BASF, bse Engineering ink landmark deal to transform CO2 and excess current into methanol
The new process developed by bse Engineering enables the sustainable use of current and CO2 with small-scale, delocalised production units built where the two components are generated.
BASF and bse Engineering signed an exclusive joint development agreement for BASF to provide custom made catalysts for a new chemical energy storage process.
This process will enable economically viable transformation of excess current and off-gas carbon dioxide (CO2) into the chemical energy storage methanol in small-scale, delocalised production units.
When generating current from renewable energy sources such as in wind or solar power plants, excess current is generated at times when consumers do not need it. This excess current can often not be reasonably used at the moment. The effective usage of this excess current is a decisive factor in making power production from renewable energy sources economically viable.
CO2 is generated in some industrial production plants such as in steel production, incineration plants or coal power plants. The reduction of this greenhouse gas is one of the most important targets set in the context of the 2015 Paris Climate Protection Agreement.
The new process developed by bse Engineering enables the sustainable use of current and CO2 with small-scale, delocalised production units built where the two components are generated, i.e., near power plants using renewable sources of energy as well as large-scale industrial plants producing CO2.
The excess current will be used to produce hydrogen through discontinuous electrolysis. In a second step, methanol is produced from CO2 and hydrogen, thus leading to a valorising of excess current and CO2 off-stream gas.
In the second process step, BASF’s catalysts will be used for the methanol synthesis step. Those catalysts have been further tuned and adapted for this specific process to enable the most efficient production of methanol. Methanol is one of the most important basic chemicals used in numerous industrial applications. For example, it is blended into diesel or gasoline in some countries.
“We are pleased to participate in this exciting endeavour and to contribute significantly to a concrete solution for the use of excess current and CO2 as a raw material,” said Adrian Steinmetz, vice president, chemical catalysts, BASF.
“We will leverage our know-how and expertise in catalysis in the service of advancing a sustainable answer for the transition to new energy sources and the material use of CO2,” added Steinmetz.
“The cooperation between BASF and bse Engineering is another example of our successful approach to collaborating with engineering companies and plant manufacturers. In doing so, we contribute our unique know-how as the world leader in the production of catalysts to facilitate new processes and innovative technologies of tomorrow,” said Detlef Ruff, senior vice president, process catalysts, BASF.
“After four years of developing the global process concept, we are now ready to enter the licensing phase of this process, with construction of the first plants starting soon,” said Christian Schweitzer, managing director, bse Engineering.
“The implementation of these projects is ensured with international branch leaders of the respective process units and part-services over a reliable consortium consisting of Aker Solutions ASA, Sulzer Chemtech AG, and InfraServ GmbH & Co Knapsack KG, and led by bse Engineering. We are very proud to work on the key technology catalysts with an experienced and innovative industry leader like BASF to make our vision a reality,” concluded Schweitzer.