Abstract
The massive amount of data generated by structural health monitoring (SHM) systems usually affects the system’s capacity for data transmission and analysis. This paper proposes a novel concept based on the probability theory for data reduction in SHM systems. The beauty salient feature of the proposed method is that it alleviates the burden of collecting and analysis of the entire strain data via a relative damage approach. In this methodology, the rate of variation of strain distributions is related to the rate of damage. In order to verify the accuracy of the approach, experimental and numerical studies were conducted on a thin steel plate subjected to cyclic in-plane tension loading. Circular holes with various sizes were made on the plate to define damage states. Rather than measuring the entire strain response, the cumulative durations of strain events at different predefined strain levels were obtained for each damage scenario. Then, the distribution of the calculated cumulative times was used to detect the damage progression. The results show that the presented technique can efficiently detect the damage progression. The damage detection accuracy can be improved by increasing the predefined strain levels. The proposed concept can lead to over 2500% reduction in data storage requirement, which can be particularly important for data generation and data handling in on-line SHM systems.
Highlights
Structural health monitoring (SHM) is an emerging field which has received notable attention in recent years
The overarching goal in this study is to develop a generic data reduction method for SHM systems that rely on strain data collected by conventional strain gauges
A new data reduction procedure has been proposed for the SHM systems
Summary
Structural health monitoring (SHM) is an emerging field which has received notable attention in recent years. The goal of SHM is to monitor the integrity of structures [1,2,3,4]. Strain gauges have been widely used in the fields of civil, mechanical and aerospace engineering to monitor the health status of structural systems. Wu et al [5] developed damage identification method for concrete continuous girder bridges based on spatially-distributed long-gauge strain sensing. Designed a low-cost graphite-based strain sensors that could be arranged in the form of an array. Nie et al [8] developed a simple-structured and low-cost grapheneon flexible strain gauge which can detect different strain levels of structural variation
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