Freezing Point of Hydrocarbon Fuels from Single Species Concentrations

David C. Bell; Randall Boehm; Joshua S. Heyne

doi:10.1021/acs.energyfuels.4c06091

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Freezing Point of Hydrocarbon Fuels from Single Species Concentrations

Journal article

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Freezing Point of Hydrocarbon Fuels from Single Species Concentrations

David C. Bell, Randall Boehm and Joshua S. Heyne

Energy & fuels, Vol.39(9), pp.4221-4226

03/06/2025

DOI: https://doi.org/10.1021/acs.energyfuels.4c06091

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Abstract

Traditional Fossil Fuels

ASCENT

The freezing point is an important property for determining the operating range of liquid hydrocarbon fuels. Many thermodynamic properties, like density, viscosity, and vapor pressure, have simple blending rules that can accurately predict the properties of a complex mixture. Freezing point, however, does not behave this way and shows nonlinear and noncontinuous responses to mixture composition. As a result, available models for freezing point predictions are generally not very effective on fuel compositions that are dissimilar to petroleum fuels. In this work, we explore a thermodynamically derived equation of state model predicting the freezing point to develop a method to predict the freezing point of mixtures from composition. The freezing point is primarily determined by the first species to freeze. Experimental control curves are used to replace complex equations to simplify the thermodynamic model. These control curves function as a strong first-order prediction of the freezing point (mean absolute error = 4.4 °C). The remaining uncertainty is attributed to the solvency effect caused by the entropy of the mixing term in the thermodynamic derivation. Utilizing the findings from this research, a 100% n-alkane fuel with a freezing point of −40.7 °C is blended. Using previous models built around data from conventional fuels, the closest prediction out of nine models was −12.8 °C, a 27.9 °C error. The proposed approach predicts −44.1 °C.

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Title: Freezing Point of Hydrocarbon Fuels from Single Species Concentrations
Creators: David C. Bell - Washington State University
Randall Boehm - Washington State University, School of Mechanical and Materials Engineering
Joshua S. Heyne - University of Dayton
Publication Details: Energy & fuels, Vol.39(9), pp.4221-4226
Academic Unit: Alternative Jet Fuel
Publisher: American Chemical Society
Number of pages: 6
Grants: 13-C-AJFE-WaSU-035, Federal Aviation Administration (United States, Washington) - FAA
Identifiers: 99901225154001842
Language: English
Resource Type: Journal article