Effect of parameter variation on the viscosity of ethanol gel propellants

Chloé Carer; Leonhard Xaver Driever; Stein Köbben; Max McKenzie; Fredrik Rhenman; Onno Van de Sype; Jesse van der Toorn; Casper van Wezel; Constança Miranda de Andrade Veiga; Aleksandrs Vinarskis; Botchu Vara Siva Jyoti

doi:10.1590/jatm.v13.1196

Effect of parameter variation on the viscosity of ethanol gel propellants

Chloé Carer, Leonhard Xaver Driever, Stein Köbben, Max McKenzie, Fredrik Rhenman, Onno Van de Sype, Jesse van der Toorn, Casper van Wezel, Constança Miranda de Andrade Veiga, Aleksandrs Vinarskis, Botchu Vara Siva Jyoti^*

^*Corresponding author for this work

Space Systems Engineering

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

This research investigated how the variation of temperature and shear rate affects the viscosity of ethanol gel propellants that use methyl cellulose as gellant and, in parts, use boron as energetic additive. Using a rotational viscometer in a cone-and-plate configuration, propellant viscosity data was recorded across a range of temperatures and applied shear rates. The temperaturedependence of the viscosity was modelled using an Arrhenius-type equation. For the high shear rates, the data was modelled using the Power Law, Herrschel–Bulkley model, Carreau model, and Cross model. For low shear rates the used model was the rearranged Herrschel–Bulkley model. The temperature investigation suggested that the trend of decreasing viscosity with increasing temperature, predicted by the Arrhenius-type equation, is only applicable until approximately 320 K, after which the gel viscosity increased strongly. At high shear rates, the gel behaved in a shear thinning manner and was modelled most accurately by the Cross model. At low shear rates, the gel was shear thickening up to its elastic limit, which was found to lie at 0.41 s^–1.

Original language	English
Article number	e1121
Pages (from-to)	1-13
Number of pages	13
Journal	Journal of Aerospace Technology and Management
Volume	13
DOIs	https://doi.org/10.1590/jatm.v13.1196
Publication status	Published - 2021

Keywords

Gel propellant
Methyl cellulose
Rheology
Shear rate
Temperature

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10.1590/jatm.v13.1196

2175-9146-jatm-13-e1121Final published version, 351 KBLicence: CC BY

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title = "Effect of parameter variation on the viscosity of ethanol gel propellants",

abstract = "This research investigated how the variation of temperature and shear rate affects the viscosity of ethanol gel propellants that use methyl cellulose as gellant and, in parts, use boron as energetic additive. Using a rotational viscometer in a cone-and-plate configuration, propellant viscosity data was recorded across a range of temperatures and applied shear rates. The temperaturedependence of the viscosity was modelled using an Arrhenius-type equation. For the high shear rates, the data was modelled using the Power Law, Herrschel–Bulkley model, Carreau model, and Cross model. For low shear rates the used model was the rearranged Herrschel–Bulkley model. The temperature investigation suggested that the trend of decreasing viscosity with increasing temperature, predicted by the Arrhenius-type equation, is only applicable until approximately 320 K, after which the gel viscosity increased strongly. At high shear rates, the gel behaved in a shear thinning manner and was modelled most accurately by the Cross model. At low shear rates, the gel was shear thickening up to its elastic limit, which was found to lie at 0.41 s–1.",

keywords = "Gel propellant, Methyl cellulose, Rheology, Shear rate, Temperature",

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doi = "10.1590/jatm.v13.1196",

language = "English",

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AU - Carer, Chloé

AU - Driever, Leonhard Xaver

AU - Köbben, Stein

AU - McKenzie, Max

AU - Rhenman, Fredrik

AU - Van de Sype, Onno

AU - van der Toorn, Jesse

AU - van Wezel, Casper

AU - Veiga, Constança Miranda de Andrade

AU - Vinarskis, Aleksandrs

AU - Jyoti, Botchu Vara Siva

PY - 2021

Y1 - 2021

N2 - This research investigated how the variation of temperature and shear rate affects the viscosity of ethanol gel propellants that use methyl cellulose as gellant and, in parts, use boron as energetic additive. Using a rotational viscometer in a cone-and-plate configuration, propellant viscosity data was recorded across a range of temperatures and applied shear rates. The temperaturedependence of the viscosity was modelled using an Arrhenius-type equation. For the high shear rates, the data was modelled using the Power Law, Herrschel–Bulkley model, Carreau model, and Cross model. For low shear rates the used model was the rearranged Herrschel–Bulkley model. The temperature investigation suggested that the trend of decreasing viscosity with increasing temperature, predicted by the Arrhenius-type equation, is only applicable until approximately 320 K, after which the gel viscosity increased strongly. At high shear rates, the gel behaved in a shear thinning manner and was modelled most accurately by the Cross model. At low shear rates, the gel was shear thickening up to its elastic limit, which was found to lie at 0.41 s–1.

AB - This research investigated how the variation of temperature and shear rate affects the viscosity of ethanol gel propellants that use methyl cellulose as gellant and, in parts, use boron as energetic additive. Using a rotational viscometer in a cone-and-plate configuration, propellant viscosity data was recorded across a range of temperatures and applied shear rates. The temperaturedependence of the viscosity was modelled using an Arrhenius-type equation. For the high shear rates, the data was modelled using the Power Law, Herrschel–Bulkley model, Carreau model, and Cross model. For low shear rates the used model was the rearranged Herrschel–Bulkley model. The temperature investigation suggested that the trend of decreasing viscosity with increasing temperature, predicted by the Arrhenius-type equation, is only applicable until approximately 320 K, after which the gel viscosity increased strongly. At high shear rates, the gel behaved in a shear thinning manner and was modelled most accurately by the Cross model. At low shear rates, the gel was shear thickening up to its elastic limit, which was found to lie at 0.41 s–1.

KW - Gel propellant

KW - Methyl cellulose

KW - Rheology

KW - Shear rate

KW - Temperature

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Effect of parameter variation on the viscosity of ethanol gel propellants

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Keywords

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