2 Conferences - 1 Location 29. August - 2. September 2022, Bremen – Germany
8th ECIC European Coke and Ironmaking Congress
9th ICSTI International Conference on Science and Technology of Ironmaking
Program of ECIC & ICSTI 2022
29 August - 2 September 2022
Opening / plenary session | Technical sessions Exhibition
Technical sessions | Evening event
Technical sessions | Closing session | Farewell event
Plant visits
Room „Hanse“ | Room „Borgwald“ | Room „Focke Wulf“ | Room „Lloyd“ | |
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9:00 | Opening Session 9:00 Opening of the conference by the chairman | 9:00 | 9:00 | 9:00 |
9:05 | 9:05 | 9:05 | 9:05 | |
9:10 | 9:10 Welcome address by the host | 9:10 | 9:10 | 9:10 |
9:15 | 9:15 | 9:15 | 9:15 | |
9:20 | Key Notes 9:20 ArcelorMittal Bremen - The road to green steel | 9:20 | 9:20 | 9:20 |
9:25 | 9:25 | 9:25 | 9:25 | |
9:30 | 9:30 | 9:30 | 9:30 | |
9:35 | 9:35 | 9:35 | 9:35 | |
9:40 | 9:40 | 9:40 | 9:40 | |
9:45 | 9:45 Exploring Paul Wurth's latest technological developments: How are we in SMS group building on our metallurgical expertise to advance green iron & steelmaking? | 9:45 | 9:45 | 9:45 |
9:50 | 9:50 | 9:50 | 9:50 | |
9:55 | 9:55 | 9:55 | 9:55 | |
10:00 | 10:00 | 10:00 | 10:00 | |
10:05 | 10:05 | 10:05 | 10:05 | |
10:10 | 10:10 Leaving Carbon Behind - A Long Bumpy Road Ahead! | 10:10 | 10:10 | 10:10 |
10:15 | 10:15 | 10:15 | 10:15 | |
10:20 | 10:20 | 10:20 | 10:20 | |
10:25 | 10:25 | 10:25 | 10:25 | |
10:30 | 10:30 | 10:30 | 10:30 | |
10:35 | 10:35 | 10:35 | 10:35 | 10:35 |
10:40 | 10:40 | 10:40 | 10:40 | 10:40 |
10:45 | 10:45 | 10:45 | 10:45 | 10:45 |
10:50 | 10:50 | 10:50 | 10:50 | 10:50 |
10:55 | 10:55 | 10:55 | 10:55 | 10:55 |
11:00 | 11:00 | 11:00 | 11:00 | 11:00 |
11:05 | Plenary I - State of the art and technical innovations in ironmaking 11:05 Economically viable and sustainable approaches to secure European steelmaking industry | 11:05 | 11:05 | 11:05 |
11:10 | 11:10 | 11:10 | 11:10 | |
11:15 | 11:15 | 11:15 | 11:15 | |
11:20 | 11:20 | 11:20 | 11:20 | |
11:25 | 11:25 | 11:25 | 11:25 | |
11:30 | 11:30 HBI: Steel’s most versatile metallic in the transition to the hydrogen economy | 11:30 | 11:30 | 11:30 |
11:35 | 11:35 | 11:35 | 11:35 | |
11:40 | 11:40 | 11:40 | 11:40 | |
11:45 | 11:45 | 11:45 | 11:45 | |
11:50 | 11:50 | 11:50 | 11:50 | |
11:55 | 11:55 Factors determining the best composition of the ferrous burden in the blast furnace | 11:55 | 11:55 | 11:55 |
12:00 | 12:00 | 12:00 | 12:00 | |
12:05 | 12:05 | 12:05 | 12:05 | |
12:10 | 12:10 | 12:10 | 12:10 | |
12:15 | 12:15 | 12:15 | 12:15 | |
12:20 | 12:20 | 12:20 | 12:20 | 12:20 |
12:25 | 12:25 | 12:25 | 12:25 | 12:25 |
12:30 | 12:30 | 12:30 | 12:30 | 12:30 |
12:35 | 12:35 | 12:35 | 12:35 | 12:35 |
12:40 | 12:40 | 12:40 | 12:40 | 12:40 |
12:45 | 12:45 | 12:45 | 12:45 | 12:45 |
12:50 | 12:50 | 12:50 | 12:50 | 12:50 |
12:55 | 12:55 | 12:55 | 12:55 | 12:55 |
13:00 | 13:00 | 13:00 | 13:00 | 13:00 |
13:05 | 13:05 | 13:05 | 13:05 | 13:05 |
