A new discriminating high temperature fission chamber filled with xenon designed for sodium-cooled fast reactors

During the operation of the Superphenix and Phenix reactors, an aberrant electrical signal was detected from the fission chambers used for neutron flux monitoring. This signal, thought to be due to partial electrical discharge (PD) is similar to the signal resulting from neutron interactions, and is generated in fission chambers at temperatures above 400 °C. This paper reports work on the characterization and localization of the source of this electrical signal in a High Temperature Fission Chamber (HTFC). The relation between the shape of the PD signal and various parameters (nature and pressure of the chamber filling gas, electrode gap distance, and fission chamber geometry) are first described. Next, experiments designed to identify the location within the chambers where the PD are being generated are presented. After verification and refinement of the results of these localization studies, it should be possible to propose changes to the fission chamber in order to reduce or eliminate the PD signal.

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Commercial Design of Custom Front-end Electronics for a High Temperature Fission Chamber

10.2172/1479737 ◽

2018 ◽

Author(s):

N. Dianne Bull Ezell ◽

Lorenzo Fabris ◽

Richard J. Wunderlich ◽

Padhraic L. Mulligan ◽

Christian M. Petrie ◽

...

Keyword(s):

High Temperature ◽

Fission Chamber ◽

Front End

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Fast Neutron-Flux Monitoring Instrumentation for Lead Fast Reactors: A Preliminary Study on Fission Chamber Performances

Volume 6: Nuclear Education, Public Acceptance and Related Issues; Instrumentation and Controls (I&C); Fusion Engineering; Beyond Design Basis Events ◽

10.1115/icone22-31011 ◽

2014 ◽

Cited By ~ 1

Author(s):

Luigi Lepore ◽

Romolo Remetti ◽

Mauro Cappelli

Keyword(s):

Neutron Flux ◽

Fuel Cycle ◽

Fast Reactors ◽

Fission Chamber ◽

Enhanced Sensitivity ◽

Flux Monitoring ◽

Preliminary Study ◽

Fast Flux ◽

Absolute Measurements ◽

Fission Chambers

Although Sodium Fast Reactors (SFRs) are the most investigated solutions for the future fast-flux facilities so far, Lead Fast Reactors (LFRs) promise to be a very competitive alternative thanks to their peculiarity concerning coolant-safety, fuel cycle and waste management. Nevertheless, the development of LFRs presents today some drawbacks still to be solved. Due to the harder neutron flux, the current instrumentation developed for SFRs is likely to be extended to LFRs as a first attempt. Otherwise, new monitoring instrumentation could be developed in order to assure more tailored results. Different measurement technologies can be considered for fast flux monitoring and flux absolute measurements in order to provide a reliable and quick calibration of the overall reactor neutron instrumentation. The goal of this paper is to study the validity of typical fast reactor fission chamber designs (e.g. SuperPhénix fission chambers), indicating which are the limitations when used in a LFR environment. Afterwards, alternative detector solutions with enhanced sensitivity and response will be proposed.

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The Role of Nuclear Power in Meeting Current and Future Industrial Process Heat Demands

Energies ◽

10.3390/en12193664 ◽

2019 ◽

Vol 12 (19) ◽

pp. 3664 ◽

Cited By ~ 1

Author(s):

Aiden Peakman ◽

Bruno Merk

Keyword(s):

High Temperature ◽

Carbon Capture ◽

Nuclear Power ◽

Carbon Capture And Storage ◽

Industrial Process ◽

Energy System ◽

Low Carbon ◽

Fast Reactors ◽

Advantages And Disadvantages ◽

Heat Demand

There is growing interest in the use of advanced reactor systems for powering industrial processes which could significantly help to reduce CO 2 emissions in the global energy system. However, there has been limited consideration into the role nuclear power would play in meeting current and future industry heat demand, especially with respect to the advantages and disadvantages nuclear power offers relative to other competing low-carbon technologies, such as Carbon Capture and Storage (CCS). In this study, the current market needs for high temperature heat are considered based on UK industry requirements and work carried out in other studies regarding how industrial demand could change in the future. How these heat demands could be met via different nuclear reactor systems is also presented. Using this information, it was found that the industrial heat demands for temperature in the range of 500 ∘ C to 1000 ∘ C are relatively low. Whilst High Temperature Gas-cooled Reactors (HTGRs), Very High Temperature Reactors (VHTRs), Gas-cooled Fast Reactors (GFRs) and Molten Salt Reactors (MSRs) have an advantage in terms of capability to achieve higher temperatures (>500 ∘ C), their relative benefit over Liquid Metal-cooled Fast Reactors (LMFRs) and Light Water Reactors (LWRs) is actually smaller than previous studies indicate. This is because, as is shown here, major parts of the heat demand could be served by almost all reactor types. Alternative (non-nuclear) means to meet industrial heat demands and the indirect application of nuclear power, in particular via producing hydrogen, are also considered. As hydrogen is a relatively poor energy carrier, current trends indicate that the use of low-carbon derived hydrogen is likely to be limited to certain applications and there is a focus in this study on the emerging demands for hydrogen.

