Natalia Casal

ITER ECE Diagnostic: Design Progress of IN-DA and the diagnostic role for Physics

The ECE Diagnostic system in ITER will be used for measuring the electron temperature profile evolution, electron temperature fluctuations, the runaway electron spectrum, and the radiated power in the electron cyclotron frequency range (70-1000 GHz), These measurements will be used for advanced real time plasma control (e.g. steering the electron cyclotron heating beams), and physics studies. The scope of the Indian Domestic Agency (IN-DA) is to design and develop the polarizer splitter units; the broadband (70 to 1000 GHz) transmission lines; a high temperature calibration source in the Diagnostics Hall; two Michelson Interferometers (70 to 1000 GHz) and a 122-230 GHz radiometer. The remainder of the ITER ECE diagnostic system is the responsibility of the US domestic agency and the ITER Organization (IO). The design needs to conform to the ITER Organizations strict requirements for reliability, availability, maintainability and inspect-ability. Progress in the design and development of various subsystems and components considering various engineering challenges and solutions will be discussed in this paper. This paper will also highlight how various ECE measurements can enhance understanding of plasma physics in ITER.

Integration of diagnostics on ITER

Diagnostics play a very important role in the modern Tokamak where optimum performance is essential. To achieve this, the device must be equipped with reliable and robust sensors and instrumentation that allow the operation envelope to be fully explored. Development of these diagnostics to maintain this reliability is necessary. Further to the development, the systems must be integrated in a way that maintains their performance while simultaneously satisfying the key requirements needed for safety and tokamak operation. ITER will have 50 diagnostics; almost all of which are utilized primarily for the real-time operation of the tokamak. While there is still much work to do, to date, significant progress has been made in the development of these systems. The work load for the developments is shared across all the ITER partners. This paper focuses on the challenges for the integration of the systems.

Environmental conditions & loads of ITER diagnostic equipment in the port plug interspace & port cell

Development of the port-based diagnostic and service system integration in the Tokamak has been a challenging task for ITER (Nuclear Facility INB-174) engineering. Port integration is demanding more work on ex-vessel to identify electromagnetic thermal and nuclear environment in interspace and port cell regions. Protecting the diagnostic equipment in the interspace & port cell regions poses considerable engineering constraints. This paper will focus on the normal and accidental environmental conditions such as seismic, magnetic field, radiation, pressure, temperature etc., with particular interest on US Domestic Agencies (USDA) based diagnostic systems.