INT9176 INTERREGIONAL WORKSHOP

IAEA Approach to the Safety Case and Safety Assessment for Predisposal Management of Disused Sealed Radioactive Sources and Radioactive Waste INT9176 INTERREGIONAL WORKSHOP Application of the IAEA Methodology and SAFRAN Tool for the Safety Case and Safety Assessment for Predisposal Management of DSRS Monika Kinker, WES/NSRW

INT9176 “Mediterranean Project” Objectives • Improved capacities and capabilities for the cradle to grave management of SRS • Staff of RBs & DSRS management organizations trained in … SA methodologies and tools Key Activities Implemented: Safety Demonstration • Implementation in SAFRAN Tool of a Generic SC & SA for Predisposal Management of DSRS • Provision of Assistance in the development of SC and SA for DSRS end of life management options • Original MSs : Slovenia, Croatia, Albania, Bosnia and Herzegovina, Cyprus, Greece, Malta, Montenegro, Turkey, Lebanon, Egypt, Libya, Morocco, Tunisia. • Joined the project in 2012: Ghana, Tanzania, Nigeria, Jordan, and The Frmr.YugRep. of Macedonia • Did not join yet, but invited: Algeria, Israel, Syria

Waste Management at the IAEA • Department of Nuclear Safety and Security • Nuclear Installation Safety • Radiation, Transport and Waste Safety • Waste and Environmental Safety Section • Department of Nuclear Energy • Nuclear Power • Nuclear Fuel Cycle andWaste Technology • Waste Technology Section overview of safety standards

Activities of the Division • Safety Standards Development • Support for International Conventions • Joint Convention, Code of Conduct • Application of Standards: • Information Exchange (e.g. Conferences, workshops, meetings, ...) • Technical Cooperation • Training & Education • Appraisals, Peer Reviews overview of safety standards 4

Vision for the IAEA Safety Standards Outcome: • A harmonized high level of protection for people and the environment worldwide based on the IAEA safety standards as the global reference Output: • Global reference for protecting people and the environment from harmful effects of ionizing radiation. • Integrated, comprehensive and consistent • Up-to-date, user friendly, fit-for-purpose and high quality • Provide for a worldwide harmonized high level of protection for people and the environment from harmful effects of ionizing radiation.

Strategies • Clear categories of safety standards consistent with Member States’ needs and use • Clear, logical and integrated structure based on a unified philosophy of safety • Consensus at the highest level on what constitutes a high level of safety and the related best international practices • Transparency and rigour of the process • Effective feedback mechanisms • User - friendliness • Manageable number of safety standards • Clear scope: areas covered and level of detail • Harmonized terminology

Safety Requirements Safety Standards Categories Fundamental Safety Principles Requirements – Legal, Technical, & Procedural Safety Imperatives Safety Fundamentals Guidance on Best Practice to Meet Requirements Safety Guides

overview of safety standards SafetyRequirements Safety Fundamentals • Policy document of the IAEA Safety Standards Series: • States the basic objectives, concepts and principles involved in ensuring protection and safety • Comprised of 10 safety principles • Principle 7: Protection of present and future generations. People and the environment, present and future, must be protected against radiation risks Safety Fundamentals SafetyGuides

overview of safety standards Safety Requirements Safety Requirements • Elaborate on the basic objectives and concepts of SF-1 as they apply to a specific activity or facility • Should be concise and reflect the ‘What’ and ‘Who’ of safety management  associated explanatory text should describe ‘Why’ the requirements exist • Use “shall” statements Safety Fundamentals SafetyGuides

overview of safety standards SafetyRequirements Safety Guides • Focus on ‘How’ safety requirements can be met • Guidance on best practices to meet requirements • Use “should” statements Safety Fundamentals Safety Guides

Status of Safety Standards • IAEA Safety standards are • Binding for IAEA’s own activities • Not binding on the Member States (but may be adopted by them) EXCEPT in relation to operations assisted by the IAEA: • Integrated Regulatory Review Service • Technical Cooperation Fund work • States wishing to enter into project agreements with the IAEA overview of safety standards

Commission on Safety Standards (CSS) Nuclear Safety Standards Committee (NUSSC) Radiation Safety Standards Committee (RASSC) Waste Safety Standards Committee (WASSC) Transport Safety Standards Committee (TRANSSC) Development of Safety Standards Outline and work plan Prepared by the Secretariat Review by the SafetyStandardsCommittees and the Commission on Safety Standards Drafting or revising of safety standard by the Secretariat and Consultants Review by the Safety Standards Committee(s) Member States Endorsement by Commission on Safety Standards * Safety Requirements approved by BoG * Safety Guides approved by DG Approvalby the IAEA’s Director General or BoG * Review period: about every 5 years overview of safety standards

Currentstatusofdevelopment of IAEA SafetyRequirements 2010 Under development Under development Published in 2011-12 Published in 2011 Under development 2009 Under development 2009 Published in 2011 Under development Published in 2012 Under development

Life Cycle of a Radiation Source

Issues in Long Term management of DSRS Waste or Resource? • Disused Source: “a radioactive source which is no longer used, and is not intended to be used, for the practice for which an authorization has been granted” (Code of Conduct) • Radioactive Waste: “Radioactive material in gaseous, liquid or solid form for which no further use is foreseen…, and which is controlled as radioactive waste by a regulatory body under the legislative and regulatory framework …” (Joint Convention)

