Biaxial 3D-printed inclinometer based on Fiber Bragg Grating technology
Biaxial 3D-printed inclinometer based on Fiber Bragg Grating technology
A Fiber Bragg Grating (FBG)-based inclinometer has been developed for field use, designed to incorporate biaxial 3-dimensional (3D) printed tilt sensors (in which four FBGs were used). The inclinometer was characterized by examining its response to a wide range of tilts, over the range from 0° to 90°, towards the inclination axes. An excellent linear correlation between the wavelength shifts and the inclination angle (up to the 90° used) was obtained, showing an average sensitivity of 0.01 nm per degree of inclination angle, for each of the FBGs used. In addition to the four FBGs that form the basis of the inclination measurement, a further FBG was included in the design to allow compensation for any temperature changes experienced during the measurements. The device was calibrated over the range from -25°C to 80°C (corresponding to the extremes of cold and hot weather conditions likely to be experienced in-the-field), and a sensitivity to temperature change of 0.011nm/°C was achieved, allowing an effective temperature correction to be applied. The data obtained from a full characterization of the performance of the sensor system, carried out in a stable, controlled environment, indicate that this inclinometer yields good sensitivity, making it highly applicable for use in monitoring rapid ground movements and deformations with its compact design allowing its wide use.
3D-printing, biaxial measurements, fiber Bragg grating-based technology, ground movements, Inclinometer
18815-18822
Ismail, N.N.
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Sa'ad, M.S.M.
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Ismail, M. F.
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Zaini, M.K.A.
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Lim, K.S.
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Grattan, K.T.V.
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Brambilla, G.
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Rahman, B.M.A.
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Mohamad, H.
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Ahmad, Harith
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Ismail, N.N.
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Sa'ad, M.S.M.
08686d35-c75f-41ec-ac1d-98d958a3f37e
Ismail, M. F.
e05c5c4a-b671-4d65-b372-0f5836a7aa92
Zaini, M.K.A.
9490bb46-b873-4fcc-945c-92adb37baa5a
Lim, K.S.
506b68d5-3223-45e7-901d-384f32484d05
Grattan, K.T.V.
2c12919a-59bd-4427-96ef-4d8c685c9893
Brambilla, G.
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Rahman, B.M.A.
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Mohamad, H.
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Ahmad, Harith
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Ismail, N.N., Sa'ad, M.S.M., Ismail, M. F., Zaini, M.K.A., Lim, K.S., Grattan, K.T.V., Brambilla, G., Rahman, B.M.A., Mohamad, H. and Ahmad, Harith
(2021)
Biaxial 3D-printed inclinometer based on Fiber Bragg Grating technology.
IEEE Sensors Journal, 21 (17), , [9458311].
(doi:10.1109/JSEN.2021.3090105).
Abstract
A Fiber Bragg Grating (FBG)-based inclinometer has been developed for field use, designed to incorporate biaxial 3-dimensional (3D) printed tilt sensors (in which four FBGs were used). The inclinometer was characterized by examining its response to a wide range of tilts, over the range from 0° to 90°, towards the inclination axes. An excellent linear correlation between the wavelength shifts and the inclination angle (up to the 90° used) was obtained, showing an average sensitivity of 0.01 nm per degree of inclination angle, for each of the FBGs used. In addition to the four FBGs that form the basis of the inclination measurement, a further FBG was included in the design to allow compensation for any temperature changes experienced during the measurements. The device was calibrated over the range from -25°C to 80°C (corresponding to the extremes of cold and hot weather conditions likely to be experienced in-the-field), and a sensitivity to temperature change of 0.011nm/°C was achieved, allowing an effective temperature correction to be applied. The data obtained from a full characterization of the performance of the sensor system, carried out in a stable, controlled environment, indicate that this inclinometer yields good sensitivity, making it highly applicable for use in monitoring rapid ground movements and deformations with its compact design allowing its wide use.
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More information
e-pub ahead of print date: 1 September 2021
Additional Information:
Funding Information: This work was supported in part by the Newton Fund Impact Scheme through the Newton-Ungku Omar Fund Partnership under Grant IF022-2020, in part by the U.K. Department for Business, Energy and Industrial Strategy and Malaysian Industry-Government Group for High Technology (MIGHT) and delivered by the British Council and MIGHT, and in part by the University of Malaya under Grant RK021-2019 and Grant TOP100PRC. The work of K. T. V. Grattan was supported by the Royal Academy of Engineering. The associate editor coordinating the review of this article and approving it for publication was Prof. Agostino Iadicicco.
Keywords:
3D-printing, biaxial measurements, fiber Bragg grating-based technology, ground movements, Inclinometer
Identifiers
Local EPrints ID: 471052
URI: http://eprints.soton.ac.uk/id/eprint/471052
ISSN: 1530-437X
PURE UUID: b33ecd18-4317-4155-afa7-df73754fbde3
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Date deposited: 25 Oct 2022 16:35
Last modified: 18 Mar 2024 02:53
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Contributors
Author:
N.N. Ismail
Author:
M.S.M. Sa'ad
Author:
M. F. Ismail
Author:
M.K.A. Zaini
Author:
K.S. Lim
Author:
K.T.V. Grattan
Author:
B.M.A. Rahman
Author:
H. Mohamad
Author:
Harith Ahmad
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