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* Chapter 6.0 -Engineered Safety Features Construction Permit Application for Radioisotope Production Facility Prepared by: NWMl-2013-021, Rev. 2 August 2017 Northwest Medical Isotopes , LLC 815 NW gth Ave , Suite 256 Corvallis, OR 97330 This page intentionally left blank.   

* NORTHWEST MEDICAL ISOTOPES NWMl-2013-021 , Rev. 2 Chap t er 6.0 -Engineered Safety Features Chapter 6.0 -Engineered Safety Features Construction Permit Application for Radioisotope Production Facility NWMl-2013-021 , Rev. 2 Date Published:

August 5 , 2017 Document Number. NWMl-2013-021 Revision Number. 2 Title: Chapter 6.0 -Engineered Safety Features Construction Permit Application for Radioisotope Production Facility Approved by: Carolyn Haass Si nature: C UAJ"rr'--(_

Rev Date 0 6/29/2015 1 6/26/2017 2 8/5/2017 NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features REVISION HISTORY Reason for Revision Revised By Initial Application Not required Incorporate changes based on responses to C. Haass NRC Requests for Additional Information Modification based on ACRS comments C. Haass   

* NORllfWHT M£DfCA.L ISOTOP£S NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features CONTENTS 6.0 ENGINEERED SAFETY FEATURES .................................................................................

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............................ 6-11 6.2.1.4 Confinement Components  

..................... 6-13 6.2.1. 7 Derived Confinement Items Relied on for Safety ................

............ 6-13 6.2.1.8 Dis so l ver Off gas Systems ...................................................

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........... 6-26 6.2.1.11 Radio active Relea se Monitoring  

.............................. 6-27 6.3 Nuclear Criticality Safety in the Radioi sotope Production Facility ................................ 6-28 6.3. l Criticality Safety Contr ol s ...........

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6-36 6.3.1.2 Derived Nuclear Criticality Safety Items Relied on for Safety ........ 6-59 6.3.2 Surveillance Requirements  

........ 6-6 Ground Level Confinement Boundary ...........................

6-8 Mecham cal Level Confinement Boundary ............................

6-9 Lower Level Confinement Boundary ............

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.......... 6-10 Dissolver Offgas System Engineered Safety Features ..............

6-14 Dissolver Off gas Hot Cell Equipment Location ......................

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.......... 6-15 Proposed Location of Double-Wall Piping (Example)  

Double-Contingency Controls .............

.............. 6-43 [Proprietary Information]

Double-Contingency Controls (3 pages) ............................ 6-53 [Proprietary Information]

.............. 6-57 6-ii TERMS NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Acronyms and Abbreviations 99 Mo 23s u ADUN AEC ANECF ANS ANSI CAAS CFR CSE DBE HEGA HEPA HVAC IEU IX IROFS Kr LEU MCNP Mo N0 2 NO x NRC NWMI PEC PHA RPF SSC SPL UN [Proprietary Information]

USL Xe molybdenum-99 uranium-235 acid-deficient uranium nitrate active engineered control average neutron energy causing fission American Nuclear Society American National Standards Institute criticality accident alarm system Code of Federal Regulations criticality safety evaluation design basis earthquake high-efficiency gas adsorber high-efficiency particulate air heating, ventilation , and air conditioning intermediate-enriched uranium ion exchange item relied on for safety krypton low-enriched uranium Monte-Carlo N-Particle molybdenum nitrogen dioxide nitrogen oxide U.S. Nuclear Regulatory Commission Northwest Medical Isotopes, LLC passive engineered control preliminary hazards analysis radioisotope production facility structures, systems, and components single parameter limit uranium nitride [Proprietary Information]

* NCMmfWEST MEDfCAl ISOTOPES Units o c o p atm cm cm 3 ft ft 2 ft 3 g hr in. L m m 2 mm mL mo) rad wt% yr degrees Celsius degrees Fahrenheit atmosphere centimeter cubic centimeter feet square feet cubic feet gram hour inch liter meter square meter minute milliliter mole radiation absorbed do se weight percent yea r 6-iv NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features "NWMI ..**.. .. .. .......... *

* NORTHWEST MEOICAl lSOTOf'£S NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features 6.0 ENGINEERED SAFETY FEATURES 6.1  

 

==SUMMARY==

DESCRIPTION Engineered safety features are active or passive features designed to mitigate the consequences of accidents and to keep radiological exposures to workers , the public , and environment within acceptable values. The engineered safety features associated with confinement of the process radionuclides and hazardous chemicals for the Northwest Medical Isotopes , LLC (NWMI) Radioisotope Production Facility (RPF) are summarized in Table 6-1 , including the accidents mitigated; structures , systems , and components (SSC) used to provide the engineered safet y features; and references to subsequent sections providing a more detailed engineered safety feature description. Confinement is a general engineered safety feature that is credited as being in place as part of the preliminary hazards analysis (PHA) described in Chapter 13.0, "Accident Analysis." Additional items relied on for safety (IROFS) associated with the confinement s y stem were derived from the accident analyses in Chapter 13.0. The derived IROFS are also listed in Table 6-1 , with reference to more detailed descriptions in Section 6.2.1. The current design approach does not anticipate requiring containment or an emergency cooling system as engineered safety features , a s discussed in Sections 6.2.2 and 6.2.3. Nuclear criticalit y safety is discussed in Section 6.3. Criticality safety controls are described in Section 6.3 .1. The currently defined criticalit y safety controls are derived from a combination of preliminar y criticality safety evaluations (CSE) and accident analyses , which are described in Chapter 13.0. The criticality safety analyses produce a set of features needed to satisfy the contingency requirements for nuclear criticality control. These features are evaluated by major systems within the RPF and listed by major system in Section 6.3.1.1 , Table 6-6 through Table 6-13. The accident analyses in Chapter 13.0 identify IROFS for the prevention of nuclear criticality , which are summarized in Table 6-2, with reference to more detailed descriptions in Section 6.3.1.2. 6-1   

* Hazardous chemical spi lls

* Confinement enclosures including penetration seals Zone I exhaust ventilation system, including ducting, filters, and exhaust stack

* Zone I inlet ventilation system, including ducting, filters , and bubble-tight isolation dampers

* Berms Confinement IROFS Derived from Accident Analyses and Potential Technical Specifications Primary offgas relief RS-09 Dissolver offgas failure . Pressure relief device system during dissolution . Pressure relief tank operation Active radiation RS-10 Transfer ofhigh-dose Radiation monitoring and isolation monitoring and process liquid outside the system for low-dose liquid isolation of low-hot cell shielding transfers dose waste transfer boundary Cask local RS-13 Target cladding leakage Local capture ventilation system ventilation during during shipment over closure lid during lid removal closure lid removal and docking preparation s Cask docking port RS-15 Cask not engaged in cask Sensor system controlling cask enabler docking port prior to docking port door operation opening docking port door Process vessel FS-03 SSC damage due to Backup bottled nitrogen gas emergency purge h y drogen deflagration or supply system detonation Irradiated target FS-04 Dislodging the target . Cask lifting fixture design that cask lifting fixture cask shield plug while prevents cask tipping workers present during

* Cask lifting fixture design that target unloading prevents lift from toppling activities during a seismic event 6-2 6.2.1.1 through 6.2.1.6 6.2.1. 7.1 6.2.1.7.2 6.2.1.7.3 6.2.1.7.4 6.2.1.7.5 6.2.1.7.6 NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features Table 6-1. Summary of Confinement Engineered Safety Features (2 pages) Detailed Engineered safety SSCs providing engineered description feature IROFS Accident(s) mitigated safety features section Exhaust stack height FS-05 . Equipment . Zone I exhaust stack 6.2.1.7.7 malfunction resulting in liquid spi ll or spray . Carbon bed fire Double-wall piping CS-09 Solution spill in facility Double-wall piping for selected 6.2.1.7.7 area where spill transfer lines containment berm is neither practical nor desirable for personnel chemical protection purposes Backflow CS-1 8 High worker exposure Backflow prevention devices 6.2.1.7.9 prevention devices from backflow of high-located on process lin es crossing Safe geometry day CS-1 9 dose solution the hot cell shielding boundary tanks Dissolver offgas . Potential limiting Dissolver offgas iodine removal 6.2.1.8 iodine removal unit* control for operation units (DS-SB-600A/B/C) . Primary iodine control system during normal operation Dissolver offgas . Potential limitin g Dissolver offgas primary adsorbe r 6.2.1.8.2 primary adsorber* control for operation units (DS-SB-620A/B

/C) . Primary noble gas control system during normal operation Dissolver offgas . Potential limiting . Dissolver offgas vacuum 6.2.1.8.3 vacuum receiver or control for operation receiver tanks (DS-TK-700A/B) vacuum pump* . Motive force for . Dissolver offgas vacuum pumps dissolver offgas (DS-P-71 OA/B)

* Examples of candidate technical specification rather than e n g ineered safety feature. lR OFS item relied on for safet y. SSC = structur e s , systems , and components. Table 6-2. Summary of Criticality Engineered Safety Features (2 pages) Engineered safety feature Interaction control spacing provided by passively de signe d fixtures and workstatio n placem ent Pencil tank, vessel, or piping safe geometry confinement using the diameter of tanks, vessels, or piping Pencil tank geometry contro l on fixed interaction spacing of individual tanks SSC features providing engineered safety features CS-04 Defines spacing between SSC components using geo metr y to prevent nuclear critica lity CS-06 Defines dimen s ions ofSSCs using geometry to prevent nuclear criticality CS-07 Defines spacing between different SSCs using geometry to prevent nucl ear criticality 6-3 * *

* NOfOlfWUT M£D.cAl ISOTOl'(S NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Table 6-2. Summary of Criticality Engineered Safety Features (2 pages) Engineered safety feature Floor and sump geometry control on slab depth, and sump diameter or depth for floor dikes Double-wall piping Closed safe-geometry heating or cooling loop with monitoring and alarm Simple overflow to normally empty safe-geometry tank with level alarm Condensing pot or seal pot in ventilation vent line Simple overflow to normally empty safe geometry floor with level alarm in the hot cell containment boundary Active discharge monitoring and isolation Independent active discharge monitoring and isolation Backflow prevention device Safe geometry day tanks Evaporator or concentrator condensate monitoring Processing component safe volume confinement Closed heating or cooling loop with monitoring and alarm IROFS item relied on for safety. SSC features providing engineered safety features -*

* CS-08 Defines sump geometry and dimensions for SSCs 6.3.1.2.4 using geometry to prevent nuclear criticality CS-0 9 Defines transfer line leak confinement in 6.3.1.2.5 locations where sumps under piping are neither feasible nor desirable CS-10 Closed-loop heat transfer fluid systems to 6.3.1.2.6 prevent nuclear criticality or transfer ofhigh-dose material across shielding boundary in the event of a leak into the heat transfer fluid CS-11 Overflow to prevent nuclear criticality from 6.3.1.2. 7 fissile solution entering non-geometrically favorable ventilation equipment CS-12 Seal pots to prevent nuclear criticality from 6.3.1.2.8 fissile solution entering non-geometrically favorable ventilation equipment CS-13 Overflow to prevent nuclear criticality from 6.3.1.2.9 fissile solution entering non-geometrically favorable ventilation equipment CS-14 Information to be provided in the Operating 6.3.1.2.10 License Application CS-15 Information will be provided in the Operating 6.3.1.2.11 License Application CS-18 Backflow prevention to preclude fissile or high 6.3.1.2.12 dose solution from crossing shielding boundary to non-geometrically favorable chemical supply tanks and prevent nuclear criticality CS-19 Alternate backflow prevention device 6.3.1.2.13 CS-20 Prevent nuclear criticality from high-volume 6.3.1.2.14 transfer to non-geometrically favorable vessels in solutions with normally low fissile component concentrations CS-26 Defines volume of SSCs to prevent nuclear 6.3.1.2.15 criticality CS-27 Closed-loop, high-volume heat transfer fluid 6.3.1.2.16 systems to prevent nuclear criticality or transfer of high-dose material across shielding boundary in the event of a leak into the heat transfer fluid with normally low fissile component concentrations SSC = structures , systems , and components. 6-4   

.... ; NWMI *::**:*:* ...... * . NORTKW£$T M£DtCAl ISOTOPES NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features 6.2 DETAILED DESCRIPTIONS The PHA used to identify accidents in Chapter 13.0 , Section 13.1.3, assumed the following known and credited safety features, or IROFS , are in place for normal operations:  

* Hot cell s hielding boundary, credited for shielding workers and the public from direct exposure to radiation (a normal hazard of the operation)

Hot cell confinement boundaries , credited for confining the fissile and high-dose solids , liquids , and gases , and controlling gaseous releases to the environment Administrative and passive design features on uranium batch , vo lume , geometry, and interaction controls on the activities, credited for maintaining normal operations involving the handling of fissile material subcritical (the PHA identified initiators for abnormal operations that require further evaluation for IROFS satisfying the double-contingency principle)

This section provides detailed descriptions of the engineered safety features identified by the accident analyses shown in Chapter 13.0. 6.2.1 Confinement The PHA was based on a definition for confinement, as follows: Confinement  

A confinement s hould include the capability to maintain sufficient internal negative pressure to ensure inleakage (i.e., prevent uncontrolled leakage outside the confined area), but need not be capable of supporting positive internal pressure or significantly shielding the external environment from internal sources of direct radiation.

