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论文:2021,Vol:39,Issue(4):883-890 |
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引用本文: |
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杨昆, 周磊, 王刚, 聂涛, 吴昕. 超高压共轨系统性能试验研究[J]. 西北工业大学学报 |
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YANG Kun, ZHOU Lei, WANG Gang, NIE Tao, WU Xin. Experimental study on the performance of ultra high pressure common rail system[J]. Northwestern polytechnical university |
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| 超高压共轨系统性能试验研究 |
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| 杨昆, 周磊, 王刚, 聂涛, 吴昕 |
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| 海军工程大学 动力工程学院, 湖北 武汉 430033 |
| 摘要: |
| 为克服高压源设计和喷油器内零部件难于集成的困难,实现超高压力喷射和可控喷油速率喷射,立足国内基础材料及加工制造工艺水平,提出并设计了超高压共轨系统。介绍了系统的工作原理,搭建了超高压共轨系统性能测试台架,定量分析了增压装置结构参数对增压峰值的影响,选取最佳参数组合开展了压力特性和喷油速率控制特性试验。结果表明:超高压共轨系统能够将燃油压力放大至超高压状态(大于200 MPa),并且通过改变增压装置和喷油器各自电磁阀的控制信号时序,能够实现灵活可控的喷油速率。在相同的增压比条件下,随着进油节流孔直径的增加,增压峰值逐渐增大,并且随着增压比的增大,增压峰值呈现非线性的增加趋势。同时,在相同弹簧预紧力的情况下,弹簧刚度越大,可承受的轨腔基压越高,这就意味着增压装置可在更高的基压下实现增压。但弹簧刚度过大会导致增压装置电磁阀电磁力不足无法打开,具体选择时应当折中考虑。 |
| 关键词:
可控喷油速率
超高压共轨系统
性能
试验研究
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| Experimental study on the performance of ultra high pressure common rail system |
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| YANG Kun, ZHOU Lei, WANG Gang, NIE Tao, WU Xin |
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| College of Power Engineering, Naval University of Engineering, Wuhan 430033, China |
| Abstract: |
| In order to overcome the difficulties of high pressure source design and parts integration in the injector, realizing the ultra high pressure injection and controllable fuel injection rate, an ultra high pressure common rail system based on domestic basic materials and manufacturing technology level was proposed and designed. The working principle of this system was first introduced; the performance test bench of ultra high pressure common rail system was built. Then, the influence of pressure-amplifier device structure parameters on the pressurization pressure peak was analyzed quantitatively, and on the basis of selecting the most appropriate combination of parameters, the pressure and fuel injection rate control characteristics were conducted. The results show that ultra high pressure common rail system can magnify fuel pressure to ultra high pressure state (more than 200 MPa) and by changing the control signal timing of pressure-amplifier device and injector solenoid valve, the flexible and controllable fuel injection rate can be achieved. Under the condition of the same pressurization ratio, the peak value of pressurization pressure increases gradually, and with the increase of pressurization ratio, the increasing trend of the pressurization pressure peak value is nonlinear. At the same time, under the same condition of spring preload, the greater of the spring stiffness, the higher of the rail base pressure can bear, that means the pressure-amplifier device can achieve pressurization at a higher base pressure. But if the spring stiffness is too large, the solenoid valve of pressure-amplifier device will not be opened due to insufficient electromagnetic force, so the specific selection should be considered in a compromise. |
| Key words:
controllable fuel injection rate
ultra high pressure common rail system
performance
test study
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| 收稿日期: 2020-12-22
修回日期:
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| DOI: 10.1051/jnwpu/20213940883 |
| 基金项目: 国家自然科学基金(51379212)与海军工程大学自主立项基金(425317S022,425317S023)资助 |
| 通讯作者: 周磊(1991-),海军工程大学讲师,主要从事柴油机高压共轨技术研究。e-mail:15345811275@163.com
Email:15345811275@163.com |
| 作者简介: 杨昆(1981-),海军工程大学副教授,主要从事柴油机高压共轨技术研究。
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| 作者相关文章 |
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| 杨昆 在本刊中的所有文章 |
| 周磊 在本刊中的所有文章 |
| 王刚 在本刊中的所有文章 |
| 聂涛 在本刊中的所有文章 |
| 吴昕 在本刊中的所有文章 |
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参考文献: |
