Abstract
This work contains experimental investigations on the correlation of the detonation initiation process via a shock-focusing device with various initial pressures and mass flow rates. A pulse detonation combustor is operated with stoichiometric hydrogen--air--oxygen mixtures in single cycle operation. A rotationally symmetric shock-focusing geometry evokes the onset of a detonation by the focusing of the reflected leading shock wave, while a blockage plate at the rear end of the test rig is applied to induce an elevated initial pressure. The results show that the reactivity has a major influence on the success rate of detonation initiation. However, measurements with different blockage plates suggest that the mass flow rate has to be considered as well when predicting the success rate. Three main statements can be drawn from the results. (1) An increase in the mean flow velocity induces higher velocity fluctuations which result in a stronger leading shock ahead of the accelerating deflagration front. (2) An increase in the initial static pressure reduces the critical shock strength that must be exceeded to ensure successful detonation initiation by shock focusing. (3) Since the initial pressure is directly linked to the mass flow rate, these contrary trends can cancel each other out, which could be observed for 40% vol. of oxygen in the oxidizer. High-speed images were taken, which confirm that the detonation is initiated in the center of the converging--diverging nozzle due to focusing of the leading shock.
Highlights
Increasing the thermal efficiency of the gas turbine cycle is a major challenge in energy generation
(3) Since the initial pressure is directly linked to the mass flow rate, these contrary trends can cancel each other out, which could be observed for 40% vol of oxygen in the oxidizer
An orifice plate is applied to create an outlet blockage. This results in an additional pressure loss at the rear end of the Pulse detonation combustors (PDCs) leading to an elevated initial pressure
Summary
Increasing the thermal efficiency of the gas turbine cycle is a major challenge in energy generation. Only small step improvements, due to physical limits, have been made in the last decades. This stagnation could be overcome by the implementation of a pressure gain combustion (PGC) process. The resulting thermodynamic cycle promises a substantial gain in thermal efficiency compared to the conventional Brayton cycle.[1]. Pulse detonation combustors (PDCs) are a promising concept for realizing PGC. The efficient and reliable initiation of a detonation is challenging and has been investigated extensively in the past. In order to realize an efficient PDC process, a reliable DDT with a short run-up distance is vital. Lee et al.[4] compared the effect of a Shchelkin spiral and a series of orifice plates on detonation
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