Air movement in a confinement area could be integrated into the heating , venti lation , and air conditioning (HV AC) systems, including exhaust stacks or vents to the external environment , filters , blowers , and dampers (ANSI/ ANS-1 5.1, Th e Development of Techni cal Specifications for R esearch R eac tors). Confinement describes the low-leakage boundary surrounding radioactive or hazardous chemical materials released during an accident to facility regions surrounding the physical process equipment c ontaining process materials.

The confinement systems localize releases of radioactive or hazardou s materials to controlled area s and mitigate the consequences of accidents.

The principal design and safety objective of the confinement system is to protect on-site workers , the public , and environment.

Per s onnel protection control features (e.g., adequate shielding and ventilation control) will minimize hazards normally associated with radioactive or chemical materials.

T he second design objective is to minimize the reliance on administrative or complex active engineering controls and provide a confinement system that is as simple and fail-safe as reasonably possible.

This subsection describes the confinement systems for the RPF. The RPF confinement areas will consist of hot cell and glovebox enclosures housing process operations , tanks , and piping. Confinement will be provided by a combination of the enclosure boundaries (e.g., walls, floor , and ceiling), enclosure ventilation, and ventilation control system. The enc lo sure boundaries will restrict bulk quantities of process materials , potentially present in solid or liquid forms , to the confinement and limit in-leakage of gaseous components controlled by the ventilation system. The venti l ation and ventilation control systems will restrict the gaseous components (including gas phase components and solid/liquid dispersions) to the confinement.

Figure 6-1 provides a simp lifi ed schematic of the confinement ventilation system, which is described in more detail as the Zone I ventilation system in Chapter 9.0 , "A uxiliary Systems." 6-5 NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

-O 1 3 , System Design D esc ription for Ventilation, R ev. A, Northwest Medical Isotope s, LLC, Corvallis , Oregon, March 2015. Figure 6-1. Simplified Zone I Ventilation Schematic 6-6   

* NOllTifWEST MEDtCAl ISOTOPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features A typical glovebox enclosure is shown in Figure 6-1, and the inlet does not have an automatic closure on the isolation damper. During development of the final safety analysis and Operating License Application, each glovebox will be evaluated based on inventory of concern (e.g., fission product gases) and hazards to determine if the inlet isolation damper is required to be an IROFS confinement control. Until the analysis is complete , the design of gloveboxes will include a bubble-tight isolation damper, as required , for the hot cells. The enclosure boundary of the hot cells will also function as biological shielding for operating personnel.

Shielding functions of the hot cells are discussed in Chapter 4.0, "Radioisotope Production Facility Description." Hazardous chemical confinement will be provided by berms located within the RPF to confine spilled material to the vicinity where a spill may originate.

6.2.1.1 Confinement System Confinement system enclosure structures , ventilation ducting, isolation dampers, and Zone I exhaust filter trains are designated as IROFS. Table 6-3 provides a description of the system component safety functions.

Figure 6-2, Figure 6-3, and Figure 6-4 indicate the general location of confinement structure boundaries to the facility ground level, mechanical level , and lower level layouts, respectively.

The confinement system is an engineered safety feature that performs the functions identified by IROFS RS-01, RS-03, and RS-04 in Chapter 13.0. Table 6-3. Confinement System Safety Functions System , structure, component Zone I enclosure inlet isolation dampers and ducting l eading from isolation dampers to enclosures Zone I enclosure exhaust ducting leading from enclosures to the exhaust stack, filters, and exhaust stack Process vessel vent exhaust ducting leading from process vessel s to Zone I exhaust plenum Ventilation control system Secondary iodine removal bed Hot cells, tank vaults, and glovebox enclosure structures IROFS = item relied on for s afet y. Description Provide confinement isolation at Zone I/Zone II enclosure boundaries Provides confinement to the confinement exhaust boundary Provides confinement to the confinement exhaust boundary Provides stack monitoring and interlocks to monitor discharge and signal changing on service filter trains during normal and abnormal operation Mitigates a release of the iodine inventory in the dissolver offgas treatment system Provide solid, liquid, gas confinement 6-7 Classification IROFS IROFS IROFS IROFS IROFS IROFS NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

Source: Figure 2-1 ofNWMI-2015-SDD-O 13 , Sy s t e m D e si gn D esc ription for Ventila ti o n , R ev. A , Northwest Medical I so topes , LLC, Corvallis , Oregon, March 20 15. Figure 6-2. Ground Level Confinement Boundary 6-8 NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietar y Inf o rmation] So ur ce: F i gu re 2-2 of NWMl-20 1 5-S DD-O 1 3, Syst e m D e s i g n Descriptio n for Ventilatio n , R ev. A, Nort h west M e di cal I so t o p es , LLC , Co r va lli s, Orego n , M arc h 2015. Figure 6-3. Mechanical Level Confinement Boundary 6-9 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietar y Information]

So urc e: Figure 2-3 ofNWMI-20 I 5-SDD-01 3, System D es i gn D esc ription for Ventilation , Rev. A , Northwest Medical I so top es , LLC , Corva lli s , Oregon , March 2015. Figure 6-4. Lower Level Confinement Boundary During normal operation, passive confinement is provided by the contiguous boundary between the hazardous materials and the surrounding environment and is credited with confining the hazards generated as a result of accident scenarios.

The intent of the passive boundary is to confine hazardous materials while also preventing di stur bance of the hazardous material inventory by external energy sources. Tills passive confinement boundary extends from the isolation valve downstream of the intake high-efficiency particulate air (HEPA) filter to the exhaust stack. An event that results in a release of process material to a confinement enclosure will be confined by the enclosure structural components.

The backflow prevention devices on piping penetrating the confinement boundary are designed as passive devices and will be located as near as practical to the confinement boundary or take a position that provides greater safety on loss of actuating power. The consequences of an uncontrolled release within a confinement enclosure, and the off-site consequences ofreleasing fission products through the vent ilation system, will be mitigated by use of an active component in the form of bubble-tight isolation dampers as IROFS on the inlet ventilation ducting to each enclosure. Tills engineered safety feature reduces the ducting to the confinement volume that needs to remain intact to achieve enclosure confinement.

The dampers will close automatically (fail-closed) on los s of power, and the ventilation system will automatically be placed into the passive ventilation operating mode. Overall performance assurance of the active confinement components will be achieved through factory testing and in-place testing. Duct and housing leak tests will be performed in accordance with minimum acceptance criteria, as specifie d in ASME AG-I , Cod e on Nuclear Air and Gas Tr e atment. Specific owner requirements with respect to acceptable leak rates will be based on the safety analysis.

Passive confinement will be achieved through a continuous boundary between the hazardous materials and the surrounding area. In the event of an accidental release, the hazardous liquid will be confined to limit the exposed surface area of the liquid. 6.2.1.2 Accidents Mitigated The hot cell confinement system and shielding boundary are credited as being in place by the accident analysis in Chapter 13.0, Section 13.1.3.1.

The confinement system is also credited with mitigating the impact of a non-specific initiating event resulting in release of the iodine inventory in the dissolver off gas treatment system. 6.2.1.3 Functional Requirements Functional requirements of the confinement structural components include: *

* Capturing and containing liquid or solid releases to prevent the material from exiting the boundary and causing high dose to a worker or member of the public or producing significant environment contamination Preventing spills or sprays of radioactive solution that are acidic or caustic from causing adverse exposure to personnel through direct contact with skin, eyes , and mucus membranes where the combination of chemical exposure and radiological contamination would lead to serious injury and Jong-lasting effects Functional requirements of the confinement ventilation components include: * *

* Providing negative air pressure in the hot cell (Zone I) relative to lower zones outside of the hot cell using exhaust fans equipped with HEPA filters and high-efficiency gas adsorbers (HEGA) to reduce the release of radionuclides (both particulate and gaseous) outside the primary confinement boundary to below Title 10 , Code of Federal Regulations, Part 20 , "Standards for Protection Against Radiation" (10 CFR 20) release limits during normal and abnormal operations.

Mitigating high-dose radionuclide releases to maintain exposure to acceptable levels to workers and the public in a highly reliable and avai l able manner. The hot cell secondary confinement boundary will perform this function using a system of passive and active engineered features to ensure a high level of reliability and availability. Removing iodine isotopes present in the process vessel vent under accident conditions to comply with 10 CFR 70.61 , " Performance Requirements

," for an intermediate consequence release. Berms confining potential hazardous chemical spills are designed to hold the entire contents of the container in the event the container fails. 6.2.1.4 Confinement Components The following components are associated with the confinement barriers of the hot cells , tank vaults , and gloveboxes.

The specific materials , construction , installation , and operating requirements of these components are evaluated based on the safety analysis.

* NORTHWlST MEDICAL ISOTOPES N W M l-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Confinement structural components include the following.  

Sumps of appropriate de s ign will be provided with remote operated pumps to mitigate liquid spills by capturing the liquid in appropriate geometry tanks. In the molybdenum-99 (99 Mo) purification clean room, smaller confinement catch basins will be provided under points of credible spill potential in addition to the sealed floor. Entryway doors into a designated liquid confinement area will be sealed against credible liquid leaks to outside the boundary.

* Zone I inlet HEPA filters will provide an efficiency of greater than 99.9 percent for removal of radiological particulates from the air that may reverse flow from Zone I to Zone II. Zone I ducting will ensure that negative air pressure can be maintained by conveying exhaust air to the stack. Bubble-tight dampers will be provided to comply with the requirements of ASME AG-I, Section DA-5141. Ventilation ductwork and ductwork support materials will meet the requirements of ASME AG-1. Supports will be designed and fabricated in accordance with the requirements of ASME AG-1. Zone I exhaust train HEPA filters will provide an efficiency of greater than 99.95 percent for removal of radiological particulates from the air that flows to the stack. Zone I exhaust train HEGA filters will provide an efficiency of greater than 90% for removal of iodine. The Zone I exhaust stack will provide dispersion of radionuclides in normal and abnormal releases at a discharge point of 23 meters (m) (75 feet [ft]) above the building ground level. Stack monitoring and interlocks will monitor discharge and signal changing of service filter trains during normal and abnormal operations.

* NORTHWEST MEDICAL ISOTOPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.2.1.6 Design Basis Codes and standards are discu s sed in Chapter 3.0, "Design of Structures , Systems , and Components

." The design bases for Zone I and Zone II ventilation systems are described in Chapter 9.0. The design basis of confinement enclosure structures is described in Chapter 4.0. Chapter 7.0 , "Instrumentation and Control Systems ," identifies the engineered safety feature-related design basis of the ventilation control system. The following information was developed for the Construction Permit Application to describe the process off gas secondary iodine removal bed: * * * * *

Potential variables , conditions , or other items that will be probable subjects of a technical specification associated with the RPF confinement systems and components are discussed in Chapter 14.0, "Technical Specifications

6.2.1.7.1 IROFS RS-09, Primary Offgas Relief System IROFS RS-09 , "Primary Offgas Relief System," is identified by the accident analysis in Chapter 13.0. As an active engineered control (AEC), the primary off gas relief system will be a component included in the off gas train for the two irradiated target dissolvers. The dissolver off gas system is intended to operate at a pressure that is less than the confinement enclosures to maintain gaseous components generated during dissolution within the vessels and route the gaseous components through the offgas treatment unit operations.

.. NWMI ...*.. ..* .... ......... *.* * *.*. ." NORTHW£ST MEDfCAl ISOTOPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Figure 6-5 is a diagram of the dissolver off gas system process, which shows the pressure relief tank position in the off gas treatment equipment train. Figure 6-6 shows the location of the pressure relief tank within the RPF hot cell (identified as " pressure relief'). [Proprietary Information]

* NORTHWEST MEDICAL lSOTWU NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

Figure 6-6. Dissolver Offgas Hot Cell Equipment Location The pressure relief tank will be evacuated to a specified , subatmospheric pressure prior to initiating dissolution of a target batch and selected valves (indicated as 2 , 3 , and 4 on Figure 6-5) closed. Valve I will be open during normal dissolver operation.

An upset during the dissolver operation (e.g., Joss of vacuum pump operation) will result in closing Valve I and opening Valve 2 to contain dissolver off gas within the dissolver and off gas vessels. Due to the short duration of dissolver operation, dissolution is assumed to go to completion independent of an off gas system upset. The pressure relief tank will contain the offgas as dissolution is completed.

Valves 3 , 4 , and 5 are provided for upset recovery.

After correction of the upset cause, gases collected in the pressure relief tank will be routed to the downstream treatment unit operations via Valve 3 or returned to a caustic scrubber via Val v e 4. Liquid condensed in the pressure relief tank as a result of activation will be routed to the dissolver offgas liquid waste collection tank via Valve 5 for disposal.

