Boosting Reduction of Energy Intensity in cleaN STeelwork platfORM
Lead Research Organisation:
University of Manchester
Department Name: Chem Eng and Analytical Science
Abstract
Iron and steel is the largest UK manufacturing industry in terms of energy demand and greenhouse gas (GHG) emissions. Currently, more than 6 Mt of steel per year are produced in six blast furnaces at two steelworks with specific energy consumptions of 19 GJ/t of steel and overall direct CO2 emissions of 13 Mt, contributing 25% to GHG emissions from UK manufacturing. Combustion of blast furnace gas (BFG) in the power station causes ~ 50% of CO2 emissions.
In BREIN-STORM we propose to convert the BFG from steel mills into valuable products, such as hydrogen and pure carbon dioxide. This will be achieved by combining calcium and chemical looping gas-solid reactions (CaL-CLC). This four-year project comprises four interlinked work packages (WPs):
1. WP1 will develop and scale up different multi-functional materials based on calcium oxide as sorbent and copper-oxide oxygen carriers. We will focus on increasing the stability over cycling operation and the sorption capacity of the materials. The produced material will be tested and characterised to examine longevity. The kinetics models will be derived to enable the scale up.
2. WP2 will focus on the development and testing of the reactor. We will carry out the experimental demonstration and long-term testing under different reactive conditions in packed and fluidised bed configurations. The experimental results will be used to validate the reactor model. The knowledge gained both from the experimental and numerical activities will be used as guidance for future pilot-scale demonstration of the technology.
3. In WP3, the CaL-CLC process will be integrated into the steelworks through a conceptual design. The techno-economic performance of the process will be compared with standard state-of-the-art technologies in the steel sector. The integration of renewables sources will be studied with the aim of designing a first 'green' steelworks plant.
4. In WP4, the developed process will be evaluated on environmental impacts as well as social and policy implications.
In BREIN-STORM we propose to convert the BFG from steel mills into valuable products, such as hydrogen and pure carbon dioxide. This will be achieved by combining calcium and chemical looping gas-solid reactions (CaL-CLC). This four-year project comprises four interlinked work packages (WPs):
1. WP1 will develop and scale up different multi-functional materials based on calcium oxide as sorbent and copper-oxide oxygen carriers. We will focus on increasing the stability over cycling operation and the sorption capacity of the materials. The produced material will be tested and characterised to examine longevity. The kinetics models will be derived to enable the scale up.
2. WP2 will focus on the development and testing of the reactor. We will carry out the experimental demonstration and long-term testing under different reactive conditions in packed and fluidised bed configurations. The experimental results will be used to validate the reactor model. The knowledge gained both from the experimental and numerical activities will be used as guidance for future pilot-scale demonstration of the technology.
3. In WP3, the CaL-CLC process will be integrated into the steelworks through a conceptual design. The techno-economic performance of the process will be compared with standard state-of-the-art technologies in the steel sector. The integration of renewables sources will be studied with the aim of designing a first 'green' steelworks plant.
4. In WP4, the developed process will be evaluated on environmental impacts as well as social and policy implications.
Planned Impact
The BREIN-STORM project will develop a new, promising technology to reduce energy consumption and GHG emissions in the steel sector. The results are expected to generate significant impacts as follows:
- Industry: the BREIN-STORM project will help the sector to reduce its energy use by 20% and its GHG emissions by up to 90%.
- Policy: A white paper will be produced to guide policy makers on policy instruments needed to stimulate the transition of the steel industry towards a low-energy future within a circular economy context.
- Knowledge: The project will develop cutting-edge materials, technology and sustainability analyses that will have an impact of researchers internationally, particularly those working in the fields of manufacturing, energy, process design and sustainability assessment.
- People: By working in a multidisciplinary team, the early-career researchers will gain knowledge outside their own discipline and learn how to communicate to those outside their field. By working closely with industry, they will be able to appreciate the balance between fundamental research and the needs of the commercial sector.
- Economy and society: By reducing GHG emissions and improving other environmental and social sustainability aspects associated with energy provision, the project will contribute to a better quality of life in the UK. Reducing energy use will also reduce costs of steel production. This will in turn help to improve the productivity in UK manufacturing, benefiting the economy as a whole.
- Industry: the BREIN-STORM project will help the sector to reduce its energy use by 20% and its GHG emissions by up to 90%.
- Policy: A white paper will be produced to guide policy makers on policy instruments needed to stimulate the transition of the steel industry towards a low-energy future within a circular economy context.
- Knowledge: The project will develop cutting-edge materials, technology and sustainability analyses that will have an impact of researchers internationally, particularly those working in the fields of manufacturing, energy, process design and sustainability assessment.
- People: By working in a multidisciplinary team, the early-career researchers will gain knowledge outside their own discipline and learn how to communicate to those outside their field. By working closely with industry, they will be able to appreciate the balance between fundamental research and the needs of the commercial sector.
- Economy and society: By reducing GHG emissions and improving other environmental and social sustainability aspects associated with energy provision, the project will contribute to a better quality of life in the UK. Reducing energy use will also reduce costs of steel production. This will in turn help to improve the productivity in UK manufacturing, benefiting the economy as a whole.
