Your search keyword '"Carwyn Frost"' showing total 17 results

1. A Linear hydrodynamic model of rotating lift-based wave energy converters

Author

Matt Folley, Paul Lamont-Kane, and Carwyn Frost

Subjects

design, Hydrodynamics, hydrofoil, Lift, Wave Energy Converter, Ocean engineering, TC1501-1800, Renewable energy sources, TJ807-830

Abstract

A linear potential flow model of a rotating lift-based wave energy converter is developed by assuming that the lift is generated by a pair of equal and opposite circulations and that the amplitude of motion is small. The linearisation of the hydrodynamics means that the forces can decomposed and expressions for the wave excitation force and radiation damping force are derived independently and shown to be related to each other through the Haskind Relations. The expressions for the forces are used to show that there is an optimum phase and product of circulation and radius of rotation to maximise the wave power extracted, which is equivalent to the optimum phase and amplitude of motion from ‘conventional’ wave energy converter theory. It is also shown that at this optimum condition 100% of the incident wave energy can be extracted. It is shown that the forces are directly proportional to the velocities due to the motion of the vortices, the water particle velocities due to the incident wave, and the water particle velocities induced by the vortices. The effect of the vortex-induced water particle velocities is considered and the importance of including these velocities on the passive generation of circulation, e.g. by hydrofoils, is highlighted. The impact of a sub-optimum product of circulation and radius of rotation is also investigated and shown that the power capture is not highly sensitive to the optimal conditions in the same way as ‘conventional’ wave energy converters

Published

2023

2. Review of experimental studies on Transverse Axis Crossflow Turbines

Author

Ronan Patrick Gallagher, Carwyn Frost, Pál Schmitt, and Charles Young

Subjects

experimental, blockage, solidity, tip speed ratio, transverse axis crossflow turbine, turbine performance, Ocean engineering, TC1501-1800, Renewable energy sources, TJ807-830

Abstract

Transverse Axis Crossflow Turbines (TACTs) are a niche subset of tidal turbines. TACTs are not as well understood as the more traditional horizontal axis turbine and associated flow theory which leans heavily on advances in wind energy and marine propulsion. This paper reviews laboratory and field based experimental fluid dynamics work from the perspective of turbine performance. The available literature deviates significantly in perspective and scope since it is found that not all papers declare a full complement of parameters, thereby making it difficult to check or validate the respective results. Therefore, identifying trends amongst the variable and sparse datasets is difficult. None of the papers reviewed cite adherence to the recommended tank testing guidelines. The work reviewed analyses aspects such as mounting supports, solidity, blockage and blade support locations in isolation, but the cumulative impact of these variables is unknown. Arising from the analyses carried out as part of this review, blade loading, solidity and blockage were identified as key parameters and are the subject of planned research. Trends between solidity and blockage with tip speed ratio were identified. This paper contributes to the understanding of TACT performance through the tidal turbine performance curve and highlights the need for comprehensive physical testing and model validation.

Published

2022

3. A comparison of platform and sea-bed mounted flow measurement instrumentation for SME PLAT-I

Author

Carwyn Frost, Michael Togneri, Penny Jeffcoate, Thomas Lake, Cuan Boake, Ralf Starzmann, and Alison Williams

Subjects

Acoustic Doppler Instrumentation, Tidal Resource Assessment, Turbulence, Tidal Stream Turbines, Device Deployment, Ocean engineering, TC1501-1800, Renewable energy sources, TJ807-830

Abstract

Tidal resource assessment for the characterisation of turbine performance or Annual Energy Prediction currently uses the method of bins as recommended by international standards. An alternative method is proposed in this paper and applied to the Sustainable Marine Energy PLAT-I deployment in Connel Sound, Scotland. This method may be suitable for tidal turbines which operate from the surface. Three instrumentation types are used in this work, a bed-mounted Acoustic Doppler Profiler (ADP), and platform-mounted Acoustic Doppler Velocimeter (ADV) and Electromagnetic Current Meter (ECM). By comparing the resource characteristics from these three sources, a comparison of their velocity magnitudes and turbulence characteristics is made, demonstrating the difference between methodologies. It was found that the ADP evaluated using the method of bins produced a more conservative velocity distribution, in comparison to the ADV and ECM. Consequently, a representative AEP showed a difference of 3.8kWh (50% of ADP total) for the month of data collected. When comparing the Turbulence Intensity between devices, the ADP and ECM had similar metrics whilst the ADV had up to 14% higher values. The significance of these differences requires further work comparing them to the SME PLAT-I turbines power output to ascertain which best represents the onset flow experienced by the turbine and if there is a correlation between power performance and turbulence intensity.

