混合动力高效甲醇发动机技术研究

    Research on High-Efficiency Methanol Engine Technology for Hybrid Power Systems

    • 摘要: 以量产汽油发动机为基础,通过适配甲醇燃料,系统探究了当量燃烧与超稀薄燃烧技术对火花点火甲醇发动机热效率的提升机制。研究优化了发动机核心参数与系统配置:当量燃烧系统将压缩比提升至15,强化喷油器耐腐蚀性;超稀薄燃烧系统集成230 mJ高能点火线圈、高效废气涡轮增压器及优化配气机构,拓展稀薄燃烧极限。通过台架试验分析发动机性能、排放及能量损失特性,同时解决甲醇发动机早燃识别难题。结果表明:当量燃烧条件下甲醇发动机最高有效热效率达45.96%,较原汽油机提升5.86个百分点,总碳氢(total hydrogen carbon, THC)、颗粒物数量(particle number, PN)排放显著降低;超稀薄燃烧条件下发动机最高热效率进一步提升至48.67%,且46.00%以上热效率区域覆盖发动机万有特性图面积的1/2,NO排放较当量燃烧条件下大幅下降。

       

      Abstract: Based on a mass-produced gasoline engine with adapted methanol fuel, the mechanisms by which stoichiometric combustion and ultra-lean burn technologies enhance the thermal efficiency of spark-ignition methanol engines were studied systematically. The core parameters and system configurations of the engine were optimized. For the stoichiometric combustion system, the compression ratio was increased to 15, and the corrosion resistance of the fuel injectors was enhanced. For the ultra-lean burn system, a 230 mJ high-energy ignition coil, a high-efficiency exhaust gas turbocharger and an optimized valve train were integrated to expand the lean burn limit. Bench tests were conducted to analyze the engine performance, emission characteristics and energy loss properties, and the challenge of identifying pre-ignition in methanol engines was addressed simultaneously. The results show that the maximum effective thermal efficiency of the methanol engine under stoichiometric combustion reached 45.96%, representing a 5.86 percentage point increase compared with that of the original gasoline engine, with total hydrogen carbon(THC) and particle number(PN) emissions reduced significantly. The maximal thermal efficiency of the methanul engine under ultra-lean burn was further increased to 48.67%, and the area with thermal efficiency above 46.00% accounted for half of the entire map. The NO emissions decreased sharply compared with those under stoichiometric combustion.

       

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