Transient Cable Overvoltage Calculation and Filter Design: Application to Onshore Converter Station for Hydrokinetic Energy Harvesting

Magnetic levitation (maglev) concepts are applied to a variety of industries such as the automotive, aerospace, or energy in order to accomplish different tasks: suspension and propulsion in maglev trains, rocket propulsion and spacecraft attitude control, centrifuge of nuclear reactors. In this paper, maglev is implemented in environmentally friendly hydrokinetic energy harvesting to achieve contactless bearing, thus, minimizing friction and improving efficiency. Generally, maglev systems exhibit higher efficiency and reduced maintenance while providing longer lifetime and higher durability when appropriate engineering design and control are applied. A Flow Induced Oscillation (FIO) energy-harvesting converter is considered in this work. To minimize friction in the support of the cylinder in FIO (vortex induced vibrations and galloping) due to high hydrodynamic drag, a maglev system is proposed. In the proposed configuration, a ferromagnetic core (element 1), of known dimensions, is considered under the effects of an externally imposed magnetic field. A second ferromagnetic element, of smaller dimensions, is then placed adjacent to the previous considered core. This particular configuration results in a non-homogenous magnetic field for element 1, caused by dimensional disparity. Specifically, the magnetic flux does not follow a linear path from the ferromagnetic core to element 2. A general electromagnetic analysis is conducted to derive an analytical form for the magnetic field of element 1. Subsequent numerical simulation validates the obtained formula. This distinct expression for the magnetic field is valuable towards calculating the magnetic energy of this specific configuration, which is essential to the design of the FIO energy harvesting converter considered in this work.

Download Full-text

Performance of single-cylinder VIVACE converter for hydrokinetic energy harvesting from flow-induced vibration near a free surface

Ocean Engineering ◽

10.1016/j.oceaneng.2020.108168 ◽

2020 ◽

Vol 218 ◽

pp. 108168

Author(s):

Wanhai Xu ◽

Meng Yang ◽

Enhao Wang ◽

Hai Sun

Keyword(s):

Free Surface ◽

Energy Harvesting ◽

Flow Induced Vibration ◽

Single Cylinder ◽

Hydrokinetic Energy

Download Full-text

Hydrokinetic Energy Harvesting System From Vortex Induced Vibrations of Submerged Bodies

ASME 2011 5th International Conference on Energy Sustainability, Parts A, B, and C ◽

10.1115/es2011-54353 ◽

2011 ◽

Cited By ~ 1

Author(s):

Varun Lobo ◽

Arindam Banerjee ◽

Nyuykighan Mainsah ◽

Jonathan Kimball

Keyword(s):

Boundary Layer ◽

Energy Harvesting ◽

Vortex Shedding ◽

Computational Study ◽

High Energy ◽

Power Converter ◽

Design Parameters ◽

Hydrokinetic Energy ◽

Energy Harvesting System ◽

Efficient Power

A Vortex Induced Vibration (VIV) based hydrokinetic energy system is discussed in this paper. Vibrations induced on a body (facing an external flow) due to the periodic irregularities in the flow caused by boundary layer separation are called as VIV. This separation of the boundary layer from the surface causes vortex formation in the wake region of the cylinder. The lift-force or the transverse oscillation of the vibrating cylinder depends upon the strength and modes of the vortex formed. The VIV energy harvesting system is based on the idea of maximizing rather than spoiling vortex shedding and was discovered in 2004 at the University of Michigan by Bernitsas and Raghavan. The vibrating bodies will in turn be used to harness energy using an efficient power-take-off system. In this paper, we discuss the hydrodynamic design of such a VIV based energy harvesting system using computational fluid dynamics. A fluid structure interaction calculation is performed to determine the forces on the surface of a bluff body due to separation of vortices from the surface. The hydrodynamic forces that act on such a system depend on the cylinder diameter, flow velocity, modes of vortex shedding and arrangement of cylinder(s). A detailed computational study on the effect of different design parameters listed above are first carried on a single cylinder arrangement; this is followed by a more detailed analysis that is extended to multiple cylinders. For a two-cylinder arrangement, the positions in which the cylinders are placed are also found to play an important role, as the vortex shed from one cylinder may be used to enhance the forces of lift on another cylinder present in its wake. Furthermore, the design of a VIV generator requires optimal damping and low mass ratio to enable high energy conversion via an efficient power take-off mechanism. The working and design considerations of the energy converter is outlined starting with a set of basic definitions pertaining to this technology. A tubular linear interior permanent magnet generator (TL-IPM) connected to a power converter is used; a linear generator was chosen to minimize mechanical components, such as gears or cams in the system.

