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Study on effects of the secondary fuel manifold unfold pressure on engine starting performance
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作者 Jianbing Cai Gaiqi Li +1 位作者 Jianhua Li Yi Hu 《Propulsion and Power Research》 SCIE 2017年第4期253-258,共6页
The fuel manifold is an import accessory through which the fuel enters in combustor,after measuring in fuel control system.The component test results of fuel manifolds show that,when the starting fuel supply is given ... The fuel manifold is an import accessory through which the fuel enters in combustor,after measuring in fuel control system.The component test results of fuel manifolds show that,when the starting fuel supply is given and the primary fuel manifold relative unfold pressure is at constant,the adjustment of the secondary fuel manifold turn-on pressure has effects on fuel flow through the secondary fuel manifold and the time of fuel into the combustion chamber.The verification test of the secondary fuel manifold unfold pressure influence on engine starting performance has been conducted,showing that the unfold pressure variation of the secondary fuel manifold has great influence on the engine start performance.The test research results have important guidance and reference meaning for confirming the secondary fuel manifold unfolds pressure. 展开更多
关键词 Fuel manifold The primary fuel manifold The secondary fuel manifold Switch pressure Turbo-shaft engine
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Development of a rarefaction wave at discharge initiation in a storage silo--DEM simulations
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作者 R. Kobylka J. Horabik M. Molenda 《Particuology》 SCIE EI CAS CSCD 2018年第1期37-49,共13页
The generation of a rarefaction wave at the initiation of discharge from a storage silo is a phenomenon of scientific and practical interest. The effect, sometimes termed the dynamic pressure switch, may create danger... The generation of a rarefaction wave at the initiation of discharge from a storage silo is a phenomenon of scientific and practical interest. The effect, sometimes termed the dynamic pressure switch, may create dangerous pulsations of the storage structure. Owing to the nonlinearity, discontinuity, and heterogeneity of granular systems, the mechanism of generation and propagation of stress waves is complex and not yet completely understood. The present study conducted discrete element simulations to model the formation and propagation of a rarefaction wave in a granular material contained in a silo. Modeling was performed for a flat-bottom cylindrical container with diameter of 0.1 or 0.12 m and height of 0.5 m. The effects of the orifice size and the shape of the initial discharging impulse on the shape and extent of the rarefaction wave were examined. Positions, velocities, and forces of particles were recorded every 10-5 s and used to infer the location of the front of the rarefaction wave and loads on construction members. Discharge through the entire bottom of the bin generates a plane rarefaction wave that may be followed by a compaction wave, depending on the discharge rate. Discharge through the orifice generates a spherical rarefaction wave that, after reflection from the silo wall, travels up the silo as a sequence of rarefaction-compaction cycles with constant wavelength equal to the silo diameter, During the travel of the wave along the bin height, the wave amplitude increases with the distance traveled. Simulations confirmed earlier findings of laboratory and numerical (finite element method) experiments and a theoretical approach, estimating the speed of the front of the rarefaction wave to range from 70 to 80 m/s and the speed of the tail to range from 20 to 60 m/s. 展开更多
关键词 Granular flow Dynamic pressure switch Discrete element method Silo discharge Stress wave Rarefaction wave
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