Temperature and Strain Measurements With Fiber Bragg Gratings Embedded in Stainless Steel 316

Havermann, Dirk; Mathew, Jinesh; MacPherson, William N.; Maier, Robert R. J.; Hand, Duncan Paul

doi:10.1109/jlt.2014.2366835

Cited by 71 publications

(40 citation statements)

References 12 publications

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“…This occurs in order to achieve reliable bonding between glass and metal, in addition to allowing to electroplate nickel coating on the metallic films as a protective layer. After that, the metal-coated RFBGs are embedded into the metallic substrate of a high melting temperature by using brazing [16], ultrasonic consolidation [22], laser additive manufacturing [19,23], or nickel electroplating [17,21]. Careful selection of the packaging materials and processes is critical to ensure the long-term survivability of the package itself under high temperatures, and to achieve a strong and reliable glass-to-metal bond without mechanical or thermal damage.…”

Section: Introductionmentioning

confidence: 99%

An Improved Metal-Packaged Strain Sensor Based on A Regenerated Fiber Bragg Grating in Hydrogen-Loaded Boron–Germanium Co-Doped Photosensitive Fiber for High-Temperature Applications

Zhou

et al. 2017

Sensors

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Local strain measurements are considered as an effective method for structural health monitoring of high-temperature components, which require accurate, reliable and durable sensors. To develop strain sensors that can be used in higher temperature environments, an improved metal-packaged strain sensor based on a regenerated fiber Bragg grating (RFBG) fabricated in hydrogen (H2)-loaded boron–germanium (B–Ge) co-doped photosensitive fiber is developed using the process of combining magnetron sputtering and electroplating, addressing the limitation of mechanical strength degradation of silica optical fibers after annealing at a high temperature for regeneration. The regeneration characteristics of the RFBGs and the strain characteristics of the sensor are evaluated. Numerical simulation of the sensor is conducted using a three-dimensional finite element model. Anomalous decay behavior of two regeneration regimes is observed for the FBGs written in H2-loaded B–Ge co-doped fiber. The strain sensor exhibits good linearity, stability and repeatability when exposed to constant high temperatures of up to 540 °C. A satisfactory agreement is obtained between the experimental and numerical results in strain sensitivity. The results demonstrate that the improved metal-packaged strain sensors based on RFBGs in H2-loaded B–Ge co-doped fiber provide great potential for high-temperature applications by addressing the issues of mechanical integrity and packaging.

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Section: Introductionmentioning

confidence: 99%

An Improved Metal-Packaged Strain Sensor Based on A Regenerated Fiber Bragg Grating in Hydrogen-Loaded Boron–Germanium Co-Doped Photosensitive Fiber for High-Temperature Applications

Zhou

et al. 2017

Sensors

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“…Such a coating mechanically protects the fiber from the high temperatures and mechanical loads experienced during the embedding process [4]. In addition, they affect the bonding to the metal, which can be compromised by slippage or delamination [5], [6]. The earliest solutions presented for embedding FOS into metals were based on deposition techniques.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Fiber Optic Sensor Embedded in Metals by Automatic and Manual TIG Welding

Grandal¹,

Zornoza

López³

et al. 2019

IEEE Sensors J.

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In this paper, the embedding of fiber optic sensors in metals, by using both automatic and manual Tungsten Inert Gas welding (TIG) is discussed for nickel-and copper-coated Fiber Bragg Gratings (FBG) written into an optical fiber, as embedding such sensors in metals provides protection against environmental effects. In the investigation and analysis of the performance of a number of such sensors, copper-coated sensors were seen to lose their temperature and strain sensitivity while being embedded due to damage to the coating, while with a nickel coating the sensors in the fiber were found to withstand the process with a lesser effect on the sensor performance. The research has also shown that the Automatic TIG process used is less invasive than the manual TIG approach, although more expensive to implement.

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“…Additive manufacturing involves building up structures layer by layer and it opens up the prospect of incorporating valuable internal features into parts during their manufacture and one of the possibilities enabled by this technology is the embedment of components during their construction [6]. Recent studies on the temperature characteristics of an embedded FBG in a metallic structure show that due to the mismatch of the coefficient of thermal expansion (CTE) between silica and the host metal, the differential strain at elevated temperatures can lead to delamination and fiber breakage [6][7][8][9][10], thus limiting the application of such direct fiber embedded sensors to ~450°C.…”

Section: Introductionmentioning

confidence: 99%

Stainless steel component with compressed fiber Bragg grating for high temperature sensing applications

et al. 2016

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A smart metal component having the potential for high temperature strain sensing capability is reported. The stainless steel (SS316) structure is made by selective laser melting (SLM). A fiber Bragg grating (FBG) is embedded in to a 3D printed U-groove by high temperature brazing using a silver based alloy, achieving an axial FBG compression of 13 millistrain at room temperature. Initial results shows that the test component can be used for up to 700°C for sensing applications.

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Temperature and Strain Measurements With Fiber Bragg Gratings Embedded in Stainless Steel 316

Cited by 71 publications

References 12 publications

An Improved Metal-Packaged Strain Sensor Based on A Regenerated Fiber Bragg Grating in Hydrogen-Loaded Boron–Germanium Co-Doped Photosensitive Fiber for High-Temperature Applications

An Improved Metal-Packaged Strain Sensor Based on A Regenerated Fiber Bragg Grating in Hydrogen-Loaded Boron–Germanium Co-Doped Photosensitive Fiber for High-Temperature Applications

Analysis of Fiber Optic Sensor Embedded in Metals by Automatic and Manual TIG Welding

Stainless steel component with compressed fiber Bragg grating for high temperature sensing applications

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