Abstract
In this paper, one advanced settlement sensor with the advantages of wide measurement range and multi-directional displacement measurement has been designed and fabricated based on multidisciplinary technologies, including fiber Bragg grating (FBG) sensing technology, 3D printing technology, and others. First, one novel structure of settlement sensor was designed by introducing the concept of a hinge joint, which mainly consists of four components, including internal rigid beam, external rigid beam, elastic FBG sensing beam, and hinge joint. The FBG sensing element inside the sensor can rotate unconstrained without disturbing stress field underground, overcoming the strengthening problem commonly existed in conventional settlement sensors. It is also worth noting that all sensor components were designed and fabricated with 3D printing technology, while the two most popular and effective 3D printing technologies, including fused deposition modeling (FDM) and stereolithography (SLA) technology were separately used for fabricating elastic sensing beam and rigid beam segments, respectively. Furthermore, the FBG sensors were successfully embedded into the printed polylactic acid (PLA) without sacrificing its sensing performance, and the superiority of FBG sensing technology, such as high sensitivity, high accuracy, strong resistance, light weight, and serial connection have been achieved. After completing the fabrication of developed sensor, the measurement performance parameters of elastic FBG sensing beam (includes two paralleled FBG sensors) including measuring linearity, repeatability, and measurement range have been calibrated and verified. Finally, working performance of the assembled settlement sensor from calibration was examined, characterized by a maximum measurement range -160 ~ +160, and a measurement sensitivity of 0.0066 pm/° (in terms of inclination degree) or 0.012 mm/pm (in terms of settlement).
Highlights
Fiber Bragg grating (FBG) is the most widely used method for monitoring strain and temperature of materials among varieties of monitoring technologies [1]–[4]
Assembling of the sensor includes (a) the inner rigid beam segment and external rigid beam segment are overlapped with the openings at their semicircular endings, (b) the elastic sensing beam is positioned inside the excavation region of the two rigid beam segments and fastened at two endings, and (c) the hinge joint connection is installed through the semicircular endings of external rigid beam, semicircular ending of internal rigid beam and elastic FBG sensing beam sequentially and symmetrically
In this study, in order to overcome some insufficiencies existing in present settlement sensors, such as influencing soil stress distribution, providing limited measuring range, facilitating monodirectional measuring and others, advanced FBG based settlement sensor characterized by large measurement range and measurement of multi-directional displacement has been developed
Summary
Fiber Bragg grating (FBG) is the most widely used method for monitoring strain and temperature of materials among varieties of monitoring technologies [1]–[4]. This sensing technology has many advantages, including high sensitivity, strong resistance to electromagnetic interference (EMI), good insulation, high insurance in harsh environment and small light structure. FBGs have been widely used in the field of civil engineering monitoring [2], [5]–[9]. In terms of monitoring settlement of a road embankment, researchers have proposed one method to embed FBG sensors in each structural layer of the road in order to realize real-time monitoring of settlement in entire road embankment [12]–[14].
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