Analysis of offshore floating photovoltaic motion power generation based on digital fusion
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摘要: 相比陆基式光伏发电系统,海上漂浮式光伏系统发电耦合了运动特征,输出功率呈现复杂随机性。为获取海上漂浮式光伏系统的发电运动特征,提出一种“一次测量三层融合”的数字化方法,即利用运动、环境、组件和发电数据表征系统耦合因素,通过测量获取运动数据,依次实现运动到环境、环境到组件、组件到发电的三层数据融合,并通过搭建实验系统,验证数字融合方法的有效性。结果表明,与实测数据相比,融合方法的最大偏差为1.11 W,最大相对偏差为1%。相较于静态时,运动造成系统整体功率减少1.14 W,降低5.06%;功率最大减少3.27 W,最大降低13.30%,为提高海上漂浮式光伏发电效率提供了有效途径。Abstract: Compared with land-based photovoltaic (PV) power generation systems, offshore floating PV systems are coupled with motion characteristics, so the output power displays complex randomness. To obtain the motion characteristics of offshore floating PV power generation, a digital method "one measurement and three-layer fusion" was proposed. Data regarding motion, environment, components, and power generation were utilized to characterize the systems' coupling factors. Motion data were acquired through measurement, and data fusion was sequentially realized from motion to environment, environment to components, and components to power generation. Finally, an experimental system was constructed to validate the method. The results indicate that the maximum absolute deviation and relative deviation between the fusion data and the data from measurement were 1.11 W and 1%, respectively. Moreover, compared with the static state, the motion leads to an overall power reduction of 1.14 W (5.06%), with a maximum reduction of 3.27 W (13.30%). This method offers an effective approach to improve the efficiency of offshore floating PV power generation.
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图 8 输出功率运动与静态下的对比图
Figure 8. Comparison chart of output power under motion and static conditions
图 9 基于互补滤波器的三轴运动姿态角
Figure 9. Three axis motion attitude angles based on complementary filters
图 10 运动与发电致因关系曲线
Figure 10. Causal relationship curve between motion and power generation
表 1 数字融合关键参数
Table 1. Key parameters of digital fusion
N(t) S(t) X[M(t)] [i j] Δt/s ${\left[ \begin{gathered} 1000{\text{ }} \\ {\text{25}} \\ \end{gathered} \right]^{\text{T}}}$ ${\left[ \begin{gathered} 3.86 \\ {\text{2}}{\text{.409e-7}} \\ {\text{0}}{\text{.01}} \\ {\text{83}}{\text{.1}} \\ {\text{1}}{\text{.31}} \\ \end{gathered} \right]^{\text{T}}}$ $\left[ \begin{gathered} 0 \\ {\text{0}} \\ {\text{90}} \\ \end{gathered} \right]$ $\left[ {1{\text{ }}2} \right]$ 0.001 K q/C EG/eV b k 0.004 1.6×10−19 1.12 0.22 1.38×10−23 
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