方案摘要
方案下载应用领域 | 能源/新能源 |
检测样本 | 其他 |
检测项目 | |
参考标准 | 暂无 |
采用Artium公司的相位多普勒粒子干涉仪对核反应堆中大型工业安全喷雾的液滴粒径和速度进行了测量,并采用数值模拟方法分析了简化喷雾边界条件对其特性的影响。
During the course of a severe accident in a Pressurized Water Reactor (PWR), hydrogen can be produced due to reactor core oxidation, leading to potential combustion and deflagration, as observed in Three Mile Island and Fukushima accidents. In some reactors, spray systems are placed at the top of the containment to prevent overpressure. Spray modelling is thus part of thermal-hydraulic containment codes. The two major phenomena involved in spray behaviour under such accidental conditions are the thermodynamical effect of a spray (steam
condensation on droplets, leading to a local increase of hydrogen concentration) and the dynamical effect (mixing of gases, leading to a decrease of hydrogen concentration). The competition of these two coupled phenomena is an important issue for nuclear safety and can be assessed using CFD codes.
For nuclear reactor (containment vessel of around 60 000 m3), simplifications have to be done to simulate a nuclear accident in the containment where gas mixture (steam, hydrogen and air) is mixed by the spray systems. Up to now, no CFD calculations are available in the open literature on spray systems in a real-scale nuclear
containment, using detailed spray initial conditions, accurate droplet modelling and droplet-gas momentum interaction. Many simplifications can be performed in the computer simulation to reduce the computational time of such sprays induced flow in a very large containment: atomization zone is neglected, considerations of only one droplet size and velocity at one single injection point, consideration of so-called ‘dynamical equilibrium’ between gas and droplet, etc. [1]. The objective of this paper is to evaluate the influence of several simplifications performed on spray boundary conditions, on some selected ‘output’ parameters that can influence the overall gas mixing in nuclear reactors.
This evaluation is performed on a real-scale PWR spray nozzle (hollow cone) having an outlet diameter of 9.5 mm and a maximum diameter of the induced spray envelope of about 2 m. CFD calculations are performed using the ANSYS code (lagrangian approach) and the EDF NEPTUNE_CFD code (eulerian approach).
在一个双稳湍流涡旋火焰中,对间歇性动态的时间-频率定位
Particle-laden Taylor-Couette流:高阶转变和径向局部波浪涡旋的证据
7根杆束的流体-结构相互作用:用实验数据对比数值模拟
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