Thermostructural Numerical Analysis of the Thrust Chamber of a Liquid Propellant Rocket Engine

Citarella, Roberto; Ferraiuolo, Michele; Perrella, Michele; Giannella, Venanzio

doi:10.3390/ma15155427

Cited by 8 publications

(3 citation statements)

References 33 publications

(57 reference statements)

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“…However, the expected number of cycles to failure is very high, more than 100. More information about the models and procedures adopted is given in [65,66].…”

Section: Resultsmentioning

confidence: 99%

Thermal Behaviour of the Cooling Jacket Belonging to a Liquid Oxygen/Liquid Methane Rocket Engine Demonstrator in the Operation Box

et al. 2023

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The cooling jackets of liquid rocket engines are composed of narrow passages surrounding the thrust chambers and ensure the reliable operation of the engine. Critical conditions may also be encountered, since the cooling jackets of cryogenic engines, such as those using LOX/LCH4 propellants, are based on a regenerative strategy, where the fuel is used as a refrigerant. Consequently, deterioration modes near where pseudocritical conditions are reached or low heat transfer coefficients where the fuel becomes a vapour and must therefore be managed. The verification of the cooling jacket behaviour to consolidate the design solutions in all the extreme points of the operating box represents a very important phase. The present paper discusses the full characterization of the HYPROB (HYdrocarbon PROpulsion test Bench Program) first unit of the final demonstrator, (DEMO-0A), by considering the working points within the limits of the operating box and comparisons with the nominal conditions are given. In this way, a full understanding of the cooling system behaviour, affecting the working of the entire thrust chamber, is accomplished. Moreover, the design strategy and choices have been confirmed, since the verifications also include potentially even more extreme conditions with respect to the nominal ones. The investigation has been numerically performed and supported the thermo-structural analyses accomplished before the final firing campaign, completed in December 2022. Since little information is available in the literature on LOX/LCH4 engines, suggestions are given as to the organization of the numerical simulations, which support the design of such rocket engine cooling systems.

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“…However, the expected number of cycles to failure is very high, more than 100. More information about the models and procedures adopted is given in [65,66].…”

Section: Resultsmentioning

confidence: 99%

Thermal Behaviour of the Cooling Jacket Belonging to a Liquid Oxygen/Liquid Methane Rocket Engine Demonstrator in the Operation Box

et al. 2023

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“…Liquid propellant rockets (Citarella, Ferraiuolo, Perrella, & Giannella, 2022) are more expensive and complex than solid fuel rockets. However, their efficiencies are greater than those of solid propellant rockets, and their burning velocity can be controlled.…”

Section: Introductionmentioning

confidence: 99%

Design and Simulation of a Model Rocket Prototype

AÇIKGÖZ,

DEMIR,

ÇETIN

2023

ASREL

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Bu çalışmada verilen görev parametrelerine göre bir model roket tasarlanmıştır. Ayrıca bir roket prototipinin nasıl üretildiği ve tasarım aşamasında hangi parametrelerin kullanıldığı anlatılmıştır. Tasarım parametreleri farklı görevler ve gereksinim konfigürasyonları için tamamen farklılık gösterebilir. Bu makalenin amacı bir model roket prototipinin tasarım adımlarını ve performans analizlerini açıklamaktır. Roket, başlangıçtan itibaren yüksek apoje ve daha yüksek yük taşıma hedefiyle tasarlanmıştır. Tasarım adımları gösterilmiş, simülasyonlar yapılmıştır ve optimizasyon sonuçları değerlendirilerek roketler üretilmiştir. Roketlerde burun konisi, kanatçık ve malzeme mukavemeti hesaplamaları, belirsizliklerin olumsuz sonuçlarını önlemek amacıyla detaylı olarak yapılmıştır. Model roketin imalatı, tasarımı ve roket prototipinin simülasyonu başarıyla gerçekleştirilmiştir.

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“…M. Ferraiuolo [10] also researched a global linear model and a local nonlinear model to improve the accuracy of the numerical simulations. Citarella R. [11] investigated the main failure phenomena that could occur during the thrust chamber's service life using non-linear finite element analyses. The most critical areas appeared on the inner surface of the chamber, which was consistent with experimental tests from literature conducted on similar geometries.…”

Section: Introductionmentioning

confidence: 99%

Life Analysis of Reusable Liquid Rocket Engine Thrust Chamber

Cheng

Zhang

2022

Aerospace

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The thrust chamber’s inner wall suffers high temperature and pressure differences from the coolant channel, which limits the life of the rocket engine. Life prediction of the thrust chamber really plays an important role in reusable launch vehicle propulsion systems. The Porowski beam model is widely used in the life prediction of reusable liquid rocket engine thrust chambers, which calculates the life caused by fatigue, creep, and thinning after each firing cycle. In order to analyze the life of the thrust chamber, a LOX/Kerosene rocket engine is investigated in this paper. The life analysis consists of pressure and temperature differences and structural parameters. Two kinds of inner wall materials were chosen for comparison in this research: OFHC copper and Narloy-Z alloy. The results are presented to offer a reference for the design and manufacture of reusable rocket engine thrust chambers in the future.

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Thermostructural Numerical Analysis of the Thrust Chamber of a Liquid Propellant Rocket Engine

Cited by 8 publications

References 33 publications

Thermal Behaviour of the Cooling Jacket Belonging to a Liquid Oxygen/Liquid Methane Rocket Engine Demonstrator in the Operation Box

Thermal Behaviour of the Cooling Jacket Belonging to a Liquid Oxygen/Liquid Methane Rocket Engine Demonstrator in the Operation Box

Design and Simulation of a Model Rocket Prototype

Life Analysis of Reusable Liquid Rocket Engine Thrust Chamber

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