近年來由於科技的進步與迅速發展，工業與家庭用電量增加，再加上各國都不遺餘力地在推行能源政策的轉變，並階段式的增加各個國家發電系統的綠電比，減少來自於火力發電與核能發電的比例，隨之而來的狀況就是電費上漲，供電裕度的下降，與綠電供應佔比過高時的供電不穩定性。這時候就需要使用儲能系統(ESS)來穩定綠電產生的供應缺口。
在現行的工業應用與實際商品化最多的儲能系統為電池儲能系統(BESS)，由於電池儲能系統能夠快速反應的特性，使的目前在世界趨勢的推動下為大眾能夠接受的儲能系統，由於目前建置的大型BESS案場還是存在高風險的，系統失常的情況下使電池毀損，在對於BESS的工作環境管控度不足，當發生電池漏液、淹水、或是電池長期在高溫環境下充放電，而導致的災害在國際間也是時常發生。為了避免災害的發生與提前預防做準備，本文提出對BESS環境控制管理系統(ECS)的規劃與設計，透過感測器來監控BESS的場域與使用的電池來思考可能發生的災害，ECS持續收集環境監控數據與MBMS聯動保護內部的電池，避免災害的蔓延與相應的預防。實驗的環境為實際的BESS案場，通過Modbus通訊協定做感測器與管理系統的傳輸，經實驗的證明此規劃的ECS能將貨櫃內部包含電池控制在工作室溫內，相關規劃的元件也確實能夠與MBMS做聯動保護儲能系統。

In the current industrial application and actual commercialization of the most energy storage system is the battery energy storage system (BESS). Due to the rapid response characteristics of the battery energy storage system, it is currently an energy storage that is acceptable to the public under the impetus of the world trend. System, due to the high risk of the large-scale BESS case currently being built, the battery will be damaged if the system is abnormal, and the control of the working environment of the BESS is insufficient. Disasters caused by charging and discharging in a high temperature environment often occur internationally. In order to avoid the occurrence of disasters and prepare for early prevention, this paper proposes the planning and design of the BESS Environmental Control management System (ECS). Sensors are used to monitor the BESS field and the batteries used to think about possible disasters. ECS continues to Collect environmental monitoring data and link with MBMS to protect internal batteries, avoid the spread of disasters and take corresponding prevention. The experimental environment is the actual BESS field. The sensor and the management system are transmitted through the Modbus communication protocol. It has been proved by experiments that the planned ECS can control the battery inside the container at the working room temperature, and the related planned components are also It can indeed be linked and protected with MBMS.

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