The design and development of a side wall wind tunnel balance using fibre optic Bragg grating sensors
- Authors: Vaz, Nuno Figueira
- Date: 2018
- Subjects: Wind tunnel balances , Bragg gratings , Optical fiber detectors , Strain gages
- Language: English
- Type: Masters (Thesis)
- Identifier: http://hdl.handle.net/10210/284102 , uj:30671
- Description: M.Ing. (Mechanical Engineering) , Abstract: The requirements that a wind tunnel balance needs to satisfy have become increasingly stringent. These requirements, as set out by the wind tunnel testing community at large, include: improved static force accuracy, improved resolution, increased stiffness, temperature compensation and immunity to electromagnetic interference (EMI). In order to satisfy these requirements, wind tunnel balance design philosophy needs to be expanded to include employing alternative strain sensing technologies and alternative manufacturing techniques. This study sets to investigate the design and development of a six component side wall balance using optical fibre Bragg grating sensors (OFBGs). This is done in an attempt to address these stringent requirements by expand on traditional balance design philosophy by determine the viability of using OFBGs in wind tunnel balances. Traditional strain gauge side wall balances (SWB) fundamentally rely on measuring strain, being induced by an applied load, on a balance. For this reasons, the regions of the balance which are intended to be gauged are intentionally made thin. This is done to achieve a high strain gauge output. This however compromises balance stiffness and induces a high level of stress in the balance material at the gauged regions. In order to employ OFBGs on a SWB, the two groove strain sensing method must be employed. The basic working principles of this method is that an optical fibre is spanned between two points across a groove. As a load is applied, the groove deforms. This deformation (displacement) of the groove induces a strain into the optical fibre spanning the groove and a shift in the Bragg grating wavelength. Therefore the design of this SWB is fundamentally based on measuring the displacement between points. Based on these fundamentals, several design iterations were generated and analysed using FEM. The selected design underwent an iterative refinement process, aimed at optimising the design. This balance was manufactured and gauged with OFBGs. The manufactured balance was calibrated at the Counsel for Scientific and Industrial Research (CSIR) wind tunnel testing division in Pretoria, South Africa. The balance was evaluated based on uncertainty, hysteresis and interactions and repeatability...
- Full Text:
- Authors: Vaz, Nuno Figueira
- Date: 2018
- Subjects: Wind tunnel balances , Bragg gratings , Optical fiber detectors , Strain gages
- Language: English
- Type: Masters (Thesis)
- Identifier: http://hdl.handle.net/10210/284102 , uj:30671
- Description: M.Ing. (Mechanical Engineering) , Abstract: The requirements that a wind tunnel balance needs to satisfy have become increasingly stringent. These requirements, as set out by the wind tunnel testing community at large, include: improved static force accuracy, improved resolution, increased stiffness, temperature compensation and immunity to electromagnetic interference (EMI). In order to satisfy these requirements, wind tunnel balance design philosophy needs to be expanded to include employing alternative strain sensing technologies and alternative manufacturing techniques. This study sets to investigate the design and development of a six component side wall balance using optical fibre Bragg grating sensors (OFBGs). This is done in an attempt to address these stringent requirements by expand on traditional balance design philosophy by determine the viability of using OFBGs in wind tunnel balances. Traditional strain gauge side wall balances (SWB) fundamentally rely on measuring strain, being induced by an applied load, on a balance. For this reasons, the regions of the balance which are intended to be gauged are intentionally made thin. This is done to achieve a high strain gauge output. This however compromises balance stiffness and induces a high level of stress in the balance material at the gauged regions. In order to employ OFBGs on a SWB, the two groove strain sensing method must be employed. The basic working principles of this method is that an optical fibre is spanned between two points across a groove. As a load is applied, the groove deforms. This deformation (displacement) of the groove induces a strain into the optical fibre spanning the groove and a shift in the Bragg grating wavelength. Therefore the design of this SWB is fundamentally based on measuring the displacement between points. Based on these fundamentals, several design iterations were generated and analysed using FEM. The selected design underwent an iterative refinement process, aimed at optimising the design. This balance was manufactured and gauged with OFBGs. The manufactured balance was calibrated at the Counsel for Scientific and Industrial Research (CSIR) wind tunnel testing division in Pretoria, South Africa. The balance was evaluated based on uncertainty, hysteresis and interactions and repeatability...
