形状记忆合金纤维混杂单层的阻尼预测

本文作者采用细观力学阻尼理论,分析SMA纤维和普通纤维混杂的单向单层材料的阻尼性能,给出材料在6个方向上的阻尼性能计算公式,通过数值算例讨论NiTi的阻尼混杂效应。     

双闭室复合材料薄壁梁的结构阻尼细观分析

研究双闭室复合材料薄壁梁的结构阻尼特性。基于单层混杂材料的细观力学阻尼计算方法和多胞模型,分别获得单层复合材料的等效阻尼特性和等效弹性特性;基于变分渐进法（VAM)和Hamilton原理,建立双闭室复合材料薄壁梁振动方程;采用Galerkin法对薄壁梁进行自由振动分析;在获得薄壁梁振动模态矢量的基础上,根据最大应变能理论,对薄壁梁的模态阻尼性能进行预测,并且将阻尼预测的结果与现有的有限元计算结果进行对比,验证了本文阻尼分析模型的有效性。进一步针对四种种构型双闭室复合材料薄壁箱形梁,进行阻尼计算,揭示了纤维铺层角和纤维含量的影响。     

形状记忆合金纤维混杂正交对称铺层板的固有频率

形状记忆合金（SMA）混杂复合材料板是将有预应变的SMA纤维与普通纤维混杂单层内构成的。基于主动应变能调节（ASET）的概念,可实现对板的固有频率的调整。本文采用Galerkin法导出形状记忆合金（SAM）纤维混杂对称正交智能复合材料铺层板自由振动的频率的分析表达式。数值结果表明,SMA纤维的相变激发温度、体积含量、分布方式及其预应变对固有频率均有的影响,尤其是温度、SAM含量及其分布的作用更为显著,是结构振动控制的重要设计参数。     

湿热环境下玻/碳纤维混杂复合材料梁阻尼特性的细观力学分析

基于复合材料细观力学,利用能量耗散原理及宏观应变能法建立了湿热环境下玻/碳纤维混杂复合材料层合梁的阻尼预测模型。利用MATLAB软件编写了湿热环境下玻/碳纤维混杂复合材料损耗因子的计算程序,研究了纤维铺设角度、体积分数、铺层顺序以及湿热效应对玻/碳纤维混杂复合材料层合梁阻尼性能的影响规律。结果表明：湿热环境导致材料产生湿热应变是影响阻尼特性的主要机理;玻/碳纤维混杂复合材料层合梁的损耗因子均随温度及吸水浓度的增大而增大,且温度的影响远大于吸水浓度的影响;纤维体积分数越高,受湿热影响程度越大;铺层角度对损耗因子影响远高于湿热、混杂方式、纤维体积分数的影响。     

环氧树脂混杂复合材料的阻尼性能研究

从本文研究的混杂复合材料阻尼特性的影响因素看,玻璃纤维和碳纤维混杂复合材料中两种纤维对阻尼性能和力学性能的作用和贡献是不同的。经GF/CF混杂后,复合材料的阻尼性能符合混合率,阻尼因子界于GF复合材料和CF复合材料的之间。另外,纤维zk强复合材料的模量变化和玻璃化转变温度受所加纤维的种类、含量和混杂效果的影响。     

层间混杂复合材料装甲板防弹性能及其防弹机制

为研究层间混杂复合材料装甲板的防弹性能及其防弹机制,采用钢芯弹侵彻层间混杂复合材料装甲板。以超高分子量聚乙烯（Ultra high molecular weight polyethylene,UHMWPE）纤维、对位芳香族聚酰胺纤维作增强纤维,水性聚氨酯（Waterborne Polyurethane,WPU）树脂和环氧树脂（Epoxy resin,EP）作基体,采用热压工艺制备单向（Unidirectional,UD）结构的层间混杂复合材料装甲板。研究混杂比例、防弹面和树脂基体对混杂复合材料装甲板防弹性能的影响以及弹击后混杂复合材料装甲板的破坏形貌,分析混杂复合材料装甲板的防弹机制,并对复合材料装甲板的破坏机制进行了分析。结果表明:混杂复合材料装甲板的防弹性能优于其任一单一纤维复合材料装甲板;WPU的防弹性能要优于环氧树脂;以UHMWPE纤维复合材料充当防弹面时,混杂复合材料装甲板具有更好的防弹性能;纤维拉伸变形和装甲板分层是纤维复合材料装甲板主要的吸能方式。      

