Neutronic Analyses for CFETR With Modular Helium Cooled Lithium Ceramic Blanket

2017 ◽  
Author(s):  
Kun Xu ◽  
Minyou Ye ◽  
Yuntao Song ◽  
Mingzhun Lei ◽  
Shifeng Mao
Keyword(s):  
Fusion Energy ◽  
Time Interval ◽  
Vacuum Vessel ◽  
Tritium Breeding ◽  
Thermal Shield ◽  
Sector Model ◽  
Self Sufficiency ◽  
Radial Profiles ◽  
Single Standard ◽  
Test Reactor

China Fusion Engineering Test Reactor (CFETR) is a superconducting tokamak proposed by national integration design group for magnetic confinement fusion reactor of China to bridge the R&D gaps between ITER and DEMO. Since the launch of CFETR conceptual design, a modular helium cooled lithium ceramic blanket concept had been under development by the blanket integration design team of the Institute of Plasma Physics of the Chinese Academy of Sciences, to complete CFETR in demonstrating its fusion energy production ability, tritium self-sufficiency and the remote maintenance strategy. To validate the feasibility, the neutronic analyses for CFETR with this modular helium cooled lithium ceramic blanket were performed. The 1-D neutronic study for CFETR was done in the first place to give a preliminary and quick demonstration of the overall neutronic performance. Meanwhile, the neutronic analyses for a single standard helium cooled lithium ceramic blanket module were done in several times to give more insight for the material and geometry parameters of intra-module structures. Therefore, the principles for neutronic design and the module level optimized parameters were produced, based on which the design of practical blanket modules planted in tokamak vacuum vessel was completed. In the end, the 3-D neutronic analysis for CFETR was done utilizing the MCNP code, in which the 11.25 degree sector model (consist of blanket modules, manifold, support plate, shield, divertor, vacuum vessel, thermal shield and TF coils) was generated with the McCad automated conversion tool from the reference CAD model for analysis, the bi-dimensional (radial and poloidal) neutron source map was plugged via general source definition card to stimulate the D-T fusion neutrons. The concerned neutronics parameters of CFETR, mainly including the tritium breeding ratio to characterize tritium self-sufficiency, the energy multiplication factor to characterize power generation, as well as, the inboard mid-plane radial profiles of neutron flux densities, helium production rate, displacement damage rate and the energy deposition to characterize the shielding performance, were produced. In principle, the neutronics performance of CFETR with modular helium cooled lithium ceramic blanket is promising. The tritium breeding capability meets the design target and, by referring to that for ITER and the EU DEMO fusion power plant, the inboard mid-plane shielding is effective to fulfill the radiation design requirement of the superconducting TF-coils, resulting in a compulsory warm-up time interval of ∼2 FPY for TF-coils. The nuclear heating loads to other CFETR components were generated. As an outcome of this work, the applicability of McCad on CFETR neutronic modeling is demonstrated.

Conceptual Design and Neutronics/Thermal-Hydraulic Coupling Optimization Analyses of Two Typical Helium Cooled Solid Breeder Blanket Modules for CFETR Phase II

2018 ◽  
Author(s):  
Shijie Cui ◽  
Dalin Zhang ◽  
Wenxi Tian ◽  
G. H. Su ◽  
Suizheng Qiu
Keyword(s):  
Conceptual Design ◽  
Phase Ii ◽  
Fusion Energy ◽  
Operation Condition ◽  
The Past ◽  
Self Sufficiency ◽  
Hydraulic Coupling ◽  
The Future ◽  
Test Reactor ◽  
Solid Breeder Blanket

Chinese Fusion Engineering Test Reactor (CFETR) is a new test Tokamak device which is now being designed in China to make the transition from the International Thermonuclear Experimental Reactor (ITER) to the future Fusion Power Plant (FPP). Breeding blanket is the key component of fusion reactor which is mainly responsible for the tritium self-sufficiency and fusion energy conversion. In the past few years, three kinds of blanket conceptual design schemes have been proposed and tested in parallel for CFETR Phase I, in which the helium cooled solid breeder (HCSB) blanket concept is acknowledged as the most promising one. However, nowadays, the design phase of CFETR has gradually changed from I to II aiming for the future DEMO operation condition, the main parameters of which are quite different from the previous one. Therefore, it’s necessary to perform conceptual design and various analyses for the HCSB blanket under the new working condition. In this work, firstly, a new conceptual design scheme of HCSB blanket for Phase II is put forward. Then, the radial build arrangements, of the two typical blanket modules are optimized by using the NTCOC. This work can provide valuable references for further conceptual design and neutronics/thermal-hydraulic coupling analyses of the HCSB blanket for CFETR Phase II.

