Innovative accident tolerant fuel concept enabled through direct manufacturing technology

•An innovative nuclear fuel using direct manufacturing to improve safety is proposed.•Rapid Laser-Induced Chemical Vapor Deposition technology is utilized.•Multiphysics modeling and simulation is used to guide the fuel design process.•New fuel stress levels are comparable to current tristructural is...

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Veröffentlicht in:	Applied energy 2020-04, Vol.264, p.114742, Article 114742
Hauptverfasser:	Li, Wei, Shirvan, Koroush, Harrison, Shay, Pegna, Joseph
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Sprache:	eng
Schlagworte:	Accident tolerant fuels Direct manufacturing FEA NUCLEAR FUEL CYCLE AND FUEL MATERIALS Nuclear fuels
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creator	Li, Wei Shirvan, Koroush Harrison, Shay Pegna, Joseph
description	•An innovative nuclear fuel using direct manufacturing to improve safety is proposed.•Rapid Laser-Induced Chemical Vapor Deposition technology is utilized.•Multiphysics modeling and simulation is used to guide the fuel design process.•New fuel stress levels are comparable to current tristructural isotropic particle fuel.•Uranium enrichment requirement is significantly lower for the new fuel. Nuclear energy is one of the largest sources of carbon-free electricity in the world. Some countries are looking at new ways to support and revitalize the nuclear sector since the Fukushima disaster. The accident tolerant fuel program is geared toward improving the safety of nuclear energy by investigating materials that can replace or modify the current uranium-dioxide nuclear fuel and zirconium-based cladding. This research program is being supported by all major nuclear countries since 2011. The practical limitations on allowable uranium enrichment has taken the focus away from the most promising fuels with high radioactivity retention such as tristructural isotropic particle fuel. To overcome such enrichment limitation, a new fuel concept is proposed using advanced ceramic direct manufacturing with laser-induced chemical vapor deposition. The fuel-as-fiber concept is an accident-tolerant fuel design that features high thermal conductivity, strong capability of radioactivity retention and most importantly requires reasonable enrichment levels with uranium nitride as the fuel. In this work, the initial fabrication of uranium-based fuel with laser-induced chemical vapor deposition technology is demonstrated. Then an advanced multi-physics guided modeling approach based on finite element analysis codes and informed by the manufacturing capabilities is developed to accelerate the advancement of fuel-as-fiber concept for use in current light-water reactor technology. The detailed thermomechanical analysis showed promising results for viability of the innovative fuel-as-fiber concept. The predicted stresses in the fuel structural materials were similar to the case of tristructural isotropic particle fuel experience base that has shown excellent reliability in retention of fuel radioactivity at high temperatures.
doi_str_mv	10.1016/j.apenergy.2020.114742
format	Article
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Nuclear energy is one of the largest sources of carbon-free electricity in the world. Some countries are looking at new ways to support and revitalize the nuclear sector since the Fukushima disaster. The accident tolerant fuel program is geared toward improving the safety of nuclear energy by investigating materials that can replace or modify the current uranium-dioxide nuclear fuel and zirconium-based cladding. This research program is being supported by all major nuclear countries since 2011. The practical limitations on allowable uranium enrichment has taken the focus away from the most promising fuels with high radioactivity retention such as tristructural isotropic particle fuel. To overcome such enrichment limitation, a new fuel concept is proposed using advanced ceramic direct manufacturing with laser-induced chemical vapor deposition. The fuel-as-fiber concept is an accident-tolerant fuel design that features high thermal conductivity, strong capability of radioactivity retention and most importantly requires reasonable enrichment levels with uranium nitride as the fuel. In this work, the initial fabrication of uranium-based fuel with laser-induced chemical vapor deposition technology is demonstrated. Then an advanced multi-physics guided modeling approach based on finite element analysis codes and informed by the manufacturing capabilities is developed to accelerate the advancement of fuel-as-fiber concept for use in current light-water reactor technology. The detailed thermomechanical analysis showed promising results for viability of the innovative fuel-as-fiber concept. 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The fuel-as-fiber concept is an accident-tolerant fuel design that features high thermal conductivity, strong capability of radioactivity retention and most importantly requires reasonable enrichment levels with uranium nitride as the fuel. In this work, the initial fabrication of uranium-based fuel with laser-induced chemical vapor deposition technology is demonstrated. Then an advanced multi-physics guided modeling approach based on finite element analysis codes and informed by the manufacturing capabilities is developed to accelerate the advancement of fuel-as-fiber concept for use in current light-water reactor technology. The detailed thermomechanical analysis showed promising results for viability of the innovative fuel-as-fiber concept. 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subjects	Accident tolerant fuels Direct manufacturing FEA NUCLEAR FUEL CYCLE AND FUEL MATERIALS Nuclear fuels
title	Innovative accident tolerant fuel concept enabled through direct manufacturing technology
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