This document contains a long list of links to various organizations related to criticality safety, including: the American Nuclear Society, US Department of Energy, US Nuclear Regulatory Commission, national laboratories involved in criticality safety (LLNL, LANL, ORNL), universities offering criticality safety courses, criticality safety code developers, US nuclear sites, international regulators and laboratories, commercial nuclear companies, standards organizations, and more.
Dr. Hugh C. DeLong presents an overview of his program, Complex Materials and Devices, at the AFOSR 2013 Spring Review. At this review, Program Officers from AFOSR Technical Divisions will present briefings that highlight basic research programs beneficial to the Air Force.
As part of our efforts to develop a public platform to provide access to predictive models we have attempted to disentangle the influence of the quality versus quantity of data available to develop and validate QSAR models. Using a thorough manual review of the data underlying the well-known EPI Suite software, we developed automated processes for the validation of the data using a KNIME workflow. This includes: approaches to validate different chemical structure representations (e.g. molfile and SMILES), identifiers (chemical names and registry numbers), and methods to standardize the data into QSAR-consumable formats for modeling. Our efforts to quantify and segregate data into various quality categories has allowed us to thoroughly investigate the resulting models developed from these data slices, as well as allowing us to examine whether or not efforts into the development of large high-quality datasets has the expected pay-off in terms of prediction performance. Machine-learning approaches have been applied to create a series of models that have been used to generate predicted physicochemical and environmental parameters for over 700,000 chemicals. These data are available online via the EPA’s iCSS Chemistry Dashboard. This abstract does not reflect U.S. EPA policy.
Dr. Hugh C. DeLong presents an overview of his program, Complex Materials and Devices, at the AFOSR 2013 Spring Review. At this review, Program Officers from AFOSR Technical Divisions will present briefings that highlight basic research programs beneficial to the Air Force.
As part of our efforts to develop a public platform to provide access to predictive models we have attempted to disentangle the influence of the quality versus quantity of data available to develop and validate QSAR models. Using a thorough manual review of the data underlying the well-known EPI Suite software, we developed automated processes for the validation of the data using a KNIME workflow. This includes: approaches to validate different chemical structure representations (e.g. molfile and SMILES), identifiers (chemical names and registry numbers), and methods to standardize the data into QSAR-consumable formats for modeling. Our efforts to quantify and segregate data into various quality categories has allowed us to thoroughly investigate the resulting models developed from these data slices, as well as allowing us to examine whether or not efforts into the development of large high-quality datasets has the expected pay-off in terms of prediction performance. Machine-learning approaches have been applied to create a series of models that have been used to generate predicted physicochemical and environmental parameters for over 700,000 chemicals. These data are available online via the EPA’s iCSS Chemistry Dashboard. This abstract does not reflect U.S. EPA policy.
Accelerators at ORNL - Application Readiness, Early Science, and Industry Impactinside-BigData.com
In this deck from the 2014 HPC User Forum in Seattle, John A. Turner from Oak Ridge National Laboratory presents: Accelerators at ORNL - Application Readiness, Early Science, and Industry Impact.
Chris Myers, VP of Energy Programs for Lockheed Martin, presented at the GW Solar Institute Symposium on April 19, 2010. More information at solar.gwu.edu/Symposium.html
APPENDICES California Energy Commission 500-2013-134-APPENDIXESFranco Moriconi
APPENDIX A: Zenergy Power HTS FCL Test Plan APPENDIX B: Zenergy Power HTS FCL Laboratory Test APPENDIX C: Zenergy Power HTS FCL Dielectric and HV Tests
APPENDIX D: Zenergy Power HTS FCL Normal State Temperature Rise Test
APPENDIX E: Zenergy Power HTS FCL Short Circuit Test APPENDIX F: Zenergy Power HTS FCL High Voltage Field Test
APPENDIX G: Zenergy Power HTS FCL Operation Manual APPENDIX H: Zenergy Power HTS FCL Cryostat Evacuation and Moisture Removal Procedure
APPENDIX I: Zenergy Power HTS FCL Liquid Nitrogen Fill Procedure
Emerging Hazards: Renewables and Microgrids, U.S. Department of Energy, Energ...AEI / Affiliated Engineers
AEI / Affiliated Engineers presents the Energy Systems Integration Facility, a 182,500 square foot building that provides laboratory and research space for 200 scientists and staff working on promising clean energy technologies and testing their interaction with each other and the grid. Specific areas of research include:
• Smart grids, power electronics.
• Solar: interconnection, parabolic solar concentrators, building integration, and system optimization.
• Buildings: sensors and controls, systems integration, modeling, and Zero Energy Building simulation.
• Hydrogen: electrical interfaces, electrolyzers, storage, quality standards, fueling systems, fuel cell integration.
• Wind: models, generation, and grid interaction, electrical grid analysis.
• Vehicles: grid connected plug-in and vehicle-to-grid electrical integration, battery thermal management, and power electronics.
• Biofuels: generator sets and engines.
• Energy storage: electrical, mechanical, and thermal.
• Microturbines.
