A new tool for energy conservation in operating room: The role of machine learning models in enhancing airflow control

[Display omitted] •A technology was created by merging experimental data and machine learning.•A comprehensive comparison of eleven machine learning algorithms was performed.•ET and MLP excel in prediction, achieving R2 values of 0.954 and 0.904, respectively.•Interval prediction provides a range of...

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Bibliographic Details
Published in:Energy and buildings 2024-04, Vol.309, p.114072, Article 114072
Main Authors: Liu, Zhijian, Huang, Zhenzhe, Li, Haochuan, Chu, Jiaqi, He, Junzhou, Liu, Haiyang, Xiao, Xia
Format: Article
Language:English
Subjects:
Aerosol
Energy consumption
Machine learning
Operating room
Ventilation
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Summary:[Display omitted] •A technology was created by merging experimental data and machine learning.•A comprehensive comparison of eleven machine learning algorithms was performed.•ET and MLP excel in prediction, achieving R2 values of 0.954 and 0.904, respectively.•Interval prediction provides a range of predicted values, enhancing confidence.•Enhancing the model's robustness through perturbation analysis by introducing noise. Maintaining high ventilation rates in operating rooms (ORs) is critical to ensure the safety of healthcare professionals and patients. Yet, the significant energy consumption associated with ventilation systems is a growing global concern. While traditional approaches have predominantly focused on optimizing ventilation design, limited attention has been given to operational control strategies. This study aims to control ceiling air supply speed by exposure aerosol concentrations exhaled by the patient. It achieves this by integrating empirical data with machine learning (ML) models, effectively balancing the need for maintaining optimal ventilation conditions and ensuring a safe aerosol exposure concentration. Experimental results from a full-scale OR setup, manipulating ceiling air supply speed, respiratory flow rate, and surgical bed height, generated 81 datasets. These datasets served as the basis for assessing the performance of 11 ML models. Notably, the extra trees (ET) and multi-layer perceptron (MLP) models outperformed the others, exhibiting impressive coefficient of determination (R2) values of 0.954 and 0.904, respectively. Moreover, the models were further enhanced by assessing their robustness with Gaussian noise and interval prediction. This study presents a novel approach that holds significant relevance for the practical control of ventilation systems, particularly with regard to health and energy efficiency considerations.
ISSN:0378-7788
DOI:10.1016/j.enbuild.2024.114072