Experimental Pressure Gain Analysis of Pulsed Detonation Engine

Bogoi, Alina; Cuciuc, Tudor; Cojocea, Andrei Vlad; Gall, Mihnea; Porumbel, Ionuț; Hrițcu, Constantin Eusebiu

doi:10.3390/aerospace11060465

Aerospace

2024

DOI: 10.3390/aerospace11060465

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Experimental Pressure Gain Analysis of Pulsed Detonation Engine

Alina Bogoi,

Tudor Cuciuc,

Andrei Vlad Cojocea

et al.

Abstract: A pulsed detonation chamber (PDC) equipped with Hartmann–Sprenger resonators has been designed and tested for both Hydrogen/air and Hydrogen/Oxygen mixtures. A full-factorial experimental campaign employing four factors with four levels each has been carried out for both mixtures. Instantaneous static pressure has been measured at two locations on the exhaust pipe of the PDC, and the signal has been processed to extract the average and maximum cycle pressures and the operating frequency of the spark plug. The … Show more

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2024

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Cited by 3 publications

References 32 publications

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Experimental Thrust and Specific Impulse Analysis of Pulsed Detonation Combustor

Cojocea,

Porumbel,

Gall

et al. 2024

Applied Sciences

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Detonation combustion represents a significant advancement in efficiency over traditional deflagration methods. This paper presents a Pulsed Detonation Combustor (PDC) model that is designed with an aerodynamic mixing chamber featuring Hartmann–Sprenger resonators and crossflow injection. This design enhances operational cycle frequency and enables sustained detonation over short distances (below 200 mm). The PDC’s performance was evaluated through a comprehensive full-factorial experimental campaign, incorporating four factors with four discrete levels each. Testing was conducted using both hydrogen/air and hydrogen/oxygen mixtures, highlighting the PDC’s potential as a carbon-free combustion chamber suitable for both air-breathing and space-based propulsion systems. One advantage is the versatility of our PDC breadboard, which lies in its applicability to both terrestrial and in-space applications, such as interplanetary travel or trajectory corrections. Thrust measurements were recorded using a load cell and time-averaged thrust levels were determined over the detonation cycle and are reported herein, together with the specific impulse. The results underscore the PDC’s promise as an efficient propulsion technology for future aerospace applications.

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Experimental Thrust and Specific Impulse Analysis of Pulsed Detonation Combustor

Cojocea,

Porumbel,

Gall

et al. 2024

Applied Sciences

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Experimental Investigations on the Impact of Hydrogen Injection Apertures in Pulsed Detonation Combustor

Cojocea,

Porumbel,

Gall

et al. 2024

Energies

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Combustion through detonation marks an important leap in efficiency over standard deflagration methods. This research introduces a Pulsed Detonation Combustor (PDC) model that uses Hydrogen as fuel and Oxygen as an oxidizer, specifically targeting carbon-free combustion efforts. The PDC aerodynamic features boost operating cycle frequency and facilitate Deflagration-to-Detonation Transition (DDT) within distances less than 200 mm by means of Hartmann–Sprenger resonators and cross-flow fuel/oxidizer injection. The achievement of quality mixing in a short-time filling process represents not only higher cycle operation but also enhanced performances. The scope of this paper is to assess the impact of different fuel injectors with different opening areas on the performances of the PDC. This assessment, expressed as a function of the Equivalence Ratio (ER), is conducted using two primary methods. Instantaneous static pressures are recorded and processed to extract the maximum and average cycle pressure and characterize the pressure augmentation. Thrust measurements obtained using a load cell are averaged over the detonation cycle to calculate the time-averaged thrust. The specific impulse is subsequently determined based on these thrust measurements and the corresponding mass flow data.

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Experimental Study on Ignition and Pressure-Gain Achievement in Low-Vacuum Conditions for a Pulsed Detonation Combustor

Cojocea,

Gall,

Vrabie

et al. 2024

Technologies

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Pressure-gain combustion (PGC) represents a promising alternative to conventional propulsion systems for interplanetary travel due to its key advantages, including higher thermodynamic efficiency, increased specific impulse, and more compact engine designs. However, to elevate this technology to a sufficient technology readiness level (TRL) for practical application, extensive experimental validation, particularly under vacuum conditions, is essential. This study focuses on the performance of a pulsed-detonation combustor (PDC) under near-vacuum conditions, with two primary objectives: to assess the combustor’s ignition capabilities and to characterize the shock wave behavior at the exit plane. To achieve these objectives, high-frequency pressure sensors are strategically positioned within both the vacuum chamber and the combustor prototype to capture the pressure cycles during operation, providing insights into pressure augmentation over a period of approximately 0.5 s. Additionally, the Schlieren visualization technique is employed to analyze and interpret the flow structures of the exhaust jet. The combination of these experimental methods enables a comprehensive understanding of the ignition dynamics and the development of shock waves, contributing valuable data to advance PGC technology for space-exploration applications.

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Experimental Pressure Gain Analysis of Pulsed Detonation Engine

Cited by 3 publications

References 32 publications

Experimental Thrust and Specific Impulse Analysis of Pulsed Detonation Combustor

Experimental Thrust and Specific Impulse Analysis of Pulsed Detonation Combustor

Experimental Investigations on the Impact of Hydrogen Injection Apertures in Pulsed Detonation Combustor

Experimental Study on Ignition and Pressure-Gain Achievement in Low-Vacuum Conditions for a Pulsed Detonation Combustor

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