The non-condensable gas volume to the pressure relief tank is equivalent to all nitrogen oxide (NO x) generated by dissolution, plus the sweep gas flow for flammable hydrogen gas mitigation.

dissolved is used . No credit is taken for reaction ofN0 2 with water to produce nitric acid . Dissolver gas additions, other than the minimum sweep gas flow for hydrogen mitigation, are terminated by the pressure relief event. Gas contained by the pressure relief tank and associated dissolver off gas piping is saturated with water vapor. The pressure change from [Proprietary Information], absolute activates the pressure relief tank . Additional detailed information on the pressure relief tank design basis will be developed for the Operating License Application.

Test Requirements The above analysis is based on information developed for the Construction Permit Application. Additional detailed information on test requirements will be developed for the Operating License Application. 6-16   

...... !* NORTHWEST MEDICAL lSOTOPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.2.1.7.2 IROFS RS-10, Active Radiation Monitoring and Isolation of Low-Dose Waste Transfer IROFS RS-10, " Active Radiation Monitoring and Isolation of Low-Dose Waste Transfer," is identified by the accident analyses described in Chapter 13.0. As an AEC, the recirculating stream and the discharge stream of the \ow-dose waste tank will be simultaneously monitored in a background shielded trunk outside of the hot cell shielded cavity. The continuous gamma instrument will monitor the transfer lines to provide an open permissive signal to dedicated isolation valves. Accident Mitigated Transfer of high-dose process liquid solutions outside the hot cell shielding boundary System Components Additional detailed information of the radiation monitor and isolation oflow-dose waste transfers will be developed for the Operating License Application.

," is identified by the accident analyses described in Chapter 13.0. As an AEC , a local capture ventilation system will be used over the irradiated target cask closure lid to remove any escaped gases from the worker breathing zone during removal of the closure lid, removal of the shielding block bolts, and installation of the lifting lugs. Accident Mitigated

* Irradiated target cladding fails during transportation , releasing gaseous radionuclides within the cask containment boundary System Components  

* Use a dedicated evacuation hood over the top of the cask during containment closure lid removal Remove gases to the Zone I secondary confinement s y stem for processing 6-17 NWM I ......

Test Requirements The above analysis is based on information developed for the Construction Permit Applicat io n. Additional detailed information on test requirements will be developed for the Operating License Application.

6.2.1.7.4 IROFS RS-15, Cask Docking Port Enabling Sensor IROFS RS-15, "Cask Docking Port Enabling Sensor ," is identified by the accident analyses described in Chapter 13.0. As an AEC , the cask docking port will be equipped with sensors that detect when a cask is mated with the cask docking port door. Accident Mitigated

* Prevent the cask docking port door from being opened and allowing a streaming radiation path to areas accessible by workers Design Basis Detailed information on the system design basis will be developed for the Operating License Application. Test Requirements The above analysis is based on information developed for the Construction Permit Application.

6-18 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.2.1.7.5 IROFS FS-03, Process Vessel Emergency Purge System IROFS FS-03, " Process Vessel Emergency Purge System," is identified by the accident analyses described in Chapter 13.0. Hydrogen gas will be evolved from process solutions through radiolytic decomposition of water in the high radiation fields. An air purge to the vapor space of selected tanks will be provided by the facility air compressors to control the hydrogen concentration from radiolysis in vessel vapor space to below the flammability limit for hydrogen.

As an AEC, an emergency backup set of bottled nitrogen gas will be provided for all tanks that have the potential to evolve s ignificant volumes of hydrogen gas through the radiolytic decomposition of water (in both a short-and long-term storage condition).

* Monitor the purge pressure going into the individual tanks and open an isolation valve on low pressure (se tpoint to be determined) to restore the continuous sweep of the system using nitrogen Provide sweep gas sufficient for the facility to allow repair of a compressed gas system outage Activate by sensing low pressure on the normal swee p air system, introducing a continuous purge of nitrogen from a reliable emergency backup station of bottled nitrogen into each affected vessel near the bottom (e.g., through a liquid level detection leg) of the vessel Dilute hydrogen as it rises to the top of the vessel and is vented to the respective vent system Additional detailed information on the process vessel emergency purge system design basis will be developed for the Operating License Application. Test Requirements The above analysis is based on information developed for the Construction Permit Application.

6.2.1. 7.6 IROFS FS-04, Irradiated Target Cask Lifting Fixture IROFS FS-04, "Irradiated Target Cask Lifting Fixture," is identified by the accident analyses described in Chapter 13.0. As a passive engineered control (PEC), the irradiated target cask lifting fixture will be designed to prevent the cask from tipping within the fixture and the fixture itself from toppling during a seismic event. 6-19 Accident Mitigated NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Dislodged irradiated target shipping cask shield plug in the presence of workers during target unloading activities System Components Detailed information on the system components will be developed for the Operating License Application.

Functional Requirements Detailed information on the system functional requirements will be developed for the Operating License Application. Design Basis Detailed information on the system design basis will be developed for the Operating License Application.

Test Requirements The above analysis is based on information developed for the Construction Permit Application. Additional detailed information on test requirements will be developed for the Operating License Application.

6.2.1.7.7 IROFS FS-05, Exhaust Stack Height IROFS FS-05 , " Exhaust Stack Height ," is identified by the accident analyses described in Chapter 13.0. Accidents Mitigated Process solution spills and sprays Carbon bed fire System Component Zone I exhaust stack Functional Requirement

6-20 6.2.1. 7.8 IROFS CS-09, Double Wall Piping IROFS CS-09 , "Doub l e Wall Piping," is identified by the accident analyses in Chapter 13.0. This IROFS has both a confinement and nuclear criticality prevention function.

As a PEC, the piping system conveying fissile solution between credited confinement locations will be provided with a double-wall barrier to contain any spills that may occur from the primary confinement NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

Figure 6-7 provides an example location where IROFS CS-09 will be applied (e.g., the transfer line between the recycle uranium decay tanks and the [Proprietary Information]). Accident Mitigated Leak in piping that passes between confinement enclosures System Components The following double-wall piping segments are identified at this time: * *

NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features 6.2.1.7.9 IROFS CS-18, Back.flow Prevention Devices, and IROFS CS-19, Safe-Geometry Day Tanks IROFS CS-18, "Backflow Prevention Devices ," and IROFS CS-19, "Safe-Geometry Day Tanks ," are identified by the accident analyses in Chapter 13.0. As a PEC or AEC, chemical and gas addition ports to fissile process solution systems will enter a confinement enclosure through a backflow prevention device. Backflow prevention devices and safe-geometry day tanks will provide alternatives for preventing process addition backflow across confinement boundaries.

The device may be an anti-siphon break, an overloop seal, or other active engineering feature that addresses the conditions of backflow and prevents fissile solution from entering non-safe geometry systems or high-dose solutions from exiting the hot cell shielding boundary in an uncontrolled manner. Therefore , these IROFSs have both a confinement and a nuclear criticality prevention function. Accident Mitigated Backflow of process material located inside a confinement boundary to vessel located outside confinement via connected piping due to process upset. System Components System component information will be provided in the Operating License Application.

Additional detailed information on test requirements will be developed for the Operating License Application. 6-22 6.2.1.8 Dissolver Offgas Systems 6.2.1.8.1 Dissolver Offgas Iodine Removal Unit NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Feat u res A significant fraction of iodine entering the RPF in targets is projected to be released to dissolver off gas during target dissolution.

The dissolver offgas iodine removal units will be included in the RPF as the primary SSCs for controlling the release of iodine isotopes to the environment or facility areas occupied by workers. Components of the dissolver off gas system, beginning with the iodine removal unit, will also be used to treat vent gas from the target disassembly system. Target disassembly vent gas is treated by dissolver offgas components for the Construction Application Permit configuration as a measure to mitigate the unverified potential for a release of fission gas radionuclides during target transportation.

Figure 6-5 (Section 6.2.1. 7.1) shows the iodine removal unit position in the off gas treatment equipment train. The dissolver offgas iodine removal unit location in the facility is shown in Figure 6-6 (identified as "p rimary fission gas treatment"). Accidents Mitigated Projected limiting control for operation Required for normal operation and not for accident mitigation System Components Iodine removal unit A (DS-SB-600A)

Functional Requirement Remove iodine isotopes from the dissolver off gas during normal operations such that the dose to workers complies with 10 CFR 20.1201, " Occupational Dose Limits for Adults," and the dose to the public complies with 10 CFR 20.1301, "Dose Limits for Individual Members of the Public." Design Basis The following information was developed for the Construction Permit Application describing each individual iodin e removal unit:

Nominal sorbent b ed operating temperature of [Proprietary Information]

Nominal sorbent bed depth of [Proprietary Information], providing iodine removal capacity of greater than 1 year (yr). Additional detailed information on the iodine removal unit design basi s will be developed for the Operating License Application. Test Requirements The above analysis is based on information developed for the Construction Permit Application.

.; .. NWMI ...*.. .. .. ... NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features * * *

* NORTifWUT MEDtCAL ISOTOP£S 6.2.1.8.2 Dissolver Offgas Primary Adsorber Noble gases (krypton [Kr] and xenon [Xe]) entering the RPF in targets are projected to be released to dissolver off gas during target dissolution.

The dissolver offgas primary adsorber units will be included in the RPF as the primary SSCs for controlling the release of noble gas isotopes to the environment or facility areas occupied by workers. Components of the dissolver off gas system will also be used to treat vent gas from the target disassembly system. Target disassembly vent gas is treated by dissolver offgas components for the Construction Application Permit configuration as a measure to mitigate the unverified potential for a release of fission gas radionuclides during target transportation. Figure 6-5 (Section 6.2.1. 7.1) shows the primary adsorber position in the off gas treatment equipment train. The dissolver off gas primary adsorber location in the facilit y is shown in Figure 6-6 (identified as " primary fission gas treatment").

Nominal superficial gas flow v elocity of [Proprietary Information]

Delay time for release of Xe isotopes of 10 days and Kr isotopes of 8 hours (hr) (additional dela y time is provided by the secondary adsorber)

6.2.1.9 Exhaust System The ventilation exhaust system is described in Chapter 9.0 , Section 9.1.2. Additional detailed information will be developed for the Operating License Application, including:  

* Describing changes in operating conditions in response to potential accidents and the mitigation of accident radiological consequences Demonstrating how dispersion or distribution of contaminated air to the environment or occupied spaces is controlled Identifying the design bases for location and operating characteristics of the exhaust stacks 6.2.1.10 Effluent Monitoring System Each RPF exhaust stack will include an effluent monitoring system. The monitoring system sample lines are designed to comply with ANSI N13.1, Sampling and Monitoring Releases of Airborne Radioactive Substances from the Stacks and Ducts of Nuclear Fa c iliti e s. Additional detailed information on the effluent monitoring systems will be developed for the Operating License Application.

6.2.1.11 Radioactive Release Monitoring The effluent monitoring system will provide flow rate , temperature , and composition inputs for dispersion modeling of releases from the exhaust stacks. These inputs will provide the capability for calculating potential exposures as a basis for actions to ensure that the public is protected during both normal operation and accident conditions.

This information will compare the radiological exposures to the facility staff and the public with and without the confinement system engineered safety feature. The comparison will be based on analyses showing airflow rates , reduction in quantities of airborne radioactive material by filter systems, system isolation, and other parameters that demonstrate the effectiveness of the system. 6-26 NWM I ...... NORTHWEST MEOICAl ISOTOPES NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features 6.2.2 Containment Containment for the RPF is defined based on NUREG-1537, Guidelines for Preparing and Reviewing Applications for the Licensing of Non-Power Reactors -Format and Content, Part 1 interim staff guidance.

A potential scenario for such a release cou ld be a significant loss of integrity of the radioisotope extraction system or the irradiated fuel processing system. The containment is designed to control the release to the environment of airborne radioactive material that is released in the facility even if the a cc ident is accompanied by a pressure surge or steam release. The NUREG-1537 Part 1 interim staff guidance has been applied to the RPF target processing systems. The current accident analysis described in Cha pter 13.0 has not identified a need for a containment system as an engineered safety feature. 6.2.3 Emergency Cooling System An emergency cooling system for the RPF is defined by NUREG-153 7 Part 1 interim staff guidance.

Jn th e event of the loss of any required primary or normal cooling system , an emergency cooling system may be required to remove decay heat from the fuel to prevent the failur e or degradation of the gas management system , the isotope extraction system , or the irradiat e d fuel processing syst e m. An eva luation of RPF cooling requirements provided in Chapter 5.0, "Coo lant Systems," indicates that an emergency cooling system will not be required to avoid rupture of the primary process vessels. In addition, the current accident analysis described in Chapter 13.0 ha s not identified a need for an emergency cooling system as an engineered safety feature. 6-27   

..... ;. NWMI ...... .. .. ........ *. * ." NORTHWEST MEDICAL ISOTOPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.3 NUCLEAR CRITICALITY SAFETY IN THE RADIOISOTOPE PRODUCTION FACILITY The RPF design will provide adequate protection against criticalit y hazards related to the storage, handling, and processing of SNM outside a reactor. This is accomplished by: * *

* Including equipment, facilities, and procedures to protect health and minimize danger to life or property Ensuring that the design provides for criticality control , including adherence to the double-contingency principle Incorporating a criticality monitoring and alarm system into the facility design For the Construction Permit Application , the design has assumed that a nuclear criticality accident is a high-consequence event independent of whether shielding or other isolation is available between the source of radiation and facility personnel.

