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Graduate Assistantships for students seeking Ph.D. or MS degrees

Self-Powered Platform to Measure and Report Used Nuclear Fuel Canister Internal Conditions

In September 2020, the US Nuclear Regulatory Commission announced, based on a competitive grant application process, it is providing the University of ÁùºÏ±¦µä, Reno College of Engineering with nearly $500,000 over three years to develop a proof-of-concept system to measure conditions inside thick-walled used nuclear fuel canisters, and safely transmit the data to a receiver outside.  This work will help assure the safety of used nuclear fuel storage and transportation.  It will require the development of low-power magnetic resonance signals that can reliably transmit data across thick metal walls.  It will also develop and place thermoelectric devices that harvest heat generated by the used fuel to produce electric power.  That energy will power the measurement and signal transmission devices.  Multiple graduate students will work closely with engineering faculty members to perform theoretical, computational, and experimental research and development.  This work will be published in archival journals and peer-reviewed conferences proceedings.  The research group will interact with a nuclear technology and services company.  The work will not involve contact with radioactive materials. 

A bachelor’s degree in mechanical or electrical engineering, or a closely related field, and a strong interest in performing research, are required.  US citizenship or permanent residency is also required.  The assistantship will provide University of ÁùºÏ±¦µä, Reno graduate tuition, health benefits, supervision by faculty members, and a stipend of $1600/month for Master students, or $1900/month for Ph.D. students.  Hourly employment for undergraduate students is available, especially for students who are interested in starting graduate studies within a year. For more information, please contact Professors Miles Greiner, Mustafa Hadj Nacer, Yan Wang, and/or JiHwan Yoon.

Ventilation Requirements for Nuclear Material Staging Facility

This work is developing computational fluid dynamics-based models to predict temperatures of heat generating nuclear materials packages within staging facilities. 

A bachelor’s degree in mechanical engineering or a closely related field, and a strong interest in performing research, are required.  US citizenship or permanent residency is also required.  The assistantship will provide University of ÁùºÏ±¦µä, Reno graduate tuition, health benefits, supervision by faculty members, and a stipend of $1600/month for Master students, or $1900/month for Ph.D. students.  Hourly employment for undergraduate students is available, especially for students who are interested in starting graduate studies within a year. For more information, please contact Professors Miles Greiner, and/or Mustafa Hadj Nacer.

UNR Graduate Fellowship in Nuclear Power

The UNR Graduate Fellowship in Nuclear Power funds US citizens and permanent residents, who are interested in working for nuclear industry, national labs, or government agencies, to earn MS and Ph.D. degrees.

Please contact Foundation Professor Miles Greiner, and/or Research Assistant Professor Mustafa Hadj Nacer for information on hourly employment or ME 499 Special Projects.

Nuclear fuel assemblies consist primarily of square arrays of zircaloy cladding tubes that contain uranium dioxide fuel pellets.  The pellets become highly radioactive and produce fission product gases while the assembly is used in a power reactor.  After used nuclear fuel (UNF) assemblies are removed from a reactor, they are stored underwater while their radioactivity and heat generation rates decrease.  The water also shields the surrounding from radiation and controls the fuel temperature.  After sufficient time, assemblies are moved into gas-filled stainless-steel canisters.   The canisters are then placed into thick-walled packages for onsite dry storage, or offsite transport.  During normal storage and transport, the fuel must remain in its original configuration to allow for future processing or repackaging.  The Code of Federal Regulations (10CFR71) also require that transport packages ensure containment, shielding, and criticality safety after a series of hypothetical accident events.  That series consists of a 9-m drop onto an unyielding surface, a 1-m drop onto a puncture bar, 30-minute engulfment in an 800^oC fire, and then water emersion.  A Safety Analysis Report of Packaging (SARP) is prepared for each system to demonstrate by analysis and/or testing that the package will meet all relevant requirements.  Before the system may be used, the SARP must be assess and approved by a regulatory authority.

Nuclear Packaging Program faculty and students are currently developing computational fluid dynamics (CFD) models to predict UNF temperatures in dry storage facilities, and during vacuum drying processes.  They are conducting bench-scale experiments to quantitatively validate these models.  They are also using data acquired by other researchers in actual used nuclear fuel packages to validate their models.  Additionally, they are performing Direct Simulation Monte Carlo (DSMC) calculations to model heat transfer in moist rarefied gases, to better understand and model heat and mass transport during vacuum drying.  We will add links to describe these research investigations.

Nuclear Packaging Program faculty and students are currently developing detailed computational fluid dynamics (CFD) simulation of facilities used to stage large numbers of nuclear materials packages.  The nuclear materials within these packages generate heat, but the temperature of certain package components must not exceed specified limits.  The computational models include the facility ventilation system, and package heat generation, and air flow within the facility.  These models will be used to predict the margin of safety between the package component temperatures and their allowed limits, for a range of ventilation temperatures and flow rates.  This work is being funded by the National Nuclear Security Administration (NNSA).  Opportunities are available for US citizens or permanent resident students to be involvement to be involved in this work. 

In September 2020, the US Nuclear Regulatory Commission announced that it is providing three-years of funding to develop a proof-of-concept platform to measure conditions inside thick stainless-steel walled used nuclear fuel canisters, and safely transmit the data to a receiver outside.  This work will help assure the safety of used nuclear fuel storage and transportation.  The research will develop low-power magnetic resonance signals that can reliably transmit data across the canister lid.  It will also develop and place thermoelectric devices that harvest heat generated by the used fuel to produce electric power.  That energy will power the measurement and signal transmission devices.  Multiple graduate students will work closely with engineering faculty members to perform theoretical, computational, and experimental research and development.  The research group will interact with a nuclear technology and services company.  Opportunities for graduate students are available.

From 2000 to 2008, Dr. Greiner and his students performed large-scale experiments and computational studies of heat transfer to massive objects engulfed in pool fires. This work focused on the interaction between fires, the surrounding wind conditions, and engulfed objects. It has led to an understanding of the thermal radiation properties of fires as well as the accuracy of inverse-conduction techniques used to measure heat flux in fires. Professor Greiner has used this work as a basis to estimate the response of truck- and railcar-sized used nuclear fuel transport packages under severe accident conditions. The DOE and Innovative Technologies Solutions Corporation have funded this work. Based on publications in this area, he received an award for co-authoring the Outstanding Operations, Applications, and Components Technical Paper at the 2003 ASME Pressure Vessel and Piping Conference, and the G.E.O. Widera Literature Award for co-authoring the Outstanding Technical Paper in the 2004 ASME Journal of Pressure Vessel Technology.

From 2011 to 2013, Professor Greiner and his students performed computational fluid dynamics/radiation heat transfer simulations, using the Container Analysis Fire Environment (CAFE). to predict the thermal response of a GA-4 truck cask, assuming it was in proximity to two historic accidental fires.  The GA-4 is licensed by the US Nuclear Regulatory Commission to transport four pressurized water reactor (PWR) used fuel assemblies, based on relevant federal regulations.  The selected fire accidents took place in the Caldicott Highway Tunnel (near Oakland, California) in 1982, and Baltimore’s Howard Street Railroad Tunnel in 2001.  The goal of that work was to evaluate the adequacy of federal regulations to assure that a licensed package would protect the public and the environment during severe accidents.

From 2000 to 2006, the State of ÁùºÏ±¦µä funded Professor Greiner and his students to predict the response of used nuclear fuel transport packages to a range of extra-regulatory fire accident conditions, using the Container Analysis Fire Environment (CAFE) computer code.