力学进展

Mao SUN

2015, 45(1) doi: 10.6052/1000-0992-14-065

Abstract(3904)

PDF(3914)

Abstract:
Insects are the earliest, most numerous and smallest fliers in the world. They can hover, fly forward, climb and descend with ease while demonstrating amazing stabilities, and they can also maneuver in impressive ways like no other organisms could. Although the wing of an insect beats at high frequency, the wing's relative velocity is small owing to the small wing length. As a result, the mean lift coefficient of wing required to balance the insect weight is relatively high, about 1.5–2, much higher than that of an airplane at cruising flight. The Reynolds number of insects' wings is small, ranging from about 10 to 3 500. How the required high-lift coefficient is produced at such low Reynolds number? Researchers are very interested in this question and in recent years, significant progress has been made in the area. Works before 2005 have been discussed in detail in several review papers, and in this article, we review the advances made since 2005. We begin with an overview of the flapping kinematics and basic equations of fluid dynamics. It is followed by a summary of the works before 2005. Then we review the advances made since 2005, dealing in turn with measurement of wing motion in freely-flying insects, leading-edge vortex, effect of wing deformation and corrugation, vortex wake of flapping wings, ground effect and aerodynamic interaction between wings and body, flight of tiny insects, flight of butterfly and dragonfly, and maneuvering flight. Finally, we make remarks on the state-of-the-art of this research field and speculate its outlooks in the near future.

The identification of dynamic loads

Zhichun YANG, You JIA

2015, 45(1) doi: 10.6052/1000-0992-14-049

Abstract(2769)

PDF(3980)

Abstract:
Dynamic load is the basis for evaluating the vibration fatigue properties of engineering structures. In most cases, it is diffcult to directly measure the external dynamic loads acting on a vibrating structure. Thus research on the dynamic load identification methods plays an important role in many engineering fields. In this paper, we first summarize the basic principles of dynamic load identification. We classify the dynamic load identification methods into two categories, i.e., those for deterministic structures and those for structures with uncertainties. Then we review the advances in the study of dynamic load identification methods for these two kinds of structures achieved in recent years, respectively. Some open problems and future research topics on dynamic load identification are discussed.

Multiphase flow in microfluidic devices

Xiaodong CHEN, Guoqing HU

2015, 45(1) doi: 10.6052/1000-0992-14-063

Abstract(2387)

PDF(2720)

Abstract:
Recent years have witnessed the rapid development of microfluidic technology and microfluidic devices as a multi-disciplinary research field. Compared to conventional methods, microfluidic technology enables us to precisely manipulate the small volume of multiphase fluids for chemical analysis, advanced materials synthesis, protein crystalliza-tion, single-cell cultivation and detection, information processing, etc. In this paper, we review the multiphase flow phenomena in microfluidic devices, summarize the fluid mechan-ics involved, describe various methods to achieve multiphase microfluidic flow, and analyze the state-of-the-art of applications and challenges in this field. Finally, numerical simulation methods and experimental measurement techniques for multiphase microflows are provided. Opportunities for future research and application of microfluidic devices are suggested.

Coherent structures and drag-reduction mechanism in wall turbulence

Chunxiao XU

2015, 45(1) doi: 10.6052/1000-0992-15-006

Abstract(2738)

PDF(3619)

Abstract:
The discovery of coherent structures in turbulent shear flows is one of the most important advances in turbulence research of the last century. These large-scale structures play important role in the physics of wall turbulence, and suggest a new direction for turbulence control. High skin friction in wall-bounded turbulent flows is closely associated with the coherent structures in the near-wall region. The control strategy based on the near-wall physics successfully achieves drag reduction, yet becomes less effective as the Reynolds number increases. It was discovered recently that large-scale coherent motions exist in the outer layer of the high-Reynolds number wall turbulence. These motions have important influence on turbulence in the near-wall region and the skin friction, and bring new challenges to the control of turbulent flow at high Reynolds number. In the present paper, we briefly review the research history on coherent structures in wall turbulence, and mainly focus on dis- cussing the near-wall coherent structures and their control mechanism, the recent research developments on the large-scale motions in the outer region of high-Reynolds number wall turbulence, and the key issues concerning the drag-reduction control of the high-Reynolds number turbulent flows.

Irradiation hardening for metallic materials

Xiazi XIAO, Dingkun SONG, Haijian CHU, Jianming XUE, Huiling DUAN

2015, 45(1) doi: 10.6052/1000-0992-14-071

Abstract(3093)

PDF(2595)

Abstract:
Investigations on irradiation hardening of metallic materials have much sig- nificance for the design of anti-irradiation materials and engineering applications. Both irradiation-induced defects and gaseous impurities produced by nuclear reactions have dra- matic irradiation effects on the mechanical properties of materials, which include irradiation hardening, irradiation embrittlement and irradiation creep, etc. In this paper we are con- cerned with irradiation hardening, i.e., the strength of materials increases with irradiation, under low irradiation doses and low temperatures of T < 0.3 T_m with T_m the melting temper- ature. Besides, other factors such as the grain size, the grain boundary and the temperature affect mechanical behaviors of irradiated polycrystalline materials. The study of irradia- tion hardening of metallic materials is a multi-scale problem, for which the macroscopic mechanical behaviors of irradiated materials are determined by both the change of interior structures with irradiation at micro-scale and the interactions among irradiated grains at meso-scale. This paper reviews experimental results, numerical simulations and theoretical models for irradiation hardening of metallic materials. Some scientific problems for future study are also presented.

