Impulse Generation by an Open Shock Tube

Kasahara, Jiro; Liang, Zijian; Browne, S.; Shepherd, Joseph E.

doi:10.2514/1.27467

Cited by 35 publications

(18 citation statements)

References 22 publications

(42 reference statements)

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“…Numerical analysis by Morris et al [23] and an experiment by Copper et al [33] showed that the expansion effect of by nozzle became dominant, like a steady flow, if the ambient pressure around a PDE was sufficiently low. Kasahara et al [34] showed the physical essence of the partial-fill effect in an experiment with a shock-tube-shaped ballistic pendulum and by numerical analysis. Not only the above-mentioned fundamental studies but also validations of PDE systems have been carried out as application studies.…”

Section: Introductionmentioning

confidence: 99%

Optical and thrust measurement of a pulse detonation combustor with a coaxial rotary valve

Matsuoka

Esumi

Ikeguchi

et al. 2012

Combustion and Flame

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We developed a rotary valve for a pulse detonation engine (PDE), and confirmed its basic characteristics and performance. In a square cross-section combustor, we visualized a multi-shot of a pulse detonation rocket engine (PDRE) cycle at an operation frequency of 160 Hz by using a high-speed camera (time resolution: 3.33 μsec, space resolution: 0.4 mm) and a Schlieren method.The propellant filling process and the purge process were confirmed, and each process was modeled.Moreover, we confirmed the processes of detonation wave generation and burned gas blowdown. In addition, we investigated the impact of shortening the passage width of a combustor and negative-time ignition (ignition time is earlier than the end-time of the propellant filling process) on the deflagration-to-detonation transition (DDT) distance and time. The DDT distance did not depend on the passage width of a combustor and decreased under the negative-time ignition condition. With a passage width of 20 mm, the DDT distance decreased by 22% under the negative-time ignition condition to a minimum value (76 ± 8 mm). The DDT time from spark time reached a minimum value (69 ± 14 μsec) under the condition of a passage width of 10 mm and negative-time ignition.The detonation initiation time and the DDT distance were represented by the time until the flame expanded toward the tube-axis one-dimensionally from ignition (characteristic time). We also carried out thrust measurement using a PDRE system composed of a circular cross-section combustor and the newly developed valve. We obtained a stable time-averaged thrust in a wide range of operation frequency (40 Hz -160 Hz) and confirmed the increase of specific impulse due to a partial-fill effect.

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Section: Introductionmentioning

confidence: 99%

Optical and thrust measurement of a pulse detonation combustor with a coaxial rotary valve

Matsuoka

Esumi

Ikeguchi

et al. 2012

Combustion and Flame

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“…This essence of the partial fill effect is explained by considering shock impedance. 16,25) If the shock impedance of the driven gas is higher than the detonation wave, the transmitted and reflected waves are both shock waves. The reflected shock wave undergoes repeated reflection between the contact surface and the closed end wall, and the impulse increases.…”

Section: Propellant-based Specific Impulsementioning

confidence: 99%

“…Kasahara et al 16) compared single-pulse experimental and numerical calculation results using an open shock tube and the bubble model (He and air, N 2 and air). When the fill fraction was small ( < 0:2), the analytical model predicted a maximum specific impulse.…”

Section: Propellant-based Specific Impulsementioning

confidence: 99%

“…The partial filling of the propellant in a detonation tube is the simplest way to increase the specific impulse. [11][12][13][14][15][16] In addition to the propellant in the detonation tube, purge gas, burned gas and air suctioned from the open end after the high-pressure burned gas has been blown down are compressed by a shock wave, and the specific impulse is increased by the compressed gases. In particular, the partial-fill effect is strongly dependent on the amount of suctioned air, because the air density of & air % 1:20 kg/m 3 at 1 atm and 300 K is higher than the burned gas density of & b % 0:104 kg/m 3 at 1atm.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Thrust Performance of Rotary-Valved Four-Cylinder Pulse Detonation Rocket Engine

Matsuoka

Sakamoto

Morozumi

et al. 2015

Trans. Japan Soc. Aero. S Sci.

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We designed a rotary valve for a multi-cylinder pulse detonation rocket engine (PDRE), and constructed a greatly simplified rotary-valved four-cylinder PDRE (inner diameter and length of detonation tube: 37 mm and 1,600 mm, respectively). The partial-fill effect of a propellant in a multi-cylinder PDRE under high-frequency operation was investigated. The suctioned-air fill fraction was estimated using the model of Sato et al., which is a semiempirical formula for the partial-

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“…However, it is important to investigate the local ignitions behind shock waves under low temperature conditions, from the point of view of chemical kinetics in high-prssure (non-diluted test gases) shock tube experiments in which the non-uniformity of reflected shock waves tends to be greater because of increased viscous effects [23,24] and from the view of application systems (for example, pulse detonation engines (PDEs) [25][26][27][28][29][30][31][32][33][34][35] etc.). Therefore we focused on local ignitions induced by non-uniformity behind reflected shock waves under low-temperature conditions (Voevodsky and Soloukhin [17] : mild ignition, Gilbert and Strehlow [2] : hot spot initiation, Mayer and Oppenheim [18] : mild ignition) and investigated numerically and experimentally the local ignition position and the reason why local ignitions are located at a point distant from the reflecting wall.…”

Section: Objective Of the Present Studymentioning

confidence: 99%

Visualization study of ignition modes behind bifurcated-reflected shock waves

Yamashita

Kasahara

Sugiyama

et al. 2012

Combustion and Flame

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This study was a numerical and experimental investigation of lowtemperature auto-ignitions behind reflected shock waves in which a shock tube was employed as the experimental system. We used a high-speed video camera and the Schlieren method to visualize the ignition phenomena. Experiments were performed over a temperature range from 54910 to 134911 K and a pressure range from 56 to 203  kPa, and a non-diluted stoichiometric acetylene-oxygen mixture was chosen as the combustible gas. We introduced a numerical simulation to help us understand the disturbed temperature distribution behind bifurcated shock waves due to interference between reflected shock waves and the boundary layer developed behind incident shock waves.Additionally, we experimentally observed and evaluated quantitatively a tendency for ignition positions to be located farther from the reflecting wall as the temperature decreased behind reflected shock waves. To focus our attention on the ignition positions, we classified the ignition types behind reflected shock waves as near-wall ignition and far-wall ignition by 4.7 mm distance from Combustion and Flame 159 (2012)

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Impulse Generation by an Open Shock Tube

Cited by 35 publications

References 22 publications

Optical and thrust measurement of a pulse detonation combustor with a coaxial rotary valve

Optical and thrust measurement of a pulse detonation combustor with a coaxial rotary valve

Thrust Performance of Rotary-Valved Four-Cylinder Pulse Detonation Rocket Engine

Visualization study of ignition modes behind bifurcated-reflected shock waves

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