AEI’s work included the design of:
• Research Electrical Distribution Bus (REDB): A first-of-its-kind, the REBD is a power integration circuit made up of two AC and two DC ring buses that interconnects testing components across the building’s 15 laboratories. Researchers can test new energy technologies on real and simulated power systems.
• Supervisory Control and Data Acquisition (SCADA) System: Integrated throughout the facility, the SCADA monitors and controls the REDB operations and gathers real-time, high-resolution data for collaboration and visualization. The SCADA also monitors SIL-2 (Safety Integrity Level) rated laboratory PLCs providing emergency stop functionality, gas detection, alarming (horns and lights), and other required safety measures. These systems are all interconnected with the fire alarm, building automation system, and local lab equipment to provide a seamless facility response across systems to various conditions.
Data Con LA 2022 - Air Quality Analytic Center Framework (AQACF)Data Con LA
Jason Kang, Software Engineer, NASA-JPL
* Develop an Analytic Center Framework (ACF) for Air Quality in support of the NASA AIST air quality technology innovation effort, Air Quality Analytics Center Framework (AQACF) * Harmonize air quality data sets, models, and algorithms to facilitate analysis and projections of air quality across those sources. * Demonstrate analysis application area will focus on air pollution in large cities (e.g., Los Angeles) * Generalize framework to facilitate analyses for air quality applications more broadly Coordinate with other AIST-18 efforts including GEOS-Chem, GCHP, Predicting What We Breathe, etc.
More Related Content
Similar to Helpful Links in the Nuclear Complex - from Justin
Accelerators at ORNL - Application Readiness, Early Science, and Industry Impactinside-BigData.com
In this deck from the 2014 HPC User Forum in Seattle, John A. Turner from Oak Ridge National Laboratory presents: Accelerators at ORNL - Application Readiness, Early Science, and Industry Impact.
Chris Myers, VP of Energy Programs for Lockheed Martin, presented at the GW Solar Institute Symposium on April 19, 2010. More information at solar.gwu.edu/Symposium.html
APPENDICES California Energy Commission 500-2013-134-APPENDIXESFranco Moriconi
APPENDIX A: Zenergy Power HTS FCL Test Plan APPENDIX B: Zenergy Power HTS FCL Laboratory Test APPENDIX C: Zenergy Power HTS FCL Dielectric and HV Tests
APPENDIX D: Zenergy Power HTS FCL Normal State Temperature Rise Test
APPENDIX E: Zenergy Power HTS FCL Short Circuit Test APPENDIX F: Zenergy Power HTS FCL High Voltage Field Test
APPENDIX G: Zenergy Power HTS FCL Operation Manual APPENDIX H: Zenergy Power HTS FCL Cryostat Evacuation and Moisture Removal Procedure
APPENDIX I: Zenergy Power HTS FCL Liquid Nitrogen Fill Procedure
Emerging Hazards: Renewables and Microgrids, U.S. Department of Energy, Energ...AEI / Affiliated Engineers
AEI / Affiliated Engineers presents the Energy Systems Integration Facility, a 182,500 square foot building that provides laboratory and research space for 200 scientists and staff working on promising clean energy technologies and testing their interaction with each other and the grid. Specific areas of research include:
• Smart grids, power electronics.
• Solar: interconnection, parabolic solar concentrators, building integration, and system optimization.
• Buildings: sensors and controls, systems integration, modeling, and Zero Energy Building simulation.
• Hydrogen: electrical interfaces, electrolyzers, storage, quality standards, fueling systems, fuel cell integration.
• Wind: models, generation, and grid interaction, electrical grid analysis.
• Vehicles: grid connected plug-in and vehicle-to-grid electrical integration, battery thermal management, and power electronics.
• Biofuels: generator sets and engines.
• Energy storage: electrical, mechanical, and thermal.
• Microturbines.
AEI’s work included the design of:
• Research Electrical Distribution Bus (REDB): A first-of-its-kind, the REBD is a power integration circuit made up of two AC and two DC ring buses that interconnects testing components across the building’s 15 laboratories. Researchers can test new energy technologies on real and simulated power systems.
• Supervisory Control and Data Acquisition (SCADA) System: Integrated throughout the facility, the SCADA monitors and controls the REDB operations and gathers real-time, high-resolution data for collaboration and visualization. The SCADA also monitors SIL-2 (Safety Integrity Level) rated laboratory PLCs providing emergency stop functionality, gas detection, alarming (horns and lights), and other required safety measures. These systems are all interconnected with the fire alarm, building automation system, and local lab equipment to provide a seamless facility response across systems to various conditions.
Data Con LA 2022 - Air Quality Analytic Center Framework (AQACF)Data Con LA
Jason Kang, Software Engineer, NASA-JPL
* Develop an Analytic Center Framework (ACF) for Air Quality in support of the NASA AIST air quality technology innovation effort, Air Quality Analytics Center Framework (AQACF) * Harmonize air quality data sets, models, and algorithms to facilitate analysis and projections of air quality across those sources. * Demonstrate analysis application area will focus on air pollution in large cities (e.g., Los Angeles) * Generalize framework to facilitate analyses for air quality applications more broadly Coordinate with other AIST-18 efforts including GEOS-Chem, GCHP, Predicting What We Breathe, etc.