Disused sources in the Safety Standards

DSRS Long Term Management Options • Return to Commercial Suppliers • Return to Country of Origin (Repatriation) • Reuse/Recycle • Storage at User Facility • Storage in Dedicated (“Centralized”) Facility • Decay to clearance levels iaw national regulations • Interim storage pending future actions • Long Term (between 50 and 100 yr) • Disposal

Why Storage is not a Sustainable Management Strategy • Not a sustainable option in the long-term • On-going financial liabilities • Poor or no regulatory control in certain countries • Limited expertise or capacity for managing sources • Institutional and social stability • Potential health and environmental hazard • Safety, Security concerns

Disposal Options • Disposal at Landfill • Near-surface Repository Disposal • (with and without engineered barriers) including underground cavities (natural or engineered) at relatively shallow depths • Geological Repository Disposal • Borehole Disposal Co-disposal might be an option e.g. NSR & BDC

Factors Affecting Choice of Disposal Option • Nature of the waste (activity, half-life, toxicity) • Quantity and location(volume, where is it?) • Site Characteristics (nature of the rock, water flow & chemistry, stability) • Preferences concerning repository design and nature of engineered barriers • Other Factors (national policy and strategy, availability of resources, stakeholder consensus)

Sustainable Management Requires: • Adequate Legal and Regulatory Framework • National Policy, Strategies that consider • Existing, future inventories • COMPLETE lifecycle • Adequate Resources and Infrastructure (technical, human, financial) • Regulatory Body with well defined responsibilities and functions • Authorization through process of licensing 21

RWM Licensing, Authorization in the Safety Standards 2010 2013 22

IAEA Requirements for RWSafety Case, Safety Assessment … • GSR Part 5, GSG-3: Safety Case • A collection of arguments and evidence in support of the safety of a facility or activity. This will normally include the findings of a safety assessment and a statement of confidence in these findings. • GSR Part 4 , GSG-3: Safety Assessment 1. Assessment of all aspects of a practice that are relevant to protection and safety; includes siting, design & operation of the facility. This normally includes risk assessment and probabilistic SA. 2. Analysis to predict the performance of an overall system and its impact, where the performance measure is the radiological impact or some other global measure of the impact on safety.

GSG-3: Safety Guide • Demonstrating the Safety of RWM • Safety Case • Role, Components, Documentation and Use • Safety Assessment • Approach, Scenarios, Models, Analysis of Results • Specific Issues • SC evolution, graded approach, DID, facility lifetime, LTS • Regulatory Review Process Annex I Examples of Hazards and Initiating Events Annex II Topical Issues for Review of SC Annex III Template of Regulatory Review Report Annex IV SADRWMSProject Proposal to June 2010 WASSC -> CRAFT NEW!!!

GSG-3: Guidance on the SC and SA Safety Assessment Radiological Impact Scenarios Models Calculations Management System Non radiological environmentalimpact Operational Safety Site and Engineering Safety Case Safety Assessment 25

Elements of Safety Case: GSG-3 • INCLUDES: Context; safety strategy; facility description; safety assessment; limits, controls and conditions (LCOs); iteration and design optimization; uncertainty management; integration of safety arguments • NOT SPECIFIED but implied: criticality, radiation, hazardous material, surveillance & maintenance, emergency preparedness and response, decommissioning, management systems, interface with LCOs from other facilities (e.g., waste acceptance criteria)

CRAFT (Complimentary Safety Reports: Development and Application to Waste Management Facilities) • 4 Year Project • 1st Plenary May 2011 • 2nd, 3rd Plenaries 2012, 2013 • Final Plenary October 2014 • Objectives: • APPLY GSG-3, SADRWMS methodology, SAFRAN Tool • PROVIDE a forum for application of the methodology and SAFRAN tool • DEVELOP, document TECDOCs illustrating application of GSG-3 • Facility/process specific • Safety Case Process/Regulatory Review

SADRWMS ProjectSafety Assessment Driving Radioactive Waste Management Solutions Long-term Project • 1st Plenary Meeting in 2003 • Final Plenary in 2010 Objectives: 1. EXAMINE the application of safety assessment methodology (ISAM, ASAM) 2. DEVELOP, document • Safety Assessment Methodology • Regulatory Review • ---> GSG-3 3. INTEGRATE methodology into software tool (SAFRAN)

CRAFT Working Methods • Radon Type Facility Application Case • develop illustrative test case(s) for applying the IAEA methodology/tools to RADON type facilities (basis: RW retrieval activity at Murmansk RADON); • Storage and Processing Facility • Apply IAEA methodology/tools to facilities for the storage and processing of RW • Central Storage Facility in Slovenia, • Waste Processing Facility in Serbia, • LTS Facility in Cuba • Regulatory Interactions • Apply IAEA methodology/tools in regulatory review of WG application cases, and provide recommendations

Generic Safety Assessment (GSA) • A SA undertaken on a site-generic rather than site-specific basis using a synthetic system • Can provide useful input to decisions concerning a variety of issues: • suitable designs, site characteristics & activity limits • Use of the GSA • Starting point for the SA of a specific site • Worked example that can be used to guide/inform a site-specific assessment • Identify key waste and site attributes that need to be characterised

Concluding Remarks Although valuable RWM experience has been collected worldwide, we are all still learning This week is a good change for exchange of experiences between participants We are looking for intensive and open discussion! Try to use the presence of this group of experts from different countries to get maximal benefit for your project! overview of safety standards

Thank you!

INT9176 INTERREGIONAL WORKSHOP