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Summary of Current Test Plan for US DCLL TBM in ITER (updated Nov.1 2005). US strategy for ITER testing of the DCLL Blanket and First Wall Concept. Develop and deploy a series (~4) of vertical half-port DCLL-TBMs during the period of the first 10 years of ITER operation with
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Summary of Current Test Plan for US DCLL TBM in ITER(updated Nov.1 2005)
US strategy for ITER testing of the DCLL Blanket and First Wall Concept • Develop and deploy a series (~4) of vertical half-port DCLL-TBMs during the period of the first 10 years of ITER operation with • Test articles from day one of ITER operation with specific testing goals and diagnostic systems • Associated ancillary equipment systems • in a transporter behind the bioshield and in space in the TCWS and tritium buildings • using bypass PbLi flow to keep temperature of ancillary equipment below material limits • Develop international collaboration on PbLi systems to the maximal extent
Electromagnetic/Structural (EM/S) TBM Testing Goals • Validate general TBM structure and design • Measure forces and the mechanical response of the TBM structure to transient EM loads • Determine ferromagnetic and MHD flow perturbation of ITER fields • Measure thermal and particle load effects on plasma facing surface (Be) and FW structure/heat sink Information in the early HH phase can be used: • to modify designs of subsequent TBMs to be deployed in the later DT phase • for ITER DT Licensing. • Establish performance baseline and operational experience of the TBM and ancillary systems • Integration of control systems and diagnostics with ITER systems • Demonstration of required subsystems and port integration • Demonstration of remote handling procedures • Measurement of thermal time constants and heat loss • Measurement of tritium (hydrogen) permeation characteristics • Testing heating/filling/draining/remelting and accident response procedures • Perform initial studies of MHD effects and Flow Channel Insert performance • MHD flow distribution (manifold design, multichannel effects) • 3D pressure drop (toroidal field and toroidal + true poloidal field) • FCI performance changes as a function LM exposure time • FCI response to loading from EM events (water hammer, transient eddy current forces) • Map ITER field in TBM area
Design of EM/S TBM • EM/S TBM based on the required design for the Integrated TBM to be deployed in the DT phase. • Identical dimensions, materials and fabrication sequence • Similar electrical characteristics including FCIs • Deploy with SiC/SiC FCIs • If development SiC/SiC FCIs requires additional time, sandwich-type RAFS clad Alumina inserts will be deployed at this stage as an electrical surrogate. • 1 TBM during entire H-H phase – 3 year lifetime • Manufacturing a spare is a possible alternative • Required ancillary equipment includes full helium coolant, PbLi circulation system • If needed, non-essential PbLi purification systems, PbLi-He HX, tritium removal systems etc. could be staged over 1st 4 year’s operation
Measurement Systems needed to meet EM/S TBM testing goals • DC and AC field measurements (with Hall Probes, other?) • Load cells at TBM attachment points • Strain gauges at selected locations on inside FW, separator plates and attachment points • Electrical potential measurements at various locations • Thermocouples at high temperature locations on the FW, in access lines, and LM and He system components in the transporter cask • Depth markers in FW beryllium • LM and High pressure He compatible pressure transducers • LM and He flow meters • PIE • deformation of module and external attachment supports • FCI cracking, crumbling, PbLi soaking • Internal weld failures Estimate: ~50 diagnostic channels required
Nuclear Field / Tritium Production (N/T) TBM • Purpose: • database of neutron field measurements for various types of ITER discharges and conditions • characterize tritium production rate (TPR), and nuclear heating rates. • FW He cooling and tritium implantation • Design: • Similar design and structure as the Integrated-TBM • Rabbit-style tube system for deploying/retrieving activation foils into several location in the TBM • Tritium diagnostics (Li glass, other) • Nuclear heat (micro-calorimeter, other) diagnostics • Testing during DD and early DT phase: • ~2 years in-ITER • Operated ‘cold’ to help control tritium • Required operational conditions still to be determined
Thermofluid / MHD (T/M) TBM • Purpose: • thermal and electrical insulation properties of the FCI • FCI failure effects • tritium permeation through FCIs • velocity measurements with FCI gap flow and natural convection • Initial data on activation products and chemistry control • Design: • Aspects of TBM itself still TBD based on ongoing R&D • Temperature, electric potential diagnostics • Calorimetry • Tritium counting diagnostics • Testing in low duty DT phase • ~2 years in-ITER • moderate temperature (<500C) operation of the TBM with PbLi
DCLL Integrated (I) TBM • Purpose: • Investigate high temperature TBM operation • flow channel inserts behavior • effect on tritium permeation • corrosion and activation products • Investigate online tritium recovery from PbLi and He streams • Investigate online PbLi purification systems • Explore longer term Integrated operation of the system • including small accumulation of radiation damage in FCIs and RAFS joints • Design • Preliminary design outlined in DDD (shown by Wong and Dagher) • Testing in high duty DT phase • ~3 years in-ITER • Continuous operation in long campaigns looking for changes in performance and failures
Comments: • Is the scope appropriate? • … • Input from materials, safety, tritium, PFC people? • … • Missing test objectives? • … • … • Mission statement?