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姓名	蕭善尹(Shan-Yin Hsiao)  查詢紙本館藏	畢業系所	光機電工程研究所
論文名稱	側聚光型太陽能電池系統之容忍角增益研究
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摘要(中)	相較於傳統聚光型太陽能電池系統之體積龐大、組裝與對位容忍度低。本論文設計側聚光元件，並將太陽能電池晶片安置於聚光元件的側面，可使系統薄型化，提升組裝及對位容忍度，而適用於平板型產品。但因此類側聚光型系統之容忍角小，以致應用受限。 為了改善側聚光型太陽能電池系統之容忍角，本論文提出兩種類型之側聚光元件：第一類為V型溝槽結構之側聚光元件，第二類則為拋物面溝槽結構之側聚光元件。首先，使用光學軟體LightTools進行設計模擬，得第一類之側聚光元件容忍角為±4.5度；第二類之側聚光元件容忍角為±6.3度，容忍角較第一類側聚光元件提升了1.8度。接著，以V型溝槽結構作為聚光元件之底部反射結構，並實際製作出成品，再利用太陽光模擬器與太陽能電池分析儀進行實驗量測，以驗證此設計的可行性。而所測得的容忍角為±4.4度。最後，將實驗結果與模擬結果進行分析比較，以探討效率損失的原因。
摘要(英)	Compared with the bulky volume and the low tolerance in alignment of conventional concentrated photovoltaic systems (CPVs), the design in this research with the solar cells placed at the both side walls of the planar solar concentrator (PSC), can be thin and has the enhanced tolerance of alignment. Although such a PSC can be used for flat products, its acceptance angle is around only ±2^°, and the application is limited. In order to improve the acceptance angle of the planar solar concentrator (PSC). Two types of the planar solar concentrator (PSC) are purposed in this research. The first type uses the V-shape grooves, and the second type uses the parabolic grooves. First, we used LightTools to design and analyze the system. In simulation, the acceptance angles of the first and the second type have achieved ±〖4.5〗^° and ±〖6.3〗^°, respectively. Experimentally, the PSC with the V-shape grooves as the bottom reflective surface was fabricated. After the designed sample was fabricated by CNC machining, we used the solar simulator and the solar module analyzer in the measurement to verify this design. The factors between experimental result, and simulation result, were then analyzed, while the acceptance angle achieved the value of ±〖4.4〗^°.
關鍵字(中)	★ 聚光型太陽能電池系統 ★ 聚光元件 ★ 側聚光元件 ★ 容忍角	關鍵字(英)	★ Concentrated photovoltaic system ★ Concentrator ★ Planar solar Concentrator ★ Acceptance angle
論文目次	目錄 摘要 I Abstract II 致謝 III 目錄 IV 圖目錄 VI 表目錄 X 第一章、緒論 1 1-1研究背景 1 1-2 文獻回顧 4 1-3 研究動機與目的 10 1-4 研究方法與流程 11 1-5 論文架構 12 第二章、基礎理論與原理 13 2-1 幾何光學理論 13 2-2 菲涅爾損失(Fresnel Loss) 16 2-3 菲涅爾反射式太陽能集光器 18 2-4 拋物面反射式太陽能集光器 20 2-5 小結 22 第三章、設計與模擬 23 3-1 設計理念 23 3-2 設計流程 25 3-3 底部V溝反射斜面設計 26 3-4 底部V溝反射斜面之光學模擬 32 3-5 底部V溝反射面為斜面之側聚光元件容忍角分析 35 3-6 底部V溝拋物反射面設計 37 3-7 底部V溝拋物面之光學模擬 41 3-8 底部V溝反射面為拋物面之側聚光元件容忍角分析 48 3-8 小結 50 第四章、實驗方法與結果討論 51 4-1 實驗設備 51 4-2 實驗方法 56 4-3 實驗結果 58 4-3-1 太陽能電池基板量測 58 4-3-2 側聚光太陽能電池系統量測 62 4-3-3 側聚光太陽能電池系統之容忍角量測 67 4-4 結果與討論 68 4-4-1 誤差來源 68 4-4-2 容忍角誤差 76 4-5 小結 77 第五章、結論與未來展望 78 5-1 結論 78 5-2 未來展望 79 參考文獻 80
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指導教授	蕭善尹	審核日期	2017-8-11
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