Automatic relative humidity optimization in underground heritage sites through ventilation system based on digital twins

Underground heritage sites generally experience significant humidity, which results in the destruction of the surfaces and structures. This study establishes an underground heritage site preservation mechanism through a dynamic ventilation system based on digital twin technology. The aim is to contr...

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Bibliographic Details
Published in:Building and environment 2022-05, Vol.216, p.108999, Article 108999
Main Authors: Zhang, Jiaying, Kwok, Helen H.L., Luo, Han, Tong, Jimmy C.K., Cheng, Jack C.P.
Format: Article
Language:English
Subjects:
Automatic ventilation system
Building management systems
Computational fluid dynamics
Computer applications
Digital twins
Dynamic ventilation
Energy consumption
Fluid dynamics
HBIM
Historic sites
Historical buildings
Humidity
Hydrodynamics
Internet of Things
Mathematical models
Optimization
Preservation
Relative humidity
Technology
Underground heritage sites
Underground structures
Ventilation
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Summary:Underground heritage sites generally experience significant humidity, which results in the destruction of the surfaces and structures. This study establishes an underground heritage site preservation mechanism through a dynamic ventilation system based on digital twin technology. The aim is to control the relative humidity (RH) gradually on the air region near the walls of sites within the standard range and reduce adverse physical equipment effects and energy consumption of the system. Underground heritage site projects have more complex shapes with irregular and nonlinear arcs and height difference distributions. It is challenging to regenerate them. To achieve this objective, a model simplification rule for irregular heritage building information modeling (HBIM) technology was first established via computational fluid dynamics (CFD) simulation. Second, a methodology was developed to design a reliable and effective ventilation equipment and its layout based on CFD for irregular heritage sites. Compared with the scheme based on the optimal geometric rule arrangement, the number of pipes can be reduced by up to 25%. Third, a web-based digital twin platform combined with Internet of Things (IoTs) technology was established for achieving real-time control of the overall RH level of underground heritage sites within the standard range. The results present new solutions to control the RH of underground heritage sites for preservation. The proposed methodology can be used in typical underground heritage sites and illustrated by a real case. The validation encompassed development of digital environment for the real case and development of the ventilation system for its RH optimization. •A model simplification and mesh generation rule was generated for irregular HBIM.•A ventilation pipe layout design methodology based on CFD can save 25% pipe equipment.•An automatic ventilation system based on IoTs and digital twin platform was proposed.•A digital-twin based RH control solution for underground heritage sites preservation.•The methodology was verified in a-thousand-year-old underground heritage site.
ISSN:0360-1323
1873-684X
DOI:10.1016/j.buildenv.2022.108999