Published

2022

4. A Comparison of Tidal Turbine Characteristics Obtained from Field and Laboratory Testing

Author

Pál Schmitt, Song Fu, Ian Benson, Gavin Lavery, Stephanie Ordoñez-Sanchez, Carwyn Frost, Cameron Johnstone, and Louise Kregting

Subjects

tidal energy, field testing, tank testing, self propelled barge, prototype, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

Experimental testing of physical turbines, often at a smaller scale, is an essential tool for engineers to investigate fundamental design parameters such as power output and efficiency. Despite issues with scaling and blockage which are caused by limitations in size and flow velocity of the test facilities, experimental tank testing in laboratory environments is often perceived as offering more control and thus trustworthier results than field testing. This paper presents field tests of a tidal turbine, performed using a self-propelled barge in real tidal flow and still water conditions, that are compared to a towing tank test. Factors influencing the performance characteristics, such as the choice of velocity sensor, vessel handling and data processing techniques are investigated in this paper. Direct comparison with test results of the exact same turbine obtained in an experimental test facility further confirms that field testing with robust data analysis capabilities is a viable, time and cost efficient alternative to characterise tidal turbines.

Published

2022

5. Investigation of the Error of Mean Representative Current Velocity Based on the Method of Bins for Tidal Turbines Using ADP Data

Author

Udara Rathnayake, Matt Folley, S.D.G.S.P. Gunawardane, and Carwyn Frost

Subjects

currents, turbulence, uncertainty, acoustic Doppler Profiler, tilt, Doppler noise, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

Representing the velocity at a tidal energy extraction site in a standardized manner is essential for the development of the tidal energy sector. The International Electrotechnical Commission (IEC) have issued a technical specification to determine the mean representative current velocity (MRV) relative to a tidal energy converter (TEC). This method determines the MRV using an acoustic Doppler profiler (ADP). This is used to evaluate the power performance of a TEC and so can have a significant influence on the power performance uncertainties, due to the cubed relationship of the MRV and power. This paper investigates these uncertainties in the MRV by considering four sources of uncertainty in the ADP. These are turbulence intensity, tilt, Doppler noise and beam misalignment of an ADP. A synthetically generated dataset is used to define current velocity and profile using the characteristics of currents and ADP. The generated synthetic dataset is processed to calculate the MRV based on the standard IEC method. An alternative method to calculate the MRV, called the temporal-spatial method (TSM), is proposed and the two methodologies are used to assess the error of the MRV. A sensitivity analysis shows that the errors of the MRV based on the standard IEC method are always higher than the TSM. The biases in the MRV based on the different combinations of the uncertainty are investigated and it is found that the bias for the MRVs based on the TSM method is generally less than that of the IEC method.

Published

2020

6. The specification and testing of a Horizontal Axis Tidal Turbine Rotor Monitoring approach

Author

Matthew Allmark, Paul Prickett, Roger Grosvenor, and Carwyn Frost

Subjects

fault detection, Engineering machinery, tools, and implements, TA213-215, Systems engineering, TA168

Abstract

The sustainable deployment of Horizontal Axis Tidal Turbines will require effective management and maintenance functions. In part, these can be supported by the engineering of suitable condition monitoring systems. The development of such a system is inevitably challenging, particularly given the present limited level of operational data associated with installed turbines during fault onset. To mitigate this limitation, a computational fluid dynamics model is used to simulate the operational response of a turbine under a known set of fault conditions. Turbine rotor imbalance faults were simulated by the introduction of increasing levels of pitch angle offset for a single turbine blade. The effects of these fault cases upon cyclic variations in the torque developed by the turbine rotor were then used to aid creation of a condition monitoring approach. A parametric tidal turbine rotor model was developed based on the outputs of the computational fluid dynamics models. The model was used to facilitate testing of the condition monitoring approach under a variety of more realistic conditions. The condition monitoring approach showed good performance in fault detection and diagnosis for simulations relating to turbulence intensities of up to 2 %. Finally, the condition monitoring approach was applied to simulations of 10 % turbulence intensity. Under the 10 % turbulence intensity case the rotor monitoring approach was successfully demonstrated in its use for fault detection. The paper closes with discussion of the effectiveness of using computational fluid dynamics simulations extended by parametric models to develop condition monitoring systems for horizontal axis tidal turbine applications.

