Viscosity of Hydrogen and Methane Blends: Experimental and Modelling Investigations

IF 2.5 4区工程技术 Q3 CHEMISTRY, PHYSICAL International Journal of Thermophysics Pub Date : 2024-07-30 DOI:10.1007/s10765-024-03394-4

Friday Junior Owuna, Antonin Chapoy, Pezhman Ahmadi, Rod Burgass

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Abstract

Understanding of thermophysical and transport properties of H₂-NG blends are needed for the gradual introduction of hydrogen into the national gas grid. A capillary tube viscometer was used to measure the viscosity of hydrogen + methane blends (with hydrogen mole fraction = 0, 0.1000, 0.1997, 0.5019, and 1) at temperatures from 213 to 324 K and pressures up to 31 MPa. A total 147 experimental viscosity measurements were made for the three H₂ + CH₄ blends and compared against the predictions of five different viscosity models: a one-reference corresponding states (Pedersen) model, a two-reference corresponding states (CS2) model, an extended corresponding states (ECS) model, a corresponding states model derived from molecular dynamic simulations of Lennard Jones (LJ) fluids, and a residual entropy scaling (SRES) method. All the model predictions showed a relatively low deviation compared to the measured viscosities. The density required for viscosity model predictions were computed using Multi-Fluid Helmholtz Energy Approximation (MFHEA) equations of state (EoS). To check the experimental procedure and applicability of the viscometer equipment, viscosity validation measurements were carried out for propane, hydrogen, and methane. The measured viscosities of the pure components were in good agreement with the respective viscosity models with AARD of 0.24%, 0.25%, and 0.58% for propane, hydrogen, and methane, respectively.

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氢气和甲烷混合物的粘度：实验和模型研究

要将氢气逐步引入国家天然气网，就必须了解氢气-天然气混合物的热物理和传输特性。使用毛细管粘度计测量了氢气 + 甲烷混合物（氢气分子分数 = 0、0.1000、0.1997、0.5019 和 1）在 213 至 324 K 温度和 31 MPa 压力下的粘度。对三种 H2 + CH4 混合物共进行了 147 次粘度实验测量，并与以下五种不同粘度模型的预测结果进行了比较：单参考对应态（Pedersen）模型、双参考对应态（CS2）模型、扩展对应态（ECS）模型、从伦纳德-琼斯（LJ）流体的分子动力学模拟中得出的对应态模型以及残余熵缩放（SRES）方法。与测量的粘度相比，所有模型预测的偏差都相对较小。粘度模型预测所需的密度是通过多流体亥姆霍兹能量近似（MFHEA）状态方程（EoS）计算得出的。为检查粘度计设备的实验程序和适用性，对丙烷、氢气和甲烷进行了粘度验证测量。丙烷、氢气和甲烷测得的纯组分粘度与各自的粘度模型十分吻合，AARD 分别为 0.24%、0.25% 和 0.58%。

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来源期刊

International Journal of Thermophysics 物理-力学

CiteScore

4.10

自引率

9.10%

发文量

179

审稿时长

5 months

期刊介绍： International Journal of Thermophysics serves as an international medium for the publication of papers in thermophysics, assisting both generators and users of thermophysical properties data. This distinguished journal publishes both experimental and theoretical papers on thermophysical properties of matter in the liquid, gaseous, and solid states (including soft matter, biofluids, and nano- and bio-materials), on instrumentation and techniques leading to their measurement, and on computer studies of model and related systems. Studies in all ranges of temperature, pressure, wavelength, and other relevant variables are included.