Yao Yao , Juan M. Fernandez , Sven G. Bilén , Xin Ning
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引用次数: 0
Abstract
Small satellites such as CubeSats pose demanding requirements on the weight, size, and multifunctionality of their structures due to extreme constraints on the payload mass and volume. To address this challenge, we introduce a concept of multifunctional deployable space structures for CubeSats based on ultrathin, elastically foldable, and self-deployable bistable composite structures integrated with flexible electronics. The multifunctional bistable booms can be stored in a coiled configuration and self-deploy into a long structure upon initiation by releasing the stored strain energy. The boom demonstrates the capabilities of delivering power and transmitting data from the CubeSat to the flexible devices on the boom tip. The boom also shows the ability to monitor the dynamics and vibration during and after the deployment. A payload boom has been installed in a 3 U CubeSat as flight hardware for in-space testing and demonstration. This effort combines morphable ultrathin composite structures with flexible electronics.
由于有效载荷的质量和体积受到极大限制,立方体卫星等小型卫星对其结构的重量、尺寸和多功能性提出了苛刻的要求。为了应对这一挑战,我们提出了一种用于立方体卫星的多功能可部署空间结构概念,这种结构基于超薄、可弹性折叠和可自行部署的双稳态复合结构,并集成了柔性电子器件。多功能双稳态吊杆可以盘绕配置存储,并在启动时通过释放存储的应变能自展开成一个长结构。该吊杆展示了从立方体卫星向吊杆顶端的柔性设备供电和传输数据的能力。吊杆还展示了在部署期间和之后监测动态和振动的能力。有效载荷吊杆已作为飞行硬件安装在 3 U 立方体卫星上,用于空间测试和演示。这项工作将可变形的超薄复合材料结构与柔性电子设备相结合。
期刊介绍:
Extreme Mechanics Letters (EML) enables rapid communication of research that highlights the role of mechanics in multi-disciplinary areas across materials science, physics, chemistry, biology, medicine and engineering. Emphasis is on the impact, depth and originality of new concepts, methods and observations at the forefront of applied sciences.