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TRL tables: power conversion and lifetime

TRL tables: power conversion and lifetime. M. S. Tillack. ARIES Project Meeting March 4, 2008. High temperature operation and power conversion. Scope Consequences of high temperature operation Performance of primary and secondary power conversion systems

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TRL tables: power conversion and lifetime

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  1. TRL tables: power conversion and lifetime M. S. Tillack ARIES Project Meeting March 4, 2008

  2. High temperature operation and power conversion • Scope • Consequences of high temperature operation • Performance of primary and secondary power conversion systems • Does not consider temperature control within components (thermal hydraulics, MHD heat transfer, etc). This is a gray area in common with “Heat and particle flux handling”. • Key science challenges (theory + experiments) • Mass transfer • Surface chemistry • Materials degradation via chemical interactions • Material properties degradation at high temperature • Key facilities • High-temperature materials properties and thermo-mechanics test rigs • Chemical interaction static and loop facilities • Integrated heat transport (or power conversion) loops

  3. Technology readiness levels for power conversion

  4. Power core lifetime • Scope • All power core components • “Normal” and “off-normal” life-limiting mechanisms • This is a gray area in common with the operations subgroup. Aspects of reliability and failure rates are considered. • Key science challenges (theory + experiments) • Neutron damage, neutron-induced burn-up • Particle erosion • Corrosion damage • Disruption and ELM damage (thermomechanical, electromechanical, plasma, runaways) • Effects of thermal cycling • Key facilities • Specimen tests (neutron, plasma, HHF, chemistry) • Component tests in a laboratory environment • Component tests in fusion facilities (nuclear, non-nuclear tokamaks)

  5. Technology readiness levels for power core lifetime

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