13:10 | 13:10 | 13:10 | 13:10 | 13:10 |
13:15 | 13:15 | 13:15 | 13:15 | 13:15 |
13:20 | 13:20 | 13:20 | 13:20 | 13:20 |
13:25 | Plenary II - Regional developments in ironmaking facing the challenges of the future 13:25 Comparison of blast furnace operation in China and Europe | 13:25 | 13:25 | 13:25 |
13:30 | 13:30 | 13:30 | 13:30 | |
13:35 | 13:35 | 13:35 | 13:35 | |
13:40 | 13:40 | 13:40 | 13:40 | |
13:45 | 13:45 | 13:45 | 13:45 | |
13:50 | 13:50 Status and development of ironmaking in Russia | 13:50 | 13:50 | 13:50 |
13:55 | 13:55 | 13:55 | 13:55 | |
14:00 | 14:00 | 14:00 | 14:00 | |
14:05 | 14:05 | 14:05 | 14:05 | |
14:10 | 14:10 | 14:10 | 14:10 | |
14:15 | 14:15 The European iron and steelmaking industry on the way to climate neutral production in the years to come | 14:15 | 14:15 | 14:15 |
14:20 | 14:20 | 14:20 | 14:20 | |
14:25 | 14:25 | 14:25 | 14:25 | |
14:30 | 14:30 | 14:30 | 14:30 | |
14:35 | 14:35 | 14:35 | 14:35 | |
14:40 | 14:40 Chinese ironmaking industry: Recent development and future perspective | 14:40 | 14:40 | 14:40 |
14:45 | 14:45 | 14:45 | 14:45 | |
14:50 | 14:50 | 14:50 | 14:50 | |
14:55 | 14:55 | 14:55 | 14:55 | |
15:00 | 15:00 | 15:00 | 15:00 | |
15:05 | 15:05 | 15:05 | 15:05 | 15:05 |
15:10 | 15:10 | 15:10 | 15:10 | 15:10 |
15:15 | 15:15 | 15:15 | 15:15 | 15:15 |
15:20 | 15:20 | 15:20 | 15:20 | 15:20 |
15:25 | 15:25 | 15:25 | 15:25 | 15:25 |
15:30 | Ways to low-CO2 or climate neutral iron and steelmaking I - General view for ways and measures 15:30 Roadmap for decarbonising the German steel industry | Coking coal and coal blending practice 15:30 In-situ study of plastic layer permeability during coking of Australian coking coals | Fundamentals in blast furnace ironmaking 15:30 Mini blast furnace project | Blast furnace campaign and campaign life extension 15:30 Research and countermeasure on abnormal erosion of hearth lining in modern blast furnace |
15:35 | ||||
15:40 | ||||
15:45 | ||||
15:50 | ||||
15:55 | 15:55 Holistic CO2e accounting for alternative ironmaking | 15:55 Characterisation of complex coal blends using Optical imaging system | 15:55 Blast furnace flame temperature calculation improvements | 15:55 Estimation of the local wall-mushroom thickness at the blast furnace taphole |
16:00 | ||||
16:05 | ||||
16:10 | ||||
16:15 | ||||
16:20 | 16:20 | 16:20 | 16:20 Dynamic analysis of raceway formation | 16:20 Challenges and improvements in the second campaign of ArcelorMittal Tubarão Blast Furnace #3 |
16:25 | 16:25 | 16:25 | ||
16:30 | Ways to low-CO2 or climate neutral iron and steelmaking II - Smart carbon usage – CO2 capture and storage, Carbon capture and usage 16:30 Sustainable production of low carbon, renewable fuels by fermenting industrial process gasses from the iron and steel industry | Coke oven gas cleaning and utilization of by-products 16:30 Removal of H2S from coke oven gas by ammonia absorption column | ||
16:35 | ||||
16:40 | ||||
