Idaho National Engineering and Environmental Laboratory SCWR Preliminary Safety Considerations Cliff Davis, Jacopo Buongiorno, INEEL Luca Oriani, Westinghouse Electric Co. April 29, 2003 Madison, Wisconsin Idaho National Engineering and Environmental Laboratory Introduction • Safety concept and classification of the events • Parametric thermal-hydraulic calculations of the SCWR during loss-of-feedwater and turbine-trip transients to determine the required response time and capacities of safety systems • Calculations used the RELAP5 computer code, which has been recently improved for SCWR applications • Analysis was performed for a design with solid moderator rods, but the results are expected to be more generally applicable • Transient cladding temperature limit of 840C was used to evaluate the thermal-hydraulic response Idaho National Engineering and Environmental Laboratory Safety Concept • Active, non-safety systems have passive, safety-related back-up to perform nuclear safety functions – Safety functions automatically actuated, no reliance on operator action – Passive features actuated by stored energy (batteries, compressed air) – Once actuated, their continued operation relies only on natural forces (gravity, natural circulation) with no motors, fans, diesels, etc. • Common approach with the most advanced LWR concept proposed by the main NSSS vendors: – Westinghouse AP600/AP1000, IRIS and System 80+ – Framatome-ANP SWR-1000 – GE ESBWR and ABWR • Design Goal: Achieve a degree of safety at least comparable to the more advanced plant concepts being currently proposed. Idaho National Engineering and Environmental Laboratory ANS Classification of Events • Classification of Accident events per ANSI N18.21973 (industry standard based on ANS committee) Condition I: Condition II: Condition III: Condition IV: Normal operation and operational transients Faults of moderate frequency Infrequent faults Limiting faults • Classification according to expected frequency of occurrence • Less frequent events may have more severe consequences Idaho National Engineering and Environmental Laboratory The loss-of-feedwater and turbine-trip transients were evaluated because • SCWR is a once-through direct cycle without coolant recirculation in the reactor vessel – Loss of feedwater is important because • It results in rapid undercooling of the core • It is a Condition II event that must not result in any significant damage to the fuel • Average coolant density is low in the SCWR core and pressurization events result in significant positive reactivity insertion – Turbine trip without steam bypass has the potential to cause a significant increase in reactor power Idaho National Engineering and Environmental Laboratory Parametric calculations for loss of feedwater investigated the effects of • Main feedwater (MFW) coastdown time (0 to 10 s) • Scram (with and without) • Auxiliary feedwater (AFW) flow rate (10-30% of rated feedwater) • Steam relief (20-100% capacity) • Step changes in MFW flow rate (25-100%) • Coolant density reactivity feedback (nominal and high) Idaho National Engineering and Environmental Laboratory Transient temperature limit met when AFW flow exceeded 15% • 5-s MFW coastdown 10% AFW 20% AFW 30% AFW 800 • Scram o Temperature ( C) 1000 • Constant pressure 600 400 200 0 10 20 Time (s) 30 40 Idaho National Engineering and Environmental Laboratory Temperature limit met for 50% step change in MFW flow 1200 • No scram • No AFW o Temperature ( C) 1000 800 25% step 50% step 75% step 100% step 600 400 0 10 20 Time (s) 30 40 Idaho National Engineering and Environmental Laboratory Fast-opening 100%-capacity turbine bypass system helps significantly 1000 • 5-s MFW coastdown o Temperature ( C) 900 800 • Scram 700 • No AFW Constant pressure 20% steam relief 100% steam relief 600 500 400 0 10 20 Time (s) 30 40 Idaho National Engineering and Environmental Laboratory Higher coolant density reactivity feedback lowers cladding temperature 1000 o Temperature ( C) • 5-s MFW coastdown • Scram 800 • No AFW 600 400 Low feedback High feedback 0 10 20 Time (s) 30 40 Idaho National Engineering and Environmental Laboratory Parametric calculations of a turbine trip without steam bypass investigated the effects of • Scram • Safety relief valve (SRV) capacity (0 - 90%) Idaho National Engineering and Environmental Laboratory Pressure response following a turbine trip is acceptable Pressure (MPa) 30 0% SRV, no scram 90% SRV, no scram 80% SRV, scram 28 • Instant control valve closure • Continued MFW at rated flow 26 24 0 2 4 Time (s) 6 8 10 Idaho National Engineering and Environmental Laboratory Small increase in reactor power following turbine trip 1.5 Normalized power • Instant control valve closure 1.0 • Continued MFW 0% SRV, no scram 90% SRV, no scram 80% SRV, scram 0.5 0.0 0 2 4 Time (s) 6 8 10 Idaho National Engineering and Environmental Laboratory Conclusions • SCWR with solid moderator rods can tolerate a 50% step change in MFW flow without scram • Transient temperature limit can be met following a total loss of MFW if AFW flow exceeds 15% of initial MFW flow • AFW flow requirements can be reduced by – Fast-opening 100%-capacity turbine bypass – Higher feedback coefficients typical of designs with water rods • Acceptable pressure response following turbine trip without steam bypass if the SRV capacity is greater than 90% • Power increase following turbine trip without steam bypass and with full MFW flow is much smaller than in comparable BWRs
