Analysis for the residual prestress of composite barrel for railgun with tension winding

Based on the elastic theory of cylindrical shells and the theory of composite laminates, a prediction model for the residual prestress of the simplified round composite barrel for railgun is established. Only the fibre pretension is considered in this model. A three dimensional numerical simulation for the residual prestress in the railgun barrel is carried out, by combining the temperature differential method with the element birth and death technology. The results obtained by the two methods are compared. It reveals that the distribution trends of residual prestress are consistent. And the difference for residual prestress in the filament wound composite housing of barrel is relatively small. The same finite element method is used to analysis the residual prestress in the non-simplified composite barrels for railgun, which are under different control modes of winding tension. The results mean that the residual prestress in barrel will increase while the taper coefficient for winding is decreasing. Therefore, the sealing performance in bore is improved, but the strength of the filament wound composite housing drops. In addition, the axial and circumferential residual prestress in the filament wound composite housing with constant torque winding are close to the ones in iso-stress design for barrel.     

各向异性材料的有效弹性模量

在夹杂理论的基础上,采用用自洽法导出了含分布夹杂的各向异性弹性体的本构关系和有效弹性模量的细观力学表达式。本文得到的公式不仅可以处理含缺陷和损伤的材料的有效弹性模量,而且还可处理诸于纤维复合材料等各向异性材料的理论及有效弹性模量,从而为建立材料细观结构与宏观性能之间的关系提供了理论基础。     

非均布应力场中内埋裂纹的应力强度因子

在内埋裂纹线性线弹簧模型的基础上,通过引入二维权函数将裂纹面上的非均布载荷进行均布化等效,求解了中心内埋椭圆形裂纹在沿板厚非均匀分布应力场中的应力强度因子,列出了问题的奇异积分方程,利用Gauss-Chebyshev方法求解了在4种应力场分布情形下的数值结果,并与已有文献的解进行了比较,当a0/c0 ＜0.4、a0/h≤0.3时,两者结果具有较好的一致性,表明了本文方法的合理性和可靠性.     

Micromechanical simulation and experimental investigation of aluminum-based nanocomposites

Ceramic reinforced metal matrix nanocomposites are widely used in aerospace and auto industries due to their enhanced mechanical and physical properties. In this research, we investigate the mechanical properties of aluminum/Nano-silica composites through experiments and simulations. Aluminum/Nano-silica composite samples with different weight percentages of silica nanoparticles are prepared via powder metallurgy. In this method, Nano-silica and aluminum powders are mixed and compressed in a mold, followed by sintering at high temperatures. Uniaxial tensile testing of the nanocomposite samples shows that adding one percent of Nano-silica causes a considerable increase in mechanical properties of nanocomposite compared to pure aluminum. A computational micromechanical model, based on a representative volume element of aluminum/silica nanocomposite, is developed in a commercial finite element software. The model employs an elastoplastic material model along with a ductile damage model for aluminum matrix and linear elastic model for nano-silica particles. Via careful determination of model parameters from the experimental results of pure aluminum samples prepared by powder metallurgy, the proposed computational model has shown satisfactory agreement with experiments. The validated computational model can be used to perform a parametric study to optimize the micro-structure of nanocomposite for enhanced mechanical properties.     

随机载荷下疲劳寿命预估计算方法研究

分析了一种用于随机载荷下零构件疲劳寿命预估的有效计算方法 .引入材料所吸收的弹性应变能和塑性应变能等参量 ,在等能量损伤法则下推算出稳态条件下随机载荷的等价常幅应力 ,适用于结构设计阶段和改进阶段或应力响应时间历程无法实测的情况 .     