形状记忆合金纤维正交各向异性层合矩形板的非线性弯曲振动

研究了形状记忆合金(SMA)纤维混杂复合材料大挠度层合板的非线性自由与受迫振动特性。基于描述SMA力学行为的Brinson理论以及层合板材料性能预测的混合率, 建立了SMA纤维混杂复合材料大挠度层合板的本构方程, 基于对称层合各向异性弹性板的非线性理论, 建立了以横向挠度和应力函数表示的板的横向振动方程和相容方程。采用Galerkin近似解法将振动方程化为时间变量的含有三次非线性项的Duffing型常微分方程, 采用谐波平衡法(HBM)获得系统的固有频率方程和强迫振动稳态频率响应方程。数值计算表明: 非线性板自由振动频率比与激励温度的关系具有与线性板相同的特征, 马氏体相向奥氏体相转变阶段温度对板的振动频响特性曲线的影响最显著, 同时也讨论了SMA纤维含量、 板的纵横比以及自由振动幅值对板的非线性频率比的影响。      

SMA纤维复合材料变截面板簧固有频率特性研究

研究了形状记忆合金(SMA)纤维混杂复合材料变截面板簧的固有频率特性.基于Brinson本构模型,讨论了SMA的受限回复特性.在建立具有SMA纤维的各向异性层合梁本构方程的基础上,利用瑞利-里兹能量法求板簧的固有频率,并给出板簧固有频率的表达式.应用MATLAB进行数值计算,得到板簧固有频率与温度、铺层角、SMA含量的关系曲线,揭示了形状记忆合金纤维复合材料变截面板簧的固有频率可调节机理.     

苎麻纤维布和玻璃纤维布混杂铺层复合材料的力学性能

利用真空吸注成型(vacuum resin absorbable molding,VRAM)工艺制备苎麻纤维布与玻璃纤维布混杂铺层的环氧树脂基复合材料。测定复合材料的损耗因子、储能模量的温度谱和力学性能;利用单悬臂梁共振实验测量复合材料的共振频率和自由振动衰减曲线并计算出了阻尼因子。用有限元软件对其共振频率和自由振动衰减实验进行仿真分析。结果表明:通过苎麻纤维布/玻璃纤维布的混杂铺层,能够实现材料阻尼性能和力学性能的可控调节,充分发挥复合材料可设计性强的优势。其中RGR铺层的复合材料的损耗因子比纯玻璃纤维板提高了1.4倍,而拉伸强度比纯苎麻纤维板提高了3倍多;自由振动的有限元模拟曲线和实验曲线基本吻合,表明可以通过模拟软件实现复合材料的虚拟振动测试,从而为材料性能预测和设计提供方便。     

SMA纤维复合材料变截面板簧的固有频率特性研究

摘 要:研究了形状记忆合金（SMA）纤维混杂复合材料变截面板簧的固有频率特性。基于Brinson本构模型,讨论了SMA的受限回复特性。在建立具有SMA纤维的各向异性层合梁本构方程的基础上,利用瑞利-里兹能量法求板簧的固有频率,并给出板簧固有频率的表达式。应用MATLAB进行数值计算,得到板簧固有频率与温度、铺层角、SMA含量的关系曲线,揭示了形状记忆合金纤维复合材料变截面板簧的固有频率可调节机理。     

Stress distributions in single shape memory alloy fiber composites

Shape memory alloy (SMA) in the form of wires or short fibers can be embedded into host materials to form SMA composites that can satisfy a wide variety of engineering requirements. The recovery action of SMA inclusions induced by elevated temperature can change the modal properties and hence the mechanical responses of entire composite structures. Due to the weak interface strength between the SMA wire and the matrix, interface debonding often occurs when the SMA composites act through an external force or through actuation temperature or combination of the two. Thus the function of SMAs inside the matrix cannot be fully utilized. To improve the properties and hence the functionality of SMA composites it is therefore very important to understand the stress transfers between SMA fibers and matrix and the distributions of internal stresses in the SMA composite. In this paper, a theoretical model incorporating Brinson’s constitutive law of SMA for the prediction of internal stresses is successfully developed for SMA composites, based on the principle of minimum complementary energy. A typical two-cylinder model consisting of a single SMA fiber surrounded by epoxy matrix is employed to analyze the stress distributions in the SMA fiber, the matrix, and at the interface, with important contributions of the thermo-mechanical effect and the shape memory effect. Assumed stress functions that satisfy equilibrium equations in the fiber and matrix respectively are utilized, as well as the principle of minimum complementary energy, to analyze the internal stress distributions during fiber pull-out and the thermal loading process. The entire range of axisymmetric states of stresses in the SMA fiber and matrix are developed. The results indicate substantial variation in stress distribution profiles for different activation and loading scenarios.     

