CCUS: more future with less CO₂

In Brevik, Heidelberg Materials is building the world’s first industrial-scale carbon capture and storage (CCS) facility at a cement plant. Thanks to the clear support of the government, social acceptance of CCS technology in Norway, and successful cooperation with the authorities, the project is now at an advanced stage. We anticipate mechanical completion by the end of 2024. The absorber, in which CO₂ will be separated from the flue gas flow, was installed in the third quarter of 2023. The tanks for temporary storage of the CO₂ prior to transport have also already been constructed.

A pilot carbon capture installation is currently under construction at Heidelberg Materials’ plant in Devnya. It will be a key proof of concept for the company’s first full-chain carbon capture, utilisation, and storage (CCUS) project in Eastern Europe. The unit has been designed to prove not only the efficiency of the new OxyCal capture technology, but also its scalability to ANRAV CCUS and other projects. Construction of the pilot unit is expected to take just a few months, with the subsequent demonstration phase scheduled to last 12 to 24 months.

Together with three other European cement manufacturers, Heidelberg Materials is participating in a research project to construct an oxyfuel kiln line. Alongside Buzzi/Dyckerhoff, Schwenk, and Vicat, Heidelberg Materials aims to create the necessary conditions for the large-scale use of low-energy, cost-effective carbon capture technologies at cement plants. A semiindustrial- scale demonstration plant is currently under construction on the site of the Mergelstetten cement plant. In addition to testing the pure oxyfuel technology, some of the CO₂ obtained will be used to manufacture climate-neutral synthetic fuels, such as kerosene for aviation.

As part of a joint venture, Heidelberg Materials and Linde aim to put the world’s first industrial-scale CCU facility in the cement industry into operation at the Lengfurt cement plant in 2025. The facility will enable the captured CO₂ from cement production to be reused as a valuable raw material in manufacturing applications. Due to its purity, the processed gas will be suitable for use in both the food and chemical industries.

The EU-funded LEILAC (Low Emissions Intensity Lime And Cement) project, in which Heidelberg Materials is one of the strategic partners, aims to demonstrate the technical and economic feasibility of process technology designed to capture CO₂ in its purest form when it is released as the raw material is heated. Following the successful completion of process trials in Lixhe, Belgium, the LEILAC technology is now being transferred to industrial scale. In collaboration with Australian technology company Calix and a European consortium, Heidelberg Materials will now build a facility four times as large at the Ennigerloh plant in Germany.

At our cement plant in Edmonton, we are developing North America’s first industrial-scale carbon capture, utilisation, and storage solution in the cement industry. In the future, we intend to capture CO₂ from the cement kiln and the connected combined heat and power (CHP) plant. Heidelberg Materials and Enbridge Inc. will collaborate on a pipeline-based transport and storage solution for the captured CO₂. A detailed FEED study is being carried out before the final investment decision is made.

At our Safi cement plant in Morocco, we are running a large-scale research and demonstration project using CO₂ captured from the cement kiln to cultivate microalgae for the production of fish food and other animal feed. We currently produce approximately 25 tonnes of dried microalgae annually on 0.5 hectares of land in Safi. The algae farm is operated by a local team. We launched the first product on the market in 2023. Based on market interest, the plan is to gradually expand capacity by 2026.

We are planning a carbon capture facility at our Padeswood cement plant. In cooperation with the government-sponsored HyNet North West consortium, it will be connected to the proposed CO₂ transport and storage system. This project will be implemented using hydrogen as an energy source. A feasibility study has been conducted to establish a clear basis for planning and provide a cost estimate for the next phase. In March 2023, the project qualified for funding from the UK Department for Energy Security and Net Zero, and detailed planning has begun.

ANRAV aims to be the first full-chain CCUS project in Eastern Europe. It will connect carbon capture facilities at the Bulgarian cement plant of Heidelberg Materials’ subsidiary Devnya Cement near Varna with offshore storage sites under the Black Sea via a pipeline system. The project is carried out jointly with the oil and gas company Petroceltic. The EU Innovation Fund will support Heidelberg Materials and Petroceltic with financing of around €190 million, supplementing the substantial contributions made by both partners.

Heidelberg Materials plans to equip its cement plant in Antoing, Belgium, with an innovative hybrid carbon capture unit. The second-generation OxyCal concept combines the oxyfuel and amine capture technology in one unit that does not require an additional preheater tower. This reduces the amount of structural steel and concrete required, considerably improving the resource efficiency of the system. Once operational, the technology will reduce CO₂ emissions from Antoing by more than 97%.

Anthemis project

Heidelberg Materials/Steffen Höft

Heidelberg Materials’ GeZero project in Geseke will be supported by the EU Innovation Fund. GeZero will model a solution for inland industrial sites that are not in close proximity to the coast or a waterway. The project also includes a transport solution to bridge the gap until the necessary pipeline infrastructure is available. The facility is scheduled to go into operation in 2029. Once captured, the CO₂ will be transported to a distribution hub in Wilhelmshaven and from there to offshore storage sites in the North Sea.

By 2030, we plan to develop a completely decarbonised cement plant at our site in Slite on the island of Gotland. The facility will be designed to capture up to 1.8 million tonnes of CO₂ per year, equivalent to the plant’s total emissions. In addition, the use of biobased fuels will be increased. After a feasibility study addressed questions concerning technology choices, environmental impact, legal aspects, financing, logistics, and energy supply, the project has now entered a more detailed engineering phase. The aim is to transport the captured CO₂ to a storage site below the North Sea.

In the project in Mitchell, 95% of the CO₂ emissions from the recently modernised production facility will be captured and stored in a nearby onshore reservoir in the Illinois Basin. A feasibility study is being carried out at the site to advance the carbon capture project. In addition to evaluating the cost and performance of the overall project, the study will examine social, economic, and environmental impacts. Funding for the study has been granted by the US Department of Energy.

The AirvaultGOCO₂ project is part of the large-scale GOCO₂ initiative to capture and transport CO₂ from industrial sources and decarbonise the West of France. The CO₂ captured in Airvault will be transported by pipeline to the port of Saint-Nazaire, liquefied and then transported by ship to storage under the North Sea. The biogenic part of the captured CO₂ will be used by a third party in Saint-Nazaire for the production of e-fuels, which are essential for sustainable transport by air and sea. The aim is to capture the first tonnes of CO₂ in 2030.