氢电混动汽车(fuel-cell hybrid electric vehicles,FCHEV)的出现克服了电动汽车充电缓慢、续航焦虑的问题,而且其灵活多样的用能方式有利于缓解电力系统调峰压力,能够促进能源–交通系统深度融合与绿色低碳转型,助力我国早日达成“30&#...氢电混动汽车(fuel-cell hybrid electric vehicles,FCHEV)的出现克服了电动汽车充电缓慢、续航焦虑的问题,而且其灵活多样的用能方式有利于缓解电力系统调峰压力,能够促进能源–交通系统深度融合与绿色低碳转型,助力我国早日达成“30×60双碳目标”。该文建立了FCHEV等效里程模型,将里程作为衡量其充电加氢状态的指标;并建立了考虑电碳耦合的能源交通融合系统优化调度模型,使得机组运行成本和环境成本最低。基于我国某省实际数据分析了电-碳市场下FCHEV的接入对提高电力系统灵活性和推动碳减排的积极作用,挖掘了氢电混动载运技术创造的产业价值,研究了大力发展新能源对碳减排的积极影响,并根据研究结果提出了促进碳市场环境下能源–交通系统发展的建议。展开更多
Charge and discharge characteristics of Ni/MH batteries are investigated with experiments. During battery’s working, the voltage, capacity, temperature and internal resistance were recorded, corresponding curves were...Charge and discharge characteristics of Ni/MH batteries are investigated with experiments. During battery’s working, the voltage, capacity, temperature and internal resistance were recorded, corresponding curves were depicted. Variations of the aforementioned four parameters are differently obvious. Ending criteria of charge and discharge of Ni/MH batteries are discussed on the basis of the curves. Voltage, capacity and temperature of a battery can be used as ending criteria during charge. When discharge takes place, voltage, capacity and internal resistance can be chosen as ending criteria. As a whole, capacity is more suitable for being used as ending criteria of charge and discharge than the other three parameters. At last, the capacity of a battery is recommended to be ending criteria of charge and discharge. The conclusions will provide references to different capacity Ni/MH batteries for electric vehicles.展开更多
Three types of low-carbon vehicle technologies in China are reviewed. Potential effects are listed for those integrated energy-saving technologies for conventional vehicles. Low carbon transitions, including alternati...Three types of low-carbon vehicle technologies in China are reviewed. Potential effects are listed for those integrated energy-saving technologies for conventional vehicles. Low carbon transitions, including alternative vehicle power train systems and fuels, are discussed on their development status and trends, including life cycle primary fossil energy use and greenhouse gas emissions of each pathway. To further support the low-carbon vehicle technologies development, integrated policies should seek to: (1) employ those integrated energy-saving technologies, (2) apply hybrid electric technology, (3) commercialize electric vehicles through battery technology innovation, (4) support fuel cell vehicles and hydrogen technology R&D for future potential applications, (5) boost the R&D of second generation biofuel technology, and (6) conduct further research on applying low-carbon technologies including CO2 capture and storage technology to coal-based transportation solutions.展开更多
文摘氢电混动汽车(fuel-cell hybrid electric vehicles,FCHEV)的出现克服了电动汽车充电缓慢、续航焦虑的问题,而且其灵活多样的用能方式有利于缓解电力系统调峰压力,能够促进能源–交通系统深度融合与绿色低碳转型,助力我国早日达成“30×60双碳目标”。该文建立了FCHEV等效里程模型,将里程作为衡量其充电加氢状态的指标;并建立了考虑电碳耦合的能源交通融合系统优化调度模型,使得机组运行成本和环境成本最低。基于我国某省实际数据分析了电-碳市场下FCHEV的接入对提高电力系统灵活性和推动碳减排的积极作用,挖掘了氢电混动载运技术创造的产业价值,研究了大力发展新能源对碳减排的积极影响,并根据研究结果提出了促进碳市场环境下能源–交通系统发展的建议。
文摘Charge and discharge characteristics of Ni/MH batteries are investigated with experiments. During battery’s working, the voltage, capacity, temperature and internal resistance were recorded, corresponding curves were depicted. Variations of the aforementioned four parameters are differently obvious. Ending criteria of charge and discharge of Ni/MH batteries are discussed on the basis of the curves. Voltage, capacity and temperature of a battery can be used as ending criteria during charge. When discharge takes place, voltage, capacity and internal resistance can be chosen as ending criteria. As a whole, capacity is more suitable for being used as ending criteria of charge and discharge than the other three parameters. At last, the capacity of a battery is recommended to be ending criteria of charge and discharge. The conclusions will provide references to different capacity Ni/MH batteries for electric vehicles.
基金co-supported by the China National Social Science Foundation(09&ZD029)MOE Project of Key Research Institute of Humanities and Social Sciences at Universities in China (2009JJD790029)+1 种基金Doctoral Thesis Fund of Beijing Municipal Science and Technology Commission (zz200923)the CAERC program(Tsinghua/ GM/SAIC-China)
文摘Three types of low-carbon vehicle technologies in China are reviewed. Potential effects are listed for those integrated energy-saving technologies for conventional vehicles. Low carbon transitions, including alternative vehicle power train systems and fuels, are discussed on their development status and trends, including life cycle primary fossil energy use and greenhouse gas emissions of each pathway. To further support the low-carbon vehicle technologies development, integrated policies should seek to: (1) employ those integrated energy-saving technologies, (2) apply hybrid electric technology, (3) commercialize electric vehicles through battery technology innovation, (4) support fuel cell vehicles and hydrogen technology R&D for future potential applications, (5) boost the R&D of second generation biofuel technology, and (6) conduct further research on applying low-carbon technologies including CO2 capture and storage technology to coal-based transportation solutions.
