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Numerical studies on flow behavior of composite propellant slurry during vacuum casting

Rockets are powered by composite solid propellant, which is a heterogeneous system consisting of solid oxidizer and metallic fuel dispersed in a polymeric fuel binder matrix. The slurry casting technique under vacuum/gravity condition is well-established for performing a different class of large siz...

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Published in:	Journal of aerospace technology and management 2012, Vol.4 (2), p.197-203
Main Authors:	Thiyyarkandy, Bejoy, Jain, Mukesh, Dombe, Ganesh Shankar, Mehilal, Singh, Praveen Prakash, Bhattacharya, Bikash
Format:	Article
Language:	English
Subjects:	ENGINEERING, AEROSPACE
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container_issue	2
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container_title	Journal of aerospace technology and management
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creator	Thiyyarkandy, Bejoy Jain, Mukesh Dombe, Ganesh Shankar Mehilal Singh, Praveen Prakash Bhattacharya, Bikash
description	Rockets are powered by composite solid propellant, which is a heterogeneous system consisting of solid oxidizer and metallic fuel dispersed in a polymeric fuel binder matrix. The slurry casting technique under vacuum/gravity condition is well-established for performing a different class of large sized case bonded rocket motors. During propellant casting, the ﬂow rate of slurry is a very critical parameter as it affects the product quality. The casting rate is governed by sufﬁcient degassing and viscosity buildup due to the progress of cure reaction. In the present study, casting rate and casting time have been numerically evaluated for ﬁxed and varying percentages of valve opening, different viscosity of slurry, and different pressure drop (driving force). The velocity proﬁle of propellant slurry inside feeding pipe and valve has also been evaluated. Furthermore, to get a ﬂawless grain and to predict the slurry casting rate, a microscopic analysis has been carried out to model the ﬂow behaviour of composite propellant slurry, where the momentum conservation law has been applied to express the mathematical model in an analytical form. The resulting differential and algebraic equations have been solved numerically using MATLAB, computing software. The numerical analysis is useful for designing new casting set-up and for giving the idea of maximum casting rate, which is achievable for given casting set-up and rheological properties of propellant slurry.
doi_str_mv	10.5028/jatm.2012.04021212
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title	Numerical studies on flow behavior of composite propellant slurry during vacuum casting
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