The nuclear criticality safety program defines the programmatic elements that work in concert to maintain criticality controls throughout the operating li fe of the RPF. The nuclear criticality safety program and facility design are developed based on the following American National Standards Institute/ American Nuclear Society (ANSI/ANS) standards , with exceptions described in U.S. Nuclear Regulatory Commission (NRC) Regulatory Guide 3.71, Nuclear Criticality Safety Standards for Fuels and Material Facilities.  

* ANSI/ ANS-8.1 , N uclear Criti c ality Safety in Operations with Fissionable Materials Outside Reactors ANSI/ ANS-8.3 , Criticality Ac c ident Alarm S y st e m ANSI/ ANS-8. 7 , N ucl e ar Criti c ality Safety in the Storage of Fissile Materials ANSI/ ANS-8.10, Criteria for N uclear Criticality Safety Controls in Operations With Shielding and Corifinement ANSI/ ANS-8.19 , Administrative Practices for Nuclear Criticality Saf e ty ANSI/ ANS-8.20 , N ucl e ar Criti c ality Safety Training ANSI/ ANS-8.22 , Nucl e ar Criticality Safety Based on Limiting and Controlling Mod e rators ANSI/ ANS-8.23 , N uclear Criti c ality A c cid e nt Emerg e nc y Planning and Response ANSI/ ANS-8.24 , Validation of Neutron Transport Methods for Nucl e ar Criticality Saf e ty Calculations ANSI/ ANS-8.26 , Criticality Safety Engineer Training and Qualification Program For the Construction Permit Application, no deviations from standards or requirements have been identified that would require development of equivalent requirements for the RPF. NWMI commits to the following standards and guides during design and construction:

* ANSI/ ANS-8.1 -Nuclear criticality safety practices, including administrative practices , technical practices, and validation of a calculational method 6-28 NWM I ...... *.

* NOf!iTHWE.ST MEIMCAL ISOTOPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features * * * * * *

; the standard is used as modified by NRC Regulatory Guide 3.71 ANSI/ ANS-8.19 -NWMI nuclear criticality safety program development as it applies to organization, administration, roles, and responsibilities ANSI/ ANS-8.20 -Nuclear criticality safety staff and contractor qualification and training procedure development ANSI/ ANS-8.24 -Validation of a calculational method NUREG-1520, Standard R ev i ew Plan for the Review of a License Application for a Fuel Cycle Facility -Guidance for meeting 10 CFR 70.61 NUREG/CR-4604, Statistical Methods for Nuclear Material Management

* Operating procedures and maintenance work Criticality safety postings Fissile material container labeling , storage, and transport Criticality safety nonconformance response Criticality safety configuration control Criticality detector and alarm system Criticality safety guidelines for firefighting Emergency preparedness plan and procedures Components of the nuclear criticality safety program specifica ll y implemented during the design and construction phases of the RPF will include: Nuclear criticality safety program policy Nuclear criticality safety program procedure Nuclear critica lit y safety evaluation procedure Nuclear criticality safety technica l/peer review procedure

Responsibilities This element describes the responsibilities of management and staff in implementing the nuclear criticality safety program. 6-29 NWMI *::**:*:* ...... * *

* NORTHWHT MEDCAL ISOTOPfS NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features * * * * *

* General facility management will ensure that the nuclear safety function is as independent as practical from the facility operating functions. A Nuclear Criticality Safety Manager will be assigned and responsible for overall coordination, maintenance, and management of the nuclear criticality safety program. A Criticality Safety Representative will be assigned who is qualified to interpret criticality safety requirements and serve as a liaison between custodians of fissionable material and other operations, advising operating personnel and supervisors on questions concerning conformance to criticality safety requirements.

Qualified Criticality Safety Engineers will responsible for performing criticality analyses and evaluations of systems, maintaining current verified and validated criticality computer codes, advising staff on technical aspects of criticality controls, and supporting/participating in inspections and management assessments.

Operations management will be responsible for establishing the respon si bility for criticality safety throughout the operations organization , communicating criticality safety responsibilities for each individual involved in operations , ensuring that controls identified by CSEs are implemented, ensuring each worker has necessary training and qualifications , and ensuring that procedures that include controls significant to criticality safety are prepared before operations commence.

Supervisors and workers will be responsible for completing training before performing fissile material operations , understanding and ensuring compliance with all applicable criticality safety controls, and reporting any proposed change in fissile material operations to the Criticality Safety Representative for evaluation and approval before the operation commences. Criticality Safety Evaluations This element describes the process for preparing CSEs that demonstrate fissile material operation will be subcritical under both normal and credible abnormal conditions.  

* CSEs will determine, identify , and document the controlled parameters and associated limits on which criticality safety depends. CSEs will be required to evaluate normal operations, and contingent and upset conditions . Preliminary CSEs prepared for the Construction Permit Application, including verification and validation of supporting computer codes , are described in Section 6.3.1.1 and provide examples of the CSEs. Design changes impacting criticality will be reviewed b y the Criticality Safety Representative . CS Es will be independently reviewed to confirm the technical adequacy of the evaluation prior to commencing new or modified fissile material operations. Nuclear criticality safety limits established for controlled parameters in the NWMI facility processes will ensure that all nuclear processes are subcritical, including an adequate margin of subcriticality for safety in accordance with the Interim Staff Guidance augmenting NUREG-1537, Guidelines for Pr epari ng and R ev i ewing Applications for the Licensing of Non-Power Reactors: Standard R eview Plan and Acceptance Criteria, Part 2, Section 6.b.3 (NRC , 2012). Monte-Carlo N Particle (MCNP) calculation results used to set limits on parameters are compared to the upper subcritical limit (USL) established in the NWMI MCNP code validation report ([Proprietary Information]), after applying a 2cr calculation uncertainty. 6-30   

.; .. ;. NWMI ...... .. ... ... NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features * * *

In addition, the area of applicability, also established in [Proprietary Information], is checked to ensure that the NWMI RPF process model physics and materials are within the bands of applicability.

If either the physics or materials are outside the bands of applicability, an additional margin of subcriticality will be applied. Criticality Safety Control Implementation This element describes the process for implementing criticality safety controls defined by the CSEs. * *

* Implementation includes confirming that: All required engineered criticality safety controls are maintained by a configuration management system. Equipment dimensions, volumes, or other features relied on for controls are with limits documented in the CSEs. Administrative criticality safety controls from CSEs are implemented in written operating and maintenance procedures.

Access to fissionable material will be controlled . Nuclear Criticality Safety Training This element describes the training program for nuclear criticality safety based on the worker's duties and responsibilities.  

* This training program is developed and implemented with input from the nuclear criticality safety staff, training staff, and management , with a focus on: Knowledge of the physics associated with nuclear criticality safety Analysis of job s and tasks to determine th e knowledge a worker must ha ve to perform tasks efficiently Design and development of learning objectives based on the analysis of jobs and tasks that reflect the knowledge, skills, and abilities needed by the worker Implementation of revised or temporary operating procedures Testing methods to demonstrate competence in training materials dependent on an individual's responsibility Training records maintenance General training on criticality hazards and alarm responses will be provided to all RPF personnel and visitors.

Operators responsible for some aspect of nuclear criticality safety will: Satisfy defined minimum initial qualifications Complete an initial criticality safety training course designed for operators Perform periodic requa li fication training Management , operations supervisor , and technical staff responsible for some aspect of nuclear criticality safety will: Satisfy defined minimum initial qualifications Complete an initial criticality safety training course designed for managers and engineers 6-31   

* Perform periodic requalification training The Criticality Safety Repre sentative will: Satisfy defined minimum initial qualifications Complete an initial criticality safety program designed for the Criticality Safety Representative Demonstrate competence in understanding facility nuclear criticality controls and procedures Perform periodic requalification trainin g Criticality Safety Engineers will be trained and qualified in accordance with ANSI/ ANS-8.26 . Nuclear criticality safety staff member s and contract support will meet the qualification and training requirements specified in the NWMI nuclear criticality safety qu a lification and training program. The NWMI nuclear criticality safety qualification and training program is compliant with ANSI/ANS 8.26. Criticality Safety Assessments This element describes the periodic criticality safety inspections and assessments conducted to ensure that the criticality safe t y program is maintained at an adequate level for the RPF. * * * *

* Annual criticality safety inspections will be conducted to satisfy the requirement of ANSI/ ANS-8. l and 8.19 for operational re views to be conducted at lea st annually. Procedures will be developed for performing periodic criticality safety inspections.

The facility Criticality Safety Representative and inspe ct ion team will comprise indi v iduals (typically from Engineering) who are knowledgeable of criticality safety , and who, to the extent practicable, are not immediatel y responsible for the operation being in specte d. Facility inspections are conducted to verify that the facility configuration and activities comply with the nuclear criticality safe ty program. Facility inspections generally consist of observation of task preparation and verification of field procedures and training. Management assessments will be conducted of the nuclear criticality safety program. These assessments will be led by the Nuclear Criticality Safety Manager, with assistance from other members of the criticality safety staff. The criticality safety staff is independent of the operating organization and not directl y responsible for the operations.

Records generated during performance of criticality safety inspection s and assessments will be included in a criticality safety inspection report or specialty assessment report. An audit to assess the overall effectiveness of the nuclear criticality safety program will be performed at least once every three yea rs. The audit will be led by a qualified se nior criticality safety engineer from outside the NWMI organization. The senior nuclear criticality safety engineer conducting the audit will be independent of the NWMI program and will not have participat e d in any nuclear criticalit y safety evaluation that will be a subject of the audit. In addition to the triennial audit from an outside organization, NWMI senio r management will perform periodic audits of the NWMI nuclear criticality safety program. The senior manager will be chosen from an NWMI organization other than the nuclear criticality safety group. The NWMI Quality Assurance Manager will select and assign auditors who are independent of the NWMI nuclear criticality safety program. Criticality Prevention Specifications This element describe s the requirements for the criticality prevention specifications used to implement limits and controls established in the CSEs for safe handling of fissionable material and implement the ANSI/ ANS-8 series requirement for clear communication of criticality safety limits and controls.

* Procedures will meet the intent of ANSI/ ANS-8.19 . Procedures for operations and maintenance work will be prepared according to approved procedure control programs, developed and maintained to reflect changes in operations , and written so that no single inadvertent failure to follow a procedure can cause a criticality accident.

Operating procedures will include: Controls and limits significant to nuclear criticality safety of the operation Periodic revisions , as necessary Periodic review of active procedures by supervisors Operating procedures will be supplemented by criticality safety postings on equipment or incorporated in operating checklists. Maintenance work procedures associated with SSCs affecting nuclear criticality safety will be reviewed by the Criticality Safet y Representative or a Criticality Safety Engineer for compliance with nuclear criticalit y safety limits based on current RPF conditions present prior to initiating each maintenance evolution.

* Criticality safety postings will be developed for the Operating License Application . Fissile Material Container Labeling, Storage, and Transport

* Fissile material container labeling , storage, and transport will be developed for the Operating License Application. Criticality Safety Nonconformance Response This element describes the response to deviations from defined nuclear criticality safety controls. *

.; .. NWMI ...... ..* .. .*.* .. *.*. * ! ' NOlmfWEST MlDtCAL ISOTOPlS NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features * *

* The Criticality Safety Representative or a Criticality Safety Engineer will support an investigative team comprising , at a minimum , the Operations Manager and operations personnel familiar with the operation in question during the development of a recovery plan for safe l y returning to compliance with the procedures.

The deviation will be corrected per the recovery plan and the incident documented . Action is to be taken to ensure that a similar situation does not exist in another part of the facility and to prevent recurrence of the nonconformance.

* The primary criticality safety control, performed at the start of a proposed activity or equipment change , is for the Criticality Safety Representative to confirm if an existing active CSE is applicable.

All dimensions , nuclear properties , and other features on which reliance is placed will be documented and verified prior to beginning operat ion s , and control will be exercised to maintain them. The nuclear criticality safety staff will provide technical guidance for the design of equipment and processes and for the development of operating procedures.

All proposed criticality safety-r elated changes to design or process configuration will be reviewed by a Criticalit y Safety Representative or Criticality Safety Engineer to ensure that the change can be performed under an approved CSE. All operational changes that impact criticality safety will be documented and include proper approva l designation.

If the potential exists for the physical configuration or operating parameters for new or revised equipment to affect critica l ity safety, the drawings and process control plans will be reviewed and approved by a Criticality Safety Representative or Criticality Safety Engineer , in compliance with standard engineering practices and procedures.