16:45 | 16:45 Computational study of gas-flow and temperature distribution in the blast furnace throat region | 16:45 Campaign life extension JSW BF#4 Vijayanagar using Rutilit® | ||
16:50 | ||||
16:55 | 16:55 Opportunities of blast furnace ironmaking to contribute to decarbonisation targets via carbon dioxide capture and utilisation | 16:55 Revamping of high pressure gas treatment unit at Zentralkokerei Saar Gmbh (ZKS) | ||
17:00 | ||||
17:05 | ||||
17:10 | 17:10 Blast furnace thermal control reconsidered | 17:10 High blast temperature study of large blast furnace stove in SHOUGANG | ||
17:15 | ||||
17:20 | 17:20 | 17:20 Presentation of thyssenkrupp Industrial Solutions | ||
17:25 | 17:25 | |||
17:30 | 17:30 | |||
17:35 | 17:35 | 17:35 Influence of iron ore shape on reduction behavior in single particle by 3-dimensional numeric assessment | 17:35 Investigation of Molten Slag Flow and Interactions in the Packed Bed | |
17:40 | 17:40 | |||
17:45 | 17:45 | 17:45 | ||
17:50 | 17:50 | 17:50 | ||
17:55 | 17:55 | 17:55 | ||
18:00 | 18:00 | 18:00 | 18:00 | 18:00 |
18:05 | 18:05 | 18:05 | 18:05 | 18:05 |
18:10 | 18:10 | 18:10 | 18:10 | 18:10 |
18:15 | 18:15 | 18:15 | 18:15 | 18:15 |
18:20 | 18:20 | 18:20 | 18:20 | 18:20 |
18:25 | 18:25 | 18:25 | 18:25 | 18:25 |
18:30 | 18:30 | 18:30 | 18:30 | 18:30 |
18:35 | 18:35 | 18:35 | 18:35 | 18:35 |
18:40 | 18:40 | 18:40 | 18:40 | 18:40 |
18:45 | 18:45 | 18:45 | 18:45 | 18:45 |
18:50 | 18:50 | 18:50 | 18:50 | 18:50 |
18:55 | 18:55 | 18:55 | 18:55 | 18:55 |
Room „Hanse“ | Room „Borgwald“ | Room „Focke Wulf“ | Room „Lloyd“ | |
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8:30 | Ways to low-CO2 or climate neutral iron and steelmaking III - Smart carbon usage – General approach 8:30 Biofuel for ironmaking | Coke plant operation, instrumentation and coke quality 8:30 The lifecycle of a quenching tower at the Schwelgern coke plant. | Blast furnace refractories and blast furnace gas 8:30 Blast furnace clean gas vent line eliminating blow-down and shut-down dust emissions | Blast furnace construction and design 8:30 Blast furnace hearth refractory lining management |
8:35 | ||||
8:40 | ||||
8:45 | ||||
8:50 | ||||
8:55 | 8:55 Evaluation for CO2 reduction at existing ironmaking sites | 8:55 Knowledge-driven process, KPI, maintenance and reliability monitoring through Paul Wurth CMXpert™ system. | 8:55 Off gas cleaning efficiency is affected by nozzles and separators | 8:55 Discussion on absorption of expansion of hearth lining by filling |
9:00 | ||||
9:05 | ||||
9:10 | ||||
9:15 | ||||
9:20 | Ways to low-CO2 or climate neutral iron and steelmaking IV - Smart carbon usage – Oxygen and top gas recycling blast furnace 9:20 Top gas recycling revisited to reduce blast furnace CO2 emissions | 9:20 Predictive gas pressure models as a tool to extend lifetime of coke ovens | 9:20 New approaches towards green and nanoscale binders for blast furnace refractories | 9:20 The Bosh Modernization of Hyundai Steel Company Dangjin No. 3 |
9:25 | ||||
9:30 | ||||
9:35 | ||||
9:40 | ||||
9:45 | 9:45 | 9:45 Gasification and mechanical strength of metallurgical coke | 9:45 | 9:45 |
