Code package for analysis of fast reactor safety: tasks of its updating and development
State Scientific Centre of the Russian Federation – Institute for Physics and Power Engineering named after A.I. Leypunsky, Obninsk, Russia
V.M. Poplavsky, I.A. Kuznetsov, Yu.E. Shvetsov, A.V. Volkov, Yu.M. Ashurko, M.V. Kashcheev, L.A.
Shchyokotova, G.A. Kuntsyo
International Meeting FR09 7-11 of December, 2009 Kyoto, Japan
2
Introduction
1. Russian approach to fast reactor safety analysis was formed on the basis of the large experience gained in designing and operating of nuclear reactors and, in particular, fast neutron reactors.(This experience included in itself large sodium leaks, leading to radioactive sodium releases from the primary circuit of the reactor, as well as failures of steam generator tubes causing water and steam penetration to the secondary sodium).
2. Experience gained in preventing and mitigating such abnormalities and accidents was used for updating normal operation and safety systems and improving reactor operation regulations and Regulatory documents
3. Main document that determined common regulatory approach and common requirements to safety analysis of fast reactors in Russia is OPB-88/97. It contents brief list of specific requirements regulating characteristics of various type reactors with regard to safety
4. One more important document - Special standard contents of safety analysis report.
SAFETY is its capability of keeping radiation doses of personnel, inhabitants and environment within permissible limits under normal operating conditions, abnormal operating conditions and in case of accident (OPB-88/97) .
3
Grounds of NPP safety concepts and tasks related to safety analysis
RUSSIAN concepts of safety analysis of fast reactors that is reflected in the Russian regulatory documents corresponds to “defense-in-depth” principle developed by IAEA .
2 3 4 1 2 … mn-2 n-1 n
Analysis of abnormaloperating conditions
PSA-1Analysis of design
basis accidents
Evaluation ofeffectiveness
of safety systems
Evaluation offrequency of
the core damages
Evaluation ofeffectiveness
of safety systems
Analysis of beyond
design accidents
Evaluation ofeffective dose
ratesof inhabitants
Initial events of abnormal operating conditions
Development of actionsfor improvement
of safety
Preparation of plan of
protection of the personnel
and the population
Evaluation of radiation
consequencesof accidents
1
Initial events of design basis accidents
PSA-2
Deterministic safety analysis Probabilistic safety analysis
4
Deterministic safety analysis of NPP designAnalysis of abnormal operation
The main objective of analysis of reactor abnormal operating conditions is to justify design requirements to the speed of response, effectiveness and other characteristics of safety systems and confirm meeting safety criteria and requirements in NPP design.
Tentative list of initial events (IE) of abnormal operating conditions for FR (15 from 40):• reactor vessel failure (leakage);• de-energizing of primary pump in different operation modes;• closure of one check valve with all primary pumps in operation;• incorrect opening of check valve in shut-down loop of heat removal system with all other loops in
operation;• unauthorized movement of control rod in various reactor states;• unauthorized movement of shim rod in various reactor states;• penetration of hydrogen containing materials to the core;• emergence of gas bubbles in the core and their movement through SA;• water leak into sodium;• loss of feed water supply to one or all SG;• loss of grid power supply (loss of power supply of auxiliaries);• failures of ionization chambers including that caused by failure of their heat removal; • failure of the main secondary pump;• disconnection of turbo-generator from the grid;• failure of the main steam pipeline, etc.IE list may change on the basis of analysis of specific reactor plant design, its operating modes and maintenance regulations
5
Deterministic safety analysis of NPP designAnalysis of design basis accidents (DBA)
In Standard Contents of Safety Analysis Report as Applied to NPP with FR there is the following tentative list of DBA IE:
GENERAL STATEMENT: It should be demonstrated that safe operation limits related to the fuel element failures, are not exceeded.
“Most important DBA” is a full blockage of FSA cross section. It should be proved that there is no “chain” propagation of destruction from one SA to another. This propagation if it take place it must be limited and total number of destoyed SAs is not more than 7.
• partial or full blockage of one SA because of materials swelling, penetration of impurities in the coolant or foreign objects followed by destruction and meltdown of the fuel elements;
• failure of the primary piping in the section having no safety jacket;• failure of the primary cover gas system;• failure of spent fuel storage drum wall.
