A fast computational method of the aerodynamic characteristics of fan and booster with inlet distortion is developed in this paper. This method is based on a time-marching throughflow model, and the governing equations are circumferentially averaged Navier-Stokes equations. A model of distributed inviscid blade force and viscid blade force is adopted to reproduce the flow deflection and loss. The deviation angle and loss parameters are interpolated from a database which is extracted from 3-D simulation results of compressor with uniform inlet. After a validation case is performed, the aerodynamical performances of a multistage fan and booster with inlet radial and circumferential distortion are computed. The results show the predictive ability of this method, and the acceptable computational time cost indicates the future application potential of this method during the design stage of a new turbomachinery.
The paper presents a micro-fluidics cooling system which is designed on a silicon substrate
including a micro-pump, two temperature sensors, a flow sensor and some microchannels. To design
the cooling system optimally, a finite element model is built. The temperature distribution on the
silicon substrate is analyzed using the model. Moreover, the quantitative relation is given of the
temperature distribution, flow velocity and driving capability of the micro pump. Consequently, the
structure parameters and design requirements of the cooling system are obtained.
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