Facility and process change contro l will include the following . The change management process will be in accordance with ANSI/ ANS-8.19. All dimensions , nuclear properties , and other features on which reliance is placed will be documented and verified prior to beginning operations , and control will be exercised to maintain them. Changes that involve or could affect nuclear criticality controls will be evaluated under 10 CFR 50.59, " Changes , Tests , and Experiments." Changes include new designs, operation , or modification to existing SSCs, computer programs, processes, operating procedures , or management measures.

Prior to implementing the change , the process will be determined to be subcritical (with an approved margin for safety) under both normal and credible accident scenarios.

6-34 NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features Testing and Calibration of Active Engineered Controls

* Testing and calibration of AECs will be developed for the Operating License Application . Criticality Safety Guidelines for Firefighting

Emergency Preparedness Plan and Procedures This element de sc ribes the response to criticality accidents.  

* The CAAS will be u se d as described in Section 6.3.1.1 and provide s for detection and annunciation of criticality accidents.

Facility and off-site organizations expected to respond to emergencies will be informed of conditions that mi g ht be encountered.

The possibility of per so nnel contamination b y radioactive material will b e considered . Personnel will be trained in evaluation method s, informed of routes and assembly stations, and drills performed at le ast annually. Instrumentation and procedures will be provided for determining radiation in an evacuated area following a criticality accident and information collected in a central location. Emergency procedures will be maintained for each area in which special nucl ear material is handled , used, or stored to ensure that all personn e l withdraw to an area of safety on sounding the alarm. Emergency procedure s will include conducting drill s to familiarize personnel with the evacuation plan, designation ofresponsible individuals to determine the cause of the alarm, and placement of radiation survey instruments in acce ssi ble locations for use in such an emergency.

The current emergency procedures for each area will be retained as a record for as long as licensed special nuclear material is handled, used , or stored in the area. Superseded sections of emergency procedures will be retained for three years after the section is superseded.

Fixed and personnel accident dosimeters will be provided in area s that require a CAAS . Dosimeters wiJJ be readily available to personnel responding to an emergency and a method provided for prompt on-site dosimeter readouts. 6-35 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.3.1 Criticality Safety Controls The following sections describe criticality safety controls based on information developed for the Construction Permit Application.

Section 6.3 .1.2 summarizes IROFS related to preventing a nuclear criticality identified by the accident analyses described in Chapter 13.0. 6.3.1.1 Preliminary Criticality Safety Evaluations A series of calculations were performed to support the Construction Permit Application inve stiga ting parameters associated with prevention of nuclear criticality in the current equipment configuration of major process sys tems. The calculations are described in the following documents:  

* NWMI-2015-CRlTCALC-001 , Singl e Param eter Subcritical Limits for 20 wt% 235 U-Ura nium Metal , Uranium Oxide , and Homogenous Water Mixtures NWMI-2015-CRlTCALC-002, Irradiat e d Target Low-Enriched Uranium Material Dissolution NWMI-2015-CRlTCALC-003 , 55-Gallon Drum Arrays NWMI-2015-CRlTCALC-005, Target Fabrication Tanks , Wet Pro cesses , and Storage NWMI-2015-CRlTCALC-006, Tank Hot Cell Calculations were performed using the MCNP 6.1 code (LA-CP-13-00634, MCNP6 User Manual). Validation of the MCNP 6.1 code used in the calculations is described in [Proprietary Information].

The primary focus of the validation was to determine the bias and bias uncertainty for intermediate-enriched uranium (IEU) systems. However, s ufficient experiments for low-enriched uranium (LEU) and high-enriched uranium were included to demonstrate that there i s no va riation in the USL with varying enrichment.

Similarly, the primary focus of the validation was on thermal neutron energy systems. Sufficient experiments for intermediate and fast energy experiments were also included to demonstrate that there is no va riation in the USL with increasing neutron energy. The purpose of the computer code validation is to determine values ofke ff that are demonstrated to be subcritical (at or below the USL) for areas of applicability similar to systems or operations being analyzed.

rearranges Equation 6-1 to produce a criterion for model cases that are considered acceptable as s ubcritical , as shown b y Equation 6-2 , and incorporates the margin of subcriticality in the USL as required b y ANSl/ANS-8.1.

where keff is the MCNP calculated k-effective and CJ c aJ c is the MCNP calculation uncertaint

6-36 Equation 6-2 NWM I ...... * * ! . NORTHWEST MEDICAL lSCJTDfl£S NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

indicates the validation is appropriate for homogeneous and heterogeneous IEU systems. A summary of the area of applicability is provided in Table 6-4. For systems outside the validation area of applicability, an increased margin of subcriticality value may be warranted, depending on the specific problem being analyzed.

Table 6-4. Area of Applicability Summary Parameter Fissile material Fissile material form H/2 35 U ratio Average neutron energy causing fission Enric hment Moderating materials Reflecting mat eria l s Absorber materials Geometry a Source: [Proprietary Information].

ANECF = average n e utron energy causing fission. Area of Applicability  

.-::*:; ..... NWM I ........... ' * * .' Nl>f'THWEST MEDtCAl. ISOTOPES NWMl-201 3-021 , Rev. 2 Chapter 6.0 -Eng i neered Safety Features Ta bl e 6-5. Con t rolle d N ucl ea r C ritic a li ty Safety P a r a m e t ers NWMI criticality safety evaluation (NWMl-2015-CSP)

Mass y y y y y y y N y y yb y y Geome tr y y y y y y ye ye y N y y y y Mo d eration y N N N N N N N N N N N N I nt erac t i on y y y y y y y y N y y y y Vo l ume y y y y y y y N N N y N y Co n ce ntra tion/ N yd yd yd yd N N N ye ye ye N N de n s i ty Reflection N N N N N N N N N N N N N Absorbers N N N N N N N N N N N N N Enrichmentr N N N N N N N N N N N N N a Derived from t h e indicated CSE reference doc u ment. b Limited b y nature of process in the air filtration.

c Limited by target design. ct Controlled thro u gh input fissile mass. e Limited b y total uran i um mass a ll owed in the system. r Faci l ity license l imited to ::;2 0 wt% m u. m u uran i um-235. NWM I Northwest Medical Isotopes , LLC. CSE = critica l it y safety eva lu at i on. y yes. N = no. The pre li minary CS Es define a series of PECs, AECs, and a d ministrative controls t h at are credited to sat i sfy the do u b l e-co n tingency co n trol princi pl e for preve n tion of nuclear critica l ity events such t h at at l eas t two changes i n process conditions m u st occur before cr it icality is possible.

PECs, AECs , an d a dm inis t rative contro l s are described for the 13 activity gro u ps in the fo ll owing reference d tab l es: * * * * * * * * * * *

* NWMI-20 1 5-CSE-Ol, Irradiated Target Handling and Disassembly (Tab le 6-6) N WMI-20 1 5-CSE-02, Irradiated Low-Enri c hed Uranium Target Mat e rial Dissolution (Tab le 6-7) NWMl-20 1 5-CSE-03, Molybdenum-99 Re covery (Table 6-8) NWMI-2015-CSE-04, Low-Enriched Uranium Target Material Produ c tion (Ta bl e 6-9) NWMI-2015-CSE-05, Targ e t Fabrication Ur anium Solution Process es (Ta bl e 6-9) NWM I-2015-CSE-06, Targ e t Finishing (Table 6-9) NWMI-2015-CSE-0 7 , Targ e t and Can Storage and Carts (Table 6-9) NWMI-2015-CSE-08 , Hot C e ll Uranium Purification (Table 6-10) NWMI-20 1 5-CSE-09, Waste Liquid Processing (Ta b le 6-11) NWMI-20 1 5-CSE-10 , Solid Waste Collection , Encapsulation , and Staging (Table 6-11) NWMI-20 1 5-CSE-l l , Offgas and Ventilation (Ta bl e 6-12) NWMI-2 01 5-CSE-12, Targ e t Transport Cask or Drum Handling-The shipping packages dictate design fea t ures that m u st b e prope rl y imp l emented for legal ove r-the-road tra n sport. This CSE d oes no t impose or cre d i t a d ditiona l pass i ve contro l s other than t h ose alrea d y incorporated in th e respect i ve sh i pping packages. 6-38   

* NWMI-20 l 5-CSE-13, Analytical Laboratory (Table 6-13) The CSEs will be updated for final design and the Operating License Application. Criticality controls are selected based on the fo llo wing order of preference:

Passive engineered controls Active engineered contro l s Enhanced administrative controls Administrative controls Note that a number of features listed in the pre l iminary CSEs are duplicated in multiple activity groups (e.g., the floor of cells is verified to be flat, with no collection points deeper than 3.5 centimeters  

Double-Contingency Controls ldentifiera Feature description and basis CSE-01-PD FI [Proprietary Information]

CSE-0 1-PD F2 [Proprietary Information]

CSE-Ol-A C3 [Proprietary Information]

CSE-01-AC4 [Propr i etar y Information]

Double-Contingency Contro l s (2 pages) Identifier" Feature description and basis CSE-02-PDFl  

6-40 "NWMI ......... * ........ *.* ' *! ." NO<<llfWUT MEDICAL ISOTOPES [Proprietary Information]

NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features Table 6-8. [Proprietary Information]

CSE-0 3-PDF3 [Proprietary Information]

CSE-03-PD F5 [Proprietary Information]

CSE-03-PD F7 [Proprietary Information]

CSE-0 3-PDF9 [Proprietary Information]

CSE-0 3-PD Fl I [Proprietary Information]

CSE-0 3-AEFI [Proprietary Information]

ion exchange. = molybdenum. Feature description and basis [Proprietary Information]  

[Proprietary Information]. 6-41   

* NOmfWUT MEDM:Al ISOTOP(S NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietar y Information]

* NORTHWEST MEOtCAl ISOTOPES NWM l-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Table 6-9. [Proprietary Information]

CSE-04-PDF4" [Proprietary Information]

CSE-04-PDFS" [Proprietary Information]

CSE-04-PDF6" [Proprietary Information]

CSE-04-PDF7" [Proprietary Information]

CSE-04-PDF8" [Proprietary Information]

CSE-04-AC3" [Proprietary Information]

CSE-04-AC4" [Proprietary Information]

CSE-04-AC5" [Proprietary Information]

CSE-04-AC6

CSE-04-AC7" [Proprietary Information]

CSE-05-PDF2b [Proprietary Information]

... ;. NWMI ..**.. ** ** .......... * *. * ! . N ORTHWtST MEDICAL ISOTOPfS NWMl-201 3-021 , Rev. 2 Chap t e r 6.0 -Engineered Sa f e t y Features Ta bl e 6-9. [Propri e ta ry I nformat i on] Double-Co ntin g en cy C ontr o l s (8 p ages) Identifier CSE-05-AEFJ b [Proprietary Information]

CSE-0 5-AEF2b [Pro pr ietary Information]

CSE-05-AClb [Pro p rietary Information]

CSE-0 5-AC3b [Pro p rietary Information]

CSE-06-PDFl c [Proprietary Information]

CSE-06-P D F2c [Pro pri etary Informatio n] CSE-06-AC l c [Proprietary Information]

CSE-0 6-AC2c [Pro pri etary Informatio n] CSE-06-AC3 c [Proprietary Information]

CSE-0 6-AC4c [Pro pr ietary Informatio n] CSE-06-ACSC [Proprietary Information]

CSE-07-PDF I d [Proprietary Information]

CSE-0 7-P D F2d [Pro p rietary Informatio n] CSE-07-PDF3d [Proprietary Information]

CSE-0 7-P D F4d [P ropr i etary Info rm atio n] CSE-07-ACJd [Proprietary Information]

CSE-07-AC2d [P roprietary In formation]

CSE-07-AC4d [P rop r ietary Informatio n] CSE-07-AC5d [Proprietary Information]

CSE-07-AC6d [P roprietary In formatio n] CSE-07-AC7d  

] b [Proprietary ln formation]

ADUN DBE u acid-deficient uranium nitrate. design basis eart hqu ake. ura n ium. Feature description and basis UN = uranium nitride. [Proprietary lnfor m ation] [Proprietary lnfo rm ation] 6-44 NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietar y Information]

* NOITHWUT MUHCAl ISOTOP&#xa3;S NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

6-46 NWM I ...... *  "NORTHWUTMEDICAllSOTOH.S NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

... ;.NWMI ...... .. **: ........ *.* * *.* ." NORTHWEST MEDICAL ISOTOPES NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietar y Information]

6-48 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

* NOflTHWUT MEtMCAl ISOTOPH NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

* NORTHWEST MEOtCAl. lSOTDH.S NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Table 6-10. [Proprietary Information]

Double-Contingency Controls (2 pages) ldentifiera Feature description and basis CSE-0 8-PDFl [Proprietary Information]

CSE-08-PDF 3 [Proprietary Information]

CSE-08-PDF5 [Proprietary Information]

DB E = de s ign basis earthquake. lX ion exchange.

