Oregon State University Academic Center of Excellence Workshop Thermal Fluids and Heat Transfer at the INL Dr. James R. Wolf, Manager Thermal Fluids &

Slides:

Advertisements

Similar presentations

Generation IV international Forum Overall Mission :

Advertisements

J. R. WOLF RELAP5-3D PROGRAM MANAGER

Office of Nuclear Energy 1May 20, 2013 Property Management Workshop Office of Nuclear Energy Program Perspective Delivering Nuclear Solutions for America's.

Aug 9-10, 2011 Nuclear Energy University Programs Materials: NEAMS Perspective James Peltz, Program Manager, NEAMS Crosscutting Methods and Tools.

Argonne National Laboratory 9700 S. Cass Avenue Argonne, IL  Original name for Argonne – the “Metallurgical Lab”, a code name for Enrico.

Nuclear Energy University Programs NGNP Methods Development August 10, 2011 Hans Gougar.

Nuclear Energy University Programs NGNP Systems Analysis August 10, 2011 Hans Gougar.

Nuclear Energy University Programs Review of the NEUP Program in 2011 Dr. Marsha Lambregts NEUP IO Program Manager.

RELAP5-3D© to Fluent CFD Software Coupling

1 Nuclear Division - GLF FP6 - Proposal for a Specific Targeted Research Project on Innovative Technologies for the Sodium cooled fast Reactor ITSR - FP6.

钍基熔盐核能系统 Safety analysis of graphite core in molten salt test reactor Derek Tsang SINAP

GENERATION III AND III+ NUCLEAR POWER PLANT DESIGNS ACR-1000 (Advanced CANDU Reactor) Dr. Şule Ergün Hacettepe University Department of Nuclear Engineering.

Nuclear Energy University Programs MS-RC1 - Reactor Concepts RD&D August 10, 2011 Christopher Grandy Argonne National Laboratory.

______________________________________________ LECTURE 10 Machines that Store and Transfer Energy Thermodynamics and Energy Conversion ________________________________________.

Nuclear Energy University Programs Advanced Fuels – (FC-2) August 10, 2011 Dr. J. Rory Kennedy Lead, Metallic Fuel Development Technical Area Advanced.

HTTF Analyses Using RELAP5-3D Paul D. Bayless RELAP5 International Users Seminar September 2010.

EERE National Laboratory Impact Initiative: Small Business Vouchers Pilot March, 2015.

September 2005 Director of Education, Training and Research Partnerships Idaho National Laboratory and University Academic Centers of Excellence Andrew.

Nuclear Plant Systems ACADs (08-006) Covered Keywords

High Efficiency UTILITY RESCUE THE MEANS TO ABUNDANT SAFE CLEAN POWER.

Wisconsin Institute of Nuclear Systems Nuclear Engr & Engr Physics, University of Wisconsin - Madison May 2006 Michael Corradini, Chair Nuclear Engineering.

Nuclear Reactors Chapter 4

Investigation into the Viability of a Passively Active Decay Heat Removal System In ALLEGRO Laura Carroll, Graduate Physicist Physics & Licensing Team,

BNFL/Westinghouse’s Perspective on the Nuclear Hydrogen Economy Dr PJA Howarth Head of Group Science Strategy.

EURATOM RESEARCH AND TRAINING ON NUCLEAR ENERGY 1.

Lead Technology Task 6.2 Materials for mechanical pump for HLM reactors M. Tarantino – ENEA Work Package Meeting – ENEA Bologna, November 17th, 2010.

The Nuclear Energy Future John F. Kotek, Deputy Manager Idaho Operations Office U.S. Department of Energy November, 2003 The Government Role in Creating.

Thermal Hydraulic Simulation of a SuperCritical-Water-Cooled Reactor Core Using Flownex F.A.Mngomezulu, P.G.Rousseau, V.Naicker School of Mechanical and.

Types of reactors.

Future perspectives of nuclear energy

3D Coupled Fault Modelling for the Gas- cooled Fast Reactor Jason Dunstall KNOO PhD Student (EPSRC Funded) Applied Modelling and Computation Group (AMCG)

MOLTEN CARBONATE FUEL CELLS ANSALDO FUEL CELLS: Experience & Experimental results Filippo Parodi /Paolo Capobianco (Ansaldo Fuel Cells S.p.A.) Roma, 14th.

Fuel Cell Initiatives Wright Fuel Cell Group Energy for Ohio’s Future.

NGNP Program NGNP Methods: Summary of Approach and Plans Richard R. Schultz.

The Nuclear Reactors from a « Natural History » Perspective Bertrand BARRÉ, AREVA President European Nuclear Society Director ANS Vice-president INSC.

PBNC- 1 Overview of US Nuclear Energy Initiatives /06- 1 Harold McFarlane President American Nuclear Society.

Nuclear Energy University Programs FY 2011 NEUP Request for Pre- Application Submission Demographics.