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[1] 唐开元, 欧阳光耀. 高等内燃机学[M]. 北京:国防工业出版社, 2008 TANG Kaiyuan, OUYANG Guangyao. Advanced internal combustion engine science[M]. Beijing:National Defense Industry Press, 2008(in Chinese)
[2] RYU Y, LEE Y, NAN J. Performance and emission characteristics of additives-enhanced heavy fuel oil in large two-stroke marine diesel engine[J]. Fuel, 2016, 182:850-856
[3] 侯玉晶, 林学东, 李德刚. 高压喷射对直喷柴油机喷雾及燃烧特性影响规律的仿真研究[J]. 内燃机工程, 2016, 37(4):1-7 HOU Yujing, LIN Xuedong, LI Degang. Simulation reasarch on the effect of high pressure injection on the spray and combustion characteristics of DI diesel engine[J]. Chinese Internal Combustion Engine Engineering, 2016, 37(4):1-7(in Chinese)
[4] MENDEZ S, THIROUARD B. Using multiple injection strategies in diesel combustion:potential to improve emissions, noise and fuel economy trade-off in low CR engines[J]. Sae International Journal of Fuels & Lubricants, 2008, 1(1):662-674
[5] 贾和坤, 刘胜吉, 尹必峰, 等. EGR对轻型柴油机缸内燃烧及排放性能影响的可视化[J]. 农业工程学报, 2012, 28(5):44-49 JIA Hekun, LIU Shengji, YIN Bifeng, et al. Visu alization of influence of ERG on combustion process and emission performance for light-duty diesel engine[J]. Trans of the Chinese Society of Agricultural Engineering, 2012, 28(5):44-49(in Chinese)
[6] 常远, 欧阳光耀, 杨昆. 超高压共轨系统燃油喷射控制[J]. 海军工程大学学报, 2015, 27(5):39-43 CHANG Yuan, OUYANG Guangyao, YANG Kun. Fuel injection control of ultra high pressure common rail system[J]. Naval Journal of University of Engineering, 2015, 27(5):39-43(in Chinese)
[7] JOONSIK H, DONGHUI Q, YONGJIN J, et al. Effect of injection parameters on the combustion and emission characteristics in a common-rail direct injection diesel engine fueled with waste cooking oil biodiesel[J]. Renewable Energy, 2014, 63:9-17
[8] 周磊, 杨昆, 安士杰, 等. 喷油速率匹配喷油提前角对超高压共轨柴油机性能影响的仿真研究[J]. 西北工业大学学报, 2019, 37(2):417-423 ZHOU Lei, YANG Kun, AN Shijie, et al. Simulation of the effect of fuel injection rate that matches fuel injection advanced angle on the performance of ultra high pressure common rail diesel engine[J]. Journal of Northwestern Polytechnical University, 2019, 37(2):417-423(in Chinese)
[9] 孙田, 苏万华, 郭红松. 应用激光诱导荧光法研究超高压喷雾气液相浓度场分布特性[J]. 内燃机学报, 2007, 25(2):97-104 SUN Tian, SU Wanhua, GUO Hongsong. Study of concentration distribution of liquid and vapor-phase of diesel spray injected at ultra-high injection pressure by planar laser induced exciplex fluorescence technique[J]. Trans of CSICE, 2007, 25(2):97-104(in Chinese)
[10] 姚春德. 货车用柴油机超高喷射压力泵喷嘴的试验研究[J]. 汽车工程, 1999, 24(4):226-231 YAO Chunde. An investigation into the unit injector with ultra-high injection pressure for heavy duty truck diesel engine[J]. Automotive Engineering, 1999, 24(4):226-231(in Chinese)
[11] NISHIDA K, MANABE T, ZHANG W. 4819 Effect of micro-hole and high-pressure on mixture properties of D.I. diesel spray[C]//The Proceedings of the JSME Annual Meeting, 2006
[12] LEINHARD R, PARCHE M, ALVARE C, et al. Pressure-amplified common rail system for commercial vehicles[J]. MTZ, 2009, 70(5):10-15
[13] GERHARD Z. Euro 4 and beyond-role of diesel fuel injection systems[R]. SAE-2004-01-0782
[14] SORIANO J A, MATA C, ARMAS O, et al. A zero-dimensional model to simulate injection rate from first generation common rail diesel injectors under thermodynamic diagnosis[J]. Energy,2018,158:845-858
[15] 冷先银, 隆武强, 冯立岩, 等. 喷射率对柴油机性能和排放影响数值模拟研究[J]. 大连理工大学学报,2011,51(2):180-187 LENG Xianyin, LONG Wuqiang, FENG Liyan, et al. Numerical simulation research into effects of injection rates on performances and emissions of diesel engine[J]. Journal of Dalian University of Technology, 2011, 51(2):180-187(in Chinese)
[16] YAN J W. Common rail injection system iterative learning control based parameter calibration for accurate fuel injection quantity control[J]. International Journal of Automotive Technology,2011,12(2):149-157
[17] 周磊,安士杰,杨昆, 等. 超高压共轨喷射系统电控增压器三维流场研究[J]. 海军工程大学学报, 2017, 29(2):37-41 ZHOU Lei, AN Shijie, YANG Kun, et al. Design of solenoid drive circuit for electronically controlled diesel engine[J]. Journal of Naval University of Engineering, 2017, 29(2):37-41(in Chinese) |
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