Optimizing Chiller Switch-on Time Interval for Chiller Power Consumption Saving Via Big Data Analytics and Machine Learning Framework

2019 Joint International Symposium on e-Manufacturing & Design Collaboration(eMDC) & Semiconductor Manufacturing (ISSM) Pub Date : 2019-09-01 DOI:10.23919/eMDC/ISSM48219.2019.9052110

Yu-Chu Tsai, C. Chien, Ying-Jen Chen, Meng-Ke Hsieh

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引用次数: 1

Abstract

In semiconductor manufacturing, the chiller water system requires huge energy consumption, especially in the countries which have high temperature and humidity climate such as Taiwan. In order to minimize chiller power consumption without affecting the environment of wafer production, optimizing chiller system operations become a crucial issue. Conventionally, chiller operations greatly depend on engineers' practical experiences. However, various uncertainties, including changeable weather and complicated chiller combinations, lead to inconsistent decisions of switching chiller machines as well as energy waste [1]. To improve the operational performance of the system for energy saving, researchers have proposed many different types of solutions, but those technologies are not easy to widely adopted in practical applications due to the complicated and limited operations and models.

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通过大数据分析和机器学习框架优化冷水机开电间隔以节省冷水机功耗

在半导体制造中，冷水机水系统需要巨大的能源消耗，特别是在台湾等高温高湿气候的国家。为了在不影响晶圆生产环境的前提下最大限度地降低制冷机的功耗，优化制冷机系统的运行成为一个关键问题。通常，冷水机组的运行很大程度上取决于工程师的实际经验。然而，由于天气多变、冷水机组组合复杂等各种不确定性，导致冷水机组切换决策不一致，造成能源浪费[1]。为了提高系统的运行性能，实现节能，研究人员提出了许多不同类型的解决方案，但由于操作和模型的复杂性和局限性，这些技术不容易在实际应用中广泛采用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2019 Joint International Symposium on e-Manufacturing & Design Collaboration(eMDC) & Semiconductor Manufacturing (ISSM)

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