conceptual design of
TRANSCRIPT
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Institute of Nuclear Energy Safety Technology (INEST)
Chinese Academy of Sciences (CAS)
Contributed jointly by FDS Team
www.fds.org.cn
Conceptual Design of
China Lead-based Mini-Reactor
CLEAR-M10d
Presented by Chao Liu
___________________________________________________
Key Laboratory of Neutronics and Radiation Safety, CAS
___ __________________
IAEA TM on Fast SMRs, 24th -27th September 2019
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I. Strategy & Plan
II. CLEAR-M Design Study
III. R&D Progress
IV.Summary
Contents
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China’s Plan on Nuclear Energy( Plan up to 2020 )
Nuclear power plant in China(by August, 2019)
45 reactors (~ 45.9 GWe) in operation
13 reactors ( ~16.6GWe) under construction
National plan of developing nuclear energy before 2020
58 GWe in operation
30 GWe under construction
National plan for nuclear and radiation safety before 2020
More R&D are required to enhance nuclear safety, especially in the basic research of nuclear safety
~79.8 billion RMB investment plan (~13 billion US $)
~5%
~4%
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High Requirements
Independent
Flexibility
Sustainability
Economical
Small-scale Energy Supply Demand in China
Remote area:~12% of land area is desert without electricity supply
Offshore unit:~1/4 of gas and oil reserve in the sea, waiting for exploitation
Distributed power supply: independent industry, with wind or solar energy
Emergency electricity supply:Natural disaster in some provinces
9.6 million km2
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Characteristics of Lead-based Reactor
Safety advantages
Sustainability advantages
Low neutron absorption,
Low moderation, enable
sustaining hard neutron
spectrum
High efficiency
in fuel utilization
Burning long-lived, high-
level actinide wastes
Neutronics:Negative coefficient, Floating core debris
Thermal-hydraulics: Low pressure, no LOCA, natural circulation
Chemistry: Chemical inertial, no reaction with water and air, no
hydrogen explosion
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Major China Lead-based Reactor Program
“863”program“973”program
ITER International/Dom
estic Research Program
Strategic Priority Research Program of CAS
National Major Science and Technology infrastructure
1980s-1990s 2000s 2010s
Y. WU,FDS Team. Design and R&D Progress of China Lead-based Reactor for ADS Research Facility,Engineering,2016, 2(1):124-131.
~30 years lead-based reactor R&D experiences
National High-Tech. Project : Fusion-fission hybrid reactorINEST/FDS in charge of Lead-based hybrid reactor
ITER Project : Fusion reactor
INEST/FDS in charge of China lead-based liquid blanket
Strategic Priority Research Program of CAS : ADS system
INEST/FDS in charge of lead-based sub-critical reactor
China Lead-based Mini-Reactor (CLEAR-M)
Supported by national/local government project and Industry investment
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I. Strategy & Plan
II. CLEAR-M Design Study
III. R&D Progress
IV.Summary
Contents
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Proposal of a Small Modular Lead-based Reactor CLEAR-M10d
10MW class lead-based nuclear reactor
Small modular
• Easy to transport and install
Inherent safety
• Exclusive severe accident
Long refueling period
• Better economy
• Environmentally friendly
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Design Basis
Small modular
Long refueling
period
Size and weight limited(mainly for vessel diameter)
Safety Diversity, redundant, passively
decay heat remove system
Pool type
double wall reactor
Less maintenance requirement
for primary system components(natural circulation)
Relatively less reactivity change
Pb as coolant (to exclude Po issue)
Less cladding corrosion(lower core velocity)
Quickly installation(Simple configuration of primary system)
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Lead-based Mini-Reactor CLEAR-M10d
Parameter Values
Thermal power 35MWth
Electrical power14MWe
10MWe+17MWt
Fuel Ave.18.5% UO2
Core life 10~20 years
Core inlet / outlet temperatures
375/495℃
Reactor vessel length-to-diameter ratio
4:1
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Reactor Core Design
Parameter Value
Enrichment of fuel 19.75%/19%/18%
Number of fuel pins 3500
Diameter of fuel pin 16 mm
Cladding thickness 1 mm
Burnup ~62000 MWd/tULayout of CLEAR-M10d core
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Core Thermal-hydraulicsItems Unit Value
Thermal power MW 35
Coolant - Pb
Inlet /outlet temp. of core ℃ 375/495
Diameter of Pins mm 16
Pitch to diameter 1.2
Height of active zone mm 790
Diameter of active zone mm 1200
Average velocity of core m/s 0.46
Max clading temp. ℃ 540.6
Max fuel temp. ℃ 15590 5 10 15 20 25 30 35 40 45 50 55 60 65
360
380
400
420
440
460
480
500
520
540
560
温度(℃)
轴向距离(cm)
最热通道冷却剂温度
包壳热点温度
Temperature distribution along fuel pin
Tem
p.
(oC
)
Coolant temp. in hottest channel
Cladding max. temp.
Main parameter of primary systerm
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Spiral Steam Generator
Item Shell side Tube side
Power 35MW
Medium LBE H2O
Temperature 495/375℃ 330/450℃
Pressure -- 13MPa
Pressure drop 0.4kPa --
tube Ф17×1.5mm;L=21.2m
Tube bundle Active height
~1460mm
Outer diameter Ф1750mm
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Passive decay heat removal system
Item Parameters for RVACS
Coolant Circulation Natural Circulation
Heat Sink Atmosphere
Power 525 kW(1.5%FP)
Chimney 10m height
• DHR1: Secondary loop (in normal condition)• DHR2: Reactor vessel air cooling system (passive operation)
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Parameter Value
Thermal power 35MWt
Electric power 10MWe
Thermal supply 17MWt
The system efficiency 78%
The inlet temperature
of turbine450℃
The inlet pressure
of turbine13MPa
Heat and Power Cogeneration System Heat and power cogeneration mode (~4 months): (power)10MW, (heat)
17MW
Power generation mode(~8 months):(power)14MW
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I. Strategy and Plan
II. CLEAR-M Design Study
III. R&D Progress1. Key Technology R&D
2. Integrated Test
IV. Summary
Contents
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Key Technologies
• Coolant Technology
• Key Components
• Materials and Fuel
• Operation and Control
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Three Integrated Test Facilities
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Industrial park for lead-based reactor
• laboratory under construction
China Industry Innovation Alliance of Lead-based
Reactors (CIIALER)
• president member INEST/FDS Team, over 100 enterprises
International Co-operative Alliance for Small LEad-based
Fast Reactors (CASLER)
• chair INEST/FDS Team, over 20 members
Further Implementation Activities
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I. Strategy and Plan
II. CLEAR-M Design Study
III.R&D Progress1. Key Technology R&D
2. Integrated Test
IV.Summary
Contents
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Summary
1. Lead-based reactor has many attractive features and may playan important role in the future energy supply.
2. 10MWe China Lead-based Mini-reactor CLEAR-M has beenproposed with three features of
• Inherent safety, exclusion of severe accidents
• Small modular, easily to transport
• Long duration, refueling period
3. Wider and deeper international collaboration is encouraged.