A Non-contact approach for cable tension evaluation based on 3D laser scanning data and nonlinear finite element analysis

•This paper presents a non-contact approach for a large-scale cable tension evaluation.•The presented non-contact approach is based on 3D laser scanning data.•An actual case study of the long-span roof cable of a big exhibition center in Thailand is performed to show the effectiveness of the present...

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Bibliographic Details
Published in:Measurement : journal of the International Measurement Confederation 2023-05, Vol.212, p.112680, Article 112680
Main Authors: Srimontriphakdi, Thaniyaphat, Mahasuwanchai, Peerasit, Athisakul, Chainarong, Leelataviwat, Sutat, Klaycham, Karun, Poovarodom, Nakhorn, Magteppong, Nuttaphon, Chucheepsakul, Somchai
Format: Article
Language:English
Subjects:
3D laser scan
Cable tension evaluation
Non-contact approach
Nonlinear finite element
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Summary:•This paper presents a non-contact approach for a large-scale cable tension evaluation.•The presented non-contact approach is based on 3D laser scanning data.•An actual case study of the long-span roof cable of a big exhibition center in Thailand is performed to show the effectiveness of the presented approach.•The presented non-contact approach yields satisfactory results compared with a conventional method by measuring the cable’s natural frequency. This study proposes a non-contact approach for tension evaluation of a large-scale cable-stayed roof. Three-dimensional (3D) laser scanning data based on a terrestrial laser scanner are utilized to explore the current cable configuration in 3D. Subsequent analysis of the exact current cable configuration indicates that the cable tension can be evaluated by minimizing the cable configuration error. The precise cable tension, which correlates with the actual cable configuration, is determined using nonlinear finite element analysis which is based on a model formulation that considers the effect of bending rigidity. The proposed method is verified by experimental studies. A case study is performed of the long-span roof cable of a large exhibition center in Thailand to demonstrate the effectiveness of this approach in comparison with the natural frequency measurement-based method. The results show that the proposed method is an alternative non-contact approach for evaluating cable tension with reasonable accuracy.
ISSN:0263-2241
1873-412X
DOI:10.1016/j.measurement.2023.112680