对车体连接部噪声侵入部位采取降噪对策后效果的验证方法

介绍了降低车辆连接部噪声的试验方案,阐述了定置试验方法以及采取降噪对策后效果的验证、确认。     

“全列车进路发码车站”站内低频信息编码设计的总结

介绍客运专线项目的施工图设计过程中,关于"全列车进路发码车站"低频信息编码设计的经验总结。     

职业卫生监测中应用个体噪声剂量计异常值处置方法的研究

针对职业卫生噪声个体监测过程中异常导致的数据无法使用的问题,本文以某大型装置巡检工个体噪声监测中出现的异常情况为例,探讨数据调整方法。研究发现删除异常值或使用平均值替代两种方法,数据调整后与实际情况吻合度较好,两种方法均能满足个体声级计监测实践要求。     

城市轨道交通高架结构噪声研究的进展

回顾了十多年来城市轨道交通高架结构噪声领域的研究状况。总结了结构噪声的频率特性、噪声和列车速度的关系、桥梁局部模态和整体模态对结构噪声的影响;比较了箱型梁和槽型梁的声压级指标。简要介绍了结构噪声的计算方法,同时指出了每种方法的不足;从减隔振、限制振动传播和能量衰减方面总结了相应的降噪措施,并重点介绍了减隔振降噪措施。最后,指出了该领域可进一步研究的问题。     

高速铁路营业线新建车站施工安全技术研究

武广英德西站是我国第一个高铁营业线的新建车站工程,安全风险大、施工难度高。详细介绍了英德西站施工中有关安全方面的一些技术措施和安全管理经验,以供类似工程参考。     

国内外经验对北京新机场线规划的启示

在研究总结国内外机场线运营模式及机场航站楼轨道交通车站特点的情况下,结合北京市新机场的选址和规模,提出北京市新机场线的运营模式和车站布置。在总结国际先进机场系统车站分布特征的基础上,阐述对北京新机场线的车站分布要求,最后提出结论和建议。     

地铁减振存在的问题分析与建议

从梳理现阶段地铁减振的程序和规范要求及通常做法入手,讨论地铁减振过度或不当所存在的问题,系统分析规范标准、基础理论和方法、管理等方面的原因,提出相应的改进建议,包括开展相关基础理论研究、完善方法标准体系、加大环保及环评在地铁项目实施中的介入深度、实施项目全过程分阶段环评、逐步建立环保(减振降噪)管理专项制度等。     

新线开通对线网客流特征的影响

随着北京市轨道交通的快速发展,每年的新线开通都将对线网各线的客流分布产生较大的影响,但新线可研多注重新线自身的预测,缺乏线网整体变化的预测分析.结合线网客流变化的关键因素,探索利用新线可研和现有OD数据预测新线开通后线网客流的方法,并以北京地铁4号线开通为例进行验证,从一定程度上证明该方法的可行性和适用性.     

不同动力电池新能源货运配送车辆节能减排绩效评价研究

为研究新能源货运车辆装配不同动力电池对节能减排的影响,选取某款新能源货运配送车辆为研究对象,利用GaBi软件建立了3种常用动力电池的整车生命周期评价模型,从原材料获取、生产制造、装配、运行使用、报废回收5个阶段进行节能减排差异分析,并对全球变暖潜值 （Global Warming Potential,GWP） 等环境影响类型进行归一化处理和量化计算处理。结果表明,分别装配3种电池整车的化石能源消耗以煤炭为主、环境排放以CO2为主;纯电动汽车的能源消耗、污染物排放集中在运行使用阶段;综合比较,装配了三元锂电池的整车,其全生命周期节能减排效果最佳,装配了锰酸锂电池的整车则表现最差。加大清洁能源的使用力度、减少用于电力生产的化石能源消耗、提高回收率等措施,可以显著减少污染物排放。     

Surf-riding and oscillations of a ship in quartering waves

The behavior of a ship encountering large regular waves from astern at low frequency is the object of investigation, with a parallel study of surf-riding and periodic motion paterns. First, the theoretical analysis of surf-riding is extended from purely following to quartering seas. Steady-state continuation is used to identify all possible surf-riding states for one wavelength. Examination of stability indicates the existence of stable and unstable states and predicts a new type of oscillatory surf-riding. Global analysis is also applied to determine the areas of state space which lead to surf-riding for a given ship and wave conditions. In the case of overtaking waves, the large rudder-yaw-surge oscillations of the vessel are examined, showing the mechanism and conditions responsible for loss of controllability at certain vessel headings.List of symbols c wave celerity (m/s) - C(p) roll damping moment (Ntm) - g acceleration of gravity (m/s²) - GM metacentric height (m) - H wave height (m) - I _x ,I _z roll and yaw ship moments of inertia (kg m²) - k wave number (m^–1) - K _H ,K _W ,K _R hull reaction, wave, rudder, and propeller - K _p forces in the roll direction (Ntm) - m ship mass (kg) - n propeller rate of rotation (rpm) - N _H ,N _W ,N _R hull reaction, wave, rudder, and propeller - N _P moments in the yaw direction (Ntm) - p roll angular velocity (rad/s) - r rate-of-turn (rad/s) - R(,x) restoring moment (Ntm) - Res(u) ship resistance (Nt) - t time (s) - u surge velocity (m/s) - U vessel speed (m/s) - v sway velocity (m/s) - W ship weight (Nt) - x longitudinal position of the ship measured from the wave system (m) - x _G ,z _G longitudinal and vertical center of gravity (m) - x _S longitudinal position of a ship section (S), in the ship-fixed system (m) - X _H ,X _W ,X _R hull reaction, wave, rudder, and propeller - X _P forces in the surge direction (Nt) - y transverse position of the ship, measured from the wave system (m) - Y _H ,Y _W ,Y _R hull reaction, wave, rudder, and propeller - Y _p forces in the sway direction (Nt) - z _Y vertical position of the point of action of the lateral reaction force during turn (m) - z _W vertical position of the point of action of the lateral wave force (m) Greek symbols angle of drift (rad) - rudder angle (rad) - wavelength (m) - position of the ship in the earth-fixed system (m) - water density (kg/m³) - angle of heel (rad) - heading angle (rad) - _e frequency of encounter (rad/s) Hydrodynamic coefficients K roll added mass - N _v ,N _r yaw acceleration coefficients - N _v N _r N _rr N _rrv ,N _vvr yaw velocity coefficients K. Spyrou: Ship behavior in quartering waves - X _u surge acceleration coefficient - X _u X _vr surge velocity coefficients - Y _v ,Y _r sway acceleration coefficients - Y _v ,Y _r ,Y _vv ,Y _rr ,Y _vr sway velocity coefficients European Union-nominated Fellow of the Science and Technology Agency of Japan, Visiting Researcher, National Research Institute of Fisheries Engineering of Japan