Insight into the nondestructive performance evaluation of fiber‐reinforced polymer composite laminate immersed in produced water using embedded fiber Bragg grating sensor

Mohanta, Santoshi; Padarthi, Yashwanth; Gupta, Jeetendra Kumar; Neogi, Sudarsan

doi:10.1002/pc.26181

Cited by 4 publications

(4 citation statements)

References 29 publications

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“…There are many types of FOS, fiber Bragg gratings (FBG), being one of them, have found extensive use in literature for strain monitoring and are therefore selected for the present research. Recently, embedded FBG sensors have shown the capability to measure strain developed by hygroscopic aging, [38] environmental effects on strain can therefore also be monitored. Regarding SHM, studies found in literature [39,40] can be used for validating the results.…”

Section: Non-destructive Techniquesmentioning

confidence: 99%

In‐line residual strain monitoring for thermoplastic automated tape layup using fiber Bragg grating sensors

et al. 2022

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Automated tape layup (ATL) has been used extensively for manufacturing composites laminates using unidirectional prepregs for high‐performance industries like aerospace. Residual stress is one of the defects that adversely affect the layup quality. These stresses affect geometrical tolerances in the form of distortion of the final product and are found to have a detrimental impact on the mechanical properties. In‐line monitoring of such defects will help in productivity increase and achieving a reliable process control. The aim of the present work is to demonstrate the feasibility of fiber Bragg grating sensors for monitoring residual strains. FBGs are embedded inside a thermoplastic UD laminate. Temperature and strain discrimination is performed to recognize intermittent residual strains during the layup. Finally, intermittent residual strain is used to develop an understanding of the global residual strain. Effect of selective process parameter on residual stress formation and the evolution of the same is also analyzed.

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Section: Non-destructive Techniquesmentioning

confidence: 99%

In‐line residual strain monitoring for thermoplastic automated tape layup using fiber Bragg grating sensors

et al. 2022

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“…Fiber Bragg Grating (FBG) sensors, known for their small size and weight, immunity to electromagnetic interference, and resistance to corrosion, 2,3 are one of the preferred sensors used in smart composites. [4][5][6][7][8][9][10] Figure 1 presents one instance of the potential application of smart composites embedded with FBG sensors used in the intelligent wing skin, which enables online monitoring of deformation and damage. 11 In addition, FBG sensors are also increasingly applied in the space domain.…”

Section: Introductionmentioning

confidence: 99%

“…With the application of these smart composites, real‐time monitoring of the health state of aircraft can be achieved, leading to its enhanced safety and reliability. Fiber Bragg Grating (FBG) sensors, known for their small size and weight, immunity to electromagnetic interference, and resistance to corrosion, 2,3 are one of the preferred sensors used in smart composites 4–10 . Figure 1 presents one instance of the potential application of smart composites embedded with FBG sensors used in the intelligent wing skin, which enables online monitoring of deformation and damage 11 …”

Section: Introductionmentioning

confidence: 99%

Influence of processing parameters on the resin pocket geometry of smart composites embedded with Fiber Bragg Grating sensor and its fast prediction

Zhao,

Zhang,

Liu

et al. 2024

Polymer Composites

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Smart composites embedded with Fiber Bragg Grating (FBG) sensors are getting increasingly popular in aircraft structures due to their self‐sensing and monitoring capability. However, a resin pocket around the FBG sensor would be formed in the manufacturing process, which strongly impacts the mechanical properties of the composite host. Therefore, the influence of primary processing parameters (FBG orientation angle, preforming temperature, and preforming pressure) on the formation of resin pockets was investigated in this work. It is found that there is a sinusoidal relation between the resin pocket geometry and the FBG orientation angle. A negative linear relation is noted between the resin pocket geometry and the preforming temperature and pressure. A prediction model based on the backpropagation neural network (BPNN) was established, which was able to quickly and accurately predict resin pocket geometry subjected to given processing parameters. This work provides useful guidance for the processing control of smart composites embedded with FBG sensors.Highlights Resin pocket geometry was formed primarily in the preforming stage. Effect of processing parameters on resin pocket geometry was characterized. A BPNN model was established for the fast prediction of resin pocket geometry.

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“…Similarly, in another study, FBG sensors monitor the health of a composite structure bonded on the metallic substrate. [ 20 ] Mohanta et al [ 21 ] used an embedded FBG sensor to monitor the long‐term degradation of epoxy–glass composite in corrosive water. It is found that the long‐term stability can be effectively monitored by tracking the hygrothermal strain developed on the specimens immersed in corrosive produced waters.…”

Section: Introductionmentioning

confidence: 99%

Monitoring and verification of micro‐strain generated inside the laminate subjected to thermal loading through fiber bragg grating sensors and classical laminate theory

2023

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Fiber Bragg Grating (FBG) sensors possess enormous potential for the cure monitoring and integrity assessment of Carbon Fiber Reinforced Polymer (CFRP) composites. These sensors can be embedded inside the structure to monitor the strain in the desired region of interest. The strain on an FBG sensor can be calculated by measuring the change in the center wavelength of the sensor. This change in center wavelength is a function of temperature and mechanical strain. Therefore, temperature compensation is necessary for a precise mechanical strain measurement with an FBG sensor. In this study, FBG sensors are embedded in different layers of the CFRP laminate to record the mechanical strain caused by the thermal expansion, which happens under the influence of temperature. Classical laminate theory (CLT) is implemented to assess the accuracy of FBG sensor measurements and the strain data acquired from both FBG sensor and CLT correlates. Furthermore, a resistive strain gauge is deployed to measure the strain under the influence of temperature. It is depicted that strain values recorded by the strain gauge under the influence of the temperature do not agree with the strain measured by CLT, and an error of 150% occurs among their values.

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Insight into the nondestructive performance evaluation of fiber‐reinforced polymer composite laminate immersed in produced water using embedded fiber Bragg grating sensor

Cited by 4 publications

References 29 publications

In‐line residual strain monitoring for thermoplastic automated tape layup using fiber Bragg grating sensors

In‐line residual strain monitoring for thermoplastic automated tape layup using fiber Bragg grating sensors

Influence of processing parameters on the resin pocket geometry of smart composites embedded with Fiber Bragg Grating sensor and its fast prediction

Monitoring and verification of micro‐strain generated inside the laminate subjected to thermal loading through fiber bragg grating sensors and classical laminate theory

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