在时代“大考”中建设人民满意海事——广西海事战“疫”纪实

新冠肺炎疫情发生以来,广西海事局始终把人民群众生命安全和身体健康放在第一位,统筹做好疫情防控与水上交通安全监管。为船员和辖区企业送上贴心服务,在保畅通、保企业复工复产中有为有位;把战斗堡垒筑在疫情防控最前沿,给人民群众带来最安心的守护;在农村疫情防控工作中贡献海事力量,增强村民和全体干部职工的幸福感与归属感,为建设人民满意海事增添了精彩一笔!     

Labview应用程序开发中使用支持文件相对路径的有关问题

用Labview开发涉及支持文件读写的应用程序时,常会出现调试正常而可执行文件运行时找不到支持文件路径的错误。基于一简单示例,分析了产生此问题的原因并提供了解决问题的思路。     

载货汽车主气瓶不同气压时制动性能分析

汽车综合性能测试仪VGQT测试分析结果表明,货车在主制动气瓶压力不同时,各轴制动气室所能达到的最大压力也不相同[1],除此之外,本试验中N类载货汽车0型制动试验表明,主气瓶气压不同时,各轴气室制动压力变化曲线以及有效最大减速度MFDD也不相同。载货汽车绝大部分是用于长途运输,尤其是N2、N3类载货汽车,由于其满载质量大,长途运输中制动效能对于行驶安全性有着很大的影响,尤其在我国西南部山道纵横,长时间上下坡很容易造成制动器的热衰退,这是引起交通事故的主要诱因之一[2,3]。本文以实际试验结果为研究对象,分析了主气瓶在不同压力下各轴制动气室压力的变化以及0型制动试验中制动气压曲线的变化和有效最大减速度的变化,这对于行驶安全性和燃油经济性都有一定的意义,进而对排放和环境造成影响。     

不锈钢车体钝化工艺研究

针对轨道交通车辆在制造过程中,不锈钢车体表面的钝化膜因机加工、焊接等因素可能遭到破坏,导致不锈钢车体防腐能力下降的情况,详细介绍了不锈钢车体的钝化原理、钝化工艺及钝化效果的检测方法。经过柠檬酸钝化液钝化处理后,可有效去除车体表面游离铁和其他杂质,车体表面颜色均匀一致,提高了不锈钢车体的耐蚀性和美观性。     

Personalization method of e-catalog based on user interesting degree

The user interesting degree evaluation index is designed to fulfill the users’ real needs, which includes the user’ attention degree of commodity, hot commodity and preferential commodity. User interesting degree model (UIDM) is constructed to justify the value of user interesting degree; the personalization approach is presented; operations of add and delete nodes (branches) are covered in this paper. The improved e-catalog is more satisfied to users’ needs and wants than the former e-catalog which stands for enterprises, and the improved one can complete the recommendation of related products of enterprises.     

两种跨平台航迹精度测评方法研究

跨平台航迹精度测评对多平台协同使用传感器航迹数据具有指导意义,论文介绍了相对于本平台距离/方位的测评方法(方法一)和空间距离精度的测评方法(方法二),从非线性坐标变换的角度分析了本平台位置对测评结果的影响,其中方法一的计算结果在两平台位置相差不大的情况下主要受被探测目标相对于这两个平台的方位角度差影响,方法二的计算结果则不受本平台位置的影响,因而后者更有意义。     

Simulation of mixed gas formation for a spray-wall complex guided LPG direct injection engine

To obtain an ultralean air-fuel ratio and to reduce engine-out NOX and HC emissions induced by the richer mixture near the spark plug, a spray and wall complex guided combustion system has been developed by utilizing the fuel characteristics of LPG. The new combustion system configuration is optimized by using a commercial CFD code, FIRE V2013, and the reliability of the system has been experimentally demonstrated by Plane Laser-Induced Fluorescence (PLIF). The mixture formation in the new combustion system under part load (2,000 rpm) is numerically simulated. With an injection timing of 40°CA BTDC, the LPG spray which is injected from two upper holes, reaches the ignition point, and the other part of the LPG spray which is injected from the bottom hole, is directed to the ignition point through the vertical vortices at the same time. At the ignition timing of about 20°CA BTDC, the two-part mixtures have been shown to form a stable and richer stratified mixture around the ignition point, and the maximum global air-fuel ratio reaches to 60: 1.     