一种金属橡胶元件建模方法研究

用理论和试验相结合的手段研究金属橡胶弹性元件的动力学建模,提出一种新的建模方法,用此方法建立了基于迟滞回线拟和分解的高次弹性复合阻尼模型。该模型用非线性刚度和非线性复合阻尼机理构造,模型中的参数由试验数据辨识。用所建模型重构恢复力-位移迟滞回线,结果表明该模型能很好描述这类非线性振动系统的特性。     

不同介质中声辐射相似性

研究不同介质中声学相似条件,可为空气噪声实验数据推算相应条件水下辐射噪声,替代复杂水下实验提供依据。因此,首先运用了因次分析法对任意不同介质中的声辐射相似性进行了分析;然后,采用结构有限元耦合流体边界元理论,利用NASTRAN计算模型表面流固耦合振动;最后,通过FORTRAN边界元程序计算辐射声场;以加肋圆柱壳为对象在水和空气两种典型介质中进行了数值模拟验证。理论推导与数值计算的结果一致性表明:不同介质中两个几何相似、表面振动相似的系统间结构表面振幅与该系统几何尺度成正比、表面振动波波长与该系统传声介质中声波波长成正比时,两个模型的无量纲声压相等。     

Modeling mechanical behaviors of composites with various ratios of matrixeinclusion properties using movable cellular automaton method

Two classes of composite materials are considered: classical metaleceramic composites with reinforcing hard inclusions as well as hard ceramics matrix with soft gel inclusions. Movable cellular automaton method is used for modeling the mechanical behaviors of such different heterogeneous materials. The method is based on particle approach and may be considered as a kind of discrete element method. The main feature of the method is the use of many-body forces of inter-element interaction within the formalism of simply deformable element approximation. It was shown that the strength of reinforcing particles and the width of particle-binder interphase boundaries had determining influence on the service characteristics of metaleceramic composite. In particular, the increasing of strength of carbide inclusions may lead to significant increase in the strength and ultimate strain of composite material. On the example of porous zirconia ceramics it was shown that the change in the mechanical properties of pore surface leads to the corresponding change in effective elastic modulus and strength limit of the ceramic sample. The less is the pore size, the more is this effect. The increase in the elastic properties of pore surface of ceramics may reduce its fracture energy.     

An efficient SPH methodology for modelling mechanical characteristics of particulate composites

Particulate composites are one of the widely used materials in producing numerous state-of-the-art components in biomedical, automobile, aerospace including defence technology. Variety of modelling techniques have been adopted in the past to model mechanical behaviour of particulate composites. Due to their favourable properties, particle-based methods provide a convenient platform to model failure or fracture of these composites. Smooth particle hydrodynamics (SPH) is one of such methods which demonstrate excellent potential for modelling failure or fracture of particulate composites in a Lagrangian setting. One of the major challenges in using SPH method for modelling composite materials depends on accurate and efficient way to treat interface and boundary conditions. In this paper, a master-slave method based multi-freedom constraints is proposed to impose essential boundary conditions and interfacial displacement constraints in modelling mechanical behaviour of composite materials using SPH method. The proposed methodology enforces the above constraints more accurately and requires only smaller condition number for system stiffness matrix than the procedures based on typical penalty function approach. A minimum cut-off value-based error criteria is employed to improve the compu-tational efficiency of the proposed methodology. In addition, the proposed method is further enhanced by adopting a modified numerical interpolation scheme along the boundary to increase the accuracy and computational efficiency. The numerical examples demonstrate that the proposed master-slave approach yields better accuracy in enforcing displacement constraints and requires approximately the same computational time as that of penalty method.     

Study on dynamic response of multi-degree-of-freedom explosion vessel system under impact load

In order to study the dynamic response and calculate the axial dynamic coefficient of the monolayer cylindrical explosion vessel, the wall of vessel is simplified as a multi-degree-of-freedom (MDoF) undamped elastic foundation beam. Decoupling the coupled motion equation and using Duhamel's integrals, the solutions in generalized coordinates of the equations under exponentially decaying loads, square wave loads and triangular wave loads are calculated. These solutions are consistent in form with the solutions of single-degree-of-freedom (SDoF) undamped forced vibration simplified model. Based on the model, equivalent MDoF design method (also called MDoF dynamic coefficient method) of cylindrical explosion vessel is proposed. The traditional method can only predict the dynamic coefficient of torus portion around the explosion center, but this method can predict that of the vessel wall at any axial n dividing point position. It is verified that the prediction accuracy of this model is greatly improved compared with the SDoF model by comparing the results of this model with SDoF model and numerical simulation in different working conditions. However, the prediction accuracy decreases as the scaled distance decreases and approaches the end of the vessel, which is related to the accuracy of the empirical formula of the implosion load, the simplification of the explosion load direction, the boundary conditions, and the loading time difference.     

