Abstract
The power harnessed by wave energy converters (WECs) in oceans is highly variable and, therefore, has a high peak-to-average power (PTAP) ratio. To minimize the cost of a WEC power take off (PTO) system, it is desirable to reduce the PTAP ratio while maximizing the mean power extracted by WECs. The important issue of how PTAP ratio reduction measures (such as adding an inertia element) can affect the mean power extracted in a reference model has not been thoroughly addressed in the literature. To investigate this correlation, this study focuses on the integration of the U.S. Department of Energy’s Reference Model 3, a two-body point absorber, with a slider-crank WEC for linear-to-rotational conversion. In the first phase of this study, a full-scale numerical model was developed that predicts how PTO system parameters, along with an advanced control algorithm, can potentially affect the proposed WEC’s PTAP ratio as well as the mean power extracted. In the second phase, an appropriate scaled-down model was developed, and extracted power results were successfully validated against the full-scale model. Finally, numerical and hardware-in-the-loop (HIL) simulations based on the scaled-down model were designed and conducted to optimize or make trade-offs between the operational performance and PTAP ratio. The initial results with numerical and HIL simulations reveal that gear ratio, crank radius, and generator parameters substantially impact the PTAP ratio and mean power extracted.
Highlights
Recognizing a need for alternative energy sources has resulted in significant momentum toward investigating renewable energy resources, such as wind and solar
Speed fluctuations limited to ±30% were found to be satisfactory through extensive simulations with irregular waves
The second objective was about tuning the power take off (PTO) system parameters and collecting and analyzing the peak-to-average power (PTAP) ratio data, for various wave conditions
Summary
Recognizing a need for alternative energy sources has resulted in significant momentum toward investigating renewable energy resources, such as wind and solar. Total nonhydro renewable energy generation (wind, solar, geothermal, and biomass) in the United States increased by 7.0% in 2019, following an increase of 8.2% in 2018 and 13.8% in 2017 [1]. In 2014, the total nonhydro renewable energy generation surpassed conventional hydroelectric generation for the first time in U.S history. The three largest nonhydro contributors were wind (7.1%), solar (2.6%), and biomass (1.4%), followed by geothermal (0.4%). The United States has announced a new goal to reach 100% carbon-pollution-free electricity by 2035 [3]. This does not necessarily mean that 100% of electricity will be from renewables, but it paves the way for more renewable generation in the United States. There is still substantial room to grow to reach these goals, considering that only 11.4% of need is met by renewable generation, and that the growth rate of renewable generation has declined in recent years [1]
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