国Ⅳ之后柴油机三种燃油喷射系统对比及其技术发展趋势

系统地介绍了电控泵喷嘴系统、电控单体泵系统、电控共轨系统的结构及牛寺｜点。阐述了电控燃油喷射系统的技术发展趋势。     

浅析汽车维修新技术中发动机故障检测及维修技术

随着我国社会发展进步,汽车已经成为人民生活中不可或缺的一部分,而汽车运行过程中难免会发生故障,其中发动机故障的影响尤为严重。从简述汽车维修新技术的重要作用入手,进一步分析汽车发动机故障的检测方法,探究汽车维修新技术在发动机异响、发动机油样、发动机启停及发动机冷却系统故障检测和维修的途径。     

Turbocharging the DA465 gasoline engine

In order to improve performance of the DA465Q gasoline engine, a substantial amount of research was done to optimize its turbocharging system. The research led to the GT12 turbocharger being selected and its turbocharging parameters being settled. Based on these tests, rational matching was worked out for respective components of the turbocharging system. Results show that this turbocharger allows the engine to easily meet the proposed requirements for power and economic performance, giving insight into further performance improvements for gasoline engines.     

电控气缸注油器注油调频控制机理分析

为实现电控气缸注油器的注油调频控制,探究其注油调频的计算方法,提出注油调频的通用计算公式,分析该计算公式在研发电控气缸注油器注油调频机理上的适用方法。     

低速柴油机增压器爆炸的原因分析和预防

船舶柴油机增压器管理是轮机管理的重要一环,如何保持柴油机增压器良好工作状态,避免故障产生是每个轮机员必须考虑的问题.文章从系统的角度对某型增压器运行产生的爆炸故障进行分析,并结合实际提出避免故障的日常管理要求.     

舰用柴油机预混合等压燃烧的数值模拟及试验研究

运用CFD软件Star-cd对一台舰用高速大功率柴油机实现预混合近似等压燃烧进行了缸内喷雾及燃烧过程的模拟计算,主要考察了不同压缩比的燃烧室型线,以及喷油器喷孔参数对柴油机性能、缸内温度场、速度场和NO排放的分布的影响.经过多方案的计算分析,确定了高速大功率柴油机实现预混合近似等压燃烧的压缩比和喷孔参数,并能在提高柴油机性能的同时降低排放.通过对最优方案的台架试验,在直喷式柴油机上实现了预混合等压燃烧要求的放热率.     

柴油机曲轴速度变化的频谱分析

使用光电转速传感器,通过计算其感应器内部时钟的脉冲测量曲轴的速度变化,分析低谐波转速变化能过滤出由曲轴的动力响应产生的失真,根据这些谐波携带的信息建立起测量数据和发动机平均气压转矩之间的关系,从而发现故障并且确定不良的气缸.     

发动机带传动中皮带寿命提高方法研究

设计一种新型的通用皮带预紧力测量装置，通过分析发动机皮带传动中的横向振动，提出带轮结构布置原则。实验证明，根据该原则进行皮带轮结构布置并设定准确的皮带预紧力，可减小传动打滑现象，有效提高皮带的使用寿命及皮带传动效率.     

缩比动力室用锆无氧铜材料的成型工艺研究

发动机动力室采用高温合金与高传导材料混合结构是延长其使用寿命的有效途径，但恶劣工作条件对铜合金传导材料的质量与性能提出了苛刻要求．文中介绍了缩比动力室用锆无氧铜合金材料的成分设计及棒材制备方法，并利用工艺性能实验、微观组织分析及数值模拟等手段，确定了锆无氧铜材料的最佳成型工艺及热加工数学模型，为不同规格锆无氧铜材料的产品开发提供了设计依据．     

An investigation of the performance of an electronic in-line pump system for diesel engines

WIT Electronic Fuel System Co., Ltd. has developed a new fuel injector, the Electronic In-line Pump （EIP） system, designed to meet China＇s diesel engine emission and fuel economy regulations. It can be used on marine diesel engines and commercial vehicle engines through different EIP systems. A numerical model of the EIP system was built in the AMESim environment for the purpose of creating a design tool for engine application and system optimization. The model was used to predict key injection characteristics under different operating conditions, such as injection pressure, injection rate, and injection duration. To validate these predictions, experimental tests were conducted under the conditions that were modeled. The results were quite encouraging and in agreement with model predictions. Additional experiments were conducted to study the injection characteristics of the EIP system. These results show that injection pressure and injection quantity are insensitive to injection timing variations, this is due to the design of the constant velocity cam profile. Finally, injection quantity and pressure vs. pulse width at different cam speeds are presented, an important injection characteristic for EIP system calibration.