Occupant injury risk analysis at NASS/CDS database

Injury information for vehicle occupants from the body regions of the head, thorax, abdomen, and upper and lower extremities, due to the restraints and interior parts of the vehicle, were extracted from the 2009 ~ 2012 NASS/CDS database. For those cases with high occurrence frequency, a detailed and comprehensive data analysis was performed to find the relationship between the accident, occupant, vehicle, and injury data. A numerical frontal impact sled model with the Hybrid III dummy and the GHBMC human body model was constructed to simulate and identify those injury risks according to NASS/CDS. Among the 5,734 injuries to the aforementioned body regions from frontal crashes are, listed by frequency of occurrence, the lower extremity (27.8 %), upper extremity (21.3 %), thorax (15.1 %), face (10.9 %), spine (8.7 %), head (7.3 %), and abdomen (6.9 %). The main injury sources to the head were the windshield, side structure, and steering wheel. For the thorax and abdomen they were the seat belt and steering wheel. For the lower extremity it was the instrument panel. The main injury patterns for the head were the concussion and the contusion. For the thorax they were vessel laceration and lung contusion. For the abdomen they were laceration and contusion of the organs. For the lower extremity they were bone fracture and ligament rupture. The steering wheel and seat positions were main factors affecting head and thorax injury risks. From the sled impact simulation, high injury risks of the head and thorax were assessed respectively at conditions of steering column tilt down and rear most seat position, which correlated well with the findings from the NASS/CDS data analysis.     

Integrated approach to an optimal automotive timing chain system design

Ensuring engine efficiency is a crucial issue for automotive manufacturers. Several manufacturers focus on reducing the time taken to develop and introduce brand new vehicles to the market. Thus, a synergic approach including various simulations is generally adopted to achieve a development schedule and to reduce the cost of physical tests. This study involved proposing a design process that is very useful in the preliminary development stage through effective support from simulations. This type of simulation-based design process is effective in developing timing chain drives; the use of this process, based on results from multiple trials, showed improvements in performance including low friction and vibration, improved durability, and cost-effective part design when compared to conventional processes. This study proposes an integrated approach to the preliminary design of an automotive timing chain system. The approach involves structural and dynamic analyses. The details of the design process are described by using the case of a virtual engine. This study conducted and summarized a dynamic and structural analysis as well as topological optimization to describe a process to obtain optimal results. The results of this study indicated the following improvements in overall performance factors: 12.1 % improvement in transmission error, 10.1 % reduction in chain tension, 46 % reduction in tensioner arm weight, and 11 % reduction in transversal displacement.     

A new model for temporal–spatial stochastic analysis of vehicle–track coupled systems

The vehicle–track coupled system has a random nature in the time–space domain. This paper proposes a computational model to analyse the temporal–spatial stochastic vibrations of vehicle–track systems, where the vehicle–track system is divided into a vehicle subsystem, track subsystem, and interfacial subsystem between the wheel and rail. In this model, the time-varying randomicity of dynamical parameters of the vehicle system, correlation, and randomness of the track structural parameters in the time–space joint dimensions, and randomness of the track random irregularities are considered. A probability dimension-reduction method was used to randomly combine different random variables. Furthermore, the probability density evolution method was applied to solve the delivery problem of probabilities between excitation inputs and response outputs. The temporal–spatial stochastic vibrations of the vehicle–track system with different coefficients of variation were studied, in which we assumed that the dynamic parameters obeyed the normal distribution, and the stochastic simulation method of the track random irregularities is probed into. The calculated results from this model are consistent with the actual measured results and physical conceptions. Thus, the temporal–spatial stochastic evolutionary mechanism can be explored, and the limits of dynamic indices can be formulated by using this developed model.