Deterministic Simulation of Surface Textures for the Piston Ring/Cylinder Liner System in a Free Piston Linear Engine

Lubricants Pub Date : 2024-01-03 DOI:10.3390/lubricants12010012

Felipe Kevin Correa Luz, F. Profito, Marcelo Braga dos Santos, Samuel A. N. Silva, H. Costa

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Abstract

The use of synthesis gas (SYNGAS) from waste gasification has been pointed out as a key strategy to help the energy transition. However, SYNGAS’ low calorific power is considered a difficult obstacle to its technological use in internal combustion engines. To overcome this, a novel free-piston linear motor has been proposed to pave the way for the use of SYNGAS in the mobility sector. Surface texturing has vast potential to reduce friction losses in this system. This study utilizes a deterministic numerical model to investigate the mixed lubrication performance of a textured piston ring/cylinder liner conjunction in a free piston engine. The model considers the simultaneous solution of the lubrication and asperity contact problems at the roughness scale, including texturing features on the cylinder surface. The numerical model employs the Reynolds equation with mass-conserving cavitation to calculate the inter-asperity fluid pressure. The rough contact model utilizes the Hertz theory for elastic contact to calculate the contact pressure at each asperity between the piston liner surface and the admitted smooth and rigid ring surface. Surface texturing demonstrated remarkable effectiveness, particularly in the hydrodynamic lubrication regime, with a maximum friction reduction of 38.5% observed for an area coverage of 50%. This was accompanied by a notable shift in the transition from the boundary to the mixed lubrication regime. The textured surfaces exhibited consistent efficiency in reducing fluid pressure and shear stress as the coverage of the textured areas increased. The incorporation of dimples on these surfaces played a crucial role by augmenting the lubricant storage capacity while concurrently reducing the real shear and contact areas. This study offers valuable insights into the nuanced friction-reducing mechanisms of surface textures, illuminating their influence on the coefficient of friction and the formation of lubricant films across various lubrication regimes.

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自由活塞式直线发动机活塞环/缸套系统表面纹理的确定性模拟

利用废物气化产生的合成气（SYNGAS）已被视为帮助能源转型的一项关键战略。然而，SYNGAS 的低热值功率被认为是将其用于内燃机的技术障碍。为了克服这一障碍，我们提出了一种新型自由活塞直线电机，为 SYNGAS 在移动领域的应用铺平道路。表面纹理处理在减少该系统的摩擦损耗方面具有巨大潜力。本研究利用确定性数值模型来研究自由活塞发动机中纹理活塞环/缸套组合的混合润滑性能。该模型考虑在粗糙度尺度上同时解决润滑和表面接触问题，包括气缸表面的纹理特征。数值模型采用质量保证气蚀的雷诺方程来计算非表面间的流体压力。粗糙接触模型利用赫兹弹性接触理论计算活塞衬垫表面与光滑刚性环表面之间每个非圆表面的接触压力。表面纹理处理效果显著，尤其是在流体动力润滑系统中，当覆盖面积为 50%时，摩擦力最大可降低 38.5%。与此同时，从边界润滑状态到混合润滑状态的转变也非常明显。随着纹理区域覆盖率的增加，纹理表面在降低流体压力和剪切应力方面表现出一致的效率。在这些表面上加入凹痕起到了至关重要的作用，既提高了润滑剂的储存能力，同时又减少了实际剪切力和接触面积。这项研究为了解表面纹理的微妙减摩机制提供了宝贵的见解，阐明了它们对摩擦系数和各种润滑状态下润滑油膜形成的影响。

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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Lubricants

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