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HFO/HC、HFO/HFC/HC混合工质气液相平衡及PVTx性质研究

项目来源

国家自然科学基金(NSFC)

项目主持人

胡芃

项目受资助机构

中国科学技术大学

项目编号

51576187

立项年度

2015

立项时间

未公开

项目级别

国家级

研究期限

未知 / 未知

受资助金额

64.00万元

学科

工程与材料科学-工程热物理与能源利用-热物性与热物理测试技术

学科代码

E-E06-E0606

基金类别

面上项目

关键词

热力学性质 ; 共沸混合工质 ; 气液相平衡 ; 氢氟烯烃类 ; 混合制冷工质 ; Thermodynamic properties ; Refrigerant mixtures ; Vapor-Liquid Equilibria ; Azeotropic mixture ; HFOs

参与者

陈龙祥;赵盼盼;胡仁东;章高伟;潘健昌;蔡旭东;于晶晶

参与机构

中国科学院福建物质结构研究所;合肥通用机械研究院有限公司

项目标书摘要:在全球气候变暖的背景下,以氢氟烯烃类(HFOs)为主要组分的低GWP制冷混合工质成为目前替代工质研究的重要方向。但是其相关基础热力学数据还极为缺乏,因此本申请以HFO-1234yf、HFO-1234ze(E)、HFO-1234ze(Z)与HCs、HFCs组成的HFO/HC二元混合工质,HFO/HFC/HC三元混合工质为研究体系,开展气液相平衡性质、气相PVTx性质以及共沸特性的实验和理论研究。预期获得一批重要的基础实验数据,建立混合工质的气相维里方程,针对PR+vdW关联模型建立能够推算HFOs、HFCs、HCs混合工质体系气液相平衡性质的推算模型,并以此为基础结合实验测量研究HFO/HFC/HC三元混合工质共沸和近共沸性质。研究结果可以为寻求低GWP且性能优异的HFO/HC、HFO/HFC/HC混合工质提供基本数据和理论支持。

Application Abstract: In the background of global warming,refrigerant mixtures containing Hydrofluoroolefins(HFOs)are considered as promising candidates because of low GWP values.However,their primary thermodynamic properties are still very limited.In this proposal,HFO/HC binary mixtures and HFO/HFC/HC ternary mixtures containing HFO-1234yf,HFO-1234ze(E)and HFO-1234ze(Z)are selected for experimental and theoretical study on their vapor-liquid equilibria,gaseous PVTx and azeotropic properties.A number of experimental data of these important properties will be obtained.Gaseous Virial equations of state will be built.An estimation method for the VLE of mixtures containing HFOs,HFCs,HCs will be developed for the PR+vdW model.The azeotropic and near-azeotropic properties of HFO/HFC/HC ternary mixtures will be investigated.The results of the study can provided basic data and theoretical support for the research of the HFO/HC and HFO/HFC/HC mixtures with both of low GWP and excellent performances.

项目受资助省

安徽省

项目结题报告

HFO/HC、HFO/HFC/HC混合工质气液相平衡及PVTx性质研究结题报告(全文)

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  • 1.Molecular modeling of vapor-liquid equilibrium properties of HFC-161 and its mixture HFC-161+HFO-1234yf

    • 关键词:
    • Ethyl fluoride; All-atom force field; Gibbs ensemble Monte Carlo;Vapor-liquid equilibrium;2,3,3,3-TETRAFLUOROPROP-1-ENE R1234YF; PHASE-EQUILIBRIA;BINARY-MIXTURES; FORCE-FIELD; THERMOPHYSICAL PROPERTIES; ALTERNATIVEREFRIGERANT; SIMULATION; VISCOSITY; PRESSURE; DENSITY
    • Zhang, Nan;Hu, Peng;Chen, Longxiang;Zhi, Lianghui
    • 《Auckland-Training-Centre-for-Psychodrama Workshop》
    • 2020年
    • SEP 20-22, 2019
    • Auckland, NEW ZEALAND
    • 会议

    Molecular simulation is an important method to acquire reliable thermophysical properties, but there are few force fields for alternative refrigerants. In this paper, an all-atom force field for ethyl fluoride (HFC-161) has been developed in the framework of the Amber force field. This force field for HFC-161 was derived from a combination of ab initio calculations, Gibbs ensemble Monte Carlo simulations and comparisons to experimental data. And then the force field was applied to the calculation of thermophysical properties of pure HFC-161. It was found that over the temperature range of 263.15 K to 363.15 K the average absolute relative deviations of vapor pressure, saturated densities in liquid and vapor phases were 1.37%, 3.87% and 1.86%, respectively. The deviations in critical temperature, critical pressure and critical density were 0.40%, 1.86% and 1.47%, respectively. This force field was also used to calculate the vapor-liquid equilibrium properties of the mixture of HFC-161 + HFO-1234yf. In this work, the vapor-liquid equilibrium properties of pure HFC-161 and its binary mixture were calculated via the Gibbs ensemble Monte Carlo simulations. Calculated results showed a good agreement with available experimental data. Since the calculated results were in good agreement with the experimental results, the predictive ability of the proposed force field model can be verified. (C) 2020 Elsevier B.V. All rights reserved.

    ...

  • 2.Molecular modeling of vapor-liquid equilibrium properties of HFC-161 and its mixture HFC-161+HFO-1234yf

    • 关键词:
    • Ethyl fluoride; All-atom force field; Gibbs ensemble Monte Carlo;Vapor-liquid equilibrium;2,3,3,3-TETRAFLUOROPROP-1-ENE R1234YF; PHASE-EQUILIBRIA;BINARY-MIXTURES; FORCE-FIELD; THERMOPHYSICAL PROPERTIES; ALTERNATIVEREFRIGERANT; SIMULATION; VISCOSITY; PRESSURE; DENSITY
    • Zhang, Nan;Hu, Peng;Chen, Longxiang;Zhi, Lianghui
    • 《Auckland-Training-Centre-for-Psychodrama Workshop》
    • 2020年
    • SEP 20-22, 2019
    • Auckland, NEW ZEALAND
    • 会议

    Molecular simulation is an important method to acquire reliable thermophysical properties, but there are few force fields for alternative refrigerants. In this paper, an all-atom force field for ethyl fluoride (HFC-161) has been developed in the framework of the Amber force field. This force field for HFC-161 was derived from a combination of ab initio calculations, Gibbs ensemble Monte Carlo simulations and comparisons to experimental data. And then the force field was applied to the calculation of thermophysical properties of pure HFC-161. It was found that over the temperature range of 263.15 K to 363.15 K the average absolute relative deviations of vapor pressure, saturated densities in liquid and vapor phases were 1.37%, 3.87% and 1.86%, respectively. The deviations in critical temperature, critical pressure and critical density were 0.40%, 1.86% and 1.47%, respectively. This force field was also used to calculate the vapor-liquid equilibrium properties of the mixture of HFC-161 + HFO-1234yf. In this work, the vapor-liquid equilibrium properties of pure HFC-161 and its binary mixture were calculated via the Gibbs ensemble Monte Carlo simulations. Calculated results showed a good agreement with available experimental data. Since the calculated results were in good agreement with the experimental results, the predictive ability of the proposed force field model can be verified. (C) 2020 Elsevier B.V. All rights reserved.

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