STRAIN ANALYSIS OF REACTOR TYPE CORE STRUCTURES BY CONSIDERING UNCERTAINTIES OF GRAPHITE’S PROPERTIES
DOI: http://dx.doi.org/10.17146/tdm.2021.23.1.6172
Abstract
The power reactor with high-temperature gas-cooled reactor (HTGR) technology uses uranium as the reactor fuel. The energy from fission is converted to electrical energy or used for other needs such as hydrogen production or other research activities at high temperatures of around 700 °C. This operation does not allow the use of metal as the core material for the reactor. The material that fits the requirements as a core structure is graphite. Graphite material has specific characteristics, namely the parameters of the modulus of elasticity, coefficient of thermal expansion, and the volume which changes due to temperature and neutron dose. Because the structure of the reactor core is a vital component in the reactor, this research will develop a method for the design of the reactor core structure with graphite material. The design method is based on "Design by Analysis" which specifically refers to the strain analysis on each of the reactor core components. The design method developed is based on the finite element method. The object of this research is the side reflector made from the Toyo Tanso IG-110 series graphite. Based on the analysis of heat distribution and heat stress for the material before the effect of neutron exposure, the temperature distribution on the side reflector was found, as well as the displacement and heat stress that occurs. isotropic properties, Young's modulus and Poisson’s ratio values can be verified and estimated. The purpose of this research is to analyze the strain of the reactor core structure by taking into account the uncertainty of the graphite properties.
Full Text:
PDFReferences
- Himawan R., Sudadiyo S., Saragi E. Comparison Study on Model of Creep Strain for Graphite Material at HTGR. Prosiding Seminar Nasional Teknologi Energi Nuklir. 2016. 385-392.
- Liu D., Mingard K., Lord O.T., Flewitt P. On the Damage and Fracture of Nuclear Graphite at Multiple Length-scales. J. Nucl. Mater. 2017. 493:246-254.
- Heijna M.C.R., de Groot S., Vreeling J.A. Comparison of Irradiation Behaviour of HTR Graphite Grades. J. Nucl. Mater. 2017. 492:148-156.
- Tian D., Shi L., Sun L., Zhang Z., Zhang Z., Zhang Z. Installation of the Graphite Internals in HTR-PM. Nucl. Eng. Des. 2020. 363:1-10.
- Xu Y., Li H., Xie F., Cao J., Tong J. Source Term Analysis of Tritium in HTR-10. Fusion Sci. Technol. 2017. 71(4):671-678.
- Wankui Y., Songbao Z., Yaoguang L., Weili N., Li D. Neutron Fluence Analysis of Graphite Reflector in SPRR-300 during the Whole Reactor Lifetime. Ann. Nucl. Energy. 2017. 106:91-96.
- He X., Shi L., Li H., Tan J., Zhang B., Fok A., et al. Experimental Study to Estimate the Surface Wear of Wuclear Graphite in HTR-PM. Ann. Nucl. Energy. 2018. 116:296-302.
- Himawan R., Lie F., Dewi Basoeki P., Haryanto M. Applicability Study of Ultrasonic Flaw Detector For Nuclear Grade Graphite Examination. J. Phys. Conf. Ser. 2019. 1198:1-8.
- Li Z. Sen, Tang L.S. Using Synchrotron-Based X-Ray Microcomputed Tomography to Characterize Water Distribution in Compacted Soils. Adv. Mater. Sci. Eng. 2019. 2019:1-12.
- Himawan R., Sutrasno, Santoso S.B. Non-destructive Evaluation of Nuclear Grade IG-110 Graphite Using Constant Potential X-Ray. J. Phys. Conf. Ser. 2020. 1436:1-7.
- Hartini E., Himawan R., Susmikanti M. Fracture Mechanics Uncertainty Analysis in the Reliability Assessment of the Reactor Pressure Vessel: (2D) Subjected To Internal Pressure. J. Teknol. Reakt. Nukl. Tri Dasa Mega. 2016. 18(2):55-64.
- Susmikanti M., Himawan R., Hafid A., Hartini E. Evaluation on Mechanical Fracture of PWR Pressure Vessel and Modeling Based on Neural Network. J. Teknol. Reakt. Nukl. Tri Dasa Mega. 2016. 18(2):87-100.
- Hashim A., Kyaw S., Sun W. Modelling Fracture of Aged Graphite Bricks under Radiation and Temperature. Nucl. Mater. Energy. 2017. 11:3-11.
- Hartini E., Himawan R., Susmikanti M. Analisis Probabilistic Fracture Mechanics Pada Evaluasi Keandalan Bejana Tekan Reaktor Secara 3-D. Urania J. Ilm. Daur Bahan Bakar Nukl. 2018. 24(1):51-60.
- Bobba S., Abrar S., Rehman S.M. Probability Study on the Thermal Stress Distribution in Thick hk40 Stainless Steel Pipe using Finite Element Method. Designs. 2019. 3(1):1-26.
- Susmikanti M., Hartini E., Saepudin A., Sulistyo J.B. Component Analysis of Purification System of RSG-GAS. J. Pengemb. Energi Nukl. 2018. 20(1):31-39.
- Hao C., Li P., She D., Zhou X., Yang R. Sensitivity and Uncertainty Analysis of the Maximum Fuel Temperature under Accident Condition of HTR-PM. Sci. Technol. Nucl. Install. 2020. 2020:1-21.
- Hong C.C., Chang C.L., Lin C.Y. Static Structural Analysis of Great Five-axis Turning-milling Complex CNC Machine. Eng. Sci. Technol. an Int. J. 2016. 19(4):71-84.
Refbacks
- There are currently no refbacks.