Preliminary Neutronics Design and Analysis of the Bit Helium Cooling Ceramics Blanket for CFETR

2013 ◽  
Author(s):  
Jia Li ◽  
Songlin Liu ◽  
Xuebing Ma ◽  
Yong Pu ◽  
Xiangcun Chen
Keyword(s):  
Calculation Model ◽  
Vacuum Vessel ◽  
Concept Design ◽  
Reactor Model ◽  
Plasma Parameters ◽  
Blanket Design ◽  
Self Sufficiency ◽  
Nuclear Heat ◽  
Tube Type ◽  
Test Reactor

CFETR is a Tokamak fusion engineering test reactor whose concept design is being developed in China. It is a key issue for breeding blanket design to attain tritium self-sufficiency as one of important missions of CFETR. This paper presents a preliminary neutronics design and analysis employing a BIT (breeder inside tube) type helium cooling ceramics blanket (HCCB) design concept as one of CFETR blanket design candidates. Firstly, 1D reactor model was designed using ceramic breeder Li4SiO4 and beryllium in pebble for multiplier. The primary blanket parameters were optimized to yield the higher tritium breeder ratio (TBR), including the thickness of outboard breeder blanket, enrichment of Li-6 and ratio of Li4SiO4 to Be. Secondly, based on the optimized blanket parameters and plasma parameters, a detailed 3D neutronics calculation model of 22.5° reactor sector was developed, including blanket modules, shield, divertor, vacuum vessel and TF coil. The gap between blanket modules had been taken into account. Finally, a set of nuclear analyses were carried out addressing the key neutronics issues by Monte Carlo neutron-photon transport code MCNP version 5 and the FENDL-2.1 data library. The preliminary analysis results showed that the global TBR could achieve 1.21 which satisfied the tritium self-sufficiency demand. Nuclear heat, neutronic flux, and distribution of neutron wall loading (NWL) were also analyzed as source terms of the blanket thermal-hydraulics design and reactor nuclear response.

scholarly journals Study on Multiphysics Coupling and Automatic Neutronic Optimization for Solid Tritium Breeding Blanket of Fusion Reactor

Energies ◽  
2021 ◽  
Vol 14 (17) ◽  
pp. 5442
Author(s):  
Shen Qu ◽  
Qixiang Cao ◽  
Xuru Duan ◽  
Xueren Wang ◽  
Xiaoyu Wang
Keyword(s):  
High Efficiency ◽  
Fusion Reactor ◽  
Optimization Method ◽  
Maximum Temperature ◽  
Tritium Breeding ◽  
Neutron Shielding ◽  
Self Sufficiency ◽  
Multiphysics Coupling ◽  
Scientific Significance ◽  
Test Reactor

A tritium breeding blanket (TBB) is an essential component in a fusion reactor, which has functions of tritium breeding, energy generation and neutron shielding. Tritium breeding ratio (TBR) is a key parameter to evaluate whether the TBB could produce enough tritium to achieve tritium self-sufficiency (TBR > 1) for a fusion reactor. Current codes or software struggle to meet the requirements of high efficiency and high automation for neutronic optimization of the TBB. In this paper, the multiphysics coupling and automatic neutronic optimization method study for a solid breeder TBB is performed, and a corresponding code is developed. A typical module of China fusion engineering test reactor (CFETR) helium cooled ceramic breeder (HCCB) TBB was selected, and a 3D neutronics model of an initial scheme is developed. The automatic neutronic optimization was performed by using the developed code for verification. Results indicate that the TBR could increase from 1.219 to 1.282 (~5.17% improvement), and that the maximum temperature of each type of material in the optimized scheme is below the allowable temperature. It is of great scientific significance and engineering value to explore and study the algorithm for automatic neutronic optimization and the code development of the TBB.

scholarly journals Study on fusion blanket with ceramic solid as tritium breeding material

2021 ◽  
Vol 2072 (1) ◽  
pp. 012004
Author(s):  
I R Maemunah ◽  
Z Su’ud ◽  
A Waris ◽  
D Irwanto
Keyword(s):  
Fusion Reactor ◽  
The Self ◽  
Tritium Breeding ◽  
Thermodynamic Behavior ◽  
Breeding Material ◽  
Self Sufficiency

Abstract Variation of solid ceramic breeding might be one of the excellent candidates in a fusion reactor. The LiAlO2, Li4SiO4, Li2O, and Li2ZrO3 show pretty good requirements in tritium breeding capability and thermodynamic behavior. Especially for LiAlO2 and Li2ZrO3, in which they could be possible to breed without neutron multiplying needed as blanket used generally in order to reach the self-sufficiency reactor. So that, it makes up the material could be possible as high-estimation breeder material.

