Cleanroom Fan Energy Reduction—Airflow Control Retrofit Based on Continuous, Real-time Particle Sensing

Q4 Engineering

Journal of the IEST Pub Date : 2019-11-01 DOI:10.17764/1557-2196-62.1.11

W. Sun

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引用次数: 5

Abstract

Cleanrooms are utilized in electronics, semiconductor, aerospace, pharmaceutical, automotive, optical, medical device, and food processing facilities where air cleanliness is required to prevent defects in high-tech or high-value products. Compared to general commercial space, cleanrooms typically use 5 to 50 times the energy for the same area. One key reason is the high volume of conditioned and filtered air required to make the room air cleaner, which is measured in room-average particle concentration. The technology in this study uses real-time continuous particle sensors as feedback signals to automatically adjust fan speed. The system can modulate fan speed and provide the correct amount of airflow into the cleanroom to prevent over-supply and save energy. In typical manufacturing cleanrooms, the unoccupied state (evenings and weekends) is approximately two times longer than the occupied state (operational work hours), and particle generation (from personnel, equipment, and process) is much lower during the unoccupied state. Limited components and parts are required to apply the technology in this study into the design of a new cleanroom or to integrate the technology into existing cleanroom fan systems.

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基于连续实时粒子传感的洁净室风机节能-气流控制改造

洁净室用于电子、半导体、航空航天、制药、汽车、光学、医疗设备和食品加工设施，这些地方需要空气清洁度，以防止高科技或高价值产品的缺陷。与一般商业空间相比，洁净室通常使用相同面积的5到50倍的能量。一个关键的原因是需要大量的调节和过滤空气，使房间空气更清洁，这是在房间平均颗粒浓度测量。本研究采用实时连续粒子传感器作为反馈信号，自动调节风扇转速。该系统可调节风机转速，为洁净室提供正确的风量，防止供过于求，节约能源。在典型的制造洁净室中，空闲状态(晚上和周末)大约是空闲状态(操作工作时间)的两倍，并且在空闲状态下产生的颗粒(来自人员、设备和过程)要低得多。将本研究中的技术应用于新洁净室的设计或将该技术集成到现有洁净室风机系统中，需要的组件和部件数量有限。

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

Journal of the IEST Engineering-Safety, Risk, Reliability and Quality

CiteScore

0.40

自引率

0.00%

发文量

期刊介绍： The Journal of the IEST is an official publication of the Institute of Environmental Sciences and Technology and is of archival quality and noncommercial in nature. It was established to advance knowledge through technical articles selected by peer review, and has been published for over 50 years as a benefit to IEST members and the technical community at large as as a permanent record of progress in the science and technology of the environmental sciences