Mechanical hybrid KERS based on toroidal traction drives: An example of smart tribological design to improve terrestrial vehicle performance

IF 1.5 Q3 ENGINEERING, MECHANICAL Advances in Tribology Pub Date : 2013-03-25 DOI:10.1155/2013/918387
F. Bottiglione, G. Carbone, L. D. Novellis, L. Mangialardi, G. Mantriota
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引用次数: 17

Abstract

We analyse in terms of efficiency and traction capabilities a recently patented traction drive, referred to as the double roller full-toroidal variator (DFTV). We compare its performance with the single roller full-toroidal variator (SFTV) and the single roller half-toroidal variator (SHTV). Modeling of these variators involves challenging tribological issues; the traction and efficiency performances depend on tribological phenomena occurring at the interface between rollers and disks, where the lubricant undergoes very severe elastohydrodynamic lubrication regimes. Interestingly, the DFTV shows an improvement of the mechanical efficiency over a wide range of transmission ratios and in particular at the unit speed ratio as in such conditions in which the DFTV allows for zero-spin, thus strongly enhancing its traction capabilities. The very high mechanical efficiency and traction performances of the DFTV are exploited to investigate the performance of a flywheel-based Kinetic Energy Recovery System (KERS), where the efficiency of the variator plays an important role in determining the overall energy recovery performance. The energy boost capabilities and the round-trip efficiency are calculated for the three different variators considered in this study. The results suggest that the energy recovery potential of the mechanical KERS can be improved with a proper choice of the variator.
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基于环形牵引驱动的机械混合动力KERS:智能摩擦学设计的一个例子,以提高地面车辆性能
我们从效率和牵引能力方面分析了最近获得专利的牵引驱动器,即双滚轮全环形变压器(DFTV)。将其性能与单辊全环面变换器(SFTV)和单辊半环面变换器(SHTV)进行了比较。这些变量的建模涉及具有挑战性的摩擦学问题;牵引力和效率性能取决于在滚轮和盘之间的界面上发生的摩擦学现象,在那里润滑剂经历了非常严格的弹流动力润滑制度。有趣的是,DFTV在大传动比范围内表现出了机械效率的提高,特别是在单位速比下,因为DFTV允许零自旋,因此大大提高了其牵引能力。利用DFTV极高的机械效率和牵引性能来研究基于飞轮的动能回收系统(KERS)的性能,其中变量的效率在决定整体能量回收性能方面起着重要作用。本文计算了三种不同变量下的能量提升能力和往返效率。结果表明,合理选择变量可以提高机械式液压泵的能量回收潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Advances in Tribology
Advances in Tribology ENGINEERING, MECHANICAL-
CiteScore
5.00
自引率
0.00%
发文量
1
审稿时长
13 weeks
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