Numerical study on increasing mass flow ratio by energy deposition of high frequency pulsed laser

Wang Diankai; Hong Yanji; Li Qian

doi:10.3788/HPLPB20132507.1715

Volume 25 Issue 07

May 2013

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Zheng Zheng, Wu Hongchun, Cao LiangZhi, et al. Application of Monte Carlo and discrete ordinate coupling method to pressurized water reactor cavity radiation streaming calculation[J]. High Power Laser and Particle Beams, 2012, 24: 2946-2950. doi: 10.3788/HPLPB20122412.2946

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Wang Diankai, Hong Yanji, Li Qian. Numerical study on increasing mass flow ratio by energy deposition of high frequency pulsed laser[J]. High Power Laser and Particle Beams, 2013, 25: 1715-1718. doi: 10.3788/HPLPB20132507.1715

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Numerical study on increasing mass flow ratio by energy deposition of high frequency pulsed laser

doi: 10.3788/HPLPB20132507.1715

1.
State Key Laboratory of Laser Propulsion and Application,Academy of Equipment,Beijing 101416,China

Received Date: 2012-09-14
Rev Recd Date: 2012-11-22
Publish Date: 2013-05-02

Abstract

Abstract

The mass flow ratio(MFR) of air breathing ramjet inlet would be decreased, when the Mach number is lower than the designed value. High frequency pulsed laser energy was deposited upstream of the cowl lip to reflect the stream so as to increase the MFR. When the Mach number of the flow was 5.0, and the static pressure and temperature of the flow were 2 551.6 Pa and 116.7 K, respectively, two-dimensional non-stationary compressible RANS equations were solved with upwind format to study the mechanisms of increasing MFR by high frequency pulsed laser energy deposition. The laser deposition frequency was 100 kHz and the average power was 500 W. The crossing point of the first forebody oblique shock and extension line of cowl lip was selected as the expected point. Then the deposition position was optimized by searching near the expected point. The results indicate that with the optimization of laser energy deposition position, the MFR would be increased from 63% to 97%. The potential value of increasing MFR by high frequency pulsed laser energy deposition was proved. The method for selection of the energy deposition position was also presented.
- high repetition frequency,
- laser energy,
- virtual cowl,
- mass flow ratio,
- flow control

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