The construction of a solution-type medical isotope test reactor for the production of isotopes such as ⁹⁹Mo and ¹³¹I is one of the important initiatives to achieve self-sufficient and controllable supply in China's medical isotope market. This article briefly introduces the application status, production principles, and production methods of medical isotopes, as well as the development overview of homogeneous solution-type reactors both domestically and internationally. It systematically elaborates on the system composition and design of the medical isotope test reactor, including the reactor and its major systems, isotope extraction process systems, and supporting systems. Furthermore, it provides a detailed explanation of the main technical issues, such as reactivity stability, radiation protection design, prevention of fuel solution precipitation, corrosion resistance of structural materials, critical safety of fuel solutions, isotope extraction processes, uranium recovery technology, fuel purification technology, and radioactive waste gas treatment technology.

Transition boiling is a very important thermo-hydraulic phenomenon in the core analysis of pressurized water reactor (PWR), especially in the accident analysis. The accurate simulation of this phenomenon can improve the accuracy of core wall temperature prediction by software. Considering the small range of the transition boiling area and the large variation of the parameters, and the limitation of the test method, there is a lack of recognized and suitable transition boiling model. In order to evaluate the effect of different transition boiling models, six transition boiling models commonly used in the world are compared in this paper. Based on LOCUST, a thermo-hydraulic system analysis software independently developed by China General Nuclear Power Corporation, code development of the six transition boiling models and comparative study of software calculation results and test data were realized. The results show that the Chen relation and the Bjornard-Griffith relation are the best in simulating transition boiling phenomenon, showing good agreement with the experiment data. The results of this study lay the foundation for further exploring the differences and computational effects of various transition boiling heat transfer models, and provide reference for the selection of transition boiling heat transfer models in the development of thermo-hydraulic system analysis software.

Five strength tests are conducted for a candidate domestic fine-grained nuclear graphite used in gas-cooled micro-reactors, including the uniaxial tensile test as per the standard of Deutsche Industrie Norm (DIN), as well as the three-point flexural test, the Brazilian disc splitting tensile test, the uniaxial compressive test, and the uniaxial tensile test as per the standards of American Society for Testing and Materials (ASTM). Based on the test results, the strength probability distributions are systematically analyzed. It was found that the fitting results of the two-parameter Weibull distribution to the five types of strength data all pass the Anderson-Darling test (A-D test). Compared to the normal distribution and the three-parameter Weibull distribution, the fitting results of the two-parameter Weibull distribution are more conservative at low probabilities. Therefore, it is reasonable to use the two-parameter Weibull distribution to describe the strength probability distribution of the domestic fine-grained graphite studied. The characteristic strength of the nuclear graphite is closely related to the stress state and gradient. The uniaxial compressive strength is much higher than the uniaxial tensile strength, while the latter is clearly higher than the Brazilian disc splitting tensile strength. The three-point flexural strength is obviously higher than the uniaxial tensile strength. In addition, the Weibull modulus, which reflects the strength dispersion, is closely related to the stress state. The strength dispersion under the uniaxial tensile stress state is much higher than that under the uniaxial compressive stress state. The strength dispersion of Brazilian disc splitting tensile strength is between the above two, because the stress state in the high-stress critical region of the Brazilian disc, where the stress reaches more than 90% of the maximum value of the center, is between the uniaxial tensile and uniaxial compressive stress states. This observation suggests that the Weibull modulus should be considered as a function of stress states.

The reactor core is a critical component of nuclear power systems with a complex geometric structure, and it experiences strong coupling effects between various physical fields. High-precision thermal-hydraulic and multi-physics coupling analysis of the core is essential for ensuring the design and safety analysis of advanced nuclear power systems. The Nuclear Reactor Thermal-Hydraulic Laboratory (NuTHeL) at Xi'an Jiaotong University has built a core-heat-flow-deposition multi-physics coupling analysis model, and has independently developed the CorTAF Three-Dimensional Cross-Scale Multi-Physics Coupling Analysis Code for Nuclear Reactor Core, which allows CFD-based multi-physics calculations and predictions for the entire pressure vessel. Validation and verification work has also been conducted based on international benchmark problems. In recent years, the research team has continually developed and refined the mathematical and physical models of the code. Currently, the CorTAF code supports cross-scale coupling calculations for multiple reactor types (PWR, LFR, SFR), physical fields (Neutronics, Thermal hydraulic, Deposition), and system structures (Core, Lower plenum, Upper plenum). This paper reviews the development process of the CorTAF series codes, presents their main functions and applications in PWR calculation, summarizes the current computational results, and discusses the future direction of the program's development.

Monte Carlo (MC) particle transport methodology incorporates stochastic principles derived from probability theory and mathematical statistics to establish computational frameworks. This approach facilitates the numerical resolution of complex particle transport phenomena in nuclear systems. Over the course of seven decades of development, MC particle transport theory and algorithms have reached a high level of technical maturity. This has resulted in the development of several specialized software packages, which are widely applied in fields such as nuclear radiation shielding, reactor core criticality safety analysis, nuclear detection, and radiation medicine. This study commences by establishing the theoretical framework underlying MC particle transport methodologies. Through rigorous mathematical derivation, we present the neutron flux density formulation developed via MC simulations for addressing integral-form neutron transport equations, coupled with analytical frameworks for determining associated response parameters. It also outlines the classification of deterministic approaches for solving transport equations. The study reviews the historical development and computational application of MC particle transport methods, while summarizing significant software developed domestically and internationally. Furthermore, it examines recent advancements in utilizing graphics processing unit (GPU) technology to develop MC particle transport software, highlighting current research directions and progress in this field. This paper provides a comprehensive review of recent advancements in MC particle transport methodologies and associated software, with a specific focus on key features and capabilities of the independently developed J Monte Carlo transport (JMCT) software.

The silent heat pipe reactor adopts a energy transmission and thermoelectric conversion system that couples high-temperature heat pipes with thermoelectric power generation. It is a preferred reactor type of portable small nuclear power source in various fields such as sea, land, air, and space in the future due to its passive safety, high reliability and ultra silence. Based on the multi physical field coupling analysis platform COMSOL Multiphysics, this paper establishes a quarter model of the whole system of the heat pipe reactor according to the design scheme of a 100-kilowatt level silent heat pipe reactor, including fuel rods, core matrix, heat pipes, reflectors, control rods, sliding reflectors, thermoelectric generations and other systems. Steady-state operating conditions, single heat pipe failure conditions, and single-row thermoelectric system unloading conditions are analyzed to investigate system thermoelectric coupling characteristics. The research results indicate that due to the temperature flattening characteristics of the core matrix and the thermoelectric system matrix, the failure of a single heat pipe will not have a significant impact on the operation of the reactor and the output power of the thermoelectric system. When the local thermoelectric system unloading accident occurs in a heat pipe reactor, the core temperature will increase due to the decrease in the heat transfer capacity of the thermoelectric system. The thermoelectric system that has not been unloaded can still work normally, ensuring effective electrical energy output.