Performance of novel overhead crane fume-collecting hood for pollutant removal

Zhixiang Cao; Pan Xiao; Yi Wang; Yuqing Bai; Chen Zhang; Tongtong Zhao; Chao Zhai; Minghao Zhang; Songheng Wu

doi:10.1007/s12273-023-1025-1

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Research Article

Performance of novel overhead crane fume-collecting hood for pollutant removal

Zhixiang Cao^{¹^,²}, Pan Xiao^², Yi Wang^{¹^,²}(

), Yuqing Bai^², Chen Zhang^², Tongtong Zhao^², Chao Zhai^², Minghao Zhang^², Songheng Wu^{¹^,²}

State Key Laboratory of Green Building in Western China, Xi'an University of Architecture and Technology, 710055 Xi'an, China

School of Building Services Science and Engineering, Xi'an University of Architecture and Technology, 710055 Xi'an, China

Show Author Information

Abstract

In industrial buildings, the presence of overhead cranes severely affects roof exhaust ventilation systems when capturing and discharging fumes, resulting in severe deterioration of the indoor plant environment. In this study, an overhead crane-based ventilation auxiliary device, called overhead crane fume-collecting hood (CFCH), is proposed to guide pollutants blocked by the overhead crane back to the roof exhaust hood. The airflow characteristics and pollutant distribution under the three modes of no overhead crane, overhead crane, and overhead crane + CFCH were compared using numerical simulations. Subsequently, the effects of the CFCH length (a), width (b), and height (h) on the pollutant capture performance were determined through orthogonal experiments and computational fluid dynamics. Finally, the pollutant capture efficiency (PCE) of the optimal CFCH was investigated considering different exhaust airflow rates. The results showed that the pollutants captured by the CFCH can be classified into directly and secondary captured pollutants, with the directly captured pollutants dominating. In addition, with the introduction of different sizes of CFCH around the overhead crane girders, the PCE significantly improved by 49.9%–74.6%. The length, width, and height of the CFCH on the PCE were statistically significant, and the priority of the three factors was as follows: h > b > a. The PCE decreased with increasing a, initially increased and then decreased with increasing b, and increased with h. Subsequently, when the optimal CFCH was used, the excessive exhaust air rate had no evident PCE improvement. This provides a new concept for the control of pollutants in industrial buildings and provides a theoretical basis for the design of CFCHs.

Keywords

CFD simulation industrial building orthogonal experiment capture efficiency exhaust hood buoyant jet

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Building Simulation

Volume 16 Issue 7,
July 2023

Pages 1081-1095

DOI: 10.1007/s12273-023-1025-1

Cite this article:

Cao Z, Xiao P, Wang Y, et al. Performance of novel overhead crane fume-collecting hood for pollutant removal. Building Simulation, 2023, 16(7): 1081-1095. https://doi.org/10.1007/s12273-023-1025-1

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Received: 03 December 2022

Revised: 20 March 2023

Accepted: 27 March 2023

Published: 27 May 2023