调制气流声源振动系统参数分析

通过实验数据与理论计算结果的对比,分析了气流对振动系统的阻尼作用;并以实验声源为基础,以等效电路方法分析了调制气流声源振动系统的弹性系数、磁感应强度、音圈质量、电阻、电感以及绕线方式等参数对音圈振幅的影响;根据调制气流声源的用途差异,提出了用于语音广播和产生大功率低频声波时振动系统各参数的选择方法.     

加筋板架抗动能穿甲的等效防护厚度研究

为研究舰船舷侧结构抗穿甲性能,采用有限元分析了两种典型工况下板架的穿甲破坏模式、弹体的剩余速度和板架的变形吸能规律,提出了基于剪切冲塞模式的剩余速度理论计算模型,比较了不同等效计算方法得到的结果,并将理论计算结果分别与相关文献的实验结果和本文的有限元计算结果进行了比较,两者之间均吻合较好。结果表明,加强筋对板架的抗穿甲性能影响较大,而板架的实际等效厚度是决定其抗穿甲性能的主要因素;不同的等效计算方法与模型相对尺寸、弹体冲击速度以及命中位置有关,对于弹体直径相对较大且初始冲击速度较高时,不同的等效计算方法得到的结果基本一致。     

一种基于SSNF的新型阈值滤波去噪算法

介绍了一种空间选择性的噪声滤波(SSNF)方法,并在此工作之上提出了一种新的自适应于小波变换尺度的阈值函数,从而对经SSNF滤波之后的小波系数进行了进一步的阈值处理,以去除残留在系数中的噪声部分。仿真试验和理论分析表明,相比其它传统的去噪方法,该方法的优点在于:所得到的小波系数不仅连续性好,而且更加接近于未加噪信号的小波系数,阈值函数具有很大的灵活性和自适应性,并适用于一些掺杂非白噪声的场合。     

基于GMAW堆焊成形的顺序焊道搭接量模型

焊道搭接量对保证三维堆焊成形过程的顺利进行以及成形件的精度都有较为重要的影响。根据焊接熔滴过渡的物理特性,建立了GMAW堆焊三维成形的顺序焊道搭接量模型,在此基础上计算了平整堆焊层的相邻两道焊道的理论间隔,采用实际焊接试验对理论模型进行了验证,得到的理论间隔为L=2/3W,并进一步计算了平整堆焊层的高度为h=H/1-θ,实际试验得到的结果与理论结果相吻合,从而为焊接成形过程的自动化奠定了基础。     

动初级高速六相直线感应电机工作特性分析

为了准确刻画对象模型,采用一阶等效电路瞬态涡流分析法对动态边端效应影响下动初级高速六相直线感应电机的参数时变规律进行了定量计算,并通过感应涡流损耗推导得到考虑动态边端效应时电机的等效电路。基于此,通过电磁推力计算及效率评估对动态边端效应影响下电机的工作特性进行了详细分析。利用不同运行速度条件下的有限元仿真及动态实验验证了理论分析和推导的正确性。     

Investigation of normal,lateral, and oblique impact of microscale projectiles into unidirectional glass/epoxy composites