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Evaluation of Testing Facilities for a High Temperature Fission Chamber Design

10.2172/1460199 ◽

2018 ◽

Author(s):

N. Dianne Bull Ezell ◽

Nesrin Ozgan Cetiner

Keyword(s):

High Temperature ◽

Fission Chamber ◽

Chamber Design

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High temperature ultrasonic transducers for in-service inspection of liquid metal fast reactors

2011 IEEE International Ultrasonics Symposium ◽

10.1109/ultsym.2011.0479 ◽

2011 ◽

Cited By ~ 6

Author(s):

J. W. Griffin ◽

G. J. Posakony ◽

R V. Harris ◽

D. L. Baldwin ◽

A. M. Jones ◽

...

Keyword(s):

High Temperature ◽

Liquid Metal ◽

Ultrasonic Transducers ◽

Fast Reactors ◽

Service Inspection

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Refueling Liquid-Salt-Cooled Very High-Temperature Reactors

Volume 3: Structural Integrity; Nuclear Engineering Advances; Next Generation Systems; Near Term Deployment and Promotion of Nuclear Energy ◽

10.1115/icone14-89471 ◽

2006 ◽

Author(s):

Charles W. Forsberg ◽

Per F. Peterson ◽

James E. Cahalan ◽

Jeffrey A. Enneking ◽

Phil MacDonald

Keyword(s):

High Temperature ◽

Fuel Element ◽

Operating Conditions ◽

Plant Design ◽

Fast Reactors ◽

Liquid Salt ◽

Study Results ◽

High Temperature Reactor ◽

High Temperature Reactors ◽

Very High

The liquid-salt-cooled very high-temperature reactor (LS-VHTR), also called the Advanced High-Temperature Reactor (AHTR), is a new reactor concept that combines in a novel way four established technologies: (1) coated-particle graphite-matrix nuclear fuels, (2) Brayton power cycles, (3) passive safety systems and plant designs previously developed for liquid-metal-cooled fast reactors, and (4) low-pressure liquid-salt coolants. Depending upon goals, the peak coolant operating temperatures are between 700 and 1000°C, with reactor outputs between 2400 and 4000 MW(t). Several fluoride salt coolants that are being evaluated have melting points between 350 and 500°C, values that imply minimum refueling temperatures between 400 and 550°C. At operating conditions, the liquid salts are transparent and have physical properties similar to those of water. A series of refueling studies have been initiated to (1) confirm the viability of refueling, (2) define methods for safe rapid refueling, and (3) aid the selection of the preferred AHTR design. Three reactor cores with different fuel element designs (prismatic, pebble bed, and pin-type fuel assembly) are being evaluated. Each is a liquid-salt-cooled variant of a graphite-moderated high-temperature reactor. The refueling studies examined applicable refueling experience from high-temperature reactors (similar fuel element designs) and sodium-cooled fast reactors (similar plant design with liquid coolant, high temperatures, and low pressures). The findings indicate that refueling is viable, and several approaches have been identified. The study results are described in this paper.

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2012 Edition of the RCC-MRx: Adaptation of Rules to the Evolution of Projects Needs and International Exchanges

Volume 1: Codes and Standards ◽

10.1115/pvp2012-78330 ◽

2012 ◽

Author(s):

T. Lebarbé ◽

C. Petesch ◽

D. Bonne ◽

F. de la Burgade ◽

M. Blat-Yrieix

Keyword(s):

High Temperature ◽

Research Reactor ◽

Fusion Reactors ◽

Vacuum Vessel ◽

Nuclear Facilities ◽

Fast Reactors ◽

Research Reactors ◽

European Code ◽

Set Up ◽

International Exchanges

In 2012, AFCEN (Association Française pour les règles de Conception et de Construction des Matériels des Chaudières Electro-nucléaires) will publish the fifth edition of the RCC-MR code, named RCC-MRx 2012. This RCC-MRx Code is the result of the merger of the RCC-MX 2008 developed in the context of the research reactor Jules Horowitz Reactor project, in the RCC-MR 2007 which set up rules applicable to the design of components operating at high temperature and to the Vacuum Vessel of ITER. RCC-MRx, developed especially for Sodium Fast Reactors (SFR), Research Reactors (RR) and Fusion Reactors (FR-ITER) can also be used for components of other types of nuclear facilities (except PWR). It has been consider for instance in the frame of the CEN-Workshop (CEN-WS-MRx) in order to develop, on its basis, the European code for the design and fabrication of mechanical equipments for ESNII innovative nuclear installations. The main objective of the RCC-MRx is to capitalize the technical feedback of projects such as SUPERPHENIX, JHR, but also to meet the needs of MYRRHA, PFBR and ASTRID projects and to prepare the design and construction of ALFRED and ALLEGRO. This paper presents the technical evolutions in the 2012 edition and the AFCEN organization dedicated to work in an international frame.

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