Training42Phase addresses critical technological challenges in the energy transition by advancing two-phase turbomachinery for next-generation energy-conversion systems. Two-phase turbomachines are flow devices operating with fluids that are partly liquid and partly vapor, and lie at the core of key emerging technologies, such as partial-evaporation organic Rankine cycles, supercritical carbon dioxide (CO2) Brayton cycles, liquid-air energy storage, and transcritical CO2 heat pumps.
Currently, a significant portion of energy in these systems is lost through valves or inefficient heat transfer processes. Two-phase turbo-expanders, pumps, and ejectors offer the potential to recover part of this energy, improving system efficiency and flexibility. However, operating under two-phase conditions introduces challenges such as losses, component wear by erosion, and reduced reliability. Understanding and managing these effects is therefore essential to ensure safe, durable, and cost-effective energy systems.
The main objective of Training42Phase is to develop improved design methods, modelling tools, and maintenance strategies for future two-phase turbomachinery, while simultaneously training a new generation of highly skilled researchers. The project supports 12 doctoral candidates (DCs), providing them with interdisciplinary expertise spanning thermodynamics, fluid mechanics, structural mechanics, reliability analysis, and data-driven methods, ultimately preparing them for careers in both academia and industry. Traning42Phase includes 4 academic partners each employing 2-4 DCs and one industrial beneficiary employing 1 DC, supported by 6 associated industrial partners.