Download Full-text

Hydrokinetic energy harvesting using tethered undersea kites

Journal of Renewable and Sustainable Energy ◽

10.1063/1.4926769 ◽

2015 ◽

Vol 7 (4) ◽

pp. 043114 ◽

Cited By ~ 11

Author(s):

David J. Olinger ◽

Yao Wang

Keyword(s):

Energy Harvesting ◽

Hydrokinetic Energy

Download Full-text

Marine hydrokinetic energy harvesting performance of diamond and square oscillators in tandem arrangements

Energy ◽

10.1016/j.energy.2020.117749 ◽

2020 ◽

Vol 202 ◽

pp. 117749 ◽

Cited By ~ 3

Author(s):

V. Tamimi ◽

M.J. Esfehani ◽

M. Zeinoddini ◽

S.T.O. Naeeni ◽

J. Wu ◽

...

Keyword(s):

Energy Harvesting ◽

Hydrokinetic Energy ◽

Marine Hydrokinetic

Download Full-text

Influence of attack angle on vortex-induced vibration and energy harvesting of two cylinders in side-by-side arrangement

Advances in Mechanical Engineering ◽

10.1177/1687814018822598 ◽

2019 ◽

Vol 11 (1) ◽

pp. 168781401882259

Author(s):

Li Zhang ◽

Xinru Mao ◽

Lin Ding

Keyword(s):

Energy Harvesting ◽

Energy Conversion ◽

Energy Conversion Efficiency ◽

Maximum Energy ◽

Attack Angle ◽

Navier Stokes ◽

Vortex Induced Vibration ◽

Hydrokinetic Energy ◽

Wake Patterns ◽

Vibration Responses

The vortex-induced vibration and energy harvesting of two cylinders in side-by-side arrangement with different attack angles are numerically investigated using two-dimensional unsteady Reynolds-Averaged Navier–Stokes simulations. The Reynolds number ranges from 1000 to 10,000, and the attack angle of free flow is varied from 0° to 90°. Results indicate that the vortex-induced vibration responses with attack angle range of 0°≤ α ≤ 30° are stronger than other attack angle cases. The parallel vortex streets are clearly observed with synchronized vortex shedding. Relatively large attack angle leads to a phase difference between the wake patterns of the two cylinders. Hydrokinetic energy can be obviously harvested when Re > 4000. Compared with the larger attack angle case, the two side-by-side cylinders with smaller attack angle have better performance on energy conversion. The maximum energy conversion efficiency of 21.7% is achieved. The optimum region for energy conversion is 5000 ≤ Re ≤ 7000 and 0°≤ α ≤ 30°.

Download Full-text

Piezoelectric Artificial Kelp for Energy Harvesting

ASME 2010 Conference on Smart Materials, Adaptive Structures and Intelligent Systems, Volume 2 ◽

10.1115/smasis2010-3881 ◽

2010 ◽

Cited By ~ 1

Author(s):

Alexander M. Pankonien ◽

Zoubeida Ounaies

Keyword(s):

Energy Harvesting ◽

Piezoelectric Material ◽

Piezoelectric Materials ◽

Kelp Forests ◽

Flow Conditions ◽

Marine Habitat ◽

Specific Flow ◽

Hydrokinetic Energy ◽

Piezoelectric Energy ◽

Energy Harvesting System

This study focuses on a hydrokinetic energy harvesting system concept using piezoelectric materials. The Piezoelectric Active Kelp (PAK) system will consist of chemically inert piezoelectric polymers or piezoelectric ceramics manufactured into long flexible ribbons. The PAK system will convert the natural mechanical motions seen in kelp forests due to oceanic wave action, into electricity. As the periodic ocean currents, resulting from waves, pass over the PAK system, they cause the structure to oscillate back and forth. The piezoelectric materials will convert this mechanical motion directly into electrical power via the inverse piezoelectric effect. Large numbers of piezo-kelp ribbons would be mounted like forests on the ocean floor, producing a constant stream of smart grid power. PAK forest systems would also provide an artificial marine habitat while meeting the world’s demand for inexpensive and sustainable energy. Contrary to most forms of hydrokinetic energy harvesting system, the PAK system has no fast-moving parts or turbines and will be made of environmentally inert materials. The amount of power harvested by the PAK system depends upon the flow conditions, device configuration and size, and its piezoelectric material properties. Assuming specific flow conditions and fluid-structure interaction, this study will determine the optimal piezoelectric material to use, along with physical dimensions and layup configuration, to maximize the volumetric power density of the PAK system. The power generated by three common piezoelectric energy harvesting configurations: the unimorph, a homogeneous bimorph and a heterogeneous bimorph, will be compared for both a piezopolymer and a piezoceramic. Additionally, an appropriate figure-of-merit is also identified, based on the piezoelectric coefficient product (d31· g31) to compare the power production capabilities across materials.

Download Full-text