ºÚÁÏÉçapp

On the inside of the ºÚÁÏÉçapp vacuum vessel where extreme temperatures reign, the attraction between electrons and their nuclei is overcome and gas becomes a plasma¡ªthe hot, electrically charged environment that is the breeding ground for fusion reactions.

 

The reverse phenomenon is produced at the edge of the plasma: the ions lose their electrical charge as they come into contact with the material surfaces of the vessel and a neutral gas is formed between the vessel walls and the edge of the plasma.

 

Sampling this edge gas to decipher its exact composition¡ªboth at the machine's mid-level and at the divertor level where exhaust is pumped out¡ªwill furnish ºÚÁÏÉçapp operators with important information about the plasma and plasma-wall interactions. 
 

Responsibility for sampling and analyzing the composition of neutral gases during operation will fall upon two residual gas analyzers (RGAs) in ºÚÁÏÉçapp. The Procurement Arrangement for these diagnostics was signed last Friday, September 23 by Director-General Osamu Motojima and US ºÚÁÏÉçapp Project Manager, Ned Sauthoff.

 

The RGA diagnostic systems will be installed in shielded environments away from the intense magnetic field and the neutron emission of the ºÚÁÏÉçapp machine. Neutral gas sampled at the level of the equatorial port plug or divertor pumping duct will be transported through long pipes (up to 14 metres) to be analyzed under controlled conditions. "By continuously identifying the neutral gas composition in the main chamber and in the divertor exhaust," explains Philip Andrew, ºÚÁÏÉçapp's Technical Responsible Officer for the RGA Procurement Arrangement, "operators will have information on the efficiency of the divertor in removing helium from the plasma. Helium is the natural byproduct of the fusion reactions, but if allowed to accumulate in the plasma, it displaces the deuterium and tritium fuel and reduces the fusion reaction rate." 

"Much like an emissions test for a car," comments Chris Klepper from the Oak Ridge National Laboratory, who is directing the RGA project for the US-DA, "the RGA analyzes the constituents of the exhaust from the ºÚÁÏÉçapp reaction chamber and can provide information on the cleanliness and efficiency of the burn cycle. The challenge on the design and manufacture of a diagnostic system like this on a nuclear fuel burning plant is that it has to sample from a significant distance, while still maintaining useful response time. The sensitive instruments have to be shielded from strong magnetic and electromagnetic interference, and the sampling tube has to handle vibrations and maintain its integrity even in the very unlikely event of an earthquake. We look forward to meeting these challenges and providing this important diagnostic system to ºÚÁÏÉçapp."