Using electrochemical technology, a new EU-funded project seeks to reduce energy consumption and cut CO₂e emissions in the European chemical industry.

The chemical industry relies on green investments to keep up with EU climate goals and to strengthen competitiveness. Today’s thermochemical production processes often use fossil raw materials and additionally require large amounts of energy from fossil energy carriers. Electrification of processes and integration of renewable energy generated in Europe, can reduce energy consumption and CO_2e emissions in the industry significantly. Novel, modern processes that replace conventional technologies also have the potential to reduce waste streams.

An EU-funded project recently started with the aim of addressing such electrification in the chemical industry. The project is coordinated by SINTEF, which will lead the process design and scale-up of the technologies. The consortium includes experts in the electrochemical field, such as the Max Planck Institute for Chemical Energy Conversions and ESy-Labs, and leading manufacturers of specialty chemicals and resins, such as Evonik and Megara Resins.

“We are proud to be the coordinator of a project that will be an important part of the twin transition. Together with highly competent and motivated research and industry partners, we will work to ensure a rapid industrial realization of the results of the project”, says Senior Business Developer at SINTEF, Bernd Wittgens.

The project kick-off meeting took place on February 8/9, 2024, at the production site of Evonik’s manufacturing facility in Marl (Germany).

New ways to produce carboxylic acids

In the focus of the project are new, sustainable ways of producing various carboxylic acids. Such compounds are important raw materials for products such as paints, polymers, catalysts, fine chemicals, agrochemicals, fragrances and dyes.

Novel technologies have the potential to produce known or even new, exciting building blocks for the chemical industry much more sustainably by reducing GHG emissions, energy consumption, and chemical waste. Preliminary calculations revealed that the ELOXYCHEM technology has the potential to reduce both energy consumption and carbon footprint by up to 60% for the production of carboxylic acids.

A credible path for Europe’s twin transition

The new electrochemical process will be demonstrated in a pilot plant that will operate in an industrial setting, with a production rate of multiple tonnes per year and will provide sufficient know-how to plan a further scale-up to industrial scale plant. The materials produced in the pilot plant will be tested and validated in existing consumer products. Furthermore, full digitalization of the process will be achieved, which will enable optimized monitoring and control of the pilot plant. AI-based technology and “digital twinning” of the plant will play a key role here. 


About the ELOXYCHEM project

ELOXYCHEM is an abbreviation for “Electrochemical Oxidation of cYclic and biogenic substrates for high efficiency production of organic CHEMicals” and is funded through the Horizon Europe call “Energy efficiency breakthroughs in the process industries (HORIZON-CL4-2023-TWIN-TRANSITION-01-31)”. The project has a budget of EUR 10 million and will run for 4.5 years.

The project is coordinated by SINTEF and the consortium consists of several European partners: Max Planck Institute for Chemical Energy Conversions (Germany), Evonik Operations GmbH (Germany), Idener (Spain), ETA (Italy), Z Prime (Germany), Imperial College London (UK), Megara Resin Industry (Greece), ESy-Labs GmbH (Germany), Iconiq Innovation Ltd (UK).


Contacts

• Bernd Wittgens (Project Coordinator, Senior Business Developer – SINTEF):
  bernd.wittgens@sintef.no
• Claudia Batini (Communication and Dissemination Manager – ETA):
  claudia.batini@etaflorence.it

Website: https://www.eloxychem-horizon.eu/
LinkedIn: https://www.linkedin.com/company/eloxychem-project/

This project has received funding from the European Union’s Horizon Europe Research and Innovation Programme under Grant Agreement No. 101138376. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union. Neither the European Union nor the granting authority can be held responsible for them.