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Fraunhofer IEE established the research project of green hydrogen in Chile

Together with its partners, Fraunhofer Institute for Energy Economics and Energy System Technology IEE is paving the way for the establishment of large-scale production of green hydrogen and its downstream products in Chile, the institute announced.

The project’s research focuses on the production potential of hydrogen and liquid fuels from solar energy. In addition to technical issues, researchers are investigating the economic, logistical, and socio-economic aspects of scaling up, through which they will also support the installation of a pilot plant.

Germany expects to cover a large part of its future demand for green hydrogen and derivatives through imports. With its excellent solar potential and stable economic conditions, Chile can make an important contribution to the production of green hydrogen and derivatives – and thus also play a central role in supplying Germany with climate-friendly energy sources.

“With our accompanying research, we are making a significant contribution towards unlocking Chile’s potential for the production of CO2-neutral energy sources. We are conducting research along the entire value chain for the production of PtX products and are not only optimizing the production process chain, but also evaluating possible local and international sales markets and business models,” explains project manager Dr. Ramona Schröer from Fraunhofer IEE.

The coordination of this research project “Power-to-MEDME-FuE” will be carried out by Fraunhofer IEE. Other Fraunhofer Institutes such as ISE, IMM, ISC/HTL, IAP, IKTS and Fraunhofer Chile are also collaborating on the project, along with the Chair of Thermodynamics of Mobile Energy Conversion Systems at RWTH Aachen University and the RILLL Research Institute on Lifelong Learning. The project will receive a total of 11 million euros in funding from the Federal Ministry of Education and Research.

Optimizing the process chain: lower costs, greater efficiency

As part of the associated “Power-to-MEDME” investment project, Linde GmbH is planning to build a pilot plant in northern Chile that will produce green methanol or dimethyl ether (DME) in the megawatt range, depending on the market situation. Both energy sources can be used as a fuel substitute for the transportation sector and locally in the mining industry. The required electricity is supplied by a local solar thermal power plant (CSP).

In order to make production cost-effective and efficient, scientists are pursuing innovative technological approaches in addition to established processes. The researchers are also examining the entire process chain using various simulations. Among other things, a digital twin is being created for methanol and DME synthesis, which is simultaneously being used to determine the optimum technical processes.

The researchers also use the results of the simulations to evaluate the use of existing technologies and to continuously optimize the process chain. For example, for the comparison of the various industrially available electrolysis technologies. Seawater desalination is also considered, as the waste heat generated can be used there.  Comprehensive techno-economic analyses, including the calculation of production costs are also conducted.

Material and substance research

Another part of the “Power-to-MEDME-FuE” project is the research on materials required for the individual steps of the process chain. For example, the development of catalysts for electrolysis.

The carbon dioxide required for methanol and DME synthesis in the pilot plant is supplied by a Chilean cement factory. A separation system is being installed to extract the CO2 from the factory’s rotary kiln. For this task, the researchers are developing a sensor and control concept that will enable efficient process monitoring.

In addition, scientists are collecting data for the design of transport logistics, with the aim of using DME and other Power-to-X fuels in Chile for export purposes as well.

Scaling requires the qualification of specialists

Another topic area is the use of the energy sources in practice. The DME produced will initially be used as a fuel in existing fleets for heavy-duty and off-road transportation. Specifically, experts are looking at the evaluation of retrofit concepts for converting vehicles to the new fuels as well as proof of their conformity with emission standards.

The assessment of the territorial, social and economic aspects of the industrial production of DME and other hydrogen derivatives in Chile is also part of “Power-to-MEDME-FuE”, as is the life cycle assessment of the production and use of DME and methanol along with the analysis of energy and raw material requirements.

Researchers are also identifying business models that enable the use of energy sources in the region. In a second step, they then carry out a technical and economic assessment of the export, aiming to scale both production capacities and the necessary infrastructure. This is coupled with an analysis of market demand for various development scenarios and sectors.

Last but not least, the research project is dedicated to establishing the necessary expertise in Chile, as there is currently still a lack of local specialists for the construction and operation of production facilities. Targeted training throughout the entire process chain is intended to ensure that sufficient experts are available for the scaling-up process.

“Ideal conditions for upscaling and export”

Fraunhofer Chile, together with the Fraunhofer Institute for Solar Energy Systems ISE and Fraunhofer IEE, was responsible for the Power-to-MEDME project idea and concept development. Project manager Lars Metkemeyer from Fraunhofer Chile sees considerable added value for the country’s development by establishing a complete value chain for new sustainable processes and technologies in Chile. “The planned location is one of the most attractive in the world because it combines exceptional solar radiation conditions with a very well-developed infrastructure, a supplier ecosystem, connections to industrial ports and one of the world’s largest mining districts for the local use of green hydrogen and its derivatives,” says Metkemeyer.

In addition, there is institutional stability along with Chile’s ambitious strategic goal to position itself as one of the most important export nations for green hydrogen. “These conditions create ideal circumstances for the subsequent scale-up and establishment of an export route to Germany and Europe,” says the Fraunhofer researcher.

Photo of Fraunhofer IEE: Kick-off meeting in Kassel at the start of the Power-to-MEDME project.

Press release https://shorturl.at/tyS36

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