Thermomechanical processes in an inert atmosphere enable the recovery of over 98% of the dry black mass - including lithium, cobalt, nickel and manganese. This ensures access to strategically important secondary raw materials while improving economic recovery efficiency.

URT plants meet all environmental, occupational and safety standards. Technical measures such as inertisation, explosion protection and closed material handling significantly contribute to plant availability and reduce the risk of costly downtime or maintenance interventions.

Precise mechanical separation processes enable clean separation of aluminium, copper, ferrous metals, plastics and other material streams, forming the basis for high output quality and flexible downstream processing.

Volatile compounds such as electrolytes are evaporated under vacuum during thermomechanical drying, condensed and treated via exhaust air systems such as RTO. The systems are designed for minimal emissions and full regulatory compliance.

Process engineering design is based on a large number of successfully implemented international lithium ion battery recycling projects as well as decades of experience in handling sensitive material streams. This ensures planning reliability and stable plant operation at all levels.

The plants feature a fully integrated automation concept, covering material feeding, shredding, fractioning and drying through to exhaust air treatment. Process parameters such as material flows, temperatures, pressure levels, nitrogen supply and emission values are digitally monitored and documented. This ensures stable process control, reduces manual intervention and supports efficient plant operation.

The modular plant concept allows flexible adaptation to different input materials, cell chemistries and throughput requirements. Expandable process stages and a flexible system architecture ensure technical and economic viability even with increasing return volumes and changing regulatory frameworks. This protects investment and enables long term technological development.