Standard Standard

A low-cost, high-fidelity converging-beam Doppler instrument for measuring velocity and turbulence at tidal energy sites. / Lake, Thomas; Glasby, David; Horrillo-Caraballo, Jose et al.
In: International Marine Energy Journal, Vol. 7, No. 1, 31.07.2024, p. 11-24.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Lake, T, Glasby, D, Horrillo-Caraballo, J, Togneri, M, Masters, I, Austin, M & Lincoln, B 2024, 'A low-cost, high-fidelity converging-beam Doppler instrument for measuring velocity and turbulence at tidal energy sites', International Marine Energy Journal, vol. 7, no. 1, pp. 11-24. https://doi.org/10.36688/imej.7.11-24

APA

Lake, T., Glasby, D., Horrillo-Caraballo, J., Togneri, M., Masters, I., Austin, M., & Lincoln, B. (2024). A low-cost, high-fidelity converging-beam Doppler instrument for measuring velocity and turbulence at tidal energy sites. International Marine Energy Journal, 7(1), 11-24. https://doi.org/10.36688/imej.7.11-24

CBE

Lake T, Glasby D, Horrillo-Caraballo J, Togneri M, Masters I, Austin M, Lincoln B. 2024. A low-cost, high-fidelity converging-beam Doppler instrument for measuring velocity and turbulence at tidal energy sites. International Marine Energy Journal. 7(1):11-24. https://doi.org/10.36688/imej.7.11-24

MLA

VancouverVancouver

Lake T, Glasby D, Horrillo-Caraballo J, Togneri M, Masters I, Austin M et al. A low-cost, high-fidelity converging-beam Doppler instrument for measuring velocity and turbulence at tidal energy sites. International Marine Energy Journal. 2024 Jul 31;7(1):11-24. doi: 10.36688/imej.7.11-24

Author

Lake, Thomas ; Glasby, David ; Horrillo-Caraballo, Jose et al. / A low-cost, high-fidelity converging-beam Doppler instrument for measuring velocity and turbulence at tidal energy sites. In: International Marine Energy Journal. 2024 ; Vol. 7, No. 1. pp. 11-24.

RIS

TY - JOUR

T1 - A low-cost, high-fidelity converging-beam Doppler instrument for measuring velocity and turbulence at tidal energy sites

AU - Lake, Thomas

AU - Glasby, David

AU - Horrillo-Caraballo, Jose

AU - Togneri, Michael

AU - Masters, Ian

AU - Austin, Martin

AU - Lincoln, Ben

PY - 2024/7/31

Y1 - 2024/7/31

N2 - Abstract—Traditional Acoustic Doppler Current Profiler (ADCP) instruments measure marine flow velocities along diverging acoustic beams. This allows estimation of ap- proximate mean velocity and turbulence at a point between the beams. Alternatively, a converging beam instrument can measure velocity components at a single point and hence provide a higher quality measurement. Here we show a new design of instrument with converging beams together with some preliminary flow measurement results.The instrument is constructed around a triangular frame with Doppler transceivers on the ends of cable stayed arms. It is designed to be installed and recovered from the seabed without use of a crane vessel. This is achieved by a pressurised air buoyancy system. The system can be slipway launched with a boat trailer and flat packed for transport on the same trailer. The system performed well for three test deployments; however, measurements of the seabed stability of the frame showed undesirable flexing of one arm when it was positioned perpendicular to the main flow direction.A traditional ADCP was located on the frame and the two instruments were operated in burst mode, with each instrument measuring alternately every 20 minutes. Results for velocity and turbulent kinetic energy at the same depth are reported for both instruments and compared. A 2D oceanographic model of the deployment site is used as an additional point of comparison to illuminate some differences in the mean flow velocity observations of both instruments.This instrument will add significantly to measurement capabilities at tidal stream turbine deployment locations. Improved turbulence measurements will give better under- standing of turbine loading and hence improve reliability

AB - Abstract—Traditional Acoustic Doppler Current Profiler (ADCP) instruments measure marine flow velocities along diverging acoustic beams. This allows estimation of ap- proximate mean velocity and turbulence at a point between the beams. Alternatively, a converging beam instrument can measure velocity components at a single point and hence provide a higher quality measurement. Here we show a new design of instrument with converging beams together with some preliminary flow measurement results.The instrument is constructed around a triangular frame with Doppler transceivers on the ends of cable stayed arms. It is designed to be installed and recovered from the seabed without use of a crane vessel. This is achieved by a pressurised air buoyancy system. The system can be slipway launched with a boat trailer and flat packed for transport on the same trailer. The system performed well for three test deployments; however, measurements of the seabed stability of the frame showed undesirable flexing of one arm when it was positioned perpendicular to the main flow direction.A traditional ADCP was located on the frame and the two instruments were operated in burst mode, with each instrument measuring alternately every 20 minutes. Results for velocity and turbulent kinetic energy at the same depth are reported for both instruments and compared. A 2D oceanographic model of the deployment site is used as an additional point of comparison to illuminate some differences in the mean flow velocity observations of both instruments.This instrument will add significantly to measurement capabilities at tidal stream turbine deployment locations. Improved turbulence measurements will give better under- standing of turbine loading and hence improve reliability

U2 - 10.36688/imej.7.11-24

DO - 10.36688/imej.7.11-24

M3 - Article

VL - 7

SP - 11

EP - 24

JO - International Marine Energy Journal

JF - International Marine Energy Journal

IS - 1

ER -