Thermal Analysis of a Raft Concrete Foundation: A Case Study of a Leaking Ethane Tank

This article presents a case study on the thermal assessment of a reinforced concrete (RC) foundation exposed to low temperatures. The foundation supports a 19,500 m3-capacity tank with low-temperature (−89 °C) ethane. Icing and bubbling were observed on the tank’s surface soon after it started oper...

Full description

Saved in:
Bibliographic Details
Published inBuildings (Basel) Vol. 12; no. 7; p. 889
Main Authors Wattanapanich, Chirawat, Imjai, Thanongsak, Aosai, Pakjira, Hansapinyo, Chayanon, Figueiredo, Fabio P., Garcia, Reyes
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.07.2022
Subjects
Ambient temperature
Case studies
Concrete
Concrete slabs
Ethane
finite element modelling
Forensic engineering
Forensic science
Gases
Heat transfer
Inspections
Leakage
Low temperature
Porous media
Quality control
raft foundation
Rebar
Reinforced concrete
Slabs
Structural integrity
temperature effects
Thermal analysis
Thailand
Online AccessGet full text

Cover

More Information
Summary:This article presents a case study on the thermal assessment of a reinforced concrete (RC) foundation exposed to low temperatures. The foundation supports a 19,500 m3-capacity tank with low-temperature (−89 °C) ethane. Icing and bubbling were observed on the tank’s surface soon after it started operations. Condensation was also observed at the bottom of the 0.8-m-depth RC slab, which raised concerns about the structural condition of the concrete. This study provides details of the field and analytical investigations conducted to assess the structural condition of the foundation. Heat transfer finite element (FE) analyses were performed to examine the concrete sections subjected to low temperatures. It was found that the ethane leakage produced a low temperature on the top side of the concrete foundation of +9.7 °C. Overall, the temperatures calculated by the FE analyses were in good agreement with actual field measurements, within a ±5% accuracy. The simplified heat transfer equation for porous media used in this study was sufficiently accurate to model the effects of the ethane leakage in the concrete foundation, provided that the ambient temperature at the site is taken into account in the analysis. The results also confirm that reinforcing bars can be neglected in the thermal analysis of massive concrete slabs. The results from the field measurements and FE analyses confirmed that the structural integrity of the RC foundation was never compromised. The approaches, methods and techniques discussed in this article are deemed suitable to solve the practical and scientific challenges involved in the thermal assessment and repairs of large special structures. Accordingly, they can serve as useful reference and guidance for engineers and practitioners working in the field of forensic engineering.
ISSN:2075-5309
2075-5309
DOI:10.3390/buildings12070889