一种不精确推理模型与模糊关系代数

提出一种不精确推理的模型以及模糊关系代数,定义了模糊集合的并、交、差和笛卡尔积等运算,从而对非精确数据及知识描述中不确定性进行有效地处理。     

基于强度折减法的海底隧道强震破坏机理

将强度折减法引入强震作用下的海底隧道衬砌结构安全稳定性研究,利用FLAC3D软件建立了海底隧道-岩土体-海水相互作用的强度折减法数值模型,综合考虑海底隧道衬砌在强震作用下的位移、剪应变增量和塑性区变化,确定了海底隧道衬砌局部破坏的极限平衡状态和整体破坏的极限平衡状态,分析了海底隧道衬砌在强震作用下的破坏机理。结果表明:海底隧道衬砌在水平地震波的作用下,主要是围岩变形导致隧道衬砌破坏;隧道衬砌破坏位置发生在右侧侧墙中部,破坏形式为剪切破坏;隧道衬砌局部破坏的极限安全系数为1.47,整体破坏的极限安全系数为1.8,2种安全系数的极限状态可对应结构设计中的正常使用极限状态和承载力极限状态。研究成果可为海底隧道衬砌设计提供理论依据。     

陆军航空兵直升机编制分形结构的验证与分析

从陆航直升机编制和陆航体系作战的实际需求出发,利用分形理论的信息维数定义,提出了定量验证陆航直升机编制分形结构的基本方法。以两个历史时期的美军陆航部队编制为例,建立了各型直升机分布的δ-覆盖,并分别测定了相应的信息维数,对比分析了两个历史时期美军陆航旅直升机编制的优劣。结果表明,利用信息维数可以定量说明陆航直升机编制的合理程度。     

面向蛋白质功能预测中有向无环图标记结构的多示例多标记学习

在多示例多标记学习问题中,标记之间往往是相互关联的,其中有向无环图结构是一种常见的层次关联结构,可见于蛋白质的基因本体学生物学功能预测的应用场景中。针对其标记间的有向无环图结构,提出了一种新的多示例多标记学习算法。算法从原始数据的特征空间训练出所有标记共享的低维子空间,通过随机梯度下降方法来降低模型排序损失,并融入标记间有向无环图结构关系对预测标记进行优化。将该算法应用于多个数据集的蛋白质功能预测中,实验结果表明,该算法具有更高的效率及预测性能。     

强磁场环境模拟系统线圈支架设计及力学仿真

强电磁冲击环境的核心执行机构是线圈,除保障强磁环境发生线圈的电磁特性外,还须确保线圈支架具有充足的机械特性。在完成对线圈磁电设计的基础上,根据线圈的三维结构图、材料配置、质量分布、各零部件之间连接方式以及线圈固定方式等,建立线圈支架结构整体系统有限元计算模型,对线圈支架系统进行静力、稳定性数值计算分析,并校核联接件强度,为线圈支架结构提供参考依据。对实用大型强磁冲击系统所用线圈整体的力学结构进行设计分析,应用背景较新,且仿真计算过程严格按照实际搭建尺寸进行,具有高度的一致性,为后续搭建强磁环境发生装置提供坚实基础。     

不同裂解温度对制备SiCf/Si-O-C复合材料性能研究

以聚硅氧烷为先驱体,研究先驱体转化过程中在不同的裂解温度下对制备SiCf/Si-O-C复合材料性能影响.结果表明,当裂解温度在700℃、800℃时,陶瓷基复合材料的弯曲强度分别为255.2 MPa、309.0 MPa;当裂解温度在1000℃时,陶瓷基复合材料的弯曲强度为45.3 MPa.对SiCf/Si-O-C复合材料的微观结构及载荷-位移曲线进行分析,发现界面结构是影响SiCf/Si-O-C复合材料性能的主要因素.     

SiCw/Al复合材料的强度分析

用简化应力的分析方法推导了SiCw Al复合材料的强度与SiC晶须偏轴角α的关系,并通过试验进行验证.结果表明,计算的SiCw Al复合材料强度与实测值比较接近,其误差归因于压缩变形过程中SiC晶须发生了转动和折断,改变了SiC晶须的偏轴角和平均长径比.     

水下爆炸载荷作用下受损加肋圆柱壳的剩余屈曲强度计算

研究了在水下爆炸载荷作用下受损的加肋圆柱壳的屈曲.结合DYTRAN软件和NASTRAN软件计算了水下爆炸载荷作用下受损的加肋圆柱壳的剩余屈曲强度,并且提出了一种结合上述两种软件计算加肋圆柱壳的剩余屈曲强度的方法.数值计算表明,预测结果与实验结果吻合较好.     

The effect of al particle size on thermal decomposition,mechanical strength and sensitivity of Al/ZrH2/PTFE composite

To study the thermal decomposition of Al/ZrH2/PTFE with different Al particle size as well as mechanical strength and impact sensitivity under medium and low strain rates, molding-vacuum sintering was adopted to prepare four groups of power materials and cylindrical specimens with different Al particle size. The active decomposition temperature of ZrH2 was obtained by TG-DSC, and the quasi-static me-chanics/reaction characteristics as well as the impact sensitivity of the specimen were studied respec-tively by quasi-static compression and drop-hammer test. The results show that the yield strength of the material decreased with the increase of the Al particle size, while the compressive strength, failure strain and toughness increased first and then decreased, which reached the maximum values of 116.61 MPa, 191％, and 119.9 MJ/m respectively when the Al particle size is 12—14μm because of particle size grading. The specimens with the highest strength and toughness formed circumferential open cracks and reacted partly when pressed. Those with developmental cracks formed inside did not react. It is considered that fracture of specimens first triggered initial reaction between Al and PTFE to release an amount of heat. Then ZrH2 was activated and decomposed, and participated in subsequent reaction to generate ZrC. The impact sensitivity of the specimens decreased with the increase of Al particle size.     

Effect of transverse compression on the residual tensile strength of ultrahigh molecular weight polyethylene (Dyneema® SK-76) yarns

Ballistic impact induces complex stress states on fiber-based armor systems. During impact fibers undergo multiaxial loading which includes axial tension, axial compression, transverse compression, and transverse shear. Transverse compression induced by the projectile leads to permanent deformation and fibrillation of fibers resulting in degradation of material tensile strength. Previous work (Sockalingam et al. Textile Res. J 2018) has shown a reduction of 20% in the tensile strength of Dyneema® SK76 single fibers subjected to 77% nominal transverse compressive strains. Experimental investigation of quasi-static transverse compression on Dyneema® SK-76 yarns, unconstrained in the lateral direction, indicate an average of 4% reduction in tensile strength of yarns compressed to 77% nominal strains. In this work we use finite element modeling techniques to understand the difference in residual tensile strength between single fibers and yarns observed in laterally unconstrained transverse compression experiments. Finite element study of the transverse compression response of single fibers and yarns indicate that local strains developed in fibers within the yarn are much lower than the local strains developed in single fibers subjected to a given nominal strain and may explain the less reduction in strength observed in yarns.