6
Deterministic safety analysis of NPP designAnalysis of beyond design basis accidents (BDBA)
Based on the estimation of effective and equivalent radiation doses of personnel and inhabitantsduring one year after accident, conclusions are drawn on meeting Radiation Safety Standardsand necessity of protection measures, in particular, evacuation of inhabitants
BDBA list (approved by the RF GAN):• loss of grid power supply with simultaneous failure of reactor safety system;• total loss of grid and independent power supply;• guillotine rupture of the primary sodium pipeline having no safety jacket;• guillotine rupture of the secondary sodium pipeline; • water-sodium interaction in the steam generator cell;• total loss of grid and independent power supply with simultaneous failure of reactor safety system (combination of the first and the second accident scenarios) (ULOF);
• failure of the main and guard reactor vessels and fire in the reactor pit;• penetration of considerable amount of hydrogen or carbon-containing materials (from lubrication system of the main primary pump) to the primary sodium;• fire causing damage of control and power supply systems.
Most representative and probably most dangerous in the List is ULOF.
7
Computer codes used for safety analysis of NPP
DINROS is system code intended for analysis of transient and accident processes in multi -circuit multi-loop reactor plants with detailed modeling of reactor design.
Total number of codes normally involved in safety analysis is more then 20.14 from 20 codes will be briefly presented below.• Brief description of the codes with the area of its application;• Examples of codes validation against experiments for some of them;• Examples of codes application for some of them.
CODE MODEL• 1D 1-phase thermal hydraulic models for primary, secondary and turbine systems• simulation of reactivity feedbacks, control system and safety systems of reactor • thermal-mechanical pin model
CODE APPLICATION:• abnormal operating conditions;• DBAs that do not lead to sodium boiling
0 2 4 6 8 10âðåì ÿ , ñ
380
400
420
440
460
òåìïå
ðàòó
ðà, 0 C
0 40 80 120âðåì ÿ, ñ
420
440
460
480
òåìïå
ðàòóð
à, Î Ñ
calculationexperiment
0 20 40 60 80 100âðåì ÿ, ñ
-1.2
-0.8
-0.4
0.0
0.4
óðîâ
åíü,
ìexperiment calculation with 10s. thermocouple time
constant loop 4 loop 5 loop 6
experiment
Leve
l, m
calculation
Time, sTime, s Time, s
Temp
eratur
e, °C
Temp
eratur
e, °C
calculation of sodium temperature
Verification of DINROS code (a) Comparison of calculated and measured temperature values at SA outlet in experiment with loop 5 shut-down. Sodium temperature (b) temperature at the outlet of SA in experiment with drop of safety rod(c) Sodium level in vessels of main pumps of BN-600 reactor with shut-down of 4th and 5th loops
a) b) c)
8
Computer codes used for safety analysis of NPPGRIF code
CODE APPLICATION:• abnormal operating conditions and accidents where spatial distributions of parameters over reactor are important (decay heat removal in the case of LOF) ;• DBAs that do not lead to sodium boiling
CODE MODEL• 3D 1-phase thermal hydraulic models for reactor primary circuit including 3D model for inter wrapper space in the core;• 1D 1-phase thermal hydraulic models for secondary and auxiliary systems.
GRIF is also system code intended for analysis of transient and accident processes in sodium cooled FR but with the emphasis on more detailed description of spatial distributions of thermal-hydraulics parameters in primary circuit
Flow
rate,
g/s
50 40 30 20 10 0
0 1 2 3 4 Time, hours
Flow
rate,
g/s
0 100 200 300 400 500 Time, s
100 80 60 40 20 0
- experiment- calculation
50 45 40 35 30
0 1 2 3 4 Time, hours
Outlet
Inlet
Outlet
Inlet
50 45 40 35 30
0 100 200 300 400 500 Time, s
Temp
eratur
e, 0 С
Temp
eratur
e, 0 С
Verification of GRIF code. RAMONA experiments.
a) Water flow rate in the core b) Water temperature at the inlet and outlet of the core
9
Computer codes used for safety analysis of NPPHYDRON code
CODE APPLICATION:DBA – partial blockage of SA cross section
CODE MODEL• 3D 1-phase thermal hydraulic models for FSA;• 3D thermal model for each pin belonging to FSA
HYDRON - code is intended for analysis of transient spacial distributions of thermal hydraulic parameters in core subassemblies
Verification of HYDRON code on FZK experiments .Central blockage 49%. Radial temperature profiles in sodium.
( Run №1: V0=4 m/s; q=68 W/сm2; Tin=400°C) .