- Full Text:
Stabilised C-band dual wavelength erbium doped fibre ring laser
- Authors: Mthukwane, Clarence Modise
- Date: 2018
- Subjects: Optical fibers , Lasers - Industrial applications , Optical amplifiers , Bragg gratings , Erbium
- Language: English
- Type: Masters (Thesis)
- Identifier: http://hdl.handle.net/10210/280397 , uj:30130
- Description: M.Ing. (Electrical Engineering) , Abstract: In this dissertation, the realisation of a dual wavelength erbium doped fibre ring cavity laser configuration is discussed. The power stability and wavelength stability of a dual wavelength erbium doped fibre laser is investigated. The lasing wavelengths of the fibre laser are 1555.12 nm and 1560.32 nm. The laser is based on a ring cavity resonator which employs a 3 dB coupler and fibre Bragg gratings, as the wavelength selective component arrangement. The active medium in the cavity is a 3.2 m long erbium doped fibre with an absorption of 11.38 dB/m at 980 nm. To achieve simultaneous dual wavelength lasing with an erbium doped fibre laser configuration, there is one major challenge that must be overcome. The challenge is to correct the cavity losses on the selected wavelengths to achieve oscillation for all desired channels. In addition, because of the unevenness of the EDF gain profile, the threshold power for individual wavelengths is different. Subsequently, loss control across each of the selected wavelengths is required to balance the power difference between the wavelengths. The power and wavelength stability of the dual lasing wavelengths is investigated using an optical loop mirror with a 1 m length of single-mode fibre, and an unpumped erbium doped fibre of length 0.5 m, 1 m and 1.5 m. Also, the effect of changing the cavity length on the uniformity of the wavelength power increase relative to an increase in pump power together with the power and spectral stability of the lasing wavelengths is investigated. A 1m long Sagnac loop with a 70:30 coupling ratio was used to adjust the threshold power for simultaneous lasing of the two wavelengths. An increase in cavity length led to a good prospect for a stable dual wavelength laser with an output power difference of 0.4 dBm between the dual wavelengths and a power stability of 0.4 dB. The multi-wavelength and narrow spectral width of 0.19 nm and 0.20 nm of the laser can be used for dispersion measurement in wavelength division multiplexed communication links which consist of more than one wavelength. The laser was characterised for simultaneous dual wavelength output power response and power stability. The project presents the characterisation of an erbium doped fibre ring laser. The laser is cost effective and flexible in selecting preferred components for optimal performance in terms of power and wavelength stability, wavelength selectivity and narrow spectral width. Erbium doped fibre ring laser lasers are commercially available and are showing great promise in terms of their formidability and compatibility with current industrial requirements.
- Full Text:
- Authors: Mthukwane, Clarence Modise
- Date: 2018
- Subjects: Optical fibers , Lasers - Industrial applications , Optical amplifiers , Bragg gratings , Erbium
- Language: English
- Type: Masters (Thesis)
- Identifier: http://hdl.handle.net/10210/280397 , uj:30130
- Description: M.Ing. (Electrical Engineering) , Abstract: In this dissertation, the realisation of a dual wavelength erbium doped fibre ring cavity laser configuration is discussed. The power stability and wavelength stability of a dual wavelength erbium doped fibre laser is investigated. The lasing wavelengths of the fibre laser are 1555.12 nm and 1560.32 nm. The laser is based on a ring cavity resonator which employs a 3 dB coupler and fibre Bragg gratings, as the wavelength selective component arrangement. The active medium in the cavity is a 3.2 m long erbium doped fibre with an absorption of 11.38 dB/m at 980 nm. To achieve simultaneous dual wavelength lasing with an erbium doped fibre laser configuration, there is one major challenge that must be overcome. The challenge is to correct the cavity losses on the selected wavelengths to achieve oscillation for all desired channels. In addition, because of the unevenness of the EDF gain profile, the threshold power for individual wavelengths is different. Subsequently, loss control across each of the selected wavelengths is required to balance the power difference between the wavelengths. The power and wavelength stability of the dual lasing wavelengths is investigated using an optical loop mirror with a 1 m length of single-mode fibre, and an unpumped erbium doped fibre of length 0.5 m, 1 m and 1.5 m. Also, the effect of changing the cavity length on the uniformity of the wavelength power increase relative to an increase in pump power together with the power and spectral stability of the lasing wavelengths is investigated. A 1m long Sagnac loop with a 70:30 coupling ratio was used to adjust the threshold power for simultaneous lasing of the two wavelengths. An increase in cavity length led to a good prospect for a stable dual wavelength laser with an output power difference of 0.4 dBm between the dual wavelengths and a power stability of 0.4 dB. The multi-wavelength and narrow spectral width of 0.19 nm and 0.20 nm of the laser can be used for dispersion measurement in wavelength division multiplexed communication links which consist of more than one wavelength. The laser was characterised for simultaneous dual wavelength output power response and power stability. The project presents the characterisation of an erbium doped fibre ring laser. The laser is cost effective and flexible in selecting preferred components for optimal performance in terms of power and wavelength stability, wavelength selectivity and narrow spectral width. Erbium doped fibre ring laser lasers are commercially available and are showing great promise in terms of their formidability and compatibility with current industrial requirements.
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