* NORTHWEST MEOJCAl ISOTOPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

6-52 NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features Table 6-11. [Proprietary Information]

Double-Contingency Controls (3 pages) Identifier Feature description and basis CSE-09-AEF I" [Proprietary Information]

CSE-09-AC2" [Proprietary Information]

CSE-09-AC3" [Proprietary Information]

AEFib CSE-I 0-AC I b [Proprietary Informat i on] CSE-I O-AC2 b [Proprietary Information]

CSE-I O-AC3 b [Proprietary Information]

CSE-I 0-AC4 b [Proprietary Information]

CSE-I O-AC5 b [Proprietary Information]

23 s u HIC RPF * [Proprietary Information]

.. NWMI *::**::* ...... ' ." NomtwtST MEDtCAl ISOTOPES NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietar y Information]

* NOATHW&#xa3;Sl MEOtCAl ISOTOf'ES NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [P rop ri e t a r y I nfo rm a t io n] 6-55   

CSE-l l-PD F3 [Proprietary Information]

CSE-11-PD FS [Proprietary Information]

CSE-l l-PD F7 [Propri etary Information]

HEPA = high-efficienc y p art iculate air. Feature description and basis Mo NO x 6-56 molybdenum. nitro ge n oxide.

NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features Table 6-13. [Proprietary Information]

Double-Contingency Controls (2 pages) ldentifiera CSE-1 3-PD Fl [Proprietary Informat i o n] CSE-13-PDF2 [Proprietary Information]

CSE-1 3-PDF3 [Proprietary Information]

CSE-1 3-AC4 [Proprietary Information]

R&D RPF re searc h and development.  

= Radi o isotope Produ ction Facility.

Feature description and basis S PL u 6-57 single parameter l imit. uranium.

NWM I ...... * * ! NOmfWlST MEDtCAL ISOTOPH NWMl-2013-021 , Rev. 2 Chapter 6.0 -Engineered Safety Features [Proprietary Information]

6-58 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Each of the preliminary CSEs indicates that the process areas evaluated will be within the detector and alarm coverage of the CAAS. Evaluation of the CAAS coverage will be performed after final design is complete and prior to facility startup. To ensure the CAAS coverage is adequate for the facility, NWMI will conduct a coverage analysis using the minimum accident of concern that produces a detector response when the dose rate at the detector is equivalent to 20 rad/min at 2 m (6.6 ft) from the reacting material.

Using the source from the minimum accident of concern, NWMI will conduct one-dimensional deterministic computations , when practical , to evaluate CAAS coverage.

For areas of the facility where the use of one-dimensional deterministic computations is not practical , NWMI will use 3D Monte Carlo analysis to determine adequate CAAS coverage. The CAAS will be designed to meet the following. * *

* 6.3.1.2 The facility CAAS: Will be capable of detecting a criticality that produces an absorbed dose in soft tissue of 20 radiation dose absorbed (rad) of combined neutron and gamma radiation at an unshielded distance of 2 m from the reacting material within 1 minute; two detectors will cover each area needing CAAS coverage Will use gamma and neutron sensitive radiation detectors that energize clearly audible alarm signals if an accidental criticality occurs Will comply with ANSI/ ANS-8.3 , as modified by NRC Regulatory Guide 3. 71 Will be appropriate for the type of radiation detected, the intervening shielding, and the magnitude of the minimum accident of concern Will be designed to remain operational during design basis accidents Will be clearly audible in areas that must be evacuated or there will be alternative notification methods that are documented to be effective in notifying personnel that evaluation is necessary Operations will be rendered safe, by shutdown and quarantine , if necessary , in any area where CAAS coverage has been lost and not restored within a specified number of hours. The number of hours will be determined on a process-by-process basis, because shutting down certain processes , even to make them safe , may carry a larger risk than being without a CAAS for a short time. Compensatory measures (e.g., limiting access , halting SNM movement , or restoring CAAS coverage with an alternate instrument) when the CAAS is not functional will be determined for inclusion i n the Operating License Application. Emergency power will be provided to the CAAS by the uninterruptable power supply system . Derived Nuclear Criticality Safety Items Relied on for Safety The following subsections describe engineered safety features that are derived from the accident scenarios that could result in a nuclear criticality , as described in Chapter 13.0. 6.3.1.2.1 IROFS CS-04, Interaction Control Spacing Provided by Passively Designed Fixtures and Workstation Placement IROFS CS-04 , " Interaction Control Spacing Provided by Passively Designed Fixtures and Workstation Placement," is identified by the accident analyses in Chapter 13.0. During handling of uranium solids and solutions outside of processing systems under normal conditions, the material will be handled in safe masses controlled by either physical measurement or batch limits on well characterized devices. 6-59   

* NORTifW(tT MEOtCAi. tsOTOPE.S NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features Solid uranium will be handled outside of processing systems during: * * * *

LEU target material (including movement of LEU target material to and from the fabrication workstation and handling of the completed targets) Disassembly of targets following irradiation Laboratory sampling and analysis activities (albeit in smaller quantities) . Each activity is assigned a mass or batch limit for safe handling.

Accident Mitigated The accident occurs when a safe mass or batch limit is exceeded beyond some bounding extent based on the management measures on the control. Note that this accident involves normal condition criticality controlled limits for safe handling, and the upset represents failure of an associated administrative control. The most limiting activity would involve processing the LEU target material from [Proprietar y Information]. If the IROFS fails , accidental nuclear criticality is possible without additional control. System Components As a PEC , fixed interaction control fi x tures or workstations will be provided for holding or processing approved containers containing approved quantities of uranium metal, [Proprietary Information], batches of targets, and batches of samples. Functional Requirements The fixtures are designed to hold only the approved container or batch and are fixed with 2-ft edge spacing from all other fissile material containers , workstations , or fissile solution tanks , vessels, and ion exchange (IX) columns. Where LEU target material is handled in open containers , the design will prevent spills from readily spreading to an adjacent workstation or storage location. Design Basis Final workstation and fixture spacing will be determined in final design when all process upsets are evaluated.

6-60 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.3.1.2.2 IROFS CS-06, Pencil Tank, Vessel, or Piping Safe Geometry Confinement Using the Diameter of Tanks, Vessels, or Piping IROFS CS-06, "Pencil Tank, Vessel, or Piping Safe Geometry Confinement using the Diameter of Tanks, Vessels , or Piping ," is identified by the accident analyses in Chapter 13.0. The PHA in Chapter 13.0 identified a number of individual potential initiating events that could lead to a spill of fissile solution from the geometrically safe confinement tanks , vessels, or piping that provide the primary safety functions of the processes. Four processing systems will handle fissile solutions:

Initiating events include the general categories of tank , vessel , or piping failure due to operator error (valves out of position), valves leaking, equipment leaking (pumps, piping, vessels, etc.), high pressure events from various causes including high temperature solutions (locked in boundary valves), hydrogen detonation, and exothermic reactions with the wrong resins or reagents used in the respective systems. Some of the initiators result in small leaks that are identified and mitigated (e.g., pump seal and small valve leaks). Over the life of the facility , these types of leaks are to be expected , but do not challenge the overall safety of RPF operations.

Thus , scenarios leading to this accident sequence involve the failure of these IROFS. Due to the nature of the process, the worst-case accident involves the tanks with the largest capacity and the highest normal case concentrations.

The safe diameters of various tanks , vessels , or components will be provided in the Operating License Application.

The safe-geometry confinement of fissile solutions will prevent accidental nuclear criticality, a high consequence event. The safe-geometry confinement diameter will conservatively include the outside diameter of the tank wall or out to the outside diameter of any heating or cooling jackets (or any other void spaces that may inadvertently capture fissile solution) on the vessels. Where insulation is used on the outside wall of a vessel, the insulation will be closed foam or encapsulated type (so as not to soak up solution during a leak) and will be compatible with the chemical nature of the contained solution.

Design Basis The safe-geometry diameter of tanks, vessels, and piping will be determined in final design after finalizing the reference CSEs. Note that preliminary vessel sizes for activity groups are listed in the double-contingency parameters described in Section 6.3.1.1. 6-61   

6.3.1.2.3 IROFS CS-07, Pencil Tank Geometry Control on Fixed Interaction Spacing of Individual Tanks IROFS CS-07, " Pencil Tank Geometry Control on Fixed Interaction Spacing oflndividual Tanks," is identified by the accident analyses in Chapter 13.0 (see description in Section 6.3.1.2.2).

System Components As a PEC , pencil tanks and other standalone vessels (controlled with safe geometry or volume constraints) are designed and will be fabricated with a fixed interaction spacing for safe storage and processing of the fissile solutions.

Tanks, vessels, and components requiring fixed interaction control spacing of the barrel s within each set of pencil tanks and between various tanks , vessels, or components will be provided in the Operating License Application.

Functional Requirements The safety function of fixed interaction spacing of individual tanks in pencil tanks and between other single processing vessels or components is designed to minimize interaction of neutrons between vessels s uch that under normal and credible abnormal process upsets, the systems remain subcritical.

The fixed interaction control of tanks, vessels, or components containing fissile solutions will prevent accidental nuclear criticality, a high consequence event. The fixed interaction spacing will be measured from the outside of the respective tanks, vessels, or component or from the outside of any heating or cooling jackets (or any other void spaces that may inadvertently capture fi ss ile solution) on the vessels or component.

* Connecting piping between fissile material components will not exceed a cross-sectional densit y to be determined during final evaluation of systems. Edge-to-edge spacing between fissile material-bearing vesse ls and components and the concrete reflector presented by the hot cell shielding walls will be fixed at a distance to be determined during final evaluation of all components.

6-62 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.3.1.2.4 IROFS CS-08, Floor and Sump Geometry Control on Slab Depth, Sump Diameter or Depth for Floor Dikes IROFS CS-08, " Floor and Sump Geometry Control on Slab Depth, Sump Diameter or Depth for Floor Dikes ," is identified by the accident analyses described in Chapter 13.0 (see description in Section 6.3.1.2.2). Accident Mitigated See description in Section 6.3.1.2.2. System Components As a PEC, the floor under designated tanks, vessels , and workstations will be constructed with a spill containment berm using a safe-geometry slab depth , and one or more collection sumps with diameters or depths , to be determined in final design. Functional Requirements The safety function of a spill containment berm is to contain spilled fissile solution from systems overhead and prevent an accidental nuclear criticality if one of the tanks or related piping leaks, ruptures , or overflows (if so equipped with overflows to the floor). Each spill containment berm will be sized for the largest single credible leak associated with overhead systems. The sump will have a monitoring system to alert the operator that the IROFS has been used and may not be available for a follow-on event. A spill containment berm is operable if it contains reserve volume for the largest single credible spill. Spill containment berm sizes and locations will be determined during final design. Design Basis The safe-geometry slab depth under designated tanks , ves s els , and workstations will be determined during final design after finalizing the reference CSEs. Note that the preliminary slab depth for the activity groups are listed in the double-contingency parameters described in Section 6.3.1.1. Test Requirements The above analysis is based on information developed for the Construction Permit Application.

6.3.1.2.5 IROFS CS-09, Double-Wall Piping IROFS CS-09 , " Double Wall Piping," is identified by the accident analyses described in Chapter 13.0. As a PEC, a piping system for conveying fissile solution between confinement structures will be provided with a double-wall barrier to contain any spills that may occur from the primary piping. Accident Mitigated

6.3.1.2.6 IROFS CS-10, Closed Safe Geometry Heating/Cooling Loop with Monitoring and Alarm IROFS CS-10 , "Closed Safe Geometry Heating or Cooling Loop with Monitoring and Alarm," is identified by the accident analyses in Chapter 13.0. As a PEC , a closed-loop, safe-geometry heating or cooling loop with monitoring for uranium process solution or high-dose process solution will be provided to safely contain fissile process solution that leaks across the heat transfer fluid boundary if the primary boundary fails. Accidents Mitigated The dual-purpose safety function of the closed-loop system is to prevent (1) fissile process solution from causing accidental nuclear criticality , and (2) high-dose process solution from exiting the hot cell containment, confinement, or shielded boundary (or to prevent low-dose solution from exiting the facility , for systems located outside of the hot cell containment , confinement , or shielded boundary), and causing excessive dose to workers and the public, and/or causing a release to the environment.

Sampling of the heating or cooling media (e.g., steam condensate conductivity, cooling water radiological activity, or uranium concentration) will be conducted to alert the operator that a breach has occurred, and that additional corrective actions are required to identify and isolate the failed component and restore the closed loop integrity.

Discharged solutions from this system will be handled as potentially fissile and sampled prior to discharge to a safe geometry. Design Basis The closed loop steam and cooling water loop design is described in Chapter 9.0. Test Requirements The above analysis is based on information developed for the Construction Permit Application. Additional detailed information on test requirements will be developed for the Operating License Application.

