Speed of sound and phase equilibria for (CO2 + C3H8) mixtures

被引：4

作者：

Lozano-Martin, Daniel ^{[1
]}

Susial, Rodrigo ^{[1
]}

Hernandez, Pedro ^{[1
,2
]}

Fernandez-Vicente, Teresa E. ^{[3
]}

Carmen Martin, M. ^{[1
]}

Segovia, Jose J. ^{[1
]}

机构：

[1] Univ Valladolid, TERMOCAL Res Grp, Res Inst Bioecon, Escuela Ingn Ind, Paseo Cauce 59, Valladolid 47011, Spain

[2] Inst Nacl Tecn Aerosp INTA, Madrid 28850, Spain

[3] Ctr Espanol Metrol CEM, Alfar 2, Madrid 2876, Spain

来源：

JOURNAL OF CHEMICAL THERMODYNAMICS | 2021年 / 158卷

关键词：

Speed of sound; Phase equilibria; Carbon dioxide; Propane; Heat capacities as perfect-gas; Acoustic virial coefficients; Density virial coefficients; VAPOR-LIQUID-EQUILIBRIA; DIOXIDE PLUS PROPANE; 2ND VIRIAL-COEFFICIENT; CARBON-DIOXIDE; THERMODYNAMIC PROPERTIES; SUPERCRITICAL CO2; BINARY-MIXTURES; PRESSURES; TEMPERATURES; EXTRACTION;

D O I：

10.1016/j.jct.2021.106464

中图分类号：

O414.1 [热力学];

学科分类号：

摘要：

This work presents phase envelope and speed of sound data for the (0.60 CO2 + 0.40 C3H8) and (0.80 CO2 + 0.20 C3H8) binary mixtures. Phase equilibria was measured using a cylindrical resonator working in the microwave band whereas an acoustic resonator was used for speed of sound measurements. The experimental results were compared with GERG-2008 equation of state, obtaining average absolute deviations by 0.24% in pressure for phase equilibria data and 0.025% for speed of sound data. Speed of sound values were used to derive perfect-gas heat capacities, acoustic virial coefficients, and second density virial coefficients. In addition, AGA8-DC92 equation of state performance was checked for the results derived from speeds of sound. (C) 2021 Elsevier Ltd.

引用

页数：15

共 50 条

[21] Laser-induced breakdown spectroscopy of gas mixtures of air, CO2, N2, and C3H8 for simultaneous C, H, O, and N measurement
Sturm, V
Noll, R
APPLIED OPTICS, 2003, 42 (30) : 6221 - 6225
[22] Gibbs ensemble Monte Carlo simulation for vapor-liquid equilibrium of binary mixtures CO2/C3H8, CO2/CH3OCH3, and CO2/CH3COCH3
Moon, SD
Moon, BK
BULLETIN OF THE KOREAN CHEMICAL SOCIETY, 2000, 21 (11) : 1133 - 1137
[23] THE DIFFUSION OF CO2, CH4, C2H4, AND C3H8 IN POLYETHYLENE AT ELEVATED PRESSURES
KULKARNI, SS
STERN, SA
JOURNAL OF POLYMER SCIENCE PART B-POLYMER PHYSICS, 1983, 21 (03) : 441 - 465
[24] CO2/N2 injection into CH4 + C3H8 hydrates for gas recovery and CO2 sequestration
Sun, Youhong
Zhang, Guobiao
Li, Shengli
Jiang, Shuhui
CHEMICAL ENGINEERING JOURNAL, 2019, 375
[25] Electrical response of MOSiC gas sensors to C3H8 and C3H8
Casals, O
Hernández-Ramírez, F
Barcones, B
Romano-Rodríguez, A
Serre, C
Pérez-Rodríguez, A
Morante, JR
Godignon, P
Montserrat, J
Millán, J
2005 SPANISH CONFERENCE ON ELECTRON DEVICES, PROCEEDINGS, 2005, : 533 - 536
[26] Effects of C3H8 on hydrate formation and dissociation for integrated CO2 capture and desalination technology
Yang, Mingjun
Zheng, Jianan
Liu, Weiguo
Liu, Yu
Song, Yongchen
ENERGY, 2015, 93 : 1971 - 1979
[27] Transient breakthroughs of CO2/CH4 and C3H6/C3H8 mixtures in fixed beds packed with Ni-MOF-74
Chen, De-Li
Shang, Hao
Zhu, Weidong
Krishna, Rajamani
CHEMICAL ENGINEERING SCIENCE, 2014, 117 : 407 - 415
[28] Numerical Analysis of Soot Dynamics in C3H8 Oxy-Combustion with CO2 and H2O
Xin, Yue
Liang, Bowen
Zhang, Yindi
Si, Mengting
Cunatt, Jinisper Joseph
Energies, 2024, 17 (24)
[29] The effect of CO2 on the lower flammability limit of C3H8 in O2/CO2 atmosphere at high temperature and pressure
Wei, Hao
Hu, Xianzhong
Huang, Bingrong
FUEL, 2022, 308
[30] Test-time extension behind reflected shock waves using CO2–He and C3H8–He driver mixtures
Anthony R. Amadio
Mark W. Crofton
Eric L. Petersen
Shock Waves, 2006, 16 : 157 - 165

← 1 2 3 4 5 →