科创中国

The large and complex structures are divided into hundreds of thousands or millions degrees of freedom(DOF) when they are calculated which will spend a lot of time and the efficiency will be extremely low. The classical component modal synthesis method(CMSM) are used extensively, but for many structures in the engineering of high-rise buildings, aerospace systemic engineerings, marine oil platforms etc, a large amount of calculation is still needed. An improved hybrid interface substructural component modal synthesis method(HISCMSM) is proposed. The parametric model of the mistuned blisk is built by the improved HISCMSM. The double coordinating conditions of the displacement and the force are introduced to ensure the computational accuracy. Compared with the overall structure finite element model method(FEMM), the computational time is shortened by 23.86%–31.56% and the modal deviation is 0.002%–0.157% which meets the requirement of the computational accuracy. It is faster 4.46%–10.57% than the classical HISCMSM. So the improved HISCMSM is better than the classical HISCMSM and the overall structure FEMM. Meanwhile, the frequency and the modal shape are researched, considering the factors including rotational speed, gas temperature and geometry size. The strong localization phenomenon of the modal shape's the maximum displacement and the maximum stress is observed in the second frequency band and it is the most sensitive in the frequency veering. But the localization phenomenon is relatively weak in 1st and the 3d frequency band. The localization of the modal shape is more serious under the condition of the geometric dimensioning mistuned. An improved HISCMSM is proposed, the computational efficiency of the mistuned blisk can be increased observably by this method.

Microchannel heat sink with high heat transfer coefficients has been extensively investigated due to its wide application prospective in electronic cooling.However,this cooling system requires a separate pump to drive the fluid transfer,which is uneasy to minimize and reduces their reliability and applicability of the whole system.In order to avoid these problems,valveless piezoelectric pump with fractal-like Y-shape branching tubes is proposed.Fractal-like Y-shape branching tube used in microchannel heat sinks is exploited as no-moving-part valve of the valveless piezoelectric pump.In order to obtain flow characteristics of the pump,the relationship between tube structure and flow rate of the pump is studied.Specifically,the flow resistances of fractal-like Y-shape branching tubes and flow rate of the pump are analyzed by using fractal theory.Then,finite element software is employed to simulate the flow field of the tube,and the relationships between pressure drop and flow rate along merging and dividing flows are obtained.Finally,valveless piezoelectric pumps with fractal-like Y-shape branching tubes with different fractal dimensions of diameter distribution are fabricated,and flow rate experiment is conducted.The experimental results show that the flow rate of the pump increases with the rise of fractal dimension of the tube diameter.When fractal dimension is 3,the maximum flow rate of the valveless pump is 29.16 mL/min under 100 V peak to peak(13 Hz)power supply,which reveals the relationship between flow rate and fractal dimensions of tube diameter distribution.This paper investigates the flow characteristics of valveless piezoelectric pump with fractal-like Y-shape branching tubes,which provides certain references for valveless piezoelectric pump with fractal-like Y-shape branching tubes in application on electronic chip cooling.

提出了一种采用视频监控系统对人行通道口进行双向人流量计数的方法.首先建立发色模型与头部形状模型,采用形态学运算提取人的头部目标,然后跟踪目标建立人头目标移动链,依据目标链位置信息判别行人的进出方向,最后设置感兴趣的检测区域,并对通过该检测区域的行人计数.实验结果表明,该方法能实时有效地统计通道口处双向人流量.