面向LNG冷能高效利用的冷-电-化多联产系统

A cold-electricity-chemical poly-generation system for efficient utilization of LNG cold energy

  • 摘要:
    目的 LNG再气化过程存在冷能利用模式单一、温区匹配不佳、㶲损失严重及综合利用效率偏低等问题,因此,构建冷-电-化多联产系统是探索LNG冷能梯级高效利用的可行路径。
    方法 提出了一种新的冷-电-化多联产系统,通过集成两级朗肯循环与甲醇制丙烯(Methanol to Propylene, MTP)工艺,构建了“深冷发电-中冷发电-浅冷化工”的3梯级冷能利用架构,实现了LNG宽温区冷能与化工过程中换热的合理匹配。在方法层面,采用夹点分析法对全局换热网络进行热集成分析,以最小传热温差(ΔTmin=20 ℃)为关键设计参数,确定相对热经济性较优的换热网络方案,引入㶲分析方法揭示系统内部不可逆损失的分布特征,并基于增量投资-增量收益原则建立经济性评估模型,再结合单因素敏感性分析与蒙特卡洛模拟量化项目风险。
    结果 LNG冷能㶲利用率从传统纯发电方案的4.99%提升至19.35%。优化后的换热网络以3梯级冷能利用架构实现冷能梯级传递,系统净发电功率为1 342 kW,并为MTP工艺提供9 663 kW冷量,等效节电3 865 kW。经济性评估结果表明,作为改造项目,增量总固定资产投资为4 962×104元,年净现金流为2 045×104元,净现值(Net Present Value, NPV)为12 540×104元,内部收益率(Internal Rate of Return, IRR)为41%,动态回收期为3.8年,平准化能源成本为0.161元/(kW·h),经济指标良好。不确定性分析结果表明,在10 000次蒙特卡洛样本中未出现NPV小于零的情景,在最不利的5%模拟情景下,NPV仍不低于8 946×104元,抗风险能力强。
    结论 所建立的“热力学梯级设计-系统集成优化-经济风险评估”综合分析框架,验证了冷-电-化多联产模式在提升LNG冷能利用效率与经济价值方面的技术可行性,为LNG冷能梯级利用系统升级提供了可推广的设计范式。

     

    Abstract:
    Objective The LNG regasification process suffers from several limitations, including single-mode cold energy utilization, poor temperature zone matching, severe exergy loss, and low comprehensive utilization efficiency. Developing a cold-electricity-chemical poly-generation system offers a viable strategy for the high-efficiency, cascade utilization of LNG cold energy.
    Methods A novel cold-electricity-chemical poly-generation system is proposed in this study. By integrating a two-stage Rankine cycle with the Methanol to Propylene (MTP) process, a three-stage cold energy cascade utilization framework is established, comprising cryogenic power generation, medium-cold power generation and mild-cold chemical production. This framework enables the precise matching of wide-temperature-range LNG cold energy with the heat-transfer demands of the chemical processes. At the methodological level, pinch analysis is applied to perform heat integration across the global heat exchange network. With the minimum temperature approach (ΔTmin = 20 °C) designated as the core design parameter, an optimized heat exchange network configuration with superior relative thermal economy is determined. Furthermore, exergy analysis is introduced to map the distribution of internal irreversible losses within the system. Finally, an economic evaluation model is developed based on the incremental investment-incremental benefit principle, and single-factor sensitivity analysis together with Monte Carlo simulation are combined to quantify project risks.
    Results The exergy efficiency of LNG cold energy is increased from 4.99% in the traditional power-only scheme to 19.35%. Through the three-stage framework, cascade transmission of cold energy is achieved within the optimized heat exchange network. The system delivers a net power output of 1 342 kW and supplies 9 663 kW of cooling duty to the MTP process, equivalent to a power saving of 3 865 kW. Economic evaluation of the retrofit scenario indicates an incremental fixed asset investment of RMB 4 962×104, yielding an annual net cash flow of RMB 2 045×104. The Net Present Value (NPV) reaches RMB 12 540×104, with an Internal Rate of Return (IRR) of 41%, a dynamic payback period of 3.8 years, and a levelized energy cost of RMB 0.161/(kW·h), demonstrating highly favorable economic indicators. Furthermore, uncertainty analysis reveals no instances of a negative NPV across 10 000 Monte Carlo samples. Even under the worst 5% of simulated scenarios, the NPV remains above RMB 8 946×104, reflecting robust risk resistance.
    Conclusion The established comprehensive analysis framework—spanning thermodynamic cascade design, system integration optimization, and economic risk assessment—verifies the technical and economic viability of the cold-electricity-chemical poly-generation mode in maximizing LNG cold energy utilization efficiency and economic value. The research findings provide a replicable design paradigm for upgrading LNG cold energy cascade utilization systems.

     

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