9:50 | 9:50 | 9:50 | 9:50 | |
9:55 | 9:55 | 9:55 | 9:55 | |
10:00 | 10:00 | 10:00 | 10:00 | |
10:05 | 10:05 | 10:05 | 10:05 | |
10:10 | 10:10 | 10:10 | 10:10 | 10:10 |
10:15 | 10:15 | 10:15 | 10:15 | 10:15 |
10:20 | Ways to low-CO2 or climate neutral iron and steelmaking V - Carbon direct avoidance – Electric hot metal, submerged arc furnace and hydrogen plasma smelting 10:20 Smart combination of new Midrex direct reduction plants in existing blast-furnace-based integrated plants: solutions for lowering OPEX and CO2 emissions vs the stand-alone approach | Fundamentals in blast furnace ironmaking 10:20 Isolating the influence of mineralogy and microstructure on iron-ore sinter reduction in the shaft and reserve zone of the blast furnace: lab experiments and thermodynamic modelling | Injection of auxiliary reductants (coal, oil, gas, plastics) and oxygen I 10:20 Temperature monitoring in the raceway during the injection of PC: Thermovision camera measurements | Blast furnace tuyeres and cooling 10:20 ILTEC Technology – New pathways towards safe and effective cooling |
10:25 | ||||
10:30 | ||||
10:35 | ||||
10:40 | ||||
10:45 | 10:45 Considerations for the use of hydrogen-based DRI in electric steelmaking | 10:45 Computer aided multidisciplinary approach to monitor and control pellet fines flow in the pellet blast furnace ironmaking | 10:45 Simulation aided extraction of conversion rates of auxiliary reducing agents (ARAs) | 10:45 ionicLife cast technology - real copper in copper cast for tuyeres |
10:50 | ||||
10:55 | ||||
11:00 | ||||
11:05 | ||||
11:10 | 11:10 Advanced melting furnace technology for green steel production | 11:10 Scale production of pig iron with specified chemical composition in blast furnace operated with 100% pellets | 11:10 Blast furnace operation practice with co-injection of natural gas and PCI | 11:10 Operational feedback of blast furnace anti-wear copper staves |
11:15 | ||||
11:20 | ||||
11:25 | ||||
11:30 | ||||
11:35 | 11:35 Sustainable steel – Carbon free steelmaking by hydrogen plasma smelting reduction | 11:35 Evaluation of Hearth Condition over Whyalla No. 2 Blast Furnace Campaign | 11:35 Conceptive design and analysis on vanadia-titania magnetite blast furnace with abandoned basic oxygen furnace gas injection | 11:35 Discussion on long life technology of copper stave |
11:40 | ||||
11:45 | ||||
11:50 | ||||
11:55 | ||||
12:00 | 12:00 | 12:00 | 12:00 | 12:00 Comparative analysis of blast furnace cooler sytem performance with different preservation techniques and design conditions |
12:05 | 12:05 | 12:05 | 12:05 | |
12:10 | 12:10 | 12:10 | 12:10 | |
12:15 | 12:15 | 12:15 | 12:15 | |
12:20 | 12:20 | 12:20 | 12:20 | |
12:25 | 12:25 | 12:25 | 12:25 | 12:25 |
12:30 | 12:30 | 12:30 | 12:30 | 12:30 |
12:35 | 12:35 | 12:35 | 12:35 | 12:35 |
12:40 | 12:40 | 12:40 | 12:40 | 12:40 |
12:45 | 12:45 | 12:45 | 12:45 | 12:45 |
12:50 | 12:50 | 12:50 | 12:50 | 12:50 |
12:55 | 12:55 | 12:55 | 12:55 | 12:55 |