Published

2018

7. The Effect of Control Strategy on Tidal Stream Turbine Performance in Laboratory and Field Experiments

Author

Carwyn Frost, Ian Benson, Penny Jeffcoate, Björn Elsäßer, and Trevor Whittaker

Subjects

tidal energy, experimental testing, acoustic Doppler profiler, Strangford Lough, Technology

Abstract

The first aim of the research presented here is to examine the effect of turbine control by comparing a passive open-loop control strategy with a constant rotational speed proportional–integral–derivative (PID) feedback loop control applied to the same experimental turbine. The second aim is to evaluate the effect of unsteady inflow on turbine performance by comparing results from a towing-tank, in the absence of turbulence, with results from the identical machine in a tidal test site. The results will also inform the reader of: (i) the challenges of testing tidal turbines in unsteady tidal flow conditions in comparison to the controlled laboratory environment; (ii) calibration of acoustic Doppler flow measurement instruments; (iii) characterising the inflow to a turbine and identifying the uncertainties from unsteady inflow conditions by adaptation of the International Electrotechnical Commission technical specification (IEC TS): 62600-200. The research shows that maintaining a constant rotational speed with a control strategy yields a 13.7% higher peak power performance curve in the unsteady flow environment, in comparison to an open-loop control strategy. The research also shows an 8.0% higher peak power performance in the lab compared to the field, demonstrating the effect of unsteady flow conditions on power performance. The research highlights the importance of a tidal turbines control strategy when designing experiments.

Published

2018

8. Investigation of the Error of Mean Representative Current Velocity Based on the Method of Bins for Tidal Turbines Using ADP Data

Author

S.D.G.S.P. Gunawardane, Carwyn Frost, Udara Rathnayake, and Matt Folley

Subjects

Doppler noise, 020209 energy, TEC, 020101 civil engineering, Ocean Engineering, 02 engineering and technology, acoustic Doppler Profiler, tilt, 0201 civil engineering, lcsh:Oceanography, symbols.namesake, lcsh:VM1-989, Currents, 0202 electrical engineering, electronic engineering, information engineering, beam misalignment, lcsh:GC1-1581, SDG 7 - Affordable and Clean Energy, Sensitivity (control systems), uncertainty, currents, Tilt, Water Science and Technology, Civil and Structural Engineering, Remote sensing, Renewable Energy, Sustainability and the Environment, business.industry, Turbulence, turbulence, Uncertainty, lcsh:Naval architecture. Shipbuilding. Marine engineering, Power (physics), Noise, Acoustic doppler profiler, Turbulence kinetic energy, symbols, Environmental science, Beam misalignment, business, Tidal power, Doppler effect

Abstract

Representing the velocity at a tidal energy extraction site in a standardized manner is essential for the development of the tidal energy sector. The International Electrotechnical Commission (IEC) have issued a technical specification to determine the mean representative current velocity (MRV) relative to a tidal energy converter (TEC). This method determines the MRV using an acoustic Doppler profiler (ADP). This is used to evaluate the power performance of a TEC and so can have a significant influence on the power performance uncertainties, due to the cubed relationship of the MRV and power. This paper investigates these uncertainties in the MRV by considering four sources of uncertainty in the ADP. These are turbulence intensity, tilt, Doppler noise and beam misalignment of an ADP. A synthetically generated dataset is used to define current velocity and profile using the characteristics of currents and ADP. The generated synthetic dataset is processed to calculate the MRV based on the standard IEC method. An alternative method to calculate the MRV, called the temporal-spatial method (TSM), is proposed and the two methodologies are used to assess the error of the MRV. A sensitivity analysis shows that the errors of the MRV based on the standard IEC method are always higher than the TSM. The biases in the MRV based on the different combinations of the uncertainty are investigated and it is found that the bias for the MRVs based on the TSM method is generally less than that of the IEC method.

