排序方式: 共有3条查询结果,搜索用时 15 毫秒
1
1.
环境实验箱气流组织与围护结构耦合传热研究 总被引:1,自引:1,他引:0
目的研究环境实验箱在升、降温过程中气流组织与围护结构的耦合传热行为,为环境实验箱制冷/加热能力的确定提供精确的设计方法。方法首先利用UC240环境实验箱搭建实验平台,测量环境箱送风口速度分布,以及升、降温过程中室内及壁面的温度曲线,然后对环境箱进行建模,以实测的送风速度、温度作为边界条件,利用CFD方法进行仿真,最后对比分析实验值与CFD仿真的结果。结果利用CFD方法计算得到的环境箱升、降温曲线与实测值吻合较好,尤其是壁面温度曲线,误差不超过4℃。送风温度可以根据蒸发器理论或加热功率和回风温度而动态地确定。结论利用CFD方法分析环境实验箱气流组织与围护结构的耦合传热是可行的,FLUENT的UDF功能可根据需要扩展,以协助设计蒸发器和控制策略。 相似文献
2.
Although the diffusion of its storage and transport under liquefied conditions, nowadays it is common to have methane in gaseous form in several industrial applications. This leads to safety implications to be considered: hazards are linked to both the high-pressure at which the gas is kept and to its flammability. Scenarios where flammable jets impact an obstacle are of paramount importance because of their possible occurrence. Following a numerical approach, literature shows up that their assessment can be reliably performed by means of only Computational Fluid Dynamics tools. However, despite the improvements of computing power, Computational Fluid Dynamics costs still limit its use in daily risk analysts’ activities. Therefore, considering an accidental jet-obstacle scenario of industrial interest, the present work investigates how a pipe rack can influence the development of a high-pressure methane jet. Based on a Computational Fluid Dynamics analysis, main achievements of this work are a simple criterion able to identify the situations where the pipe rack does not influence the high-pressure methane jet behavior, therefore allowing to identify the scenarios where simpler models can be used (i.e., analytical correlations known for the free jet situation), and, if present, a simple analytical relationship that roughly predicts the influence of the pipe rack without the need of performing complex Computational Fluid Dynamics simulations. 相似文献
3.
1