13:00 | 13:00 | 13:00 | 13:00 | 13:00 |
13:05 | 13:05 | 13:05 | 13:05 | 13:05 |
13:10 | 13:10 | 13:10 | 13:10 | 13:10 |
13:15 | 13:15 | 13:15 | 13:15 | 13:15 |
13:20 | Ways to low-CO2 or climate neutral iron and steelmaking VI - Carbon direct avoidance – Gas and hydrogen based direct reduction 13:20 SALCOS® – the sustainable way of green steel production | Modern process control techniques 13:20 Channelling in the blast furnace | Injection of auxiliary reductants (coal, oil, gas, plastics) and oxygen II 13:20 Effect of PC residues on the BF streaming conditions | Blast furnace charging 13:20 Simulation of burden charging in a blast furnace equipped with a bell-less top system using Discrete Element method |
13:25 | ||||
13:30 | ||||
13:35 | ||||
13:40 | ||||
13:45 | 13:45 Hydrogen based direct reduction for CO2-lean steelmaking | 13:45 Improving blast furnace thermal control by integrating continuous hot metal temperature measurement | 13:45 Improvement of blast furnace operation and carbon footprint using the state-of-the-art Oxygen Pulsing Technology | 13:45 Development and application of a 3D sector model for blast furnace burden distribution |
13:50 | ||||
13:55 | ||||
14:00 | ||||
14:05 | ||||
14:10 | 14:10 Process and equipment design of an open bath furnace for the production of hot metal | 14:10 The development of a modern BF-hearth side wall observation management | 14:10 The PCI expansion at Ternium' blast furnaces in Brazil | 14:10 |
14:15 | 14:15 | |||
14:20 | 14:20 | |||
14:25 | 14:25 | |||
14:30 | 14:30 | |||
14:35 | 14:35 | 14:35 | 14:35 | 14:35 |
14:40 | 14:40 | 14:40 | 14:40 | 14:40 |
14:45 | 14:45 | 14:45 | 14:45 | 14:45 |
14:50 | 14:50 | 14:50 | 14:50 | 14:50 |
14:55 | Sinter plant operation, gas cleaning and automation 14:55 SmartSinter – Bulk material tracking and its properties | New developments and fundamentals in direct reduction I 14:55 Rising and failure of gas based direct reduction processes | Fundamentals in cokemaking 14:55 Influence of elevated temperature and gas atmosphere on coke abrasion and interface properties in blast furnace and pilot oven cokes | Hot metal and slag quality 14:55 Application of slag holdup index in the dripping zone of the blast furnace |
15:00 | ||||
15:05 | ||||
15:10 | ||||
15:15 | ||||
15:20 | 15:20 Greening Ironmaking – State of the art environmental and energy efficiency solutions for agglomeration and direct reduction plants | 15:20 Carburization and melting characteristics of hydrogen-reduced DRI | 15:20 Comparison between industrial and test oven coke textures and their impact on coke quality | 15:20 Development of a highly efficient fluidized lime for hot metal desulfurization based on thermodynamic calculations and industrial validation |
15:25 | ||||
15:30 | ||||
15:35 | ||||
15:40 | ||||
15:45 | 15:45 | 15:45 Effect of direct reduction process parameters on DRI re-oxidation behavior | 15:45 Characteristics of bio-coke in technical scale cokemaking | 15:45 |
