Pathways for reducing CO 2 emissions from Raahe steel plant

Pathways for reducing CO 2 emissions from Raahe steel plant Seminar on Carbon Capture and Storage (CCS) 11th of November at Hanasaari, Espoo, Finland Erkki Pisilä, Director, development of iron making & Operations Control Rautaruukki Oyj, Raahe works 6 / 2010 www.ruukki.com

Ruukki today Nostoja kuljetusvälineteollisuuden laitevalmistajat Nostoja kuljetusvälineteollisuuden laitevalmistajat Nostoja kuljetusvälineteollisuuden laitevalmistajat Metal solutions for construction and the engineering industry Standard and special steel products Strong presence in Nordic countries Growth focus in CEE, Russia and Ukraine Net sales in 2009 2.0 billion Personnel 11,800 in 27 countries Construction Engineering Steel production and processing Sales and services 2 6 / 2010 www.ruukki.com

Ruukki s commitment and corporate responsibility is recognised Ruukki is included in the Dow Jones Sustainability indexes (DJSI World and DJSI Europe) representing the top companies committed to sustainable development. Ruukki is among the best global steel companies. The Prime status awarded by Oekom Research indicates that Ruukki is among the most responsible companies in its branch of business and best steel company in 2010 assessment. Ruukki meets social and ecological responsibility criteria. 6 / 2010 www.ruukki.com

Pathways for CO 2 reduction 6 / 2010 www.ruukki.com

Role of carbon in steel making is vital Blast furnaces and power plant Fe 2 O 3 + C => (Fe+C) + CO + O 2 => CO 2 Steel plant and rolling mill (Fe+C) + O 2 => (Fe+C) + CO + O 2 => CO 2 Picture: Metallinjalostajat ry 6 / 2010 www.ruukki.com

CO 2 reduction pathways 1-5 years ~10% Current technologies Future technologies 5-15 years ~25% 20-25 years Saving energy ~50% Reducing CO 2 emissions 20-40 years ~80% 2010 2015 2020 2025 2030 2035 2040 6 / 2010 www.ruukki.com

CO 2 reduction pathways 1-5 years ~10% 5-15 years ~25% Current technologies Future technologies 20-25 years ~50% Closing of sintering plant 100% pellet based steel production Efficient waste heat recovery 20-40 years ~80% 2010 2015 2020 2025 2030 2035 2040

10% in five years by process change and increased efficiency 220 000 t Process heat CO 2 emissions avoided with energy recovery 400 000 t Process gases CO 2 emissions avoided Emission reduction with more efficient process heat recovery. Around ten potential targets exists. CO 2 emissions avoided with recycling Steel 450 000 t 160 000 t Mineral products 3.5 million tonnes of CO 2 emissions Closing of sintering plant will decrease Ruukki s carbon footprint by more than 330,000 tonnes a year This is about 8% of annual emissions on a typical production year

CO 2 reduction pathways 1-5 years ~10% 5-15 years ~25% Current technologies Future technologies 20-25 years ~50% Systematically further improved energy efficiency in production processes and power plant Study to recover waste gas from converters. Potential in electricity production efficiency 10% 20-40 years ~80% 2010 2015 2020 2025 2030 2035 2040

Systematically improved energy efficiency helps combat climate change Rautaruukki is committed to the Finnish Energy Efficiency Agreement for 2008 16 The aim is to achieve energy savings of 9 per cent, compared to 2005 levels, by 2016 Energy efficiency is managed within ISO 14001 certified environmental management systems with the principle of continuous improvement It is taken account also in Sourcing Decisions related to investments and production development Product and process planning Real estates and their repair plans In logistics 18/11/2010 www.ruukki.com Erkki Pisilä

CO 2 reduction pathways 1-5 years ~10% Current technologies Future technologies 5-15 years ~25% 20-25 years ~50% ULCOS Top gas recycling blast furnaces ULCOS = Ultra Low CO 2 Steelmaking 20-40 years ~90 ~90 ~90 2010 2015 2020 2025 2030 2035 2040

Largest endeavour in steel industry looking for solutions for global warming ULCOS Top gas recycling BF relies on separation of the off gases so that the useful components can be recycled back into the furnace and used as a reducing agent Coke Top gas Fuel gas (for re-heating) Benefits CO 2 Lower carbon usage, lower CO 2 emissions Coke rate reduction Oxygen The concept has been tested on a large scale laboratory blast furnace with a positive outcome PCl Re-injection Picture: ULCOS

CO 2 reduction pathways 1-5 years ~10% Current technologies Future technologies 5-15 years ~25% 20-25 years ~50% Integration of CCS technology into ULCOS Top Gas Recycling blast furnaces 20-40 years ~80% 2010 2015 2020 2025 2030 2035 2040

ULCOS TGR blast furnace facilitates Carbon Capture and Storage In top gas recycling BF, the concept of injecting O 2 into the furnace instead of preheated air facilitates the use of CCS Concept to apply CCS to the TGR-BF is in-process CO2 capture, with oxygen operation Picture: ULCOS

CO 2 reduction pathways 1-5 years ~10% Current technologies Future technologies 5-15 years ~25% 20-25 years ~50% Relining of current blast furnaces and integration of CCS technologies into them 20-40 years ~80% 2010 2015 2020 2025 2030 2035 2040

CO 2 reduction pathways 1-5 years ~10% Current technologies Future technologies 5-15 years ~25% 20-25 years - 30% New steel making technologies jointly with CCS 20-40 years ~80% 2010 2015 2020 2025 2030 2035 2040

Can future technologies and their development set CO 2 at zero? HIsmelt is a technology where fine iron ores and non-coking coals are injected into a molten iron bath Can be considered both as a potential replacement for the blast furnace and as a new source of low cost iron units for the electric arc steelmaking industry ISARNA technology includes very compact cyclone, to feed molten and slightly pre-reduced iron ore into the bath smelter Picture: ESTEP

Benefits for customers and end-users Our products give environmental benefits to our customers 100% recyclable, wear-resistant, high strength steels Fuel savings arising from slimmer structures in mobile machines and material production with minimum emissions Renewable energy production with Ruukki Tower solution Energy-efficient construction Energy efficient, recyclable, highly prefabricated products save energy, waste and time on site Integration of geothermal and solar energy provide alternatives to use renewable energy

Conclusions Ruukki will study very carefully all existing technologies and possibilities to reduce energy consumption. The investments will be done not only ecological but also economical reasons Ruukki will participate to the national and some international research programs which are targeting to use the future technologies in long term Our products already provide environmental benefits to our customers through 100% recyclable, wear-resistant, high strength steels, lighter vehicles and energy efficient construction products