Published

2020

9. The impact of axial flow misalignment on a tidal turbine

Author

Magnus Harrold, Allan Mason-Jones, Paul Evans, Daphne Maria O'Doherty, Carwyn Frost, and Timothy O'Doherty

Subjects

Engineering, Renewable Energy, Sustainability and the Environment, business.industry, Rotor (electric), 020209 energy, Magnitude (mathematics), 02 engineering and technology, Mechanics, Computational fluid dynamics, Turbine, law.invention, Axial compressor, law, Drive shaft, 0202 electrical engineering, electronic engineering, information engineering, Bending moment, business, Tidal power, Simulation

Abstract

Extensive Research and Development have helped drive the tidal energy industry towards commercial viability, with full-scale prototypes starting to meet marine environmental challenges. This paper utilises velocity data collected from a site off the welsh coast with Computational Fluid Dynamics (CFD) to determine the effects of misaligned flows on the performance of a tidal stream turbine. The field observations indicate that the majority of the currents tend to fall within ±20° of the principal flow direction for economically viable velocities. The CFD modelling suggests a reduction in the non-dimensional performance parameters as the angle of misalignment increases between the axis of rotation and the free stream velocity. The resultant magnitude of the bending moments acting on the rotor end of the driveshaft for the misaligned turbines was found to be up to ten times greater than the aligned turbine. The paper also shows that an accurate definition of the tolerance to axial flow misalignment between the free stream velocity and the axis of rotation of a turbine is required to prevent any negative effects on performance and loading.

Published

2017

10. The Effect of Control Strategy on Tidal Stream Turbine Performance in Laboratory and Field Experiments

Author

Ian Benson, Trevor Whittaker, Penny Jeffcoate, Björn Elsäßer, and Carwyn Frost

Subjects

0209 industrial biotechnology, Control and Optimization, acoustic Doppler profiler, 020209 energy, Energy Engineering and Power Technology, PID controller, 02 engineering and technology, Inflow, Turbine, lcsh:Technology, 020901 industrial engineering & automation, Strangford Lough, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), Renewable Energy, Sustainability and the Environment, business.industry, Turbulence, lcsh:T, experimental testing, Rotational speed, Feedback loop, tidal energy, Flow conditions, Environmental science, business, Tidal power, Energy (miscellaneous), Marine engineering

Abstract

The first aim of the research presented here is to examine the effect of turbine control by comparing a passive open-loop control strategy with a constant rotational speed proportional–integral–derivative (PID) feedback loop control applied to the same experimental turbine. The second aim is to evaluate the effect of unsteady inflow on turbine performance by comparing results from a towing-tank, in the absence of turbulence, with results from the identical machine in a tidal test site. The results will also inform the reader of: (i) the challenges of testing tidal turbines in unsteady tidal flow conditions in comparison to the controlled laboratory environment, (ii) calibration of acoustic Doppler flow measurement instruments, (iii) characterising the inflow to a turbine and identifying the uncertainties from unsteady inflow conditions by adaptation of the International Electrotechnical Commission technical specification (IEC TS): 62600-200. The research shows that maintaining a constant rotational speed with a control strategy yields a 13.7% higher peak power performance curve in the unsteady flow environment, in comparison to an open-loop control strategy. The research also shows an 8.0% higher peak power performance in the lab compared to the field, demonstrating the effect of unsteady flow conditions on power performance. The research highlights the importance of a tidal turbines control strategy when designing experiments.

Published

2018

11. Computational analysis and experimental verification of a Boundary Integral Equation Model for tidal turbines

Author

Zohreh Sarichloo (1), Francesco Salvatore (1), Fabio Di Felice (1), Marcello Costanzo (1), Ralf Starzmann (2), and Carwyn Frost (3)

Subjects

Experimental validation, Marine Renewable Energy, CFD, Boundary Element Methods, Tidal turbines

Abstract

Inviscid flow hydrodynamics provides fast computational models for analysis and design. Ap- plication to marine current turbines implies the development of suitable models to account for viscosity effects that govern turbine operation over a significant range of operating conditions. The aim of the present work is to analyse the capability of the Viscous Flow Correction (VFC) model combined with a Boundary Integral Equa- tion Model (BIEM) to describe onset flow speed effects on turbine thrust and power. Numerical predictions by BIEM-VFC are compared with results of flume tank tests over a speed range from 0.6 to 2.75 m/s on a 500 mm diameter model turbine in the framework of a research project with industrial partners. Results from this comparative study demonstrate that the simple viscosity correction model is able to capture the effect of onset flow speed, with maximum thrust and power predicted within 3% accuracy at 1.2 m/s and higher.

