The content discusses the optimization of HVAC systems in electric city buses to balance energy consumption and thermal comfort. It highlights the benefits of using a steady-state model for quick optimization, compares results with dynamic simulations, and presents case studies showcasing practical applications.
The electrification of public transport vehicles aims to reduce emissions, with electric buses showing lower life-cycle greenhouse gas emissions than diesel counterparts. However, HVAC systems can significantly impact driving range due to high energy consumption.
Research focuses on improving the trade-off between reducing HVAC energy consumption and maintaining thermal comfort for passengers. Existing literature categorizes approaches into design improvements and control enhancements specific to public transport applications.
Public transport vehicles like city buses operate for extended periods, making transient scenarios less relevant compared to passenger vehicles. Dynamic models are commonly used for vehicular applications, while public buses' short thermal timescales allow for steady-state modeling.
Steady-state models offer an efficient approach to analyze year-round operation of HVAC systems in electric city buses. By simplifying complex dynamics, these models provide valuable insights into optimizing performance without extensive computational demands.
Comparisons between steady-state optimizations and dynamic simulations reveal close alignment in HVAC system power demand and thermal comfort outcomes. The study emphasizes the practicality and accuracy of using steady-state analysis for evaluating and enhancing system performance.
Two case studies demonstrate how steady-state optimization can evaluate different system designs based on year-round performance evaluation and generate setpoints for online controllers. The approach proves valuable in assessing HVAC system efficiency in real-world applications.
他の言語に翻訳
原文コンテンツから
arxiv.org
深掘り質問