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In order to counteract climate change and thus herald the mobility transition from combustion engines to battery electric vehicles in Germany, the German government has set the target of registering a total of 15 million electric vehicles by the end of 2030. This is accompanied by enormous demands on battery logistics, as car manufacturers generally decide to have the finished battery systems installed in the bodywork at physically separate locations. Both the transportation of lithium-ion batteries as hazardous goods and their storage are subject to a large number of regulatory requirements. In particular, the handling of critical or critical/defective batteries is complex from a logistics perspective in terms of regulation. In order to keep lithium-ion batteries in the cycle for a correspondingly long time and to ensure that a circular economy can function in general, several stakeholders from different groups must collaborate with each other. Once the battery has reached around 80% state-of-health, the end of the automotive application has been reached. However, this does not mean that it has to be recycled immediately in line with the circular economy. The aim is to extend the life of the battery, for example as second-life energy storage. Other so-called
M.Yu. Plotnikov (Mon,) studied this question.