New studies of innovative systems planned at Research Centre Řež Research Centre Rez – Jan Kysela Innovative nuclear concepts – workshop Liblice Jan

VHTR Modeling and Experimental Validation Studies July 27, 2011 Salt Lake City, UT Richard R. Schultz Idaho National Laboratory.

Nuclear Power Reactors SEMINAR ON NUCLEAR POWER REACTOR.

4/2003 Rev 2 I.4.7 – slide 1 of 48 Session I.4.7 Part I Review of Fundamentals Module 4Sources of Radiation Session 7Nuclear Reactors IAEA Post Graduate.

Priority Programs of the Nuclear Power Industry Branch of Russia Vladimir Asmolov 17 th Symposium of AER on VVER Reactor Physics and Reactor Safety

Development of a RELAP5-3D thermal-hydraulic model for a Gas Cooled Fast Reactor D. Castelliti, C. Parisi, G. M. Galassi, N. Cerullo (San Piero A Grado.

THE FUTURE OF NUCLEAR POWER GREG RAABERG NOVEMBER 24, 2008 The University of Texas at Austin Department of Chemical Engineering ChE 359.

Milestones or Millstones Alex R. Burkart, Deputy Director Office of Nuclear Energy, Safety and Security United States Department of State.

PIME 2004 / Barcelona, Feb. 10, 2004Nuclear Energy Division 1 PIME 2004 plenary session February 10, 2004 – Barcelona Preparing the future : New challenges.

ENERGY FOR THE 21 ST CENTURY the Potential for Nuclear Power Luis Echávarri Director-General, OECD Nuclear Energy Agency IAEA Scientific Forum at the General.

DAVID VAN WAGENER NOVEMBER 26, 2008 CHE 384: TECHNOLOGY REPORT Nuclear Power: Advanced Generations and Outlook.

Future Nuclear Reactors Third and Third-Plus+ Generation Reactors Next Generation is Simpler

Master’s of Engineering Project Fall 2010 Viram Pandya.

Modeling a Turbine with TRACE

DOE ASSET MANAGEMENT PLAN

Slide 1 Author D:/DATA/POWERPNT/Hugon/InnconceptsFP5toFP6 INNOVATIVE CONCEPTS FOR NUCLEAR FISSION ENERGY: FROM FP5 TO FP6 Michel Hugon DG RTD-J-4.

Role of Self-Assessment V.C. Agarwal, Director (HR) NPCIL,INDIA.

J. G. Weisend II for the ESS Team Energy Efficiency & Recovery at ESS.

Project X Workshop - Cryogenics1 Project X CRYOGENICS Arkadiy Klebaner.

Heat Network Demonstration SBRI: policy context & objectives for the competition Natalie Miles Heat Strategy and Policy (Heat Networks)

Experimental and Computational Investigations of Plenum-to-Plenum Heat Transfer and Gas Dynamics Under Natural Circulation in a Prismatic Very High Temperature.

Algirdas Kaliatka, Audrius Grazevicius, Eugenijus Uspuras

Panel Discussion: Discussion on Trends in Multi-Physics Simulation

Demonstration of Small Scale Solar Gas Turbine

IAEA International Conference on Fifty Years of Nuclear Power – The next Fifty Years Moscow - Obninsk, Russian Federation - June 28, 2004 Nuclear.

Collaborative Research in

Nuclear James F. Stubbins, Professor and Head

DOE Nuclear Safety Research and Development Program

Idaho National Laboratory Community College Partnerships

Nuclear Hydrogen Production Program in the U.S.

Status of the INL High-Temperature Electrolysis Research Program

The Fuel Cycle Analysis Toolbox

Conceptual design of the Cryogenic System of Comprehensive Research Facility for Key Fusion Reactor Core Systems Liangbing Hu Sep.4.

Presentation transcript:

Oregon State University Academic Center of Excellence Workshop Thermal Fluids and Heat Transfer at the INL Dr. James R. Wolf, Manager Thermal Fluids & Heat Transfer Dept. September 19, 2005

Outline Collaboration between INL and the Thermal Hydraulic Academic Center of Excellence Very High Temperature Reactor INL Thermal hydraulic Capabilities and Programs Summary

DOE’s Nuclear Energy Program Increase the Productivity of Currently-Installed US Nuclear Power Plants Minimize the Risks and Stimulate New Construction of Generation III Nuclear Power Plants (NP-2010) Develop and Demonstrate Next-Generation Advanced Rector Systems (Generation IV, Nuclear Hydrogen) Develop and Demonstrate Advanced, Proliferation- Resistant, Fuel Cycle Technology to Support a Future Secretarial Decision on US Long-Term Waste Disposition Policy Support a Healthy University and Laboratory Educational and Research Infrastructure to Ensure the Long-Term Supply of Trained Nuclear Professionals and Advanced Technology.