Oil and water separation technology

Yingxiang WU, Jingyu XU

2015, 45(1) doi: 10.6052/1000-0992-15-001

Abstract(3370)

PDF(3461)

Abstract:
With the growth of oil exploration lasting, the water content of output fluids is increasing year by year, and in some oil wells the water content has reached to 95% and above, which brings new challenges to the existing treatment technology. To solve these problems, it is urgent to develop a new kind of oil-water separation technology to break through the "bottle-neck" of traditional technology. In this work, combined with the current demands of the oil and gas exploitation, the current situation of oil-water separation technology has been introduced systematically, as well as the characteristics of oily wastewater treatment technology, and the new demand and futural development trend of oil-water separation technology. At the same time, a new kind of pipe-type oil-water separation technology, developed by the Institute of Mechanics, Chinese Academy of Sciences, has been introduced in detail, which includes cylindrical pipe separation technology, vane-type pipe separation technology, and T-type pipe separation technology. Due to the technical advantages of new pipe-type separation technology, it can solve practical engineering problems successfully, such as heavy oil exploitation, submarine operation, and downhole separation. Furthermore, the development direction of oil-water separation technology has also been specified in this work.

Research progress on the mechanics of high speed rails

Guowei YANG, Yujie WEI, Guilin ZHAO, Yubiao LIU, Xiaohui ZENG, Yunlin XING, Jiang LAI, Yingying ZHANG, Han WU, Qisheng CHEN, Qiusheng LIU, Jiachun LI, Kaixin HU, Zhongping YANG, Wenzheng LIU, Wenjing WANG, Shouguang SUN, Weihua ZHANG, Ning ZHOU, Ruiping LI, Qingsong LV, Xuesong JIN, Zefeng WEN, Xinbiao XIAO, Xin ZHAO, Dabin CUI, Bing WU, Shuoqiao ZHONG, Xin ZHOU

2015, 45(1) doi: 10.6052/1000-0992-14-002

Abstract(6923)

PDF(5941)

Abstract:
As a result of the "Speed Up" campaigns initiated in the end of last centurywhen commercial train service averaged 48 km/h, China now has the world's longest highspeed rail (HSR) network. In the past decade, China Railway High-speed (CRH) has undergone numerous technological innovation to ensure their safe, eco-friendly, and economicaloperation. With the privilege of involving in the construction and operation of such a largescale and long distance HSR network, researchers and engineers in the eld have gained systematic and deep understanding about the dynamic system composed of train, wheels andrails, catenary and pantograph, and aerodynamic resistance. In this review paper, we summarize current research progress covering aerodynamics, catenary-pantograph interaction,dynamics and related issues of carbody, stability analysis, rail-wheel interaction, reliabilityof key components, and mechanisms about noise-generation. At the end, we supply ourperspective about opportunities and challenges for future research and development on themechanics of high speed rail.

Magneto-sensitive smart soft material and magnetorheological mechanism

Yangguang XU, Xinglong GONG, Qiang WAN, Taixiang LIU, Shouhu XUAN

2015, 45(1) doi: 10.6052/1000-0992-15-010

Abstract(2077)

PDF(1274)

Abstract:
Magneto-sensitive smart soft materials are a class of multi-functional compos-ite materials prepared by dispersing micrometer or nanometer sized magnetic particles into di®erent carrier matrix. As external magnetic field may control the rheological properties in a continuous, rapid and reversible manner, these materials have wide applications in con-struction, vibration control, automotive industry, etc. In this paper, we first introduce the history and classification of magneto-sensitive smart soft materials, and analyze the charac-teristics and existing scientific issues for di®erent kinds of such materials. Then we discuss the state-of-the-art for experimental and theoretical studies of the magnetorheological mech-anism. Finally, we propose some future trends in this smart material development aiming at practical applications.

Relative measurement for the proof mass flying along a purely gravitational orbit

Zhendong HOU, Zhaokui WANG, Yulin ZHANG

2015, 45(1) doi: 10.6052/1000-0992-15-012

Abstract(1489)

PDF(944)

Abstract:
Purely gravitational orbits are the trajectories of objects in space with grav-itational force only. Once constructed, they allow us to detect spaceborne gravity with extremely high precision, and provide highly stable spacecraft platforms for scientific ex-periments. As the core of purely gravitational orbit construction, the relative measurement for the proof mass is used for scientific data acquisition, and spacecraft tracking control input. In this paper, we first present the concept of purely gravitational orbits, and sum-marize the applications on satellite gravity measurement and gravitational wave detection. Then we survey the relative measurement requirements for various missions, and give the principles, pros and cons for three major measurement methods, namely, capacitive sensing, magnetic sensing and optical sensing. According to the attitude motion of the proof mass, the relative state resolving for its mass center can be classified into three categories. We investigate the typical resolving models based on attitude dynamics and surface modeling of the proof mass, and the velocity estimation methods for mass center. Finally we discuss the-oretical computations, on-ground validations and on-orbit validations for non-gravitational disturbances.

Modelling gas and PM pollutant dispersion in urban environments

XIE Zheng-Tong, LIU Chun-Ho, CAI Xiaoming

2015, 45(1) doi: 10.6052/1000-0992-15-008

Abstract(2001)

PDF(1833)

Abstract:
Dispersion of gas and particulate matter (PM) pollutant in urban environments is a rising concern. Physical and numerical modelling is extremely challenging due to a number of parameters involved including the turbulence nature and complex physical and/or chemical processes. The paper attempts to review the latest advances on this topic. The major contents are: using generic geometry models to understand the mechanism, coupling meso-scale (weather scale) and micro-scale (street scale) lareg-eddy simulations, effects of thermal stratification, effects of tall buildings, modelling extreme pollutant concentration in extreme conditions and coupling chemistry with turbulence. This paper focuses more on the progress of the numerical model study in the UK and Europe.

2015 Vol. 45, No. 1

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