2020-06-012024-05-17https://scholars.lib.ntu.edu.tw/handle/123456789/688946摘要：本計畫將針對設置於苗栗後龍之綠能智慧屋，進行系統重建及最佳化配置分析，使其恢復運作並保持穩定狀態，並延伸至民生交通應用，舉辦活動推廣綠能建設。 綠能智慧屋包含 10 kW太陽能電池、6kW風機、3kW質子交換膜燃料電池、800Ah 鉛酸電池、與耗能2.5kW產率500L/hr的電解產氫系統，是中華顧問工程司 (China Engineering Consultants Inc.; CECI) 於 2016 年建置，建置之初參考先期計畫開發之混合式燃料電池電力系統，期望電力供給能達到季節互補及日夜協調的作用，以提供負載系統穩定且持續的電源。在綠能示範屋建立後，我們以Matlab/SimPowerSystems 建立電力系統模型並進行進行最佳化分析，研究結果顯示可以進一步優化系統配置與能源管理策略，以降低系統成本並提高系統可靠度。 本計畫擬重整綠能智慧屋，並改善綠能配置及能源管理策略，將其應用至行動交通以落實民生需求，並舉辦活動推廣綠能觀念。首先，我們將重整綠能屋元件，包括氫燃料電池、太陽能發電板、風力發電機、二次電池等，結合電解與化學產氫技術，以提升系統運作可靠度。其次，我們將利用MATLAB SimPowerSystems 電力模型模擬智慧綠能屋系統運作狀況，定義目標函數以進行最佳系統設計分析，並調整綠能屋配置；我們也將運用小型氣象站紀錄天氣數據，用以擬定智慧化能源分配管理策略，以提升綠能屋系統性能。最後，我們將延伸綠能屋的應用，將其發展成為綠色能源充電站，為交通工具提供純淨的綠色能源作為動力，示範綠色能源的交通行動力，並舉辦活動推廣。<br> Abstract: This project proposes the applications of an intelligent green building that was constructed by China Engineering Consultants Inc (CECI) in Miao-Li county of Taiwan. We will restore the green building and apply optimization analyses techniques to improve the performance and reliability of the hybrid power system. Furthermore, we will explore the potential applications of the green building to green-power transportation. The green building was built in 2016. It consisted of a 3kW Proton Exchange Membrane Fuel Cell (PEMFC), 10 kW solar panels, 6kW wind turbine, 800Ah secondary battery sets, and a hydrogen electrolyzer. These components were selected to satisfy the daily energy demands of about 20 kWh, based on the weather data from NASA. However, currently some components are damaged and the recorded weather data is different from the NASA data such that the power supply is not sufficient for the preset loads. Therefore, this project will adjust the components of the green building, then we will demonstrate its potential for green transportation. First, we will restore the green building. The weather data will be measured and applied to build a hybrid power model by MATLAB SimPowerSystems. Then we will apply the model to analyze costs and reliability of the green building. From the previous studies, the performance of the green building can be greatly improved by adjusting the component sizes and energy management of the systems. Furthermore, the application of chemical hydrogen production module can guarantee power supply even in the extreme weather conditions, thus improve system reliability. Finally, we will discuss the potential applications of the green building to green-power transportation. We will apply the renewable energy from the green building to charge electric vehicles and promote the green-power transportation by activities.綠能屋混合電力系統電力模型SimPowerSystems最佳化綠色能源Green buildingHybrid power systemsSimPowerSystemsoptimizationgreen-power transportation