Status report on the cold neutron source of the Garching neutron research facility FRM-II
Autor: | Klaus Gobrecht, A Scheuer, Erwin Gutsmiedl |
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Rok vydání: | 2002 |
Předmět: |
Materials science
Nuclear engineering Nuclear reactor Condensed Matter Physics Electronic Optical and Magnetic Materials law.invention Nuclear physics Neutron generator Nuclear reactor core Neutron flux law Neutron research facility Neutron source Neutron Research reactor Electrical and Electronic Engineering |
Zdroj: | Physica B: Condensed Matter. 311:148-151 |
ISSN: | 0921-4526 |
DOI: | 10.1016/s0921-4526(01)01130-9 |
Popis: | The new high flux research reactor of the Technical University of Munich (Technische Universitat Munchen, TUM) will be equipped with a cold neutron source (CNS). The centre of the CNS will be located in the D 2 O-reflector tank at 400 mm from the reactor core axis close to the thermal neutron flux maximum. The power of 4500 W developed by the nuclear heating in the 161 of liquid deuterium at 25 K, and in the structures, is evacuated by a two-phase thermal siphon avoiding film boiling and flooding. The thermal siphon is a single tube with counter current flow. It is inclined by 10° from vertical, and optimised for a deuterium flow rate of 14 g/s. Optimisation of structure design and material, as well as safety aspects will be discussed. Those parts of the structure, which are exposed to high thermal neutron flux, are made from Zircaloy 4 and 6061T6 aluminium. Structure failure due to embrittlement of the structure material under high rapid neutron flux is very improbable during the lifetime of the CNS (30 years). Double, in pile even triple, containment with inert gas liner guarantees lack of explosion risk and of tritium contamination to the environment. Adding a few percent of hydrogen (H 2 ) to the deuterium (D 2 ) will improve the moderating properties of our relatively small moderator volume. Nearly all of the hydrogen is bound in the form of HD molecules. A long-term change of the hydrogen content in the deuterium is avoided by storing the mixture not in a gas buffer volume but as a metal hydride at low pressure. The metal hydride storage system contains two getter beds, one with 250 kg of LaCo 3 Ni 2 , the other one with 150 kg of ZrCo 0.8 Ni 0.2 Each bed can take the total gas inventory, both beds together can absorb the total gas inventory in < 6 min at a pressure < 3 bar. The new reactor will have 13 beam tubes, 4 of which are looking at the CNS, including two for very cold (VCN) and ultra-cold neutron (UCN) production. The latter will take place in the horizontal beam tube SR4, which will house an additional cryogenic moderator (e.g. solid deuterium). More than 60% of the experiments foreseen in the new neutron research facility will use cold neutrons from the CNS. The mounting of the hardware components of the CNS into the reactor has started in the spring of 2000. The CNS went into trial operation in the end of year 2000. |
Databáze: | OpenAIRE |
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