Need for Collaboration Limited resources require close collaboration between Universities and the INL –Capital –Intellectual –Personnel Existing resources must be leveraged in the most efficient and effective manner possible. –Government –Industry –University

Academic Centers of Excellence Battelle Energy Alliance (BEA) has chosen to implement DOE’s support through a number of different programs –The Academic Centers of Excellence (ACE). Oregon State University is the thermal hydraulics ACE –University Nuclear Energy Research Initiatives Programs (UNERI) –International Nuclear Energy Research Initiatives (INERI) –Nuclear Engineering Education Research Program (NEER) –INL Laboratory Directed Research and Development Programs (LDRD) University and INL partnerships are a key part of the Laboratory and DOE’s future nuclear strategy

University Collaborations Each organization has its own strengths that must be emphasized and capitalized on in future collaborations Where there is value added, joint INL/University funding proposals to government and private organizations will provide a synergistic benefit to – Expand current INL programs and scope VHTR Other Gen IV concepts LDRD –Jointly secure new scope and funding Nuclear industry vendors and utilities UNERI and NEER proposals Other DOE program funding Other government agency funding INL involvement in University contracts and projects

University Collaborations (cont.) Joint university and INL collaboration makes a powerful team for winning competitive solicitations.

Thermal Hydraulic Areas of Emphasis at INL Advanced reactor methods development and applications Nuclear reactor system safety code development and applications Other analytical thermal hydraulic programs Experimental studies

VHTR R&D Plan National Energy Policy divides the VHTR into two phases –Phase 1, now through 2011 when vendor designs are submitted –Phase 2, 2011 through 2021 covers actual design and construction of selected concept An R&D Program Plan encompassing validation, experiments, and further code development has been developed –R&D Plan looks several years into the future –Budgets fluid –Plan and budgets includes both thermal hydraulics and neutronic methods development activities

Thermal Hydraulic Aspects of the R&D Plan The foundation for a thermal-hydraulic systems analysis capability directed specifically toward the VHTR has been under development for three years at the INEEL. This has resulted in the coupled RELAP5- 3D/FLUENT code. RELAP5-3D provides a system-wide analysis capability and FLUENT provides the CFD capability. While the basic physical models in RELAP5-3D have been extensively validated for light water reactors, its applicability to the VHTR design must be demonstrated.

RELAP5-3D Modeling Features Single or two-phase flow 1-, 2-, or 3- dimensional flow networks Reactor kinetics – 1-, 2-, or 3-dimensional nodal kinetics model Heat Transfer – conduction, convection, radiation Components – pump, compressor, turbine, valves, phase- separators, accumulators, jet-mixers, and pressurizers Process models – critical flow, abrupt area change, form loss, phase separation at tees Control systems Graphical user interface Multiple fluids Coupling capability to other codes such as CFD through the PVM Executive

RELAP5-3D Working Fluids Heavy water Hydrogen Carbon Dioxide Helium Nitrogen Lithium Light water Molten Salt HeXe Sodium Potassium Lead-Bismuth NaK Lithium-Lead Ammonia SCW Different fluids can exist in thermally-coupled loops

Core Upper Plenum Lower Plenum Balance Of Plant FLUENT model RELAP5-3D model RELAP5-3D Coupled to FLUENT For Detailed Analysis of Lower Plenum Flow Patterns

GT MHTGR Fluent Calculation

GEN IV Advanced Reactor Concepts Supported at INL Very High Temperature Gas Reactor Super Critical Water Reactor Molten Salt Gas Fast Reactor Liquid Metal

Other INL Thermal Hydraulic Analytical Programs Basic RELAP5-3D Code Development and Applications Development of a Super Critical Carbon Dioxide Bray ton Cycle: Improving PBR Efficiency and Materials testing capability (NERI) Development of Safety Analysis Codes and Experimental Validation for a Very High Temperature Gas Cooled Reactor (K- INERI) Advanced Computational Thermal Fluid Physics Assessments (K- INERI) RELAP5 Appendix K Development (INER Taiwan) Maple Reactor Analysis ATR Gas Test Loop International RELAP5 Users Group LDRD programs with Oregon State University and MIT

Experimental Activities Matched Index of Refraction Flow Loop used for VHTR Studies May St. Thermal Sciences laboratory –High temperature oxide fuel cell testing for hydrogen production –Enhanced heat transfer studies using nano particles

MIR Lower Plenum Test Section Lower plenum experimental design completed for mixed- index of refraction (MIR) experiment

High Temperature Electrolysis

A Six-Cell High Temperature Electrolysis Stack Operated at 850  C Under Test for >1100 Hours Produced 32 Normal Liters/Hour at Nearly 45% Net Efficiency

Summary INL involved in a wide range of thermal hydraulic related programs and activities In today’s climate, collaboration between INL universities and industry through organizations such as the Oregon State Academic Center of Excellence is a necessity Numerous possibilities for collaboration on INL and university programs