Thermal and mutual diffusivities of fuel-related binary liquid mixtures under pre-combustion conditions

Beitrag in einer Fachzeitschrift
(Originalarbeit)


Details zur Publikation

Autorinnen und Autoren: Piszko M, Wu W, Will S, Rausch MH, Giraudet C, Fröba AP
Zeitschrift: Fuel
Verlag: ELSEVIER SCI LTD
Jahr der Veröffentlichung: 2019
Band: 242
Seitenbereich: 562-572
ISSN: 0016-2361
Sprache: Englisch


Abstract

In modelling heating and evaporation of fuel droplets, infra-droplet heat and mass transfer has to be considered. This is only possible with the help of reliable data for thermal and mutual diffusivity. At present, research activities in connection with the modelling of the evaporation of fuel droplets are based on theoretical diffusivity data. For their check and validation, there is, however, a lack of reliable experimental data. In this study, a dynamic light scattering apparatus which was especially developed for the simultaneous determination of both thermal and mutual diffusivity for fuel-related mixtures is presented. In the apparatus, fuel-related mixtures can be investigated under defined conditions in the compressed liquid phase close to saturation conditions in macroscopic thermodynamic equilibrium. Model binary mixtures composed of five different substances representative for fuel-related compounds were investigated at temperatures up to 523 K and close to their bubble point line. In detail, the mixtures investigated in the present study include 9 of the 10 possible binary combinations of isopentane, isooctane, toluene, n-decane, and ethanol. The results document that even under extreme conditions, thermal and mutual diffusivities are accessible with average expanded uncertainties (k = 2) of 8% and 6%. For all systems, concentrations, and temperatures, the thermal diffusivity changes only slightly. In contrast, the mutual diffusivity varies by more than two orders of magnitude from about 10(-10) to 10(-8) m(2).s(-1). For mixtures of isooctane and toluene, the concentration dependency of the mutual diffusivity reveals a nonideal behavior which becomes more pronounced with increasing temperature. For all binary mixtures, the temperature dependency of the mutual diffusivity can be correlated well with the vapor pressure of the individual components. The presence of the biofuel ethanol strongly slows down the molecular diffusion process at low temperatures.


FAU-Autorinnen und Autoren / FAU-Herausgeberinnen und Herausgeber

Fröba, Andreas Paul Prof. Dr.-Ing.
Lehrstuhl für Advanced Optical Technologies - Thermophysical Properties
Giraudet, Cédric Dr.
Erlangen Graduate School in Advanced Optical Technologies
Piszko, Maximilian
Erlangen Graduate School in Advanced Optical Technologies
Rausch, Michael Heinrich Dr.-Ing.
Lehrstuhl für Advanced Optical Technologies - Thermophysical Properties
Will, Stefan Prof. Dr.-Ing.
Lehrstuhl für Technische Thermodynamik
Wu, Wenchang
Lehrstuhl für Advanced Optical Technologies - Thermophysical Properties


Zusätzliche Organisationseinheit(en)
Erlangen Graduate School in Advanced Optical Technologies


Zitierweisen

APA:
Piszko, M., Wu, W., Will, S., Rausch, M.H., Giraudet, C., & Fröba, A.P. (2019). Thermal and mutual diffusivities of fuel-related binary liquid mixtures under pre-combustion conditions. Fuel, 242, 562-572. https://dx.doi.org/10.1016/j.fuel.2019.01.078

MLA:
Piszko, Maximilian, et al. "Thermal and mutual diffusivities of fuel-related binary liquid mixtures under pre-combustion conditions." Fuel 242 (2019): 562-572.

BibTeX: 

Zuletzt aktualisiert 2019-13-03 um 07:23

Link teilen