15:50 | Sinter process optimisation 15:50 GEOSCAN use to control basicity of sinter feed | 15:50 | ||
15:55 | 15:55 | |||
16:00 | 16:00 | |||
16:05 | 16:05 | |||
16:10 | 16:10 Deactivation of direct reduced iron using organic coating agents | 16:10 Influence of coal grain composition and maceral associations on fluidity development during the coking process | 16:10 | |
16:15 | 16:15 Investigation on microstructure and elemental distribution in phases of an industrial sinter by various methods | 16:15 | ||
16:20 | 16:20 | |||
16:25 | 16:25 | |||
16:30 | 16:30 | |||
16:35 | 16:35 | 16:35 Impact of microalgae addition on thermoplastic behaviour of Australian metallurgical coals during the coking process | 16:35 | |
16:40 | 16:40 Phase assemblages for high sinter productivity | 16:40 | 16:40 | |
16:45 | 16:45 | 16:45 | ||
16:50 | 16:50 | 16:50 | ||
16:55 | 16:55 | 16:55 | ||
17:00 | 17:00 | 17:00 Reflectance measurements coal macerals using Optical imaging system | 17:00 | |
17:05 | 17:05 | 17:05 | 17:05 | |
17:10 | 17:10 | 17:10 | 17:10 | |
17:15 | 17:15 | 17:15 | 17:15 | |
17:20 | 17:20 | 17:20 | 17:20 | |
17:25 | 17:25 | 17:25 | 17:25 | 17:25 |
17:30 | 17:30 | 17:30 | 17:30 | 17:30 |
17:35 | 17:35 | 17:35 | 17:35 | 17:35 |
17:40 | 17:40 | 17:40 | 17:40 | 17:40 |
17:45 | 17:45 | 17:45 | 17:45 | 17:45 |
17:50 | 17:50 | 17:50 | 17:50 | 17:50 |
17:55 | 17:55 | 17:55 | 17:55 | 17:55 |
18:00 | 18:00 | 18:00 | 18:00 | 18:00 |
18:05 | 18:05 | 18:05 | 18:05 | 18:05 |
18:10 | 18:10 | 18:10 | 18:10 | 18:10 |
18:15 | 18:15 | 18:15 | 18:15 | 18:15 |
18:20 | 18:20 | 18:20 | 18:20 | 18:20 |
18:25 | 18:25 | 18:25 | 18:25 | 18:25 |
18:30 | 18:30 | 18:30 | 18:30 | 18:30 |
18:35 | 18:35 | 18:35 | 18:35 | 18:35 |
18:40 | 18:40 | 18:40 | 18:40 | 18:40 |
18:45 | 18:45 | 18:45 | 18:45 | 18:45 |
18:50 | 18:50 | 18:50 | 18:50 | 18:50 |
18:55 | 18:55 | 18:55 | 18:55 | 18:55 |
Room „Hanse“ | Room „Borgwald“ | Room „Focke Wulf“ | Room „Lloyd“ | |
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8:30 | Ways to low-CO2 or climate neutral iron and steelmaking IV - Smart carbon usage – Gas and hydrogen injection, DRI/HBI charge into the blast furnace 8:30 Development of advanced H2 utilization technology for reduction of CO2 emission from blast furnace using 12 m3 experimental blast furnace. | Recycling and briquetting I 8:30 Reduction of the carbon footprint: low-carbon BF charge: Sintering substitution by cold process | Application examples and horizontal / vertical integration in steel industry 8:30 BF-process monitoring with a soft-sensor for the online measurement of dust concentration in the top gas | Blast furnace liquid management and casting practice 8:30 Tapping operation in the digital era |
8:35 | ||||
8:40 | ||||
8:45 | ||||
8:50 | ||||
8:55 | 8:55 Investigating of H2 and/or hydrogenous gas injection into the blast furnace shaft and tuyere | 8:55 Recycling of blast furnace sludge – best available technology | 8:55 Benefits of a detailed value-in-use analysis of raw materials by an integrated optimization model | 8:55 Transient DEM-CFD simulations of a blast furnace tapping process: Effect of flow and carbon dissolution on the movement of coke particles |