Published

2018

12. Modelling tidal stream turbines

Author

Sarah Tatum, Carwyn Frost, Daphne O’Doherty, Allan Mason-Jones, Tim O’Doherty, and Ali, Sayigh

Subjects

TD

Published

2015

13. The effect of axial flow misalignment on tidal turbine performance

Author

Timothy O'Doherty, Carwyn Frost, Allan Mason-Jones, Ceri E. Morris, Paul Evans, and Daphne Maria O'Doherty

Subjects

Axial compressor, business.industry, Mechanics, business, Tidal power, Geology

Published

2015

14. Flow Misalignment and Tidal Stream Turbines

Author

Carwyn Frost, Evans, Paul, Morris, Ceri, Mason-Jones, Allan, O'Doherty, Daphne, and O'Doherty, Tim

Published

2015

15. Renewable Energy in the Service of Mankind Vol I

Author

Timothy O'Doherty, Sarah Tatum, Allan Mason-Jones, Carwyn Frost, and Daphne Maria O'Doherty

Subjects

Engineering, business.industry, Rotational symmetry, Thrust, Mechanics, Rotation, Turbine, Civil engineering, law.invention, law, Drive shaft, Bending moment, Transient (oscillation), business, Tidal power

Abstract

The transient behaviour of the sea and the rotation of a turbine rotor can result in high asymmetric loadings, which are transmitted to the drive shaft. A turbine mounted on a circular stanchion has been used to highlight the effects of introducing more realistic boundary conditions, over a rotational cycle of the turbine. The consequences on the turbine’s performance characteristics and crucial structural loading are shown. The position of the turbine relative to the support structure and its alignment to the flow direction can have significant temporal hydrodynamic and structural effects. Depending on their wavelength, waves can also have a significant effect on the overall design decisions and placement of devices. Thrust loading and bending moments applied to the drive shaft can be of the order of hundreds of kN and kNm, respectively. This leads to the need to not only size the drive shaft and bearings to account for axisymmetric thrust but also consider large asymmetric loads.

Published

2015

16. How much variation in CS rates can be explained by case mix differences?

Author

J. Thomas, Shantini Paranjothy, and Carwyn Frost

Subjects

Adult, Pediatrics, medicine.medical_specialty, Adolescent, Cross-sectional study, medicine.medical_treatment, Logistic regression, Odds, Case mix index, Pregnancy, medicine, Humans, Childbirth, Caesarean section, Child, Diagnosis-Related Groups, Wales, Cesarean Section, Vaginal delivery, business.industry, Obstetrics and Gynecology, Middle Aged, medicine.disease, Cross-Sectional Studies, England, Regression Analysis, Female, business, Demography

Abstract

Objective To quantify the amount of variation in caesarean section (CS) rates between maternity units explained by case mix differences. Design Cross-sectional study. Setting All 216 maternity units in England and Wales. Population Women giving birth at these maternity units between May and July 2000. Methods Logistic regression models were developed to investigate the relationship between case mix characteristics, and odds of (i) CS before labour, (ii) CS in labour. Using these results, overall CS rates standardised for case mix were calculated for each maternity unit. Random-effects meta-analysis was used to examine heterogeneity between maternity units. Main outcome measures CS before labour and CS during labour. Results Adjustment for case mix differences between maternity units explained 34% of the variance in CS rates. Odds of CS (before and in labour) increased with maternal age. Women from ethnic minority groups had lower odds of CS before labour, and increased odds of CS in labour. Women with a previous vaginal delivery had lower odds of CS, although the magnitude of this for CS before and in labour is markedly different. Conclusions Case mix adjustment is important to enable understanding of the factors that influence the CS rate. These include organisational and staffing levels as well as women's preferences for childbirth and clinician's attitudes. An understanding of how these factors influence the CS rate is essential for evaluation of quality and appropriateness of obstetric care provided to women.

Published

2005

17. Knowledge gaps around crossflow tidal turbines

Author

Rónán Gallagher, Trevor Whitaker, Carwyn Frost, Pal Schmitt, Charles Young, and John Doran