6.3.1.2.7 IROFS CS-11, Simple Overflow to Normally Empty Safe Geometry Tank with Level Alarm IROFS CS-11 , "Simple Overflow to Normally Empty Safe Geometry Tank with Level Alarm," is identified by the accident analyses described in Chapter 13 .0. As a PEC, a simple overflow line will be installed below the level of the process vessel ventilation port and any chemical addition ports (where an anti-siphon safety feature will be installed) for each vented tank containing fissile or potentially fissile process solution for which this IROFS is assigned.

System Components Locations of the overflow and overflow collection tanks will be provided with the final design. Functional Requirements The safety function of this feature is to prevent accidental nuclear criticality in non-geometrically favorable sections of the process ventilation system. The overflow will be directed to a safe-geometry storage tank. The overflow storage tank will normally be maintained empty. The overflow storage tank will be equipped with a level alarm to inform the operator when use of the IROFS has been initiated , so that actions can be taken to restore operability of the safety feature by emptying the tank. Design Basis Design basis information will be provided in the Operating License Application.

6-65 NWMI *::**:*:*** ...... . NORTifW&#xa3;tT MlDICAl ISOTOftl S Test Requirements NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features The above analysis is based on information developed for the Construction Permit Application.

6.3.1.2.8 IROFS CS-12, Condensing Pot or Seal Pot in Ventilation Vent Line IROFS CS-12, "Condensing Pot or Seal Pot in Ventilation Vent Line," is identified by the accident analyses described in Chapter 13.0. As a PEC, a safe-geometry condensing pot or seal pot will be installed downstream of each tank for which this IROFS is assigned to capture and redirect liquids to a safe-geometry tank or flooring area with safe-geometry sumps. One such condensing or seal pot may service several related tanks within the safe-geometry boundary of the ventilation system. The condensing or seal pot will prevent fissile solution from flowing into the respective geometrically favorable process ventilation system by directing the solution to a safe-geometry tank or flooring area with safe-geometry sumps. Accident Mitigated Where independent seal or condensing pots are credited , the drain s of the seal or condensing pots must be directed to independent locations to prevent a common clog or over-capacity condition from defeating both. System Components Locations of the condensing pots or seal pots and associated drain points will be provided with the final design. Functional Requirements The safety function of the condensing or seal pots is to prevent accidental nuclear criticality in geometrically favorable sections of the process ventilation system. The safe-geometry tank or sumps will be equipped with a level alarm to inform the operator when use of the IROFS has been initiated.

Test Requirements The above analysis is based on information developed for the Construction Permit Application. Additional detailed information on test requirements will be developed for the Operating License Application.

6-66 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 6.3.1.2.9 IROFS CS-13, Simple Overflow to Normally Empty Safe Geometry Floor with Level Alarm in the Hot Cell Containment Boundary IROFS CS-13 , " Simple Overflow to Normally Empty Safe Geometry Floor with Level Alarm in the Hot Cell Containment Boundary," is identified by the accident analyses described in Chapter 13.0. As a PEC , a simple overflow line will be installed above the high alarm setpoint for each vented tank containing fissile or potentially fissile process solution for which this IROFS is assigned.

The overflow will be directed to one or more safe-geometry flooring configurations with safe-geometry sumps. Accident Mitigated This IROFS prevents accidental criticality b y ensuring that overflowing fissile solutions are captured in a safe-geometry slab configuration with safe-geometry sumps. System Components System component information will be provided in the Operating License Application.

Design Basis Design basis information will be provided in the Operating License Application. Test Requirements The above anal y sis is based on information developed for the Construction Permit Application.

6.3.1.2.10 IROFS CS-14, Active Discharge Monitoring and Isolation IROFS CS-14, " Active Discharge Monitoring and Isolation ," is identified by the accident analyses described in Chapter 13.0. Additional detailed information describing active discharge monitoring and isolation will be developed for the Operating License Application. System Components System component information will be provided in the Operating License Application.

6-67 NWMI ...... *. * ! NORTifWEST MEDICAL ISOTOPES Test Requirements NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features The above analysis is based on information developed for the Construction Permit Application. Additional detailed information on test requirements will be developed for the Operating License Application.

6.3.1.2.11 IROFS CS-15, Independent Active Discharge Monitoring and Isolation IROFS CS-15 , "Independent Active Discharge Monitoring and Isolation," is identified by the accident analyses described in Chapter 13.0. Additional detailed information describing independent active discharge monitoring and isolation will be developed for the Operating License Application.

Functional Requirements Functional requirements information will be provided in the Operating License Application. Design Basis Design basis information will be provided in the Operating License Application.

6.3.1.2.12 IROFS CS-18, Backflow Prevention Device IROFS CS-18 , "Backflow Preventions Device," is identified b y the accident analyses described in Chapter 13.0. See description in Section 6.2.1.7.9. Accident Mitigated See description in Section 6.2.1.7.9. System Components See description in Section 6.2.1.7.9. Functional Requirements See description in Section 6.2.1.7.9.

Design Basis See description in Section 6.2.1.7.9. 6-68 NWMI ...... .. .. . .*.* .. *.*. * * ! NORTHWEST MlDfCAL tsOTOP&#xa3;S Test Requirements See description in Section 6.2.1. 7.9. 6.3.1.2.13 IROFS CS-19, Safe-Geometry Day Tanks NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features IROFS CS-19, "Safe Geometry Day Tanks ," is identified by the accident analyses described in Chapter 13.0. See description in Section 6.2.1.7.9.

6.3.1.2.14 IROFS CS-20, Evaporator/Concentrator Condensate Monitoring IROFS CS-20, "Eva porator/Concentrator Condensate Monitoring," is identified by the accident analyses described in Chapter 13.0. As an AEC, the condensate tanks will use a continuous active uranium detection system to detect high carryover of uranium that shuts down the evaporator feeding the tank. The purpose of this system is to (1) detect an anomaly in the evaporator or concentrator indicating high uranium content in the condenser (due to flooding or excessive foaming), and (2) prevent high concentration uranium solution from being available in the condensate tank for di sc harged to a favorable geometry system or in the condenser for leaking to the non-safe geometry cooling loop. Accident Mitigated The safety function of this IROFS is to prevent an accidental nuclear criticality bec ause of excessive uranium in the condensate carryover to a non-geometrically favorable waste collection tank. System Components System components consist of: Condensate sample tank 1 A Condensate delay tank 1 Condensate sample tank 1 B Condensate sample tank 2A Condensate delay tank 2 Condensate sample tank 2B Condensate sampling sys tems Condensate monitors (UR-TK-340) (UR-TK-360) (UR-TK-370) (UR-TK-540) (UR-TK-560) (UR-TK-570) 6-69   

..... NWMI ...... ........... ' *. * ! NORTHWfST MEDtcAL ISOTOPES Functional Requirements NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features The detection system works by continuously monitoring condensate uranium content and detecting high uranium concentration, and then shutting down the evaporator to isolate the condensate from the condenser and condensate tank. At a limiting setpoint , the uranium monitor detecting device will close an isolation valve in the inlet to the evaporator (or otherwise secures the evaporator) to stop the discharge of high uranium content solution into the condenser and condensate collection tank. The uranium monitor is designed to produce a valve-open permissive signal that fails to an open state, closing the valve on loss of electrical power. The isolation valve is designed to fail-closed on loss of instrument air , and the solenoid is designed to fail-closed on loss of signal. Locations where these IROFS are used will be determined during final design. Design Basis Design basis information will be provided in the Operating License Application.

Additional detailed information on test requirements will be developed for the Operating License Application. 6.3.1.2.15 IROFS CS-26, Processing Component Safe Volume Confinement IROFS CS-26 , "Processing Component Safe Volume Confinement," is identified by the accident analyses described in Chapter 13.0 (see description in Section 6.3.1.2.2). Accident Mitigated See description in Section 6.3.1.2.2. System Components As a PEC , some processing components (e.g., pumps, filter housings, and IX columns) will be controlled to a safe volume for safe storage and processing of the fissile solutions.

Components that may be controlled to a safe volume will be described in the Operating License Application. Functional Requirements The safety function of a safe-volume component is also one of confinement of the contained solution.

The safe-volume confinement of fissile solutions will prevent accidental nuclear criticality , a consequence event. The safe-volume confinement will conservatively include the outside diameter of any heating or cooling jackets (or any other void spaces that may inadvertently capture fissile solution) on the component.

Design Basis The safe-volume confinement components will be determined in final design after finalizing the referenced CSEs. 6-70 Test Requirements NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features The above analysi s is based on information developed for the Construction Permit Application.

6.3.1.2.16 IROFS CS-27, Closed Heating or Cooling Loop with Monitoring and Alarm IROFS CS-27, "Closed Heating or Cooling Loop with Monitoring and Alarm ," is identified by the accident analy ses in Chapter 13.0. As a PEC, closed cooling water loops with monitoring for breakthrough of process solution will be provided on the evaporator or concentrator condensers to contain process solution that leaks across this boundary , if the boundary fails. This IROFS will be applied to those high-heat capacity cooling jackets (requiring very large loop heat exchangers) servicing condensers where the leakage is always from the cooling loop to the condenser.

The inherent characteristics of the leak path will reduce back-leakage into the closed loop system, and the risk of product solutions entering the condenser will be very low by evaporator and concentrator design. System Components The purpose of this safety function is to monitor the health of the condenser cooling jacket to ensure that in the unlikel y event that a condenser overflow occurs, fissile and/or high-dose process solution will not flow into this non-safe-geometry cooling loop and cause nuclear criticality.

The closed loop will also i so late any high-dose fissile product solids, from the same event, from penetrating the hot cell shielding boundary, and any high-dose fission gases from penetrating the hot cell shielding boundary during normal operations.

Functional Requirements The heat exchanger materials will be compatible with the harsh chemical environment of the tank or vesse l process (t his may vary from application to application).

Sampling of the cooling media (e.g., cooling water radiological activity, or uranium concentration) will be conducted to alert the operator that a breach has occurred, and that additional corrective actions are required to identif y and isolate the failed component and restore the closed-loop integrity.

Closed-loop pressure will also be monitored to identify a leak from the closed loop to the process syste m. Discharged solutions from this sys tem will be handled as potentially fissile and sampled prior to di sc harge to a non-safe geometry.

Design Basis Design basis information will be provided in the Operatin g License Application.

Test Requirements The above anal ys is is based on information developed for the Construction Permit Application.

NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features 10 CFR 20, "Standards for Protection Against Radiation," Code of Federal R egu lations , Office of the Federal Register, as amended. 10 CFR 20.1201, "Occupational Dose Limits for Adults," Code of Federal R egu lations , Office of the Federal Register, as amended. 10 CFR 20.1301, "Dose Limits for Individual Members of the Public," Code of Federal Regulations , Office of the Federal Register , as amended. 10 CFR 50.59 , "C hanges , Tests, and Experiments

," Code of Federal R egu lation s, Office of the Federal Register, as amended. 10 CFR 70.61, "Performance Requirements

," Code of Federal Regulations, Office of the Federal Register , as amended. ANSI/ ANS-8.1, Nuclear Criticality Safety in Operation s with Fissionable Material Outsid e of Reactors , American National Standards Institute/ American Nuclear Society, LaGrange Park, Illinois , 2014. ANSl/ANS-8.3, Criticality Accident Alarm System, American National Standards Institute/American Nuclear Society , La Grange Park, Illinois, 1997 (Reaffirmed in 2012). ANSI/ ANS-8. 7, Nuclear Criticality Safety in the Storage of Fissile Materials, American National Standards Institut e/ American Nuclear Society, La Grange Park, Illinoi s, 1998 (Reaffirmed in 2007). ANSI/ ANS-8.10, Criteria for Nuclear Criticality Safety Controls in Op e rations with Shi e lding and Confinement, American National Standards Institute/American Nuclear Society, La Grange Park , Illinois , 2015. ANSI/ ANS-8.19 , Administrative Pra ctices for N ucl ear Criticality Safety, American National Standards Institute/ American Nuclear Society, La Grange Park, Illinois , 2014. ANSI/ ANS-8.20, Nuclear Criticality Safety Training , American National Standards Institute/ American Nuclear Society, La Grange Park , Illinois , 1991 (Reaffirmed in 2005). ANSI/ ANS-8.22, Nuclea r Criticality Safety Based on Limiting and Controlling Moderators, American National Standards Institute/ American Nuclear Society, La Grange Park , lllinois , 1997 (Reaffirmed in 2011 ). ANSI/ ANS-8.23, Nuclear Criticality Accident Emergency Planning and R esponse, American National Standards Institut e/ American Nuclear Society, La Grange Park, Illinois , 2007 (Reaffrrmed in 2012). ANSl/ANS-8.24, Validation of Neutron Transport Methods for Nucle ar Criticality Safety Calculations, American National Standards Institute/ American Nuclear Society, La Grange Park , Illinois, 2007 (Reaffrrmed in 2012). ANSI/ ANS-8.26, Criticality Safety Engineer Training and Qualification Program , American National Standards Institute/American Nuclear Society , La Grange Park, lllinois , 2007 (Reaffirmed in 2012). ANSI/ANS-15