Spacesuits and spacecraft must endure high velocity impacts from micrometeoroids. This work considers the impact of 100 μm diameter projectiles into composite targets at velocities from 0.5 km/s to 2 km/s. This work begins by presenting an energy-based theoretical model relating depth of penetration (DoP) and impact force to impact velocity, characteristic time, and threshold velocity and force. Next, this work compares numerical simulations of normal impact on composites to the theoretical model. Numerical simulations are conducted with LS-DYNA and the well-known composite model, MAT-162. The numerical models consider unidirectional S2-glass fiber reinforced SC-15 epoxy composite laminates. The numerical model shows good correlation with the theoretical model. The numerical model also investigates lateral impact, parallel to the fiber direction, and oblique impact at angles from 30° to 82.5°. This work decomposes oblique impact into normal and lateral components, and compares them with normal and lateral impact results. The results show good correlation of the normal component of oblique results with the theoretical model. This numerical and theoretical study focuses on DoP, velocity, and penetration resistance force as functions of time. The theoretical model and numerical simulations are used to determine new DoP parameters: characteristic time of depth of penetration and threshold impact velocity. These models are a first step in developing the capability to predict DoP for oblique, microscale, high-speed impact on composite materials.     

The mechanical performance and a rate-dependent constitutive model for Al3Ti compound

The Al₃Ti compound has potential application in the high temperature structure materials due to its low density, high strength and stiffness. The mechanical behaviors of the material under different loading rates were studied using compression tests. The results indicate that Al₃Ti is a typical brittle material and its compressive strength is dependent on the strain rate. Therefore, a series of rate-dependent constitutive equations are needed to describe its mechanical behaviors accurately. However, it is still short of professional research on the material model for Al₃Ti. In this study, the material model was developed on the basis of JH-2 constitutive equations using the experimental data. The model was then applied in simulating the impact process of Ti/Al₃Ti metal-intermetallic laminate composites so as to validate the established model. Good agreement between simulation and experiment results shows the constitutive model predict the material responses under high rate and large deformation accurately. This work provides more support for the theoretical and numerical research on the intermetallic.     

Establishment,simulation and verification of firepower safety control model

On a narrow warship platform, the coordinated use of shipborne weapon systems may cause firepower conflicts, which seriously endangers the ship safety. Meanwhile, with directed-energy weapons mounted on ships, firepower conflicts between weapons become a “high probability event”. Aiming at the problem of firepower safety control, based on the research about the collision probability model of air crafts and space targets and according to the cone of fire model of conventional weapons and directed-energy weapons, this paper solved the firepower conflict probabilities between conventional weapons as well as between conventional weapons and directed-energy weapons respectively using the methods of probability theory, and established the firepower safety control model. Then the calculation of firepower conflict probability was carried out using the dimensionality reduction method based on the equivalent conversion of polar coordinates and the power series method based on Laplace transform. The simulation results revealed that the proposed model and calculation methods are effective and reliable, which can provide theoretical basis and technical support for resolution of firepower conflicts between weapons.     

不同初速弹丸对靶板的损伤仿真与评估

为了研究弹丸对武器装备的损伤,建立弹丸侵彻多层靶板的有限元模型,对不同初速弹丸侵彻多层靶板进行仿真试验,引入等效应变及等效应力参量以精确描述靶板损伤,提出一种基于多元统计分析对靶板损伤进行评估的方法。结果表明：利用该方法所得到的计算结果与理论分析结果完全一致。这说明基于多元统计分析的靶板损伤评估方法能够正确地评价仿真实验中目标靶板的战损程度,因而可以进一步应用于装备侵彻损伤评估与易损性研究中。     

具有分流型抑制机制的视网膜细胞神经网络模型及其应用

视觉细胞之间存在的侧抑制机制能够对接收到的视觉信息进行选择性的提取。运用数学方法模拟视觉细胞之间存在的这种生理机制,提出了一种具有分流型抑制机制的视网膜细胞神经网络模型(SIRCNN),分析了该模型的稳定性,给出了等价电路图,并且基于此模型提出了一种边缘检测算法。将该算法应用于图像边缘检测中,试验结果表明,这种以生物视觉感知机理为基础的神经计算方法可有效地增强图像反差,检测图像边缘。由于细胞神经网络具有高速并行运算、便于硬件实现等特点,因此这种方法在图像实时处理中也具有很大的潜力和应用前景。