基于真空脉动循环参数调控的管腔结构蒸汽穿透机制研究*

doi:10.13385/j.cnki.vacuum.2025.06.07

摘要/Abstract

摘要： 针对微米级管腔结构中蒸汽渗透效率低、分布不均的问题,本文研究真空脉动循环参数对蒸汽传质的调控机制,提升穿透性能与能效利用率。构建频率（0.5~2.0 Hz）与压力幅值（5~15 kPa）耦合的蒸汽扩散动力学模型,结合计算流体力学（CFD）模拟,揭示脉动压力场对蒸汽相变与边界扰动的影响规律。搭建真空脉动实验平台,集成高速显微成像与X射线微CT,量化分析不同参数下的蒸汽穿透深度与三维分布,并采用响应面法优化参数组合。结果表明,脉动条件下穿透均匀性提升约21%,末端饱和度达0.78±0.05,较静态工况提升约50%。在1.2 Hz/10 kPa参数组合下,实现单位能效指标（η=5.06 s/J）最优,较基准工况提升约40%,对应关键性能指标KPI达2.37 g/（kW·s）,较标准提升58%。研究表明,真空脉动参数可协同强化蒸汽传质与能效控制,显著改善微结构渗透性能,为微通道干燥、器械灭菌及多孔介质传质提供理论依据与优化路径。

关键词: 真空脉动, 微尺度管腔结构, 蒸汽穿透效率, 循环参数调控, CFD模拟

Abstract: To address the challenges of low steam penetration efficiency and uneven distribution in microscale lumen structures, this study investigates the regulatory mechanism of vacuum pulsation parameters on steam mass transfer, aiming to improve penetration performance and energy utilization. A steam diffusion dynamics model coupling pulsation frequency (0.5~2.0 Hz) and pressure amplitude (5~15 kPa) was developed, and computational fluid dynamics (CFD) simulations were employed to reveal how pulsating pressure fields influence steam phase change and boundary layer disturbances. A dedicated vacuum pulsation experimental platform was constructed, integrating high-speed micro-imaging and X-ray micro-CT to quantitatively analyze steam penetration depth and 3D distribution under various parameter conditions. Response surface methodology was used to optimize the parameter combinations. The results show that under pulsation conditions, the penetration uniformity index improved by approximately 21%, and the terminal steam saturation reached 0.78±0.05, representing an approximately 50% increase compared to static conditions. At the optimal parameter combination of 1.2 Hz/10 kPa, the unit energy efficiency index (η=5.06 s/J) achieved its highest value, representing an approximate 40% improvement over the baseline, with the corresponding key performance indicator (KPI) reaching 2.37 g/(kW·s), a 58% improvement over the standard. The study confirms that vacuum pulsation parameters can synergistically enhance steam transfer efficiency and energy performance, significantly improving permeation in microscale structures, and providing theoretical guidance and optimization strategies for applications such as microchannel drying, instrument sterilization, and mass transfer in porous media.

Key words: vacuum pulsation, microscale lumen structure, steam penetration efficiency, cycle parameter regulation, CFD simulation

中图分类号: R197.39

雷丽, 郑伟, 孙立红, 李又聪. 基于真空脉动循环参数调控的管腔结构蒸汽穿透机制研究^*[J]. 真空, 2025, 62(6): 47-53.

LEI Li, ZHENG Wei, SUN Lihong, LI Youcong. Study on the Steam Penetration Mechanism in Tubular Structures Based on Vacuum Pulsation Cycle Parameter Regulation[J]. VACUUM, 2025, 62(6): 47-53.

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