A Removable elevated-hinge wave generator for testing marine energy devices

Authors

DOI:

https://doi.org/10.36688/ewtec-2023-212

Keywords:

Wave maker, Experiments, Laboratory, Wave energy, Wave flume

Abstract

A new removable elevated-hinge wave generator has been designed and commissioned in the O.H. Hinsdale Wave Research Laboratory (HWRL), at Oregon State University. The wave maker, built by Edinburgh Designs Ltd., is comprised by six electrically actuated dry-back paddles, self-contained in a single steel box and capable of generating mid-scale regular, irregular and user defined waves in a typical range of periods from 0.5 to 4 s at a maximum depth of 4 m. The system is intended to increase the available depth range in the Large Wave Flume (LWF) and satisfy the demand of intermediate to deep water waves at a relatively large scale by the marine energy industry.

The existing Large Wave Flume at the HWRL, is currently equipped with a piston-type, dry-back wave generator with a 4.2 m maximum stroke hydraulic actuator assembly. The flume is 104.24 m long, 3.66 m wide, and the sidewalls are 4.57 m high. The existing wave maker can generate large regular, random and tsunami-like long waves for the purpose of large-scale model tests, particularly in the area of coastal hazards (storm waves and tsunamis). Currently, the maximum water depth for generation of regular or random waves is 2.7 m, with a maximum wave height of 1.7 m in a wave period range from 4 to 8 s. The maximum depth for tsunami-like waves (solitary waves) in the flume is 2.0 m, with a maximum wave height of 1.4 m. The LWF works as a standard coastal (shallow water) testing facility where the models, bathymetry and instrumentation are typically installed with the facility completely empty. This allows for a full range of testing depths (from practically 0 to the maximum depth corresponding to the wave type to be generated). Correct representation of the bathymetry is necessary in coastal studies since wave propagation, transformation and breaking is part of the intended research. However, intermediate to deep water conditions, required for medium scale marine energy studies, represented a challenge.

The maximum depth at the flume for wave generation was limited by the structural design of the wave machine. However, the flume wall height is capable of handling a maximum depth in excess of 4 m. To increase the capabilities of the facility and responding to an increasing demand of deeper experimental conditions (particularly from the wave energy industry), the procurement of a specialized wave machine able to generate high-quality waves in deeper water was deemed necessary.

The uniqueness of the system relies on its flexibility. It was conceived to be, first, removable and can be relocated anywhere along the flume, at the full range of depths (from 1 m to 4 m) and it can be reversed facing both directions along the flume. This flexibility, required by the intention to keep the existing wave machine operational, increases its functionality by making it compatible to the generation of waves and co-linear currents, as well as expanding the available testing section along the flume, with generation on one side and absorption on the opposite.

Author Biography

  • Pedro Lomonaco, Oregon State University

    Dr. Lomonaco is the Director of the Hinsdale Wave Research Laboratory at Oregon State University as well as Teaching Faculty of Coastal Infrastructures for the School of Civil and Construction Engineering at OSU. He has over 30 years of experience with the academy and the industry on theoretical and applied research studies of physical modelling of waves, current and wind-structure interactions. He has authored and co-authored more than 100 papers in scientific journals and conference proceedings, and has prepared more than 60 technical reports of national and international projects and studies. His professional and scientific activity primarily deals with studies of physical and numerical modelling of wave generation and propagation, wave-structure interaction, stability of coastal and submarine structures, behaviour of floating structures, characterization of wave energy converters, offshore wind technology, hydrodynamics, scour protection, and non-linear behaviour of long-waves in shallow waters.

    Dr. Lomonaco received a B.Sc. in civil engineering from the National University of Mexico in 1991, a M.Sc. in coastal engineering from the International Institute of Hydraulic and Environmental Engineering – Delft, The Netherlands in 1994, and a Ph.D. in civil engineering from the University of Cantabria, Spain in 1999.

Published

2023-09-02

How to Cite

[1]
“A Removable elevated-hinge wave generator for testing marine energy devices”, Proc. EWTEC, vol. 15, Sep. 2023, doi: 10.36688/ewtec-2023-212.

Similar Articles

211-220 of 255

You may also start an advanced similarity search for this article.

Most read articles by the same author(s)