直升机蜂窝夹层结构缺陷验收准则验证技术研究

蜂窝夹层作为一种特殊的复合材料结构,具有比强度、比刚度较高,性能易设计且便于大尺寸整体成型等诸多优点,广泛应用在航空器的结构设计中。但蜂窝夹层结构在制造、使用和维护过程中易出现脱／漏粘、冲击、磕碰等内在缺陷或外来损伤,可能导致结构强度的降低,从而危及结构安全。基于强度理论制定了一种直升机蜂窝夹层结构的静强度、疲劳强度和剩余强度综合验证思路与方法。针对典型结构的构型、缺陷类型和工程可检缺陷参数尺寸,设计了模拟真实蜂窝夹层结构的验证样件和缺陷预制技术,通过强度性能的试验和研究,获得了带有脱／漏粘缺陷、冲击／磕碰损伤等缺陷的结构强度缺陷容限值,为其缺陷验收准则的制定提供了技术依据。     

Numerical investigation of windage heating within shrouded rotor-stator cavity system with central inflow

The rotating disk surface temperature rise due to windage heating effect by numerically modeling the turbulent flow within a rotor-stator cavity which is available with a peripheral shroud and imposed through airflow was dealt with. The windage heating may be defined as viscous friction heating caused by relative velocity differences across the boundary layers between the fluid and the rotating disk surface. The kinetic energy dissipation process could transform the rotating shaft power into thermal heating. Commercial finite volume based solver, ANSYS/CFX was employed to numerically simulate this physical process by using the shear stress transport (SST) turbulence model. CFD results include the rotating disk surface temperature axial distribution and tangential velocity distribution of the fluid domain. The velocity difference between the result obtained by particle image velocimetry (PIV) experiments and CFD simulation are within 5%. The adiabatic disk temperature rise can be calculated by the tangential velocity of disk and fluid in large gap ratio and turbulent parameter. CFD temperature distribution results and those estimated via velocity differences are within 10%.     

Experimental study of partially-cured Z-pins reinforced foam core composites：K-Cor sandwich structures

This paper presents an experimental study of a novel K-Cor sandwich structure rein- forced with partially-cured Z-pins. The influence of pultrusion processing parameters on Z-pins characteristics was studied and the effect of Z-pins on mechanical properties was disclosed. Differential scanning calorimetry （DSC） and optical microscopy （OM） methods were employed to determine the curing degree of as-prepared Z-pins and observe the implanted Z-pins in the K-Cor structure. These partially-cured Z-pins were treated with a stronger bonding link between face sheets and the foam core by means of a hot-press process, thereby decreasing burrs and cracking defects when the Z-pins were implanted into the Rohacell foam core. The results of the out-of-plane tensile tests and the climbing drum peel （CDP） tests showed that K-Cor structures exhibited superior mechanical performance as compared to X-Cor and blank foam core. The observed results of failure modes revealed that an effective bonding link between the foam core and face sheets that was provided from partially-cured Z-pins contributed to the enhanced mechan- ical performances of K-Cor sandwich structures.     

叶栅安装角异常的非定常流场数值模拟

采用商用软件NUMECA对叶栅安装角异常进行二维流场定常和非定常数值模拟,并进行对比分析,得到了因叶栅安装角异常造成通道堵塞对该叶片以及相邻叶栅通道流场结构和非定常气动力的影响.结果表明:安装角异常角度大于0°时,主要对沿吸力面方向叶栅通道流场结构影响较大,随着安装角异常角度的增大,气流不断恶化,出现大面积的附面层分离,尾涡脱落主频率随着安装角异常角度的增大而减小,次频率随着安装角异常角度的增大而增大;并导致叶片非定常气动力相对脉动量迅速增大,这可能是导致叶片疲劳破坏的原因之一.     

A fuzzy PID-controlled SMA actuator for a two-DOF joint

Shape memory alloy(SMA) actuator is a potential advanced component for servosystems of aerospace vehicles and aircraft. This paper presents a joint with two degrees of freedom(DOF) and a mobility range close to ±60 when driven by SMA triple wires. The fuzzy proportional-integral-derivative(PID)-controlled actuator drive was designed using antagonistic SMA triple wires, and the resistance feedback signal made a closed loop. Experiments showed that, with the driving responding frequency increasing, the overstress became harder to be avoided at the position under the maximum friction force. Furthermore, the hysteresis gap between the heating and cooling paths of the strain-to-resistance curve expanded under this condition. A fuzzy logic control was considered as a solution, and the curves of the wires were then modeled by fitting polynomials so that the measured resistance was used directly to determine the control signal. Accurate control was demonstrated through the step response, and the experimental results showed that under the fuzzy PID-control program, the mean absolute error(MAE) of the rotation angle was about 3.147. In addition, the investigation of the external interference to the system proved the controllable maximum output.     

