{"title":"Real area of contact and tractions on the patterned surfaces generated by spinodal decomposition and amplified instability","authors":"Wonhyeok Lee, Melih Eriten","doi":"10.3389/fmech.2023.1253207","DOIUrl":null,"url":null,"abstract":"Past decades featured significant advancements in additive and micromanufacturing that facilitated the creation of functional patterned surfaces with impressive spatial resolutions. However, these techniques are expensive and require a considerable amount of time and energy, and hence lack scalability to practical surfaces. Recent techniques employing spinodal decomposition and instabilities amplified via centrifugal acceleration offer viable and cheaper alternatives. The patterns created by those techniques, however, vary randomly in geometry. When interfacing those patterned surfaces with other components and under self-contact scenarios, geometric variations lead to stress concentration and abrupt failure around the contact. In this study, we investigate numerically real contact areas, contact tractions, and stress concentration. We generate patterned surfaces in congruence with actual surfaces created by those techniques. Then, we conduct normal-contact analyses of those surfaces boundary element method (BEM) under nominal mean pressures ranging from 0.001 E * to E *, where E * is the contact modulus. We record real contact areas and stress concentration as a function of nominal mean pressures. We compare these values with the analytical solutions from sinusoidally-patterned and randomly rough surfaces. Randomness in pattern geometry is primarily influenced by the processing parameters such as the degree of anisotropy in spinodal decomposition and acceleration in amplified instabilities. To understand the influence of the processing parameters, we perform a parametric study. We find isotropic spinodal decomposition creates patterns that deliver contact area and traction distributions similar to randomly rough surfaces, and lead to high-stress concentrations. Such high-stress concentrations are expected to occur under self-contact loading scenarios, and thus can explain the compromised resilience and strength in recently-proposed spinodal metamaterials. For patterned surfaces created by amplified instabilities, high-stress concentrations are obtained for the surfaces created at high accelerations. At high accelerations, increased elastic instabilities and stochastic growth result in a more skewed and broader distribution in heights. Therefore, high-stress concentrations are inevitable. To account for combined loading scenarios, we conduct additional simulations on the same surface patterns with frictional pre-sliding contacts. We find the frictional tractions play a secondary role in stress concentrations where the primary factor is the processing parameters determining the degree of randomness in pattern geometry.","PeriodicalId":53220,"journal":{"name":"Frontiers in Mechanical Engineering","volume":null,"pages":null},"PeriodicalIF":2.0000,"publicationDate":"2023-09-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Frontiers in Mechanical Engineering","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3389/fmech.2023.1253207","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENGINEERING, MECHANICAL","Score":null,"Total":0}
引用次数: 0
Abstract
Past decades featured significant advancements in additive and micromanufacturing that facilitated the creation of functional patterned surfaces with impressive spatial resolutions. However, these techniques are expensive and require a considerable amount of time and energy, and hence lack scalability to practical surfaces. Recent techniques employing spinodal decomposition and instabilities amplified via centrifugal acceleration offer viable and cheaper alternatives. The patterns created by those techniques, however, vary randomly in geometry. When interfacing those patterned surfaces with other components and under self-contact scenarios, geometric variations lead to stress concentration and abrupt failure around the contact. In this study, we investigate numerically real contact areas, contact tractions, and stress concentration. We generate patterned surfaces in congruence with actual surfaces created by those techniques. Then, we conduct normal-contact analyses of those surfaces boundary element method (BEM) under nominal mean pressures ranging from 0.001 E * to E *, where E * is the contact modulus. We record real contact areas and stress concentration as a function of nominal mean pressures. We compare these values with the analytical solutions from sinusoidally-patterned and randomly rough surfaces. Randomness in pattern geometry is primarily influenced by the processing parameters such as the degree of anisotropy in spinodal decomposition and acceleration in amplified instabilities. To understand the influence of the processing parameters, we perform a parametric study. We find isotropic spinodal decomposition creates patterns that deliver contact area and traction distributions similar to randomly rough surfaces, and lead to high-stress concentrations. Such high-stress concentrations are expected to occur under self-contact loading scenarios, and thus can explain the compromised resilience and strength in recently-proposed spinodal metamaterials. For patterned surfaces created by amplified instabilities, high-stress concentrations are obtained for the surfaces created at high accelerations. At high accelerations, increased elastic instabilities and stochastic growth result in a more skewed and broader distribution in heights. Therefore, high-stress concentrations are inevitable. To account for combined loading scenarios, we conduct additional simulations on the same surface patterns with frictional pre-sliding contacts. We find the frictional tractions play a secondary role in stress concentrations where the primary factor is the processing parameters determining the degree of randomness in pattern geometry.
在过去的几十年里,增材制造和微制造取得了重大进展,促进了具有令人印象深刻的空间分辨率的功能性图案表面的创造。然而,这些技术是昂贵的,需要大量的时间和精力,因此缺乏实际表面的可扩展性。最近的技术采用了独立分解和通过离心加速放大的不稳定性,提供了可行且更便宜的替代方案。然而,这些技术创造的图案在几何上是随机变化的。当这些有图案的表面与其他部件接触时,在自接触情况下,几何变化会导致接触周围的应力集中和突然破坏。在这项研究中,我们调查了数值实际接触面积,接触牵引力和应力集中。我们生成与这些技术创建的实际表面一致的图案表面。然后,我们在名义平均压力范围为0.001 E *至E *(其中E *为接触模量)的条件下对这些表面进行法向接触分析。我们记录实际接触面积和应力集中作为名义平均压力的函数。我们将这些值与正弦图案和随机粗糙表面的解析解进行比较。图案几何的随机性主要受处理参数的影响,如旋量分解的各向异性程度和放大不稳定性的加速度。为了了解加工参数的影响,我们进行了参数研究。我们发现各向同性旋量分解产生的模式提供了类似于随机粗糙表面的接触面积和牵引力分布,并导致高应力集中。这种高应力集中预计会发生在自接触加载情景下,因此可以解释最近提出的spinodal超材料的弹性和强度受损。对于由放大的不稳定性产生的图案表面,在高加速度下产生的表面获得高应力集中。在高加速度下,增加的弹性不稳定性和随机增长导致高度分布更偏和更宽。因此,高应力集中是不可避免的。为了考虑组合加载场景,我们对具有摩擦预滑动接触的相同表面模式进行了额外的模拟。我们发现摩擦牵引力在应力集中中起次要作用,主要因素是决定图案几何随机性程度的加工参数。