10
Computer codes used for safety analysis of NPPSUBMELT code
EXAMPLE of APPLICATION: Rapid blockage of SA inlet cross section for BN-600 reactor
SUBMELT- the code was developed for analysis of process of FSA destruction under conditions of DBA caused by blockage
Fields of components concentrations in τ time points in failed SA
τ=8.2 sτ=4.7 sτ=3 s τ=9.9 s τ=10.5 s
fuel pelletmolten fuelfuel crustcladding steelmolten cladding steelsteel crustsodium vaporliquid sodiumwrapper steelblockage
Wrapper ofblocked FSA
Wrapper of adjacent SAPins
CODE MODEL• 2D multi-component multi-speed thermally non-equilibrium model for of boiling , melting and freezing of the components
Main objective – to prove non-propagation of the accident to the neighboring SA
11
Auxilary codes for study of acident consequencies
CODE APPLICATION:analysis of abnormal operating conditions and DBA leading to fuel element failure and release of fission gas to sodium (Blockages)
CODE MODEL•3D model of subassembly;•two-component two-speed thermally non-equilibrium model of thermal-hydraulics
TWOCOM - for analytical study of the consequencies of accidents related to gas injection into sodium flow
Verification of TWOCOM code.Experiments with gas release to sodium loop (O-Arai, Japan). Pin-surface
temperature rise (a) and gas component concentration field at the hole level (b), hole in the fuel element is shown by arrow.
a) b)
203040506070
0 1 2 3 4 5 6 7 8
Tw -T
in, o C
203040506070
0 1 2 3 4 5 6 7 8
Tw -T
in, o C
203040506070
0 1 2 3 4 5 6 7 8Pin number
Tw -T
in, o C
experiment G-4619calculation G-4619
Gas-injection plan
40 mm downstream from gas-injection plan
80 mm downstream from gas-injection plan
0.93 -- 1.00 0.87 -- 0.93 0.80 -- 0.87 0.73 -- 0.80 0.67 -- 0.73 0.60 -- 0.67 0.53 -- 0.60 0.47 -- 0.53 0.40 -- 0.47 0.33 -- 0.40 0.27 -- 0.33 0.20 -- 0.27 0.13 -- 0.20 0.07 -- 0.13 0.00 -- 0.07
Experiment G-4619 Calculation G-4619
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Auxilary codes for study of acident consequencies TWOCOM code
EXAMPLE of TWOCOM APPLICATION to BN-600 safety analysis:
Gas concentration in vertical plane (central cross section) in various time pointsGas flowing out from central fuel element through 2mm dia. hole in the bottom and in the mid
plane of the core.
τ=0.018s τ=0.098s τ=0.178s τ=0.022s τ=0.062s τ=0.142s
hole in the core mid plane (k=13)hole in the core bottom level (k=5)
CONCLUSION from the study: There is no pin-to-pin propagation of damage inside subassembly
13
Auxilary codes for study of acident consequencies
CODE APPLICATION:“ND” code is used for estimation of effectiveness of fuel element failure detection system
CODE MODEL•1F 3D model reactor thrmal hydrailics;•Lagrangian and Eulerian approaches for modeling of transportation of delayed neutron precursors along primary circuit.