Publications
Alexandros Argyris P
(2022)
Chemical looping reforming for syngas generation at real process conditions in packed bed reactors: An experimental demonstration
in Chemical Engineering Journal
De Leeuwe C
(2023)
Thermochemical syngas generation via solid looping process: An experimental demonstration using Fe-based material
in Chemical Engineering Journal
Khallaghi N
(2022)
Techno-economic assessment of blast furnace gas pre-combustion decarbonisation integrated with the power generation
in Energy Conversion and Management
Fernández J
(2020)
Advanced Packed-Bed Ca-Cu Looping Process for the CO2 Capture From Steel Mill Off-Gases
in Frontiers in Energy Research
Abbas S
(2022)
Lab-scale experimental demonstration of Ca Cu chemical looping for hydrogen production and in-situ CO2 capture from a steel-mill
in Fuel Processing Technology
Abbas S
(2021)
A Ca-Cu Chemical Loop Process for CO2 Capture in Steel Mills: System Performance Analysis
in SSRN Electronic Journal
Argyris P
(2022)
Mono-dimensional and two-dimensional models for chemical looping reforming with packed bed reactors and validation under real process conditions
in Sustainable Energy & Fuels
Jeswani H
(2022)
Environmental sustainability of negative emissions technologies: A review
in Sustainable Production and Consumption
| Description | The results carried out in the techno-economic assessment to decarbonise steel industry have shown that existing technology will impact the economics resulting in a high price of carbon dioxide removal (> £ 50 per ton) which is currently higher than the existing carbon tax the use of new processes based on gas-solid reaction could reduce the economic impact by 20%, reducing the energy cost and investment costs. |
| Exploitation Route | Testing of new technologies combined with numerical modelling will provide the required confidence to expected results. Follow up projects targeting technology scale-up and a bigger involvement of industry will generate the required understanding and validate the expected outcomes. |
| Sectors | Chemicals,Energy |
| Description | The results of this project has generated interest among industrial company within UK and Europe. As an example, TotalEnergies, Johnson Matthey and Arcelor Mittal have engaged with us to develop further study for the decarbonisation of chemical and energy processes and steel industry. the research grants which are following this project includes the scale up of the technology to decarbonise also steel industry. |
| First Year Of Impact | 2023 |
| Sector | Chemicals,Energy |
| Impact Types | Economic |
| Description | (C4U) - Advanced Carbon Capture for steel industries integrated in CCUS Clusters |
| Amount | € 13,845,497 (EUR) |
| Funding ID | 884418 |
| Organisation | European Commission |
| Sector | Public |
| Country | European Union (EU) |
| Start | 04/2020 |
| End | 03/2024 |
| Description | Low Carbon Hydrogen Supply 2 Stream 1 Phase 1 Competition: RECYCLE |
| Amount | £288,668 (GBP) |
| Funding ID | HYS2137 |
| Organisation | Department for Business, Energy & Industrial Strategy |
| Sector | Public |
| Country | United Kingdom |
| Start | 01/2022 |
| End | 10/2022 |
| Description | RECYCLE BEIS - Phase II |
| Amount | £5,110,205 (GBP) |
| Organisation | Department for Business, Energy & Industrial Strategy |
| Sector | Public |
| Country | United Kingdom |
| Start | 03/2023 |
| End | 01/2025 |
| Title | High pressure laboratories for gas-solid reactions |
| Description | We have an advanced chemical engineering laboratory that has been upgraded in the past year in which we can operate fluidised and packed beds for gas-solid and catalytic reactions that could operate up to 10 bar and 900 °C using different reactive gases such as methane, air, carbon monoxide and carbon dioxide, water/steam, hydrogen, helium, nitrogen. |
| Type Of Material | Improvements to research infrastructure |
| Year Produced | 2022 |
| Provided To Others? | Yes |
| Impact | Scientific and technical impacts. The laboratory has attracted interest of companies which can now test their materials at relevant conditions. |
| Title | 1D and 2D model for gas-solid reactions |
| Description | in the framework of this project, we have develop and 1D and 2D model to simulate the performance of gas-solid reaction that operates at very high temperatures in presence of a high heat of reactions. The model has been successfully validated with experimental results. the model is developed in C++ |
| Type Of Material | Computer model/algorithm |
| Year Produced | 2021 |
| Provided To Others? | No |
| Impact | Scientific and Economic Impact the model proposed is unique and industries (Johnson Matthey and TotalEnergies) are interested to use it for the design and scale up of chemical and energy processes |
| Description | UKCCSRC - collaboration with UCL |
| Organisation | University College London |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | This is a collaboration with UCL, Prof. Haroun Mahgerefteh to perform a feasibility study on how to covert waste blast furnace gas into valuable chemical product. |
| Collaborator Contribution | the UCL is carrying out the thermodynamic performance analysis of one of the technology to be developed in BREISTORM integrated with a system for the synthesis of liquid fuels |
| Impact | the collaboration is currently ongoing |
| Start Year | 2019 |