Abstract
Dielectric elastomer generators (DEGs) are soft electrostatic generators based on low-cost electroactive polymer materials. These devices have attracted the attention of the marine energy community as a promising solution to implement economically viable wave energy converters (WECs). This paper introduces a hardware-in-the-loop (HIL) simulation framework for a class of WECs that combines the concept of the oscillating water columns (OWCs) with the DEGs. The proposed HIL system replicates in a laboratory environment the realistic operating conditions of an OWC/DEG plant, while drastically reducing the experimental burden compared to wave tank or sea tests. The HIL simulator is driven by a closed-loop real-time hydrodynamic model that is based on a novel coupling criterion which allows rendering a realistic dynamic response for a diversity of scenarios, including large scale DEG plants, whose dimensions and topologies are largely different from those available in the HIL setup. A case study is also introduced, which simulates the application of DEGs on an OWC plant installed in a mild real sea laboratory test-site. Comparisons with available real sea-test data demonstrated the ability of the HIL setup to effectively replicate a realistic operating scenario. The insights gathered on the promising performance of the analysed OWC/DEG systems pave the way to pursue further sea trials in the future.
Highlights
Ocean wave power is among the most abundant resources of clean renewable energy and it has the potential to become one of the key contributors in the future energy mix
With reference to this application, we present tests in which a fully-functional dielectric elastomers (DEs) generators (DEGs) prototype is coupled with a hydrodynamic model of a scaled U-oscillating water columns (OWCs) [11], paving the way towards future sea tests on small-scale systems operating in a mild sea climate
The plots show portions of time-series of the measured variables in two tests in which the simulated U-OWC was subject to incident irregular waves compatible with a JONSWAP frequency spectrum [23], similar to the actual sea states experimentally observed at Natural Ocean Engineering Laboratory (NOEL) [31]
Summary
Ocean wave power is among the most abundant resources of clean renewable energy and it has the potential to become one of the key contributors in the future energy mix. The simulator consists of a software environment running a real-time hydrodynamic model of an OWC converter, and a mechanical interface that drives the physical DEG PTO deformation, emulating the action of an OWC. In contrast, we propose for the first time coupling criteria which allow studying a diversity of scenarios, including the simulation of large DEG plants with several DEGs, whose dimensions generally differ from those of the tested physical samples. With reference to this application, we present tests in which a fully-functional DEG prototype is coupled with a hydrodynamic model of a scaled U-OWC [11], paving the way towards future sea tests on small-scale systems operating in a mild sea climate.
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