Summary
In this work, it was found that the experimental heat capacity difference (cp-cv)exp has a linear relationship with the heat capacity difference calculated by using PR equation (cp-cv)PR. Based on this linear relationship, a predicted model of isobaric heat capacity for liquid refrigerants was presented. The accurate isobaric heat capacity of refrigerants in liquid phase can be obtained if the critical temperature, critical pressure, critical density, acentric factor and several experimental isobaric heat capacity data (at least two, more is better) are known. The proposed model was applied to 17 refrigerants (including HC, HFC, HFO and HCFO refrigerants) and a comparison was performed between the calculations by the proposed model and the experimental heat capacity data to validate the prediction. The results indicated the proposed method can represent the isobaric heat capacity of 17 refrigerants in liquid state with an average absolute deviation of 1.00%. The performance of this proposed method was then compared with that of other models (including Helmholtz equation, Peng-Robinson equation and a generalized corresponding state principle equation). It can be concluded that the proposed method generally shows better performance than other models. In addition, the proposed model reveals a good extrapolation ability in low temperature regions for refrigerants.
Available documents
Format PDF
Pages: 41-49
Available
Public price
20 €
Member price*
Free
* Best rate depending on membership category (see the detailed benefits of individual and corporate memberships).
Details
- Original title: Isobaric heat capacity prediction for HC, HFC, HFO and HCFO refrigerants in liquid phase.
- Record ID : 30027695
- Languages: English
- Subject: Technology, HFCs alternatives
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 118
- Publication date: 2020/10
- DOI: http://dx.doi.org/10.1016/j.ijrefrig.2020.05.022
Links
See other articles in this issue (50)
See the source
Indexing
-
Themes:
Hydrocarbons;
HFCs;
HFO et HCFO;
Thermodynamic measurements - Keywords: Hydrocarbon; HFC; HFO; HCFO; Thermodynamic property; Heat capacity; Modelling; Expérimentation
-
Measurement and modelling of the thermodynamic ...
- Author(s) : ARAMI NIYA A., XIAO X., AL GHAFRI S. Z. S., JIAO F., KHAMPHASITH M., SADEGHI POUYA E., SADAGHIANI M. S., YANG X., TSUJI T., TANAKA Y., SEIKI Y., MAY E. F.
- Date : 2020/10
- Languages : English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 118
- Formats : PDF
View record
-
Analysis of refrigerant R452B in use-phase vers...
- Author(s) : GUNASEKARA S. N., PALM B., IGNATOWICZ M., HILL P.
- Date : 2023/08/21
- Languages : English
- Source: Proceedings of the 26th IIR International Congress of Refrigeration: Paris , France, August 21-25, 2023.
- Formats : PDF
View record
-
Solubility measurements of refrigerants in poly...
- Author(s) : BROCUS J., VALTZ A., COQUELET C., CARLAN F. de
- Date : 2022/02
- Languages : English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 134
- Formats : PDF
View record
-
Dipole moment and heat capacity in the ideal ga...
- Author(s) : KANO Y., KAYUKAWA Y., FUJITA Y.
- Date : 2020/10
- Languages : English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 118
- Formats : PDF
View record
-
Measurement of kinematic viscosity of refrigera...
- Author(s) : MOROTOMI S., KARIYA K., MIYARA A.
- Date : 2021/05
- Languages : English
- Source: 2021 Purdue Conferences. 18th International Refrigeration and Air-Conditioning Conference at Purdue.
- Formats : PDF
View record