A numerical model for bird strike on sidewall structure of an aircraft nose

In order to examine the potential of using the coupled smooth particles hydrodynamic(SPH) and finite element(FE) method to predict the dynamic responses of aircraft structures in bird strike events, bird-strike tests on the sidewall structure of an aircraft nose are carried out and numerically simulated. The bird is modeled with SPH and described by the Murnaghan equation of state, while the structure is modeled with finite elements. A coupled SPH–FE method is developed to simulate the bird-strike tests and a numerical model is established using a commercial software PAM-CRASH. The bird model shows no signs of instability and correctly modeled the break-up of the bird into particles. Finally the dynamic response such as strains in the skin is simulated and compared with test results, and the simulated deformation and fracture process of the sidewall structure is compared with images recorded by a high speed camera. Good agreement between the simulation results and test data indicates that the coupled SPH–FE method can provide a very powerful tool in predicting the dynamic responses of aircraft structures in events of bird strike.     

锂离子电池新型三维纳米结构负极研究进展

高性能锂离子电池在微/小型侦察机和空间飞行器等应用中有重要意义。构建三维纳米结构负极,是提高锂离子电池性能的有效方法。综述了国内外锂离子电池新型三维纳米结构负极材料的发展,将其分为3种类型,分别是三维纳米多孔结构、三维纳米阵列结构和三维纳米网络结构。涉及的材料包括碳类材料、合金类材料与过渡金属氧化物材料。相对于传统二维平面负极,三维纳米结构电极可以减小离子迁移距离、增加电极/电解液界面面积、缓冲活性材料充放电体积变化,从而可以提高材料的储能容量,提高电极的循环稳定性,改善电极的倍率性能。     

电-热耦合对航空复合材料拉伸及疲劳性能的影响

为研究碳纤维增强树脂基复合材料(CFRP)层合板的导电性能和电-热耦合效应及其对拉伸和疲劳性能的影响,主要针对2种不同铺层的试件(单向层合板(UD)[0]8和准各向异性层合板(QI)[45/90/-45/0]s)进行导电及电-热耦合实验和通电状态下的拉伸及疲劳实验。在电-热耦合实验中分别对试件通以1~8A的直流电和交流电,测量其温度场的分布及最高温度,以确定温度对电阻的影响。依据实验现象建立了简化后的电-热耦合分析模型,并与实验结果进行对比,发现两者吻合很好。简化后的电-热耦合模型能够很好地预测试件在达到稳态平衡时的最高温度值。在通电情况下对不同初始状态时的QI试件进行拉伸和疲劳实验,通过实验发现,在疲劳加载过程中无论是通以直流电、交流电或者是改变电流强度和电流频率,对试件的疲劳寿命影响不大,没有发现明显差异,但在实验过程中试件表面的温度会随着电流强度的增加而升高。同时,在监测试件沿着纤维方向的电阻变化时发现,在一定的疲劳载荷下,随着循环次数的增加,试件的电阻会不断增加,这表明试件内部出现了损伤,累积后直至试件断裂。依据实验现象分别建立了电阻模型-1和电阻模型-2,分析计算后发现模型-1能够较好地模拟试件变形的线性阶段(εxx≤0.4%),而模型-2能较好地模拟非线性阶段直至试件断裂(εxx0.4%)。     

基于可靠性优化的芯片自愈型硬件细胞阵列布局方法

以提高可靠性为目标,研究芯片自愈型硬件细胞阵列布局的新结构和新方法。针对传统可靠性模型无法体现细胞内部模块随布局结构动态变化的不足,通过细胞单元电路资源消耗分析,面向二维阵列结构进行了新的可靠性建模。根据新模型,在分析布局结构参数对可靠性影响程度的基础上,提出了一种先分块再分层的细胞布局新结构。用实例验证了新布局结构对可靠性提高的有效性,给出了不同设计任务和细胞电路设计方法情况下确定最佳布局方式的计算方法,并总结出了新布局结构中分块、分层参数选择规律,最终论证了最佳布局方式计算方法和参数选择规律的一般适用性。     

航空发动机高压转子的结构动力学设计方法

建立了航空发动机高压转子的动力学模型,该模型包含所有的结构动力学设计参数,揭示了设计参数与转子振动特性间的关系,提出了转子临界转速界值的估计方法,并予以理论证明.建立了分别基于两阶临界响应的支承刚度设计准则.发现了转子参数临界转速现象,在参数临界转速处,阻尼器将失去阻尼作用,振动趋于无穷大;给出了参数临界转速出现的条件,上述的结论对于航空发动机高压转子的设计具有重要的指导意义.