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Numerical simulation of the structural response of a composite rocket nozzle during the ignition transient.

dc.contributor.advisorBright, Glen.
dc.contributor.advisorMorozov, Evgeny.
dc.contributor.authorPitot de la Beaujardiere, Jean-Francois Philippe.
dc.date.accessioned2010-08-31T14:03:49Z
dc.date.available2010-08-31T14:03:49Z
dc.date.created2009
dc.date.issued2009
dc.descriptionThesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2009.en_US
dc.description.abstractThe following dissertation describes an investigation of the structural response behaviour of a composite solid rocket motor nozzle subjected to thermal and pressure loading during the motor ignition period, derived on the basis of a multidisciplinary numerical simulation approach. To provide quantitative and qualitative context to the results obtained, comparisons were made to the predicted aerothermostructural response of the nozzle over the entire motor burn period. The study considered two nozzle designs – an exploratory nozzle design used to establish the basic simulation methodology, and a prototype nozzle design that was employed as the primary subject for numerical experimentation work. Both designs were developed according to fundamental solid rocket motor nozzle design principles as non-vectoring nozzles for deployment in medium sized solid rocket booster motors. The designs feature extensive use of spatially reinforced carbon-carbon composites for thermostructural components, complemented by carbon-phenolic composites for thermal insulation and steel for the motor attachment substructures. All numerical simulations were conducted using the ADINA multiphysics finite element analysis code with respect to axisymmetric computational domains. Thermal and structural models were developed to simulate the structural response of the exploratory nozzle design in reference to the instantaneous application of pressure and thermal loading conditions derived from literature. Ignition and burn period response results were obtained for both quasi-static and dynamic analysis regimes. For the case of the prototype nozzle design, a flow model was specifically developed to simulate the flow of the exhaust gas stream within the nozzle, for the provision of transient and steady loading data to the associated thermal and structural models. This arrangement allowed for a more realistic representation of the interaction between the fluid, thermal and structural fields concerned. Results were once again obtained for short and long term scenarios with respect to quasi-static and dynamic interpretations. In addition, the aeroelastic interaction occurring between the nozzle and flow field during motor ignition was examined in detail. The results obtained in the present study provided significant indications with respect to a variety of response characteristics associated with the motor ignition period, including the magnitude and distribution of the displacement and stress responses, the importance of inertial effects in response computations, the stress response contributions made by thermal and pressure loading, the effect of loading condition quality, and the bearing of the rate of ignition on the calculated stress response. Through comparisons between the response behaviour predicted during the motor ignition and burn periods, the significance of considering the ignition period as a qualification and optimisation criterion in the design of characteristically similar solid rocket motor nozzles was established.
dc.identifier.urihttp://hdl.handle.net/10413/778
dc.language.isoenen_US
dc.subjectSolid propellant rockets.en_US
dc.subjectRockets (Aeronautics)--Nozzles.en_US
dc.subjectTheses--Mechanical engineering.
dc.titleNumerical simulation of the structural response of a composite rocket nozzle during the ignition transient.en_US
dc.typeThesisen_US

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