Similar to Helpful Links in the Nuclear Complex - from Justin (20)
Data Con LA 2022 - Air Quality Analytic Center Framework (AQACF)
Helpful Links in the Nuclear Complex - from Justin
1. American Nuclear Society Links
ANS Main Web Page
ANS Criticality Safety Division
ANSI/ANS Standards
US Department of Energy Links
DOE Main Web Page
DOE Criticality Safety Division
Nuclear Criticality Safety Program Group
DOE Standards
DOE Field Reports
Occurrence Reporting and Processing System (ORPS)
Occurrence Reporting and Processing System (ORPS) Database Access
DOE Defense Programs
DOE Environment, Safety, and Health
DOE Albuquerque Operations Office
DOE Chicago Operations Office
DOE Grand Junction Projects Office
DOE Idaho Operations Office
DOE Livermore/Oakland Operations Office
DOE Nevada Operations Office
DOE Oakland Operations Office
DOE Oak Ridge Operations Office
DOE Ohio Field Office
DOE Richland Operations Office
DOE Rocky Flats Field Office
DOE Savannah River Operations Office
US Defense Nuclear Facilities Safety Board
US Nuclear Regulatory Commission Links
Main Web Page
NRC Criticality Safety Division
Regulatory Guides
NUREG Technical Reports
NRC Daily Event Reports
NRC Performance Reviews
2. NRC Public Electronic Reading Room
NRC Search Page
NRC Standard Review Plan
Status of NRC Criticality Safety Rules
International Criticality Safety Benchmark Evaluation Project (ICSBEP)
Lawrence Livermore National Lab Criticality Safety Page
Los Alamos National Lab Criticality Safety Page
Oak Ridge National Lab Criticality Safety Page
Criticality Safety Courses
Los Alamos National Lab Criticality Safety Courses
University of New Mexico Short Course
University of Tennessee Courses
Criticality Safety Code Links
Radiation Safety Information Computational Center
Standized Computer Analysis for Licensing Evaluations (SCALE)/KENO
KENO-3D
MCNP
Links to US DOE National Labs and Sites with Criticality Safety Interests
Argonne National Labs
Argonne National Labs - West
Bettis Atomic Power Lab
3. Brookhaven National Laboratory
Fernald Environmental Management Project
Hanford Site
Idaho National Engineering and Environmental Lab
Knolls Atomic Power Lab
Los Alamos National Lab
Lawrence Livermore National Lab
Miamisburg Environmental Management Project (Mound Plant)
National Nuclear Data Center
Oak Ridge National Lab
Pacific Northwest National Lab
Pantex Plant
Rocky Flats Environmental Technology Site
Sandia National Labs
Savannah River Site
Waste Isolation Pilot Plant
Yucca Mountain Project
Links to Other US DOE National Labs and Sites
Ames Laboratory
Advanced Computing Laboratory
Fast Flux Test Facility
Fermi National Accelerator Laboratory
High Flux Isotope Reactor
Kansas City Plant
Lawrence Berkeley National Lab
National Renewal Energy Lab
Naval Petroleum/Shale Reserves
Nevada Test Site
New Brunswich Laboratory
Office of Civilian Radioactive Waste Management
Princeton Plasma Physics Lab
Stanford Linear Accelerator Center
Strategic Petroleum Reserves
Thomas Jefferson National Accelerator Facility
US Commerical Nuclear Fuel Fabricators Links
BWX Technologies (Lynchburg, Virginia)
Framatome-Cogema Fuels (Lynchburg, Virginia)
Nuclear Fuel Services (Erwin, Tennessee)
4. Paducah Gaseous Diffusion Plant
Portsmouth Gaseous Diffusion Plant
Atomic Vapor Laser Isotope Separation Project
Links to Significant US Companies Dealing With Criticality Safety Not Listed
Above
(Listing herein does not imply any particular quality of work.)
Duke Engineering & Services
Fluor Daniel
General Atomics
Mohr and Associates
NISYS Corporation
Nuclear Safety Associates, Inc.
Science Applications International Corporation
Westinghouse Safety Management Solutions
Your Company Missing? Email us to Add You to the List
International Regulator Links
International Atomic Energy Agency
Japanese Office of Science and Technology
International National Labs Links
Japan Nuclear Cycle Development Institute
International Uranium Enrichment/Conversion and Fuel Fabrication Facilities
Links
AEA Technologies - United Kingdom
British Nuclear Fuels, plc - United Kingdom
5. Non-Regulator Agencies Links
Electric Power Research Institute
Nuclear Energy Institute
OECD Nuclear Energy Agency
Other Standards Organization Links
American National Standards Institute
International Organization for Standardization
American Society of Mechanical Engineers
International Society for Measurement and Control
American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc.
(ASHRAE)
Society of Manufacturing Engineers
Institute of Electrical and Electronics Engineers
Society of Fire Protection Engineers
Society for Industrial and Applied Mathematics
American Society for Nondestructive Testing
Human Factors and Ergonomics Society
Standards Engineering Society
US Code of Federal Regulations Online
Federation of American Scientists
FAS Main Page
Nuclear Facilities Guide