9:00 | ||||
9:05 | ||||
9:10 | ||||
9:15 | ||||
9:20 | 9:20 Coke oven gas injection into the blast furnace at the saar to reduce the overall carbon footprint and to improve the conversion of pulverized coal via Oxy-Coal-Lances | 9:20 Evaluation of the suitability of auger pressing briquettes for BF use | 9:20 Integrated steel plant strategic planning – an extension of coke production modelling in the m.simtop process integration platform | 9:20 Blast furnace casting guidance model |
9:25 | ||||
9:30 | ||||
9:35 | ||||
9:40 | ||||
9:45 | 9:45 | 9:45 | 9:45 Prescription of actionable items for process adaptations, maintenance tasks and schedules with DataXpert and Digital Twin | 9:45 |
9:50 | 9:50 | 9:50 | 9:50 | |
9:55 | 9:55 | 9:55 | 9:55 | |
10:00 | 10:00 | 10:00 | Blast furnace process automation and environmental control 10:00 NOx emission from the Hot Blast System: Formation, effects, and the possibilities for its reduction | |
10:05 | 10:05 | 10:05 | ||
10:10 | 10:10 | 10:10 | 10:10 | |
10:15 | 10:15 | 10:15 | 10:15 | |
10:20 | 10:20 | 10:20 | 10:20 | |
10:25 | 10:25 | 10:25 | 10:25 | 10:25 An analysis of sinter quality adjustments for blast furnace process optimization |
10:30 | Ways to low-CO2 or climate neutral iron and steelmaking V - Smart carbon usage – Gas and hydrogen injection, DRI/HBI charge into the blast furnace 10:30 On the mission to “green” steel - CO2 reduction steps at HKM | Recycling and briquetting II 10:30 Recycling of residues from Midrex direct reduction of iron ore pellets by means of agglomeration | Big data 10:30 Using AI and digital twins to improve blast furnace operations | |
10:35 | ||||
10:40 | ||||
10:45 | ||||
10:50 | 10:50 Automated systems for control lining wear, heat losses and charging model on blast furnaces: experience in Ukraine | |||
10:55 | 10:55 Addition of DRI/HBI to the blast furnace – a means to reduce greenhouse gas emissions? | 10:55 Hydrogen Reduction of Organic Bonded Mill Scale Briquettes | 10:55 Artificial intelligence and data driven modelling in ironmaking – potential and limitations | |
11:00 | ||||
11:05 | ||||
11:10 | ||||
11:15 | 11:15 Influence of Irregularity of hot metal and slag tapping on blast furnace performance at NTMK-Evraz | |||
11:20 | 11:20 | 11:20 | 11:20 | |
11:25 | 11:25 | 11:25 | 11:25 | |
11:30 | 11:30 | 11:30 | 11:30 | |
11:35 | 11:35 | 11:35 | 11:35 | |
11:40 | 11:40 | 11:40 | 11:40 | 11:40 |
11:45 | 11:45 | 11:45 | 11:45 | 11:45 |
11:50 | Iron ores for DRI production 11:50 Direct reduction and smelter combination for processing of low-grade iron ores | Fundamentals in agglomeration I 11:50 Development and evaluation of a furnace for lab-scale pellet induration studies | Material tracking, material genealogy and predictive maintenance 11:50 Data-driven maintenance for the Paul Wurth® Bell Less Top® charging system | Hot blast stoves I 11:50 Techno-commercial reasons to invest in hot blast stove |
