Abstract
Within the Lysekil wave energy research project at the Swedish west coast, more than ten Wave Energy Converters (WECs) prototypes have been developed and installed in an ocean based test site. Since 2006 various experiments have been conducted and the generated electricity was delivered to shore at a nearby island. While experiments are essential for the development of wave energy converters, theoretical studies and simulations are an important complement – not only in the search for advanced designs with higher efficiency, but also for improving the economic viability of the studied concepts. In this paper a WEC model is presented. The model consists of three subsystems: i) the hydrodynamic source, ii) the linear generator model, and iii) the electrical conversion system. After the validation with the experimental results at the research site, the generator model is connected to three passive load strategies – linear resistive load, passive rectification and resonance circuit. The paper focuses on analysing the operation of the model coupled with three load cases. The results prove that the WEC model correctly simulates the linear generator developed in the Lysekil Project. Moreover, the comparison among different load cases is made and discussed. The results gives an indication of the efficiency of energy production as well as the force ripples and resulting mechanical loads on the wave energy converters.
Highlights
The direct drive linear generator developed in the Lysekil Project consists of one movable part and stationary part
The resistance marked with ‘experiment’ is the parameter used in the experiment, while the resistance marked with ‘adjust’ means the adjusted values to be used in the simulation, which are chosen in order to gain the same energy output with other load cases
The significance with the load cases is to observe how much energy can be captured with different strategies
Summary
The direct drive linear generator developed in the Lysekil Project consists of one movable part and stationary part. The generator is standing on the seabed and it is connected to a floating buoy which moves mostly in heave motion, inducing a vertical motion of the translator inside the stator [1]. In the Lysekil Project so far, three different control strategies [3] have been experimentally tested. They are the passive diode rectification, DC/DC control, and resonance circuit [4]. The hydrodynamic function was built to emulate the motion of the buoy body when it reacted to the sea wave. Different load cases were studied when the generator model was connected to the electrical system. In addition to the studied load strategies, active control of various types will be included – the goal being to optimise energy absorption and total system efficiency
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