.1 , The D eve lopment ofTechnical Specifications/or Res ea rch R eac tors, American National Standards Institute/American Nuclear Society , LaGrange Park, Illinois , 2013. ANSI N13.1, Sampling and Monitoring Releases of Airborne Radioactive Substances from the Stacks and Ducts of Nuclear Facilities, American Nuclear Society, La Grange Park, Illinois, 2011. 6-72 NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features ASME AG-1, Code on Nuclear Air and Gas Treatment, American Society of Mechanical Engineers, New York, New York, 2003. LA-CP-13-00634, MCNP6 User Manual, Rev. 0 , Los Alamos National Laboratory, Los Alamos, New Mexico , May 2013. NRC, 2012, Final Interim Staff Guidance Augmenting NUREG-153 7, " Guidelines for Preparing and Revi ewing Applications for the Licensing of Non-Power R eactors , " Parts 1 and 2, for Licensing Radioisotop e Produ ction Facilities and Aqueous Homogeneous R eac tors , Docket Number: NRC-2011-0135 , U.S. Nuclear Regulatory Commission, Washington , D.C., October 30, 2012. NUREG-1520, Standard R eview Plan for the R eview of a License Application for a Fuel Cycle Facility, Rev. I , U.S. Nuclear Regulator y Commission, Office of Nuclear Material Safety and Safeguards, Washington , D.C., May 2010. NUREG-1537, Guidelines for Preparing and Revi ewing Appl ications for the Licensing of Non-Power Reactor s -Format and Content, Part 1, U.S. Nuclear Regulatory Commission, Office of Nuclear Reactor Regulation , Washington, D.C., February 1996. NUREG/CR-4604 1 PNL-5849 , Statistical Methods for Nuclear Material Management, Pacific Northwest Laboratory, Richland, Washington, December , 1988. NUREG/CR-6698, Guide for Validation of Nuclear Criticality Safety Calculational Methodology, U.S. Nuclear Regulator y Commission, Office of Nuclear Material Safety and Safeguards, Washington, D.C., January 2001. [Proprietary Information]  

NWMI-2015-SDD-013, System Design Des cription for Ventilation, Rev. A, Northwest Medical Isotopes, LLC, Corvallis, Oregon , 2015. NWMI-2015-CRITCALC-001, Single Parameter Subcritical Limits for 20 wt% 235 U-Uranium Metal , Uranium Oxide, and Homogenous Water Mixtures , Rev. A, Northwest Medical Isotopes, LLC, Corvallis, Oregon, 2015. NWMI-2015-CRITCALC-002, Irradiated Target Low-Enriched Uranium Material Dissolution, Rev. A Northwest Medical Isotopes , LLC , Corvallis, Oregon, 2015. NWMI-2015-CRITCALC-003 , 55-Gallon Drum Arrays, Rev. A Northwest Medical Isotopes, LLC, Corvallis, Oregon, 2015. NWMI-2015-CRITCALC-005, Target Fabrication Tanks , Wet Processes , and Storage, Rev. A, Northwest Medical Isotopes, LLC, Corvallis, Oregon, 2015. NWMI-2015-CRITCALC-006, Tank Hot Cell, Rev. A, Northwest Medical Isotope s, LLC, Corvallis, Oregon , 2015. NWMI-2015-CSE-001, NWMI Preliminary Criticality Safety Evaluation:

Irradiat ed Target Handlin g and Di sasse mbl y, Rev. A, Northwest Medical Isotopes , LLC , Corvallis, Oregon , 2015. NWMI-2015-CSE-002 , NWMI Pr e limina ry Criticality Safety Evaluation:

Irradiat ed Low-Enriched Uranium Target Material Di sso lution , Rev. A, Northwest Medical Isotopes, LLC, Corvallis, Oregon, 2015. NWMI-2015-CSE-003, NWMI Preliminary Criticality Safety Evaluation:

Molybdenum-99 Recov ery, Rev. A, Northwest Medical Isotopes , LLC, Corvallis, Oregon , 2015. 6-73   

* NORTHWUT MEDtCAl. ISOTDPES NWMl-2013-021, Rev. 2 Chapter 6.0 -Engineered Safety Features NWMI-2015-CSE-004, NWMI Preliminary Criticality Safety Evaluation:

Low-Enriched Uranium Target Material Production, Rev. A, Northwest Medical Isotopes, LLC , Corvallis , Oregon, 2015. NWMI-2015-CSE-005, NW MI Preliminary Criticality Safety Evaluation:

Target Fabrication Uranium Solution Process es, Rev. A, Northwest Medical Isotopes , LLC , Corvallis , Oregon , 2015. NWMI-2015-CSE-006, NWMI Preliminary Criticality Safety Evaluation:

Target Finishing, Rev. A, Northwest Medical Isotopes, LLC, Corvallis , Oregon , 2015. NWMI-2015-CSE-007, NWMI Preliminary Criticality Safety Evaluation:

Target and Can Storage and Carts, Rev. A, Northwest Medical Isotopes , LLC, Corvallis, Oregon, 2015. NWMI-2015-CSE-008, NW MI Preliminary Criticality Safety Evaluation

: Hot Cell Uranium Purification, Rev. A, Northwest Medical Isotopes, LLC , Corva llis , Oregon, 2015. NWMI-2015-CSE-009 , N WMI Preliminary Criticality Safety Evaluation

: Liquid Wast e Proc es sing, Rev. A, Northwest Medical Isotopes, LLC , Corvallis, Oregon, 2015. NWMI-2015-CSE-010 , NWMI Preliminary Criticality Safety Evaluation

: Solid Waste Collection , Encapsulation , and Staging , Rev. A , Northwest Medical Isotopes, LLC, Corvallis, Oregon, 2015. NWMI-2015-CSE-O 11 , N WMI Preliminary Criticality Safety Evaluation

: O.ffgas and Ventilation, Rev. A , Northwest Medical Isotopes , LLC , Corvallis , Oregon , 2015. NWMI-2015-CSE-012, NWMI Preliminary Criticality Safety E v aluation: Target Transport Cask or Drum Handling, Rev. A , Northwest Medical Isotopes, LLC, Corvallis, Oregon , 2015. NWMI-2015-CSE-013 , N WMI Preliminary Criticality Safety Evaluation:

Analytica l Laboratory, Rev. A, Northwest Medical Isotopes , LLC, Corvallis, Oregon, 2015. Regulator y Guide 3. 71, N uclear Criticality Safety Standards for Fuels and Material Facilities, Rev. 2 , U.S. Nuclear Regulatory Commission, Washington , D.C., December 2010. 6-74   

* * * * * * * * * ****** * * ** * * * ** * ** * * * ** * ** * * ** * * . *. *. * . NORTHWEST MEDICAL ISOTOPES *

* Chapter 7.0 -Instrumentation and Control Systems Construction Permit Application for Radioisotope Production Facility Prepared by: NWMl-2013-021, Rev. 2 August 2017 Northwest Medical Isotopes , LLC 815 NW 9th Ave , Suite 256 Corvallis , OR 97330 This page intentionally left blank.   

... ;. NWMI ...... .. *.. .......... * * ! NORTNW&#xa3;ST M&#xa3;DfCAl ISOTOPES NWMl-2013-021 , Rev. 2 Chapter 7.0 -Instrumentation and Control Systems Chapter 7 .0 -Instrumentation and Control Systems Construction Permit Application for Radioisotope Production Facility NWMl-2013-021, Rev. 2 Date Published:

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* NORT H WEST MlOfCAl ISOTOP1S Rev Date 0 6/29/2015 1 6/26/2017 2 8/5/2017 NWMl-2013-021 , Rev. 2 Chapter 7.0 -Instrumentation and Control Systems REVISION HISTORY Reason for Revision Revised By Initial Application Not required Incorporate changes based on responses to C. Haass NRC Requests for Additional Information Modification based on ACRS comments C. Haass   

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..... NWMI *:.**.*.* .*.* .. *.*.* *! NOflTHWtST ME.DtCAL ISOTOftES NWMl-2013-021 , Rev. 2 Chapter 7.0 -Instrumentation and Control Systems CONTENTS 7.0 INSTR UMEN T ATION AN D C O NT R O L SYSTEMS .............................................................. 7-1 7 .1 Su mm ary D escr iption ................

.................................................................................... 7-1 7.2 Des i gn o fl n stru m e nt a ti o n a nd Co n tro l Syste m s .............................................................

7-4 7.2.1 D esign Cr it e ri a ................................................................................................. 7-4 7.2.2 D esign B as is a nd Safe t y R e qu ireme n ts ............................................................. 7-4 7.2.3 System D esc ripti on ........................................................................................ 7-1 3 7.2.3.1 Fac ilit y Process Co n trol Syste m ..................................................... 7-14 7.2.3.2 E n gi n eere d Safe t y Feature Ac tu ation Sys t ems ................................ 7-14 7.2.3.3 Co nt rol R oom/Hum a n-M a c hin e I n t erface D escriptio n .................... 7-14 7.2.3.4 Buildin g Ma n age m e n t Sys t e m .............................................

7-1 5 7 .2.3.5 F ir e P rotect i o n System ................................................................... 7-1 5 7 .2.3.6 Fac ilit y Co mmuni cation Sys t e m s ................................................... 7-1 5 7 .2.3. 7 Ana l yt i ca l La b oratory Syste m ........................................................ 7-1 5 7.2.4 System P e r for m a n ce An a l ys is ........................................................................

7-16 7.2.4.l Faci l i t y Tr ip a nd Alarm Des i gn B asis ............................................. 7-16 7.2.4.2 An a l ysis ......................................................................................... 7-1 7 7.2.4.3 C on c lu sion ............................................

......................................... 7-1 7 7.3 Process Co ntr o l Sys t e m s ............................

......................................... 7-22 7.3.1 Ura niu m R ecover y a nd R ecy cl e Sys t e m .........................................................

7-23 7.3.1.1 D esign C r i t e ria ............................................................................... 7-23 7.3.1.2 D es i gn Basis a nd Safet y R e quir e m ents ...........

................................ 7-23 7.3.1.3 Sys t e m Desc ription .............................

........................................... 7-23 7.3.1.4 Sys t e m P erfo rm a n ce Ana l ys is a nd Co n cl u s i o n ............................... 7-28 7.3.2 T a r get Fa bri c ati o n S y ste m .............................................................................. 7-28 7.3.2.1 D es i gn Cri t er i a .........................

...................................................... 7-29 7.3.2.2 D es i g n Bas is a nd Safety R e quir e m ents ........................................... 7-29 7.3.2.3 Sys t e m D escr iption ...................

........................ 7-29 7.3.2.4 Sys t em Perfo rm a n ce Ana l ys is a nd Co n cl u s i o n ............................... 7-32 7.3.3 T a r ge t Rece ipt a nd Di sasse mbl y Sys t e m ......................................................... 7-32 7.3.3.1 D es i g n Cr i ter ia ............................................................................... 7-32 7.3.3.2 D es i gn B a s is a nd Safety R e qu ire m ents ........................................... 7-32 7.3.3.3 Sys t e m Desc ription ........................................................................ 7-33 7.3.3.4 Sys t e m P erfor m a n ce Analys is a nd Concl u s i o n ............................... 7-33 7.3.4 Ta r get D iss oluti o n Sys t e m .............................................................................. 7-33 7.3.4.1 D es i g n Criter i a .....................

.......................................................... 7-3 4 7.3.4.2 D es i gn B as is a nd Safety R e qu i r e m e n ts ...........................................

7-3 4 7.3.4.3 Sys t e m D es c r iption ........................................................................ 7-3 4 7.3.4.4 Sys t e m P erfor m a n ce Ana l ys is a nd Co n c lu s i o n ............................... 7-37 7.3.5 Mol y b den um R ecovery a nd Puri ficat ion System ............................................ 7-37 7.3.5.1 D es i gn C ri ter i a ............................................................................... 7-37 7.3.5.2 D es i gn Ba sis a nd Safety R e quir e m e n ts ...........................................

7-3 7 7.3.5.3 Sys t e m D e s cr iption ................

........................................................ 7-38 7.3.5.4 Sys t e m P erfor m a n ce Ana l ys is a n d Concl u s ion ............................... 7-3 9 7.3.6 W as t e Ha ndlin g Sys t e m .................................................................................

7-3 9 7.3.6.1 D es i gn C r ite ri a ........................

....................................................... 7-40 7.3.6.2 D es i gn Ba sis a nd Safety R eq uir e m e n ts ........................................... 7-40 7.3.6.3 Sys t e m D escr ipti o n ........................................................................ 7-40 7-i NWMl-2013-021, Rev. 2 Chapter 7.0 -Instrumentation and Control Systems 7.3.6.4 System Performance Anal ys i s and Conclusion  

............................... 7-4 3 7.3.7 Criticality Accident Alarm System ............................................................

..... 7-4 3 7.3.7.1 Design Criteria .......................................

............. 7-43 7.3.7.2 Design Basi s and Safety Requirements  

7-4 3 7.3.7.4 System Performance Analysis and Conclusion