11:55 | ||||
12:00 | ||||
12:05 | ||||
12:10 | ||||
12:15 | 12:15 | 12:15 Study on optimization of agglomeration process for sea sand vanadia-titania magnetite smelting in the blast furnace | 12:15 Drone inspection of difficult to reach facilities with the possibility of generating a 3D Model for a better damage analysis | 12:15 Construction of the new SSAB Oxelösund hot blast stove 47 |
12:20 | 12:20 | |||
12:25 | 12:25 | |||
12:30 | 12:30 | |||
12:35 | 12:35 | |||
12:40 | 12:40 | 12:40 | 12:40 | 12:40 |
12:45 | 12:45 | 12:45 | 12:45 | 12:45 |
12:50 | 12:50 | 12:50 | 12:50 | 12:50 |
12:55 | 12:55 | 12:55 | 12:55 | 12:55 |
13:00 | 13:00 | 13:00 | 13:00 | 13:00 |
13:05 | 13:05 | 13:05 | 13:05 | 13:05 |
13:10 | 13:10 | 13:10 | 13:10 | 13:10 |
13:15 | 13:15 | 13:15 | 13:15 | 13:15 |
13:20 | 13:20 | 13:20 | 13:20 | 13:20 |
13:25 | 13:25 | 13:25 | 13:25 | 13:25 |
13:30 | 13:30 | 13:30 | 13:30 | 13:30 |
13:35 | 13:35 | 13:35 | 13:35 | 13:35 |
13:40 | New developments and fundamentals in direct reduction II 13:40 History, developments and processes of direct reduction of iron ores | Fundamentals in agglomeration II 13:40 Influence of Oxygen Partial Pressure on High Temperature Oxidation Behavior of Iron Bearing Materials in Iron Ore Sintering Bed | Pellet plant operation and automation 13:40 Experience with SCARABAEUS® 7500 in Pelletizing Iron Ores – Industry 4.0 in harsh industrial installa-tions. | Hot blast stoves II 13:40 Research on high efficiency and high blast temperature technology for modern blast furnace |
13:45 | ||||
13:50 | ||||
13:55 | ||||
14:00 | ||||
14:05 | 14:05 Modernization of dri shaft furnaces to enhance process performance and improve product quality | 14:05 | 14:05 Simulation based Pellet Plant Operation | 14:05 The evolution of hot blast stoves: history, development, and the emergence of top fired stoves as best available technology |
14:10 | 14:10 | |||
14:15 | 14:15 | |||
14:20 | 14:20 | |||
14:25 | 14:25 | |||
14:30 | 14:30 Reduction of sticking tendency of iron ore pellets by using steel by-product as coating | 14:30 | 14:30 | 14:30 Innovative top combustion stove of Kalugin design and different options of stove modernization |
14:35 | 14:35 | 14:35 | ||
14:40 | 14:40 | 14:40 | ||
14:45 | 14:45 | 14:45 | ||
14:50 | 14:50 | 14:50 | ||
14:55 | 14:55 | 14:55 | 14:55 | 14:55 |
15:00 | 15:00 | 15:00 | 15:00 | 15:00 |
15:05 | 15:05 | 15:05 | 15:05 | 15:05 |
15:10 | 15:10 | 15:10 | 15:10 | 15:10 |
15:15 | 15:15 | 15:15 | 15:15 | 15:15 |
15:20 | 15:20 | 15:20 | 15:20 | 15:20 |
15:25 | 15:25 | 15:25 | 15:25 | 15:25 |
15:30 | 15:30 | 15:30 | 15:30 | 15:30 |
15:35 | 15:35 | 15:35 | 15:35 | 15:35 |
15:40 | 15:40 | 15:40 | 15:40 | 15:40 |
15:45 | 15:45 | 15:45 | 15:45 | 15:45 |
15:50 | 15:50 | 15:50 | 15:50 | 15:50 |
15:55 | 15:55 | 15:55 | 15:55 | 15:55 |
16:00 | 16:00 | 16:00 | 16:00 | 16:00 |
16:05 | 16:05 | 16:05 | 16:05 | 16:05 |
16:10 | 16:10 | 16:10 | 16:10 | 16:10 |