无人机路径生成图像采集辅助定日镜场光学特性

Kidus Guye, Rebecca Mitchell, G. Zhu
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引用次数: 0

摘要

研究了无人机在聚光太阳能电站定日镜光学误差测量中的应用。在CSP中,需要测量太阳场光学误差,这对未来的生产改进以及定日镜场的操作和维护至关重要。后一种需求尤其具有挑战性,因为大量的定日镜(一个公用事业规模的发电厂超过10,000个)在野外单独跟踪太阳。为了解决这个问题,配备了摄像头的无人机,开发并上传了优化的无人机飞行路径,收集每个定日镜上塔的精确反射图像,以评估光学误差源,而不会中断工厂的操作。生成用于捕获反射图像的无人机路径受到许多技术和现实约束的影响,其中包括用于捕获图像的相机角度,由于周围定日镜导致的相机视图阻塞,相机相对于目标定日镜的位置以及目标定日镜相对于塔的位置。这些约束对计算相机位置的影响将在本文中详细讨论。生成了一种有效的无人机路径算法,以满足各种约束条件下的图像采集需求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Unmanned Aerial Vehicle Path Generation for Image Collection to Assist Heliostat Field Optical Characterization
This paper focuses on applications of unmanned aerial vehicles (UAVs) for measuring optical error of heliostats in concentrating solar power (CSP) plants. In CSP, there is a need to measure solar-field optical errors, which is critical for future production improvement as well as for operations and maintenance of a heliostat field. This latter need is particularly challenging because of the large number of heliostats (over 10,000 for a utility-scale power plant) that individually track the sun in the field. To address this issue, a camera-equipped UAV, with an optimized drone flight path developed and uploaded to it, collects images of a precise reflection of the tower on each heliostat to evaluate optical error sources without interrupting plant operation. Generation of the drone path for capturing the reflected images is affected by a number technical and realistic constraints, which include the camera angle used to capture the image, the blocking of the camera view due to surrounding heliostats, the location of the camera in reference to the target heliostat, and the target heliostat position with reference to the tower. The effect of these constraints on calculating the camera position will be discussed in detail in this article. An effective drone-path algorithm is generated to fulfil the need of image collection under various constraints.
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