Damping,tensile, and impact properties of superelastic shape memory alloy (SMA) fiber-reinforced polymer composites

The potential of superelastic shape memory alloy (SMA) fibers to enhance the damping capacity and toughness of a thermoset polymer matrix was evaluated. A single-fiber winder was designed and built to manufacture a pre-form consisting of 102 μm diameter SMA fibers aligned parallel to each other. This pre-form was loaded to varying amounts of pre-strain and impregnated with vinyl ester to manufacture SMA fiber composites with 20% fiber volume fraction. The composites were tested using a Differential Scanning Calorimeter (DSC) and a Dynamic Mechanical Analysis (DMA), to evaluate the improvement in damping capacity of the polymer matrix due to the SMA fibers. Tensile and instrumented impact testing were carried out to evaluate improvements in mechanical properties and toughness of the composites. Appreciable improvement was observed in damping, tensile, and impact properties of the polymer matrix due to reinforcement with superelastic SMA fibers, highlighting the advantages of their use in polymer composites.     

SMA纤维混杂层合梁的振动分析

提出一类形状记忆合金(SMA)纤维混杂层合梁的数学模型。采用多胞模型、形状记忆合金一维本构关系分析方法,同时考虑铁木辛柯剪切和马氏体相变的影响。目的是为了更进一步了解层合梁的振动控制。SMA纤维用来作为驱动器,它能够改变弹性模量和回复力,以此改变梁的频率。分析了SMA纤维含量、铺设角度和横向剪切变形的影响。结果表明,通过激活形状记忆合金纤维及改变初始变形,对层合梁的自振频率有很强的控制和调节能力。     

Design of hybrid steel/composite circular plate cutting tool structures

Substituting composite structures for conventional metallic structures has many advantages because composite materials have both high specific stiffness and damping characteristics compared to conventional metallic materials. In this study, circular plate cutting tools which are used for rough machining of bearing sites in crankshafts or camshafts were designed with the fiber reinforced composite material to reduce tool mass and to improve the dynamic stiffness of circular plate cutting tools. The hybrid steel/composite circular plate cutting tool was analyzed by finite element method with respect to material types such as composite and foam, stacking angles of the composite, adhesive bonding thickness, and dimensions of the cutting tool. Also, the constrained damping characteristics of the tools were experimentally investigated with respect to the adhesive bonding thickness and material type such as composite and PVC foam. From the finite element analysis and experimental results, optimal design parameters for the hybrid steel/composite circular plate cutting tool were suggested.     

Development of the composite third robot arm of the six-axis articulated robot manipulator

The material used for robot structures should have specific stiffness (stiffness/density) to give positional accuracy and fast maneuverability to the robot manipulator. Also, high material damping is beneficial because it can dissipate the structural vibration induced in the robot manipulator structure. Both the high specific stiffness and damping of the material cannot be achieved through conventional materials such as steel and aluminum because they have almost the same low specific stiffness and low material damping. However, fiber reinforced polymeric composite materials that consist of high specific modulus fiber and high damping matrix have both high specific stiffness and high material damping.

In order to increase specific stiffness and damping, in this work, the third robot arm of the articulated robot manipulator that has 6 d.f. (degrees of freedom), 60 N payload and 0.1 mm positional accuracy of the end effector was designed and manufactured with carbon fiber epoxy composite material. The composite third robot arm was composed of the composite yoke, the composite cylindrical tubular structure and the aluminum flange.

After manufacturing the composite arm, the dynamic property and operational performance were compared to those of the hybrid third robot arm that was composed of the aluminum yoke, the composite tubular structure and the aluminum flange.

From the experiments, it was found that the composite third robot arm contributed to improving both the dynamic characteristics and operational performance of the articulated robot.     

叠层复合材料圆柱壳的细-宏观阻尼特性预测

研究了叠层复合材料圆柱壳的细-宏观阻尼特性。基于Reissner-Naghdi薄壳理论,给出了圆柱壳的振动微分方程,在分量变量的过程中,采用Haar小波级数表示轴向振型,Fourier级数表示环向振型,通过边界条件求解积分过程中出现的未知系数,进而得到用于分析圆柱壳自由振动特性的特征方程;基于单层混杂材料的细观力学阻尼计算方法和多胞模型,分别获得单层复合材料的等效阻尼特性和等效弹性特性,利用复模量法对复合材料圆柱壳的阻尼特性进行预测。通过与其他文献中阻尼预测的结果进行对比,验证了该研究所采用方法的有效性;进一步针对四种典型的边界条件,即固支-固支(C-C)、固支-简支(C-S)、简支-简支(S-S)、固支-自由(C-F)等边界,从细-宏观层面分析了纤维含量、环向波数、铺层方式和几何参数等因素对复合材料圆柱壳阻尼特性的影响规律。     

环氧树脂基复合材料的阻尼性能及在降噪上的应用研究

玻璃纤维ＧＦ和碳纤维ＣＦ混杂复合材料中期两种纤维对阻尼性能和贡献是不同的,混杂纤维种类、方式、含量的选择与设计对兼顾最终复合材料的力学性能和阻尼性能是起决定性的。通过复合材料的设计,利用阻尼复合材料制备的螺旋桨比金属螺旋桨显示出更好的抑制振动的能力,可以研制出满足条件的复合材料制品。