Solar Tracking Using Linear Actuator

Volume 7A: Dynamics, Vibration, and Control Pub Date : 2020-11-16 DOI:10.1115/IMECE2020-23607

J. Betai, Hong Zhou

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Abstract

Solar trackers make solar panels perpendicular to solar ray to enhance solar power reaping. The relative motion between Sun and Earth has two degrees of freedom. Sun travels from east to west during daytime and also moves north and south due to Earth’s tilt. However, Sun’s daily north-south move is much smaller than its east-west move. Sensor-based solar trackers make solar panels perpendicular to solar ray based on sensor information. Although the existing sensor-based solar trackers increase solar power reaping from solar panels significantly, they also consume considerable power by driving solar trackers. Sensorless solar trackers make solar panels perpendicular to solar ray based on calculated solar location. The performance of sensorless solar trackers is not affected by bad weather. This paper is on sensorless solar trackers. Single-axis solar trackers have one degree of freedom solar tracking motion. They can catch Sun’s daily east-west movement effectively. The Sun’s small north-south movement can be covered for single-axis solar trackers by monthly or seasonal adjustment of their orientations. This research is focused on single-axis sensorless solar trackers that are driven by linear actuators. The advantages of linear actuator driven solar trackers are their self-locking function and high load carrying capacity. Their challenges include limited solar panel motion range, potential interference between an oscillating solar panel and its fixed supporting ground link, and high motor power consumption for solar tracking. The research of this paper is motivated by surmounting the challenges facing sensorless single-axis linear actuator driven solar trackers. In this research, linear actuator driven solar trackers will be designed and analyzed. The models of the designed solar trackers will be developed. The kinematic and dynamic performances of the modeled solar trackers will be analyzed and simulated. The results of this research will provide some guidelines for developing linear actuator driven solar trackers.

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采用直线执行器的太阳能跟踪

太阳能跟踪器使太阳能电池板垂直于太阳光线，以提高太阳能的收获。太阳和地球之间的相对运动有两个自由度。太阳在白天从东向西运动，也由于地球的倾斜而向南北移动。然而，太阳的每日南北移动远小于其东西向移动。基于传感器的太阳能跟踪器根据传感器信息使太阳能电池板与太阳光垂直。虽然现有的基于传感器的太阳能跟踪器显著增加了太阳能电池板的太阳能收获量，但它们在驱动太阳能跟踪器的过程中也消耗了相当大的功率。无传感器太阳能跟踪器根据计算的太阳位置使太阳能电池板垂直于太阳光线。无传感器太阳能跟踪器的性能不受恶劣天气的影响。这篇论文是关于无传感器太阳能跟踪器的。单轴太阳跟踪器具有一个自由度的太阳跟踪运动。他们可以有效地捕捉到太阳每天东西向的运动。单轴太阳跟踪器可以通过每月或季节性的方向调整来覆盖太阳的南北运动。本研究的重点是由线性致动器驱动的单轴无传感器太阳能跟踪器。直线执行器驱动的太阳能跟踪器具有自锁功能和高承载能力。他们面临的挑战包括有限的太阳能电池板运动范围，振荡太阳能电池板与其固定支撑接地链路之间的潜在干扰，以及用于太阳能跟踪的高电机功耗。本文的研究是为了克服无传感器单轴线性执行器驱动的太阳能跟踪器所面临的挑战。在本研究中，将设计和分析直线执行器驱动的太阳能跟踪器。设计的太阳能跟踪器的模型将被开发。对模型太阳跟踪器的运动学和动力学性能进行了分析和仿真。研究结果将为直线作动器驱动太阳能跟踪器的研制提供一定的指导。

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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Volume 7A: Dynamics, Vibration, and Control

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