【摘 要】
:
Due to their potential properties unlike traditional materials and structures,elastic wave metamaterials have received signifi-cant interests in recent years.With the coupling between the acoustic and vibration,their mechanical characteristics can be tune
【机 构】
:
Institute of Engineering Mechanics,Beijing Jiaotong University,Beijing 100044,China;Department of Me
论文部分内容阅读
Due to their potential properties unlike traditional materials and structures,elastic wave metamaterials have received signifi-cant interests in recent years.With the coupling between the acoustic and vibration,their mechanical characteristics can be tuned by the active feedback control system at low frequency ranges in which the traditional passive control is limited.This work illustrates that the superior performances of the effective mass density and sound pressure level (SPL) of an elastic wave metamaterial can be significantly changed by the active control,in which the periodic array of local resonators and orthogonal stiffeners are included.Significantly,based on the locally resonant mechanism,the negative density occurs over a frequency range.Due to the effects of lattice constant,structural damping and other parameters,the SPL with the function of fluid-solid coupling are illustrated and discussed.
其他文献
In engineering component design,material models are increasingly used in finite element simulations for an expeditious and less costly analysis of the design prototypes.As such,researchers strive to formulate models that are less complex,robust,and accura
针对三维内转式进气道V字形唇口部位气动热载荷严酷的问题,将唇口简化为V字形钝前缘,在来流马赫数6条件下,采用数值模拟并辅以激波风洞实验,研究了气动热随前缘几何参数的变化规律.结果表明,在半径比R/r(根部倒圆半径R和前缘钝化半径r之比)和半扩张角β的联合作用下,V字形根部主要出现三种激波反射类型,其壁面热流峰值的位置和大小均差异明显.在(R/r,β)几何参数空间中,当R/r和β都相对较小时,V字形根部发生异侧激波规则反射,超声速气流冲击驻点附近壁面,并产生极其严酷的第一类中心热流峰值,最高可达相同钝化半径
Collective cell migration is extensively observed in embryo development and cancer invasion.During these processes,the interactions between cells with distinct identities and fates are of importance for boundary formation and host defense against cancer.I
Vitrimer is a polymer network with dynamic covalent bonds,which can be dynamically broken and reformed.Thanks to the dynamic covalent bonds,vitrimer behaves like an elastomer at high deformation rate or low temperature but a viscous fluid at low deformati
等离子体流动控制技术是一种以等离子体气动激励为控制手段的主动流动控制技术.为了进一步提高等离子体激励器可控机翼尺度,以超临界机翼SC(2)-0714大迎角分离流为研究对象,以对称布局介质阻挡放电等离子体为控制方式,以测力、粒子图像测速仪为研究手段,从等离子体激励器特性研究出发,深入开展了机翼尺度效应对等离子体控制的影响研究,提出了适用于分离流控制的能效比系数,探索了分离流等离子体控制机理,掌握了机翼尺度对分离流控制的影响规律.结果表明:(1)随着机翼尺度的增大,布置到机翼上的激励器电极长度会相应增加;在本
激波-激波干扰流场预测是超声速乃至高超声速流动中最具挑战性的问题之一.特别地,第IV类激波干扰由于其在壁面驻点附近产生极高的热载荷而备受关注.本文针对圆柱诱导的弓形激波和入射斜激波的干扰问题,分别基于量热完全气体模型和考虑振动激发的热完全气体模型,数值求解有黏二维可压缩NS方程,分析了高温气体效应对激波干扰流场结构,以及第IV类激波干扰流场状态参数的影响.接着,本文基于一种具有广义可分离特性的遗传算法(多层分块算法),给出能够预测不同气体模型下第IV类激波干扰流场三波点的坐标位置、超声速射流的几何形状等特
相比于传统乘波体外形,双后掠乘波体在保持高超声速良好性能的条件下能够提升乘波体低速气动性能,但其仍存在低速稳定性不好等缺陷.本文从密切锥乘波体理论提出给定前缘型线的乘波体设计方法,通过给定三维前缘型线分别生成具有相同平面投影形状的上反和下反机翼双后掠乘波体.使用CFD技术评估不同上下反程度外翼乘波体的低速性能,分析升阻特性以及流场涡结构特点.选取稳定性判据,研究上下反翼对纵向和横侧向稳定性的影响.结果表明,机翼上下反对乘波体低速升阻特性影响较小;不同外形均为纵向静不稳定的,且俯仰力矩变化趋势比较类似,机翼
以喷气推进为动力的水下超空泡航行体,通气空泡的稳定性和空泡形态控制问题是关键所在.本文利用VOF耦合水平集界面追踪方法,考虑气体的可压缩性,通过改变射流强度和模型长度,开展了一系列通气空泡和超音速尾射流相互作用的数值仿真,重点分析了通气空泡的稳定性和闭合位置.数值结果表明:(1)在超音速尾射流作用下,通气空泡的界面会经历膨胀、颈缩、断裂回缩过程,然后开始周期性震荡泄气.通气空泡的形态长度相较于无射流条件下大大减小;(2)气液界面两侧强剪切有可能诱导空泡失稳溃灭,而这种空泡失稳机制主要取决于两个无量纲参数(
The waterjet propulsion is widely applied in the marine vessels over 30 knots,and the intake duct is considered as an essential component that strongly relates to the propulsion performance.This paper sheds light on the flow features inside an intake duct
激光冲击强化技术可以有效地提高材料的疲劳寿命,被广泛应用于航空航天领域.CoCrFeMnNi高熵合金作为一种经典的高熵合金体系,研究其激光冲击强化后的微观组织变化以及冲击动态响应对该材料未来在航空航天领域中的应用具有重要意义.采用分子动力学方法,对CoCrFeMnNi高熵合金进行了冲击模拟,发现冲击时弹、塑性双波分离现象以及微结构演化具有明显的取向相关性.沿[100]方向进行冲击时未出现双波分离结构,并且塑性变形过程中会产生中间相;而沿[110]与[111]方向冲击时产生了双波分离结构,并且受冲击区域存在