Numerical calculation method of typical hydrate phase diagram

doi:10.16085/j.issn.1000-6613.2024-1714

Abstract

Abstract:

With the deepening research on gas hydrates in carbon capture and oil-gas transportation, the study to their phase equilibrium is significantly important. The gas forming hydrates can be either pure components or mixtures. Hydrate formation involves three- or four-phase equilibria, including I-H-V (ice-hydrate-vapor), L_w-H-V (liquid water-hydrate-vapor), L_w-H-L_HC (liquid water-hydrate-liquid hydrocarbon), and L_w-H-V-L_HC (liquid water-hydrate-vapor-liquid hydrocarbon). The phase diagrams of hydrates formed by different gas compositions exhibit notable differences, particularly in the number of four-phase points. This paper focuses on methane, nitrogen, carbon dioxide, propane and natural gas mixture systems, discussing numerical calculation methods for hydrate phase diagrams containing one or two four-phase points and four-phase lines. Numerical simulations are conducted using the independently developed SimTech Simulator, and the results are compared with those from the commercial software Pro/Ⅱ, validating the reliability of the Simulator.

Key words: gas hydrate, phase diagram, four-phase point, numerical simulation, phase equilibrium

摘要：

随着气体水合物在碳捕集与在油气运输中的相关研究不断深入，研究其相平衡具有重要意义。形成水合物的气体可以是纯组分，也可以是混合物。水合物的形成伴随着三相或者四相平衡，包括I-H-V（冰-水合物-气相）、L_w-H-V（液态水-水合物-气相）、L_w-H-L_HC（水-水合物-液态烃）以及L_w-H-V-L_HC（液态水-水合物-气相-液态烃）的相平衡。不同气体组分形成的水合物相图有很大的差别，主要体现在四相点的个数。本文以甲烷、氮气、二氧化碳、丙烷等和天然气混合物体系为例，分别讨论了含一个、两个四相点及四相线的水合物相图的数值计算方法。利用自主研发的SimTech Simulator进行了数值模拟，并与商业软件Pro/Ⅱ的计算结果进行了对比，验证了其可靠性。

关键词: 气体水合物, 相图, 四相点, 数值模拟, 相平衡

CLC Number:

TQ013.1

LONG Huilong, TANG Haoran, MA Yuan, QIN Yunfeng, BAO Yihui, ZHANG Zengfu. Numerical calculation method of typical hydrate phase diagram[J]. Chemical Industry and Engineering Progress, 2025, 44(8): 4871-4878.

龙回龙, 唐浩然, 马源, 秦云锋, 包祎辉, 张增富. 典型水合物相图的数值计算方法[J]. 化工进展, 2025, 44(8): 4871-4878.

Figures/Tables 10

References 13

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项目	Q₁
项目	甲烷	氮气
SimTech Simulator	273.0K、2.55MPa	273.15K、14.467MPa
Pro/Ⅱ	273.0K、2.32MPa	273.15K、14.569MPa
文献[13]	273.15K、2.56MPa	273.15K、14.3MPa

项目	Q₁
项目	甲烷	氮气
SimTech Simulator	273.0K、2.55MPa	273.15K、14.467MPa
Pro/Ⅱ	273.0K、2.32MPa	273.15K、14.569MPa
文献[13]	273.15K、2.56MPa	273.15K、14.3MPa

项目	Q₁平均相对误差
项目	甲烷误差/%	氮气误差/%
SimTech Simulator	-0.222	0.584
Pro/Ⅱ	-4.715	0.9405

项目	Q₁平均相对误差
项目	甲烷误差/%	氮气误差/%
SimTech Simulator	-0.222	0.584
Pro/Ⅱ	-4.715	0.9405

项目	Q₂
项目	二氧化碳	丙烷
SimTech Simulator	287.4K、3.35MPa	278.5K、0.54MPa
Pro/Ⅱ	288.1K、3.63MPa	278.4K、0.591MPa
Exp	287.8K、3.39MPa	278.8K、0.556MPa