Design and development of soft robotic hand for vertical farming in spacecraft

A. Suresh, G. Udupa, Dhruv Gaba
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引用次数: 4

Abstract

For colonization in deep space we need to explore the feasibility of a bioregenerative system in microgravity or artificial gravity environments. The process has various complexities form ranging to biological obstacles to engineering limitations of the spacecraft. Concentration of microbes in the confinements of a spacecraft can be fatal for the crew. In this paper, a solution to the elevated microbial levels by farming using robots is discussed. The soft robotic arm is made up of Asymmetric Flexible Pneumatic Actuator (AFPA). The AFPA under internal pressure will curve in the direction of the side having greater thickness as the expansion of the thinner side (outside radius) will be more than thicker side (inside radius) due to differential expansion and moment induced due to eccentricity. Simulation results demonstrate that bending based on AFPA can meet the designed requirement of application. The AFPA is used for five fingers of the robotic hand. The safe, soft touch and gentle motion of the bellow (AFPA) gives the feel of real human hand. The internal pressure of the AFPA is controlled using a solenoid valve which is interfaced using an Arduino microcontroller for hand like moves. The bending of the fingers and degree of freedom (DOF) of the joints of the hand is controlled using an IMU and flex sensor. Wireless connection of the hand and the control system is implemented using XBee pro 60mW with a range of 1 miles.The pneumatic soft robotic hand is made up of solenoid valve, Mini Compressor, AFPA bellow, and Servos. This soft robotic hand has many advantages such as good adaptability, simple structure, small size, high flexibility and less energy loss. As an extension Manual control of the robot using a virtual reality environment and well as some possible aspects of an automated farming systems can be considered as future additions.
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航天器垂直农业用柔性机械手的设计与研制
对于深空殖民,我们需要探索在微重力或人工重力环境中建立生物再生系统的可行性。这个过程有各种各样的复杂性,从生物障碍到航天器的工程限制。航天器密闭空间中的微生物浓度对机组人员来说可能是致命的。在本文中,讨论了使用机器人耕种来解决微生物水平升高的问题。软机械臂由非对称柔性气动执行器(AFPA)组成。内压下的AFPA将向厚度较大的一侧弯曲,因为较薄一侧(外半径)的膨胀将大于较厚一侧(内半径),这是由于偏心引起的差异膨胀和力矩。仿真结果表明,基于AFPA的弯曲可以满足设计的应用要求。AFPA用于机械手的五个手指。波纹管(AFPA)的安全、柔软的触感和轻柔的动作给人一种真正人手的感觉。AFPA的内部压力由一个电磁阀控制,该电磁阀通过Arduino微控制器接口进行手动移动。手指的弯曲和手的关节的自由度(DOF)使用IMU和柔性传感器来控制。手和控制系统的无线连接使用XBee pro 60mW实现,续航里程为1英里。气动软机械手由电磁阀、迷你压缩机、AFPA波纹管和伺服系统组成。这种柔性机械手具有适应性强、结构简单、体积小、灵活性高、能量损失小等优点。作为扩展,使用虚拟现实环境以及自动化农业系统的一些可能方面对机器人进行手动控制可以被视为未来的补充。
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