ND code - analysis of transportation of delayed neutron precursors released from failed fuel elementsin the reactor and determination of changes of delayed neutron sensor signals
Example of application of “ND” code is presented in POSTER 03-15P
14
Computer codes used for safety analysis of NPPBOS code
CODE APPLICATION:ULOF, UTOP accidents in the frame of safety justification
CODE MODEL • two-component thermally non-equilibrium model of two-phase flow• 2D core model for core as whole combined with 2D simulation of thermal hydravlic parameters inside FSA• Only core region is modeled
BOS is a code for analytical studies on reactor accidents accompanied by sodium boiling in the core
Verification of BOS code aganst FZK experiment on sodium flow rundown through 37-pin SA (а) Axial distribution of sodium temperature in the central channel (b) Radial distribution of sodium temperature for axial coordinate z=775 mm(c) Total volume of sodium vapor in SA
Time, s
800
400
0
600
200
1000
Vapo
r volu
me, cm
3
ExperimentCalculation BOS (α)Calculation BOSCalculation GRIF-SM
5 6 7 8 9 10 11 12 13Time, s
800
400
0
600
200
1000
Vapo
r volu
me, cm
3
ExperimentCalculation BOS (α)Calculation BOSCalculation GRIF-SM
5 6 7 8 9 10 11 12 13
heated area unheatedarea
Temp
eratur
e, °C
Z, mm i, cannel number
At the time of boiling
Steady state
Ts
0 200 400 600 800 1000 12003004005006007008009001000
1 2 3 43004005006007008009001000
0 200 400 600 800 1000 12003004005006007008009001000
1 2 3 43004005006007008009001000
Calculation BOSCalculation BOS (α)
Experiment Calculation BOSCalculation BOS (α)
Experiment
a) b) c)
15
Computer codes used for safety analysis of NPPBOS code (2)
Verification of BOS code on sodium boiling in the sodium loop under natural circulation conditionsSodium velocity at the inlet of subassembly (FZK experiment N25). Disturbance of boiling process
in sodium natural flow in case of linear power increase up to 40 W/cm
Time, s
0 1 00 20 0 300 400 500
0.00
0.05
0.10
Stage 2 Stage 3Stage 1 Stage 4
Time, sVe
locity
, m/s
Veloc
ity, m
/s
Stage 2 Stage 3Stage 1
0 1 00 20 0 300 4 00 500
0.00
0.05
0.10
Stage 4
calculation
experiment
16
Computer codes used for safety analysis of NPPCOREMELT code
CODE APPLICATION area: ULOF and UTOP BDBAsCODE MODEL
• multi-component multi-speed thermally non-equilibrium model for of boiling , melting and freezing• 2D modeling of whole primary reactor circuit
COREMELT - code for study of core desruption
Fields of components concentrations in τ time points
τ=27 sτ=25.5 s τ=27.5 s τ=28.5 s
fuel pelletmolten fuelfuel crustcladding steelmolten cladding steelsteel crustsodium vaporliquid sodiumwrapper steel
CORE
Header
Upper plenum
EXAMPLE of APPLICATION: Analysis of initial phase of ULOF accident for BN-600
17
Computer codes used for safety analysis of NPPSACTA code + ACME code (Auxilary codes)
CODEs APPLICATION: evaluation (in combination with neutronic code) of reactivity effects for accidents related with core radial and axial thermal expansion (Initial stage of ULOF and atc.)
SACTA -� ACME � TRIGEX
SACTA - 3D 1F thermal hydraulic code for detailed analysis of temperature in the core including 3D temperature in SA wrappers for each core subassembly.
Temperature field in peripheral core SA under accident conditions
τ = 5 s τ = 10 s τ = 15 s
ACME - Analysis of strains and bending of the core and blankets SAs caused by materials swelling, thermal expansion, thermal and radiation creep and heterogeneous temperature
Azimuthal non-uniformity of temperature in horisontal SA cross section leads to SA bending and this results in proper reactivity effects
SA wrappertemperature
Coredeformation Reactivityeffect
Example of SACTA calculation �
Example of application of “SACTA” code is presented in POSTER 06-29P
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Computer codes for study of FINAL stages of BDBAs of NPP
INTERACT, DINAMIKA-3, ANPEX, BRUT, RGT – the set of codes intended for analysis of late stages of BDBAs
INTERACT was developed for modeling of fuel-coolant thermal interaction in the upper plenum in order to determine pressure loading of reactor structures (vessel. Code is used for analysis of consequences of BDBAs. (Post disassembly expansion stage of ULOF and UTOP )
DINAMIKA-3 – Code purpose is evaluation of stresses and strains in reactor vessel and in-vessel structures on the basis of 3D finite-element technique.
ANPEX code was created for 2D analysis of recriticality event.
BRUT code. His application area is 2D analysis of transient processes of molten core material relocation in order to make a conclusion on confinement or non-confiment of molten materials within reactor vessel.
RGT – is special thermal hydraulic code for 3D analysis of radioactive materials transportation in cover gas system of the reactor in order to determine the release of these radioactive materials through ventilation stack to the atmosphere.
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Plans for future
All above mentioned codes should be validated and proper sertificate should be issued.
At the moment Codes are in different stages of verification process. For some of them validation is almost finished and most important document – Verification report - is issued. For others verification is still under way.
Task “number one” for nearest future – to comlete validation and to attest codes used for safety justification before the end of 2012.
MORE GLOBAL PLANS for future:•development of advanced codes for support of design work on reactors and NPP as a whole on the basis of modern technologies;
• development of codes package for optimization of design approaches as applied to the NPP from the standpoint of safety;
• development of software for informational support of operation, diagnostics of failures, estimation of residual lifetime of reactor core elements and NPP components.
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