iron by mechanical spectroscopy
|
··· 1518
|
H.Numakura
|
|
95 16:20∼16:40
|
Gas analysis by small quadrupole mass spectrometer
under low vacuum
|
··· 1519
|
T.Yamamoto
|
|
96 16:40∼17:00
|
On-site analysis of some materials evaluation using
small X-ray fluorescence spectrometer
|
··· 1522
|
H.Yoshikawa
|
|
97 17:00∼17:20
|
The development of a very small amount of inter.
evaluation method in magnesium and magnesium alloy
|
··· 1523
|
S.Tsutsukawa
|
|
Structural
and compositional characterization of heterogeneity in multi-components
steel-relevant materials
|
|
98 9:00∼9:25
|
(Invited Lecture)Nanostructure analyses of metallic
alloys using X-ray probe
|
··· 1527
|
S.Sato
|
|
99 9:25∼9:50
|
Effect of P precipitation on the grain boundary
segregation of P in Fe-P alloys
|
··· 1531
|
T.Tanaka
|
|
100 9:50∼10:15
|
New proposal to take into account precipitation of
copper sulfide by residual level of copper in quantitative chemical analysis
of each kind of sulfide
|
··· 1534
|
Y.Ishiguro
|
|
101 10:15∼10:40
|
Analysis of Cu segregation to oxide-metal interface
of Ni-base alloy by HX-PES
|
··· 1538
|
T.Doi
|
|
102 10:45∼11:10
|
Characterization of transformation of green rust to
iron oxides and ferric oxyhydroxides in aqueous media
|
··· 1540
|
K.Inoue
|
|
103 11:10∼11:35
|
Structural analysis of inorganic matter in coal by
high-resolution solid state NMR
(Changes of inorganic chemical structure during coalification)
|
··· 1542
|
T.Takahashi
|
|
104 11:35∼12:00
|
Structural characterization of stress-induced phase
transformation in polycrystalline austenitic Fe base alloys
|
··· 1545
|
S.Suzuki
|
|
Environmental and Energy
Technology/Microstructure and Properties of Materials
Lecture No Title Page Speaker
|
|
Studies on heat resistant
materials for eco-friendly A-USC power plants
|
|
105 9:00∼9:45
|
(Keynote Lecture)A-USC technology development,a
challenge to the global warming
|
··· 1018
|
M.Fukuda
|
|
106 9:45∼10:30
|
(Keynote Lecture)Formation and thermal stability of
gamma+gamma-prime two-phase microstructures in Ni-base alloys
|
··· 1022
|
M.Doi
|
|
107 10:40∼11:10
|
Development of a low thermal expansion superalloy
for steam turbine applications
|
··· 1026
|
T.Ohno
|
|
108 11:10∼11:40
|
Trial melting of Ni-Fe base superalloy(FENIX-700)
large ingot for 700°C class A-USC turbine rotor
|
··· 1030
|
S.Imano
|
|
109 11:40∼12:10
|
Trial rotor manufacture by Ni based heat resistant
alloy for A-USC power generating system
|
··· 1034
|
K.Imai
|
|
110 13:10∼13:55
|
(Keynote Lecture)Development of heat resistant
structural materials and creep strength estimation methods for the coal fired
power plant application with 700°C of steam temperature
|
··· 1036
|
Y.Hasegawa
|
|
111 13:55∼14:25
|
Alloy design of Ni-base superalloys for 750°C class
A-USC steam turbine rotor
|
··· 1040
|
J.Sato
|
|
112 14:25∼14:55
|
Effect of cooling rate after solution treatment on
mechanical properties of Ni-Fe base superalloy for advanced USC turbine rotor
shafts
|
··· 1044
|
S.Ohsaki
|
|
113 14:55∼15:25
|
Creep properties of austenitic heat resistant steel
strengthened by intermetallic compounds
|
··· 1048
|
N.Takata
|
|
114 15:35∼16:05
|
Improvement of creep property in high Cr ferritic heat
resistant steel welded joint
|
··· 1049
|
S.Tsukamoto
|
|
115 16:05∼16:35
|
Estimation of the system free energy in HAZ of 9Cr
heat resistant ferritic steels
|
··· 1053
|
Y.Murata
|
|
116 16:35∼17:05
|
Creep properties evaluation of local regimes in welded
joint of 8Cr-2W-VTa steel by small punch test
|
··· 1057
|
S.Komazaki
|
|
117 17:05∼17:35
|
Materials science and technology on martensitic
steels for advanced USC power plants
|
··· 1058
|
M.Igarashi
|
|
Studies on heat resistant
materials for eco-friendly A-USC power plants
|
|
118 9:00∼9:30
|
Effect of Cr on the creep strength in high Cr
ferritic heat resistant steels
|
··· 1062
|
K.Miki
|
|
119 9:30∼10:00
|
(ISIJ Research Promotion Grant)Phase transformation
behaviour of Gr.91 ferritic steel around the Ac1 temperature
|
··· 1066
|
T.Tokunaga
|
|
120 10:00∼10:30
|
High-temperature strength mechanism of 9Cr-ODS
ferritic steels with complex structure
|
··· 1068
|
S.Ukai
|
|
121 10:40∼11:10
|
Creep behavior of SUS304 steels studied by creep
test using helicoid springs
|
··· 1069
|
M.Mitsuhara
|
|
122 11:10∼11:40
|
Position lifetime spectrometer for in-situ
measurement of high-temperature creep of metals
|
··· 1073
|
Y.Shirai
|
|
123 11:40∼12:10
|
(ISIJ Research Promotion Grant)The cause and
detection of creep strength breakdown in strength enhanced high Cr ferritic
steels
|
··· 1077
|
K.Maruyama
|
|
|
|
|
|