基于云台式激光甲烷检测仪的天然气泄漏溯源定位模型开发与评估

doi:10.11885/j.issn.1674-5086.2024.12.24.02

摘要/Abstract

摘要： 天然气站场突发气体泄漏事故的应急响应高度依赖于泄漏位置与泄漏量等关键信息获取的准确性。当前，多数天然气站场已配备云台式激光甲烷检测仪，该设备具备感知微小泄漏的能力，但由于缺乏配套气云循迹与搜索算法，无法实现对泄漏源的自主搜寻。为解决这一问题，研究建立了全局式泄漏源搜索模型(GSRC)和球形泄漏源搜索模型(SSRC)，并分别通过数值模拟和现场试验评估其有效性和优缺点。结果表明，基于实时气云浓度和搜索算法建立的GSRC和SSRC两种泄漏源搜索模型，赋予了云台式激光甲烷检测仪对泄漏的自动搜寻和定位功能，同时，通过对影响因素的深入分析，确定了模型的基本参数值；建立了西部典型站场全尺度CFD泄漏扩散模型，模拟发现SSRC模型具有最小的搜寻路径长度和平均搜寻时间，即最高的搜寻效率；将SSRC模型内嵌至云台式激光甲烷检测仪的工控平台后，现场试验数据显示，在10~60 m³/h泄漏速率条件下，86%的泄漏事件可在4 min内完成定位，且44%定位误差不超过2 m，72%定位误差不超过4 m。该泄漏源搜寻模型可大幅提高搜寻精度，为应急抢险和恢复提供技术支撑。

关键词: 天然气站场, 泄漏溯源, 计算流体力学, 全局式泄漏源搜索模型, 球形泄漏源搜索模型

Abstract: In the operation of natural gas stations, emergency response to sudden gas leakage accidents highly depends on the accurate acquisition of critical information such as leakage location and volume. Currently, most natural gas stations are equipped with TDLAS methane detectors capable of sensing minor leaks. However, due to the absence of integrated gas plume tracking and search algorithms, autonomous leakage source identification remains unachievable. To address this issue, this study established a global source model based on real-time concentration (GSRC) and a spherical source model based on real-time concentration (SSRC), with their effectiveness and advantages evaluated through numerical simulations and field tests. The results demonstrate that the GSRC and SSRC models, based on real-time gas plume concentration and search algorithms, enable cloud-based laser methane detectors to autonomously search and locate leaks. Furthermore, key model parameters were determined through in-depth analysis of influencing factors. Meanwhile, a full-scale CFD leakage dispersion model was developed for a natural gas station in western China, and the simulation found that the SSRC model has the smallest search path length and average search time, and the highest search efficiency. Field tests conducted after embedding the SSRC model into the detector's industrial control platform revealed that 86% of leakage incidents (within 10~60 m³/h leakage rates) could be located within 4 min, with positioning errors ≤2 m in 44% of cases and ≤ 4 m in 72% of cases. The developed leakage source search models significantly enhance localization accuracy, providing critical technical support for emergency response and recovery operations.

Key words: natural gas station, leakage source localization, computational fluid dynamics, global leak source release concentration model, spherical source release concentration model

中图分类号:

TE88

陈学忠. 基于云台式激光甲烷检测仪的天然气泄漏溯源定位模型开发与评估[J]. 西南石油大学学报(自然科学版), 2025, 47(3): 145-155.

CHEN Xuezhong. The Development and Evaluation of Leakage Source Localization Model in Natural Gas Stations Based on TDLAS Methane Detector[J]. Journal of Southwest Petroleum University(Science & Technology Edition), 2025, 47(3): 145-155.

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