Oxygen sensors and electrochemical oxygen pumps for lead alloy cooled nuclear systems

Manfredi, Gabriele

21 February 2018

MYRRHA, a Multi-purpose hYbrid Research Reactor for High-tech Applications is currently under development at the Belgian nuclear research center SCK•CEN. It is the first prototype of a nuclear reactor driven by a particle accelerator in the world. Lead-Bismuth Eutectic (LBE) has been selected as spallation neutron source and as primary reactor coolant. Oxygen control strategy has been defined to mitigate undesirable liquid metal corrosion occurring between the steel surface of the main components of MYRRHA and the LBE itself. The development of a reliable oxygen sensor and control device beyond the state-of-the-art for operation in the conditions foreseen in MYRRHA are therefore crucial. A potentiometric oxygen sensor based on the use of yttria partially stabilized zirconia as solid electrolyte combined respectively with air/perovskite oxides, Cu/Cu2O, In/In2O3 or LBE/PbO reference electrode has been developed and operated successfully between 200 and 450 °C in oxygen saturated LBE overcoming the operating temperature limit of previously used Bi/Bi2O3 and air/Pt reference electrode oxygen sensors being of 280 °C and 300 °C approximately.An electrochemical oxygen pump based on the use of yttria partially stabilized zirconia as solid electrolyte and air/Lanthanum Strontium Manganite electrode has been tested both to add and extract oxygen from LBE. The oxygen addition might be limited by the oxygen reduction kinetics at the air/LSM side while, the oxygen extraction is limited at high oxygen potential by the diffusion of oxygen ions through the solid electrolyte and at low oxygen potential by the oxygen diffusion in the liquid LBE. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences de l'ingénieur

Oxygen, MYRRHA, Sensor, LBE

CONQUER CORROSION : Key issues of the lead-cooled fast reactor design

Hareland, Mathias

January 2011

The lead-cooled fast reactor (LFR) is one of the concepts of the Generation IV reactorsystems. There are some issues that have to be solved before a research orcommercial LFR can be built. The objective of this thesis was to identify these keyissues and analyse them by studying results from previous research: choice of fuel,corrosion on structural materials and corrosion/erosion on pumps.The major fuel candidates for the LFR are MOX fuel (Mixed OXide fuel), metallic fuel,nitride fuel and carbide fuel. Nitride fuel has desirable properties but its production ismore difficult than for MOX fuel.Most of today’s commercial steels are not corrosion resistant at higher temperaturesbut they could possibly be used for an LFR test demonstrator with an operatingtemperature lower than 450 ºC. A new type of steel called oxide dispersionstrengthened (ODS) steel and a new ceramic material MAXTHAL both showpromising corrosion resistance even at higher temperatures.By controlling the oxygen concentration a protective oxide film is produced. Flowingliquid coolant causes erosion and wears down the oxide film. Pumps are exposed tocoolant velocities of 10-15 m/s causing both erosion and corrosion. There is nosolution today, but MAXTHAL shows promising results in tests with liquid lead of lowvelocity. There are also other issues unsolved, such as irradiation damage onstructural materials, thus more research is needed.Economic and political aspects were not covered in this study. This thesis work wasperformed at Vattenfall Research and Development AB.

Nuclear power

Generation-IV

lead cooled fast reactor

LFR

corrosion

MAXTHAL

MYRRHA

Lead-bismuth eutectic

LBE

Pokročilé kompozitní konstrukční oceli pro použití v taveninách těžkých kovů / Advanced Composite Structural Steels for Applications in Heavy Liquid Metals

Husák, Roman

January 2019

Doctoral thesis was focused on preparing of new advanced ODS steels for use in heavy metal liquids enviroments. Possibility of new course for creating oxide dispersion in microstructure was verified by the course of internal oxidation of elements. By the internal oxidation method were prepared new ODS steels strengthened by complex oxides which were created by elements of IIIB and IVB group of elements. Based on analysis of damage ODS steels in LBE were designed surface protection of ODS steel by the oxide layer. The ODS steel protected by oxide layer was subjected to a corrosion test in LBE. For the experiments were chosen class of chromium steels: ferritic-martensitic steel 9Cr1WMnVTa and ferritic steels 14CrWTi and 17Cr1Mo. Steels without oxide dispersion and steel strenghtened by the dispersion based on Y-Ti-O oxides were prepared. On the steels were made series of mechanic tests which should reveal the effectivity of oxide dispersion on the strenght of steel prepared by the internal oxidation method and by the direct addition of oxide elements. It was found that significantly harder oxide material couldn't be fully disrupted through the mechanical alloying and fine oxide dispersion couldn't be created. There was verified fine oxide dispersion could be created by the internal oxidation method and by the direct adding of oxide elements. Same kind of steels strenghtened by new kind of complex oxides based on Y, Ce, Hf, La, Sc and Zr were prepared. The chemical analyses have proven that all added elements could created complex oxide by the reaction with yttrium. The computational analyses for observing of matrix influence and oxide phase influence on strenghtening of steels were performed. These computational analyses were based on microstructural analyses of ODS steels. There was found that the oxide particles could very effectively improve strenght of steels at room temperature and especialy at high temperature. Based on corrosion tests of 14Cr ODS steel in liquid Pb and LBE enviroment were designed surface protection of ODS steel. The effectiveness of protective layer was verified by the high temperature corrosion test of PM2000 in LBE. No damage of oxide layer was observed although Pb and Bi diffused through protective layer.

Výpočetní simulace urychlovačem řízeného jaderného reaktoru pro transmutaci vyhořelého jaderného paliva / Simulation of Accelerator Driven Nuclear Reactor for Spent Nuclear Fuel Transmutation

Jarchovský, Petr

January 2015

This master’s thesis deals with usage of burn-up (spent) nuclear fuel in nuclear power plants of next generation – accelerator driven transmutation plants which is produced in current nuclear power plants. This system could significantly reduce the volume of dangerous long-lived radioisotopes and moreover they would be able to take advantage of its great energy potential due to fast neutron spectrum. In the introduction are listed basic knowledge and aspects of spent nuclear fuel along with its reprocessing and the possibility of further use while minimizing environmental impact. As another point detailed description of accelerator driven systems is described together with its basic components. In addition this search is followed by individual chronological enumeration of projects of global significance concerning their current development. Emphasis is placed on SAD and MYRRHA projects, which are used like base for calculations. This last, computational part, deals with the creation of the geometry of subcritical transmutation reactor driven by accelerator and subsequent evaluation which assembly is the most effective for transmutation and energy purposes along with changing of target, nuclear fuel and coolant/moderator.