高级检索

一种用于多气源管网混输模拟的动态批次组分跟踪法

A dynamic batch component tracking method for simulating mixed transportation in multi-source natural gas pipeline networks

  • 摘要:
    目的 针对多气源天然气管网在混输过程中,现有气质动态预测方法存在精度低与响应慢的技术瓶颈,开发一种高精度动态组分跟踪方法,以支撑管网的精细化运行与质量合规。
    方法 依托国产化管网仿真软件(pipeline network simulation, PNS)平台,提出一种动态批次组分跟踪(dynamic batch component tracking, DBCT)方法。该方法通过建立基于物理条件的流体批次生成与运移准则,实现对非稳态工况下组分演化过程的高解析度跟踪。首先构建并校准了与物理系统高度一致(精度99.56%)的管网仿真模型,随后应用DBCT方法开展稳态与瞬态模拟分析以验证其有效性。
    结果 稳态分析精确量化了各气源的贡献权重,明确了东干线(贡献率66.298%)是影响终端气质的主导气源;瞬态模拟成功再现了上游组分扰动事件在管网中的传播过程,并精确解析了终端气质在潜伏期、跃变期与新稳态期的完整动态响应特征。最后,通过将稳态预测结果进行物性换算,验证了当前工况下外输商品天然气的质量指标符合国家标准要求。
    结论 本研究提出的DBCT方法能够显著提升复杂管网气质预测的准确性与动态性,为管网系统的运行优化与质量达标控制提供了有效的技术手段与理论支撑。

     

    Abstract:
    Objective To address the technical bottlenecks of low accuracy and slow responsiveness in existing dynamic gas quality prediction for multi-source natural gas pipeline networks during mixed transportation, this study aims to develop a high-precision dynamic component-tracking method to support refined network operation and quality compliance.
    Method Based on the domestically developed Pipeline Network Simulation (PNS) platform, a Dynamic Batch Component Tracking (DBCT) method was proposed. Physics-based criteria for fluid batch generation and transport were established to enable high-resolution tracking of component evolution under unsteady conditions. A pipeline simulation model that closely matches the physical system (simulation accuracy of 99.56%) was first established and calibrated. The DBCT approach was then validated through steady-state and transient simulation analyses.
    Result Steady-state analysis quantitatively resolved source contribution weights and identified the East Trunk Line as the dominant source influencing terminal gas quality, with a contribution of 66.298%. Transient simulations successfully reproduced the propagation of upstream composition perturbations through the network and accurately characterized the terminal gas quality dynamic response across latent, transition, and new steady-state stages. Conversion of steady-state predictions to physical properties confirmed that the exported commercial natural gas under the studied operating conditions meets national quality standards.
    Conclusion The proposed DBCT method substantially improves the accuracy and dynamic performance of gas quality prediction in complex pipeline networks, offering an effective technical and theoretical tool for operation optimization and quality compliance.

     

/

返回文章
返回