Design and simulation of a blanket module for TOKAMAK reactors

2019 ◽  
Vol 34 (13) ◽  
pp. 1950103 ◽  
Author(s):  
H. Sadeghi ◽  
M. Habibi
Keyword(s):  
Comsol Multiphysics ◽  
Fusion Reactors ◽  
Tritium Breeding ◽  
Mcnpx Code ◽  
Self Sufficiency ◽  
Proposed Model ◽  
Tokamak Reactors ◽  
Breeding Ratio ◽  
Neutron Multiplier ◽  
Temperature And Pressure

In this paper, we simulated an appropriate model for an advanced breeding blanket of future TOKAMAK fusion reactors with solid breeder (Li4SiO4) building material in the form of pebble beds, ODS ferritic steel as structural material and Beryllium as neutron multiplier. With the MCNPX code, the efficiency of this proposed model for the production and self-sufficiency of tritium was investigated. Total tritium breeding ratio of 1.15 is achieved. The helium-cooled pebble bed system and parameters of temperature and pressure are investigated by COMSOL multiphysics simulating software. The temperature of helium as cooling gas never exceeded 530[Formula: see text]C and the tolerable temperature of beryllium was obtained at 650[Formula: see text]C. In the proposed design, it is adequate to enrich the 6Li to 40%.

Manufacturing progress of first delivery sector of ITER vacuum vessel thermal shield

2018 ◽  
Vol 134 ◽  
pp. 132-136 ◽  
Author(s):  
Dong Kwon Kang ◽  
Kwanwoo Nam ◽  
Kyoung-O Kang ◽  
Chang Hyun Noh ◽  
Wooho Chung ◽  
...  
Keyword(s):  
Vacuum Vessel ◽  
Thermal Shield

Optimal Design for Helium Cooled Solid Breeder Blanket of CFETR

2020 ◽  
Author(s):  
Jose A. Nogueron ◽  
Zhang Baorui ◽  
Zhou Zhiwei
Keyword(s):  
Fluid Dynamic ◽  
Fusion Energy ◽  
Heat Removal ◽  
Cooling Capacity ◽  
Radiation Shielding ◽  
Breeding Cycle ◽  
Tritium Breeding ◽  
Tritium Production ◽  
Nuclear Fusion Reactor ◽  
On The Road

Abstract On the road to achieving fusion energy production at a commercial level, China has proposed the design of a nuclear fusion reactor based on the tokamak configuration. Aimed to produce self-sustained burning plasma and a closed tritium breeding cycle, this device is expected to provide a bridge between ITER and DEMO designs. The Breeding Blanket (BB) is one of the key technological challenges to be designed in order to guarantee sufficient tritium production, heat removal capabilities and radiation shielding protection. Two preliminary designs of the Helium-Cooled Solid Breeder (HCSB) blanket have been suggested to be subjected to further investigation. Despite the fact that both designs use the same materials, they present completely different geometrical arrangements. In the present analysis, these two concepts of the HCSB are examined, addressing the critical design issues that affect the performance of the system. A neutronic analysis is performed to calculate the Tritium Breeding Ratio (TBR), which is a crucial parameter to meet tritium production requirements. Based on this investigation, the cooling capacity of the reactor is analyzed with the help of a Computational Fluid Dynamic (CFD) software through a dynamic evaluation. Valuable conclusions can be extracted from the results of this work, which can be referenced for investigations regarding further studies of HCSB blankets.

CFD Modelling of Loss of Vacuum Accident (LOVA) for CFETR

2018 ◽  
Author(s):  
Youyou Xu ◽  
Songlin Liu ◽  
Xiaoman Cheng ◽  
Xuebin Ma
Keyword(s):  
High Speed ◽  
Reverse Flow ◽  
Fluid Dynamic ◽  
Fusion Energy ◽  
Normal Operation ◽  
Vacuum Vessel ◽  
Cfd Modelling ◽  
Ansys Cfx ◽  
Section Area ◽  
Break Area

Chinese Fusion Engineering Testing Reactor (CFETR) is a tokamak-type machine and next device in the roadmap for the realization of fusion energy in China, which aims to bridge the gaps between the International Thermonuclear Experimental Reactor (ITER) and the demonstration reactor (DEMO) [1]. The accident sequence starting from loss of vacuum accident (LOVA) is an important issue concerning the performance of CFETR. During LOVA, air will leak into the vacuum vessel (VV) causing fast pressurization of VV. At the same time, the high speed airflow jet will result in migration and re-suspension of the large quantity of tungsten dust produced and deposited in the lower part of plasma chamber, causing possibilities of radioactive dust leakage into the workshop and environment. In order to conduct a comprehensive analysis of the accident sequence, firstly, the airflow characteristics of LOVA should be studied. In this article, a postulated rupture of different section area is assumed due to a failed component at the equatorial port level. The computational fluid dynamic (CFD) modelling of LOVA was conducted by ANSYS CFX. The results show that the break area has significant influences on the characteristics of the airflow. Two swirling airflows are formed in the upper and lower part of the torus. The airflow characteristics are quite different when the LOVA happens during maintenance or during normal operation. A reverse flow occurs when the LOVA happens during normal operation. Yet can not be observed when LOVA occurs during maintenance. The results are the basis to the further safety study of CFETR such as the re-suspension, migration and explosion of dust.

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