Manipulation of Elastic Deformation in Bio-inspired Wet Adhesion

仿生湿粘附中弹性变形的操纵

• 批准号: 1538003
• 负责人: Joelle Frechette
• 金额: $ 32.5万
• 依托单位: Johns Hopkins University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-09-01 至 2019-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1538003&HistoricalAwards=false
• 关键词: Manipulation; Elastic; Deformation; Bio; inspired

The choice of materials to control adhesion depends on the desired application. In robotics, for example, multiple adhesive cycles are necessary for locomotion, gripping, and manipulation. Synthetic hierarchical structures based on the gecko toe pads demonstrated these capabilities in air. Fulfilling these requirements for reversible adhesion in fluid environments (for example underwater), however, is more challenging. In fluids, dynamic effects such as drag and swelling can deform surface structures prior to contact and prevent adhesion. The objective of the work is to develop the fundamental understanding in mechanics necessary for the creation of structured surfaces that can act as reversible adhesives in liquids. The strategy to be followed is the fabrication of porous soft material films with a surface topography inspired by the frog toe pads. These films will be employed to investigate the role played by porosity and deformation on adhesion. The development of coatings for reversible underwater adhesion will advance the manufacturing of robotic components, bandages and wound sealants, and could help understand the mechanisms of biofouling. Beyond underwater adhesion for robotic and larger scale applications, a better understanding of poroelasticity in compliant materials could lead to better performing materials to replace joint cartilage. Outreach efforts include participation of high school and undergraduate students in the laboratory. Students participating in the project will be encouraged to present at conferences and be involved with additional outreach efforts at local elementary schools.The dynamics of friction, adhesion, and fracture of porous compliant materials involve poorly understood phenomena because transport, deformation, and adhesion are highly coupled. To address this issue, new instrumentation will be developed to study the mechanical performance of soft and porous coatings to measure simultaneously dissipative forces and spatiotemporal deformation. The performance (e.g. adhesion and poroelastic relaxation) of polymer coatings fabricated with three different type of anisotropic pillars will be investigated and results will be compared with uniform coatings of the same material. In particular, dissipative force measurements in fluids will be performed to determine the role played by out-of-contact deformation alter the magnitude and directionality of adhesion. Throughout the project, experiments will be compared to existing theories and continuum numerical finite element models for elastohydrodynamics and poroelasticity that are based on lubrication, elasticity, and transport in porous media. The contributions of multi-scale porosity (e.g. mesh scale, pillar spacing, and surface roughness), modulus, and directional anisotropy in surface topography will be characterized in terms of their ability to be engineered toward applications in reversible adhesion in wet environments.

控制粘附力的材料的选择取决于所需的应用。例如，在机器人技术中，多个粘合剂循环对于移动、抓握和操纵是必要的。基于壁虎趾垫的合成层次结构在空气中展示了这些能力。然而，在流体环境（例如水下）中满足这些可逆粘附的要求更具挑战性。在流体中，诸如拖曳和膨胀的动态效应可以在接触之前使表面结构变形并防止粘附。这项工作的目的是发展必要的结构化表面，可以作为可逆的粘合剂在液体中创建力学的基本理解。要遵循的策略是制造多孔软材料薄膜，其表面形貌受到青蛙脚趾垫的启发。这些薄膜将被用来研究孔隙率和变形对粘附力所起的作用。用于可逆水下粘附的涂层的开发将促进机器人组件，绷带和伤口密封剂的制造，并有助于了解生物污垢的机制。除了用于机器人和更大规模应用的水下粘附之外，更好地理解顺应性材料中的孔隙弹性可以导致更好地性能材料来替代关节软骨。外联工作包括高中生和本科生参加实验室。将鼓励参与该项目的学生出席会议，并参与当地小学的额外外联工作。多孔柔顺材料的摩擦、粘附和断裂动力学涉及到人们知之甚少的现象，因为传输、变形和粘附是高度耦合的。为了解决这个问题，将开发新的仪器来研究软质和多孔涂层的机械性能，以同时测量耗散力和时空变形。将研究用三种不同类型的各向异性柱制造的聚合物涂层的性能（例如粘附性和多孔弹性松弛），并将结果与相同材料的均匀涂层进行比较。特别是，将进行流体中的耗散力测量，以确定脱离接触变形改变粘附的大小和方向性所起的作用。在整个项目中，实验将比较现有的理论和连续数值有限元模型的弹性流体动力学和多孔弹性的基础上润滑，弹性，和多孔介质中的运输。多尺度孔隙率（如网格尺度，支柱间距和表面粗糙度），模量和方向各向异性的贡献，在表面形貌将其特征在于它们的能力，在湿环境中的可逆粘附工程应用。