Mooring dynamics for wave energy applications

Thesis

Title: Mooring dynamics for wave energy applications

Author:

Palm, J.

Publication Date:

January 1, 2017

Thesis Type:

Doctoral Dissertation

Academic Department:

Shipping and Marine Techonolgy

Pages:

Affiliation:

Chalmers University of Technology

Technology:

Wave

Engineering:

Mooring

Language:

English

Document Access

Website:

External Link

Citation

Palm, J. (2017). Mooring dynamics for wave energy applications (Doctoral Dissertation). Chalmers University of Technology.

@phdthesis{Palm-2017-,
author = {Palm, J},
title = {Mooring dynamics for wave energy applications},
school = {Chalmers University of Technology},
year = {2017},
month = {jan},
url = {https://search.proquest.com/openview/0a5c744532c40d9ca8b9594dc0b5672c/1?pq-origsite=gscholar&cbl=18750&diss=y},
keywords = {Wave, Mooring},
}

Export Citation to BibTex

TY - THES
TI - Mooring dynamics for wave energy applications
AU - Palm, J
AB - This work aims to increase the modelling accuracy of two important problems for the wave energy industry. One concerns the mooring dynamics in the presence of snap loads (shock waves in cable tension). The other is related to nonlinear effects in the resonance region of moored wave energy converters (WECs).The thesis describes the development of Moody, a high-order discontinuous Galerkin (DG) model for mooring dynamics aimed at capturing snap loads. Two different DG formulations are presented. The first version uses the local DG method, while the second is based on the Lax-Friedrich (LF) approximative Riemann solver. Exponential convergence for smooth cases and excellent agreement with experimental data are shown for both versions. The LF-based solver is extended to include shock-identifiers, slope limiters and hpadaptive mesh refinement. Computational results show good shock resolution in both linear and nonlinear cable materials. We further develop an automated program interface to provide dynamic mooring response to volume of fluid Reynolds averaged NavierStokes (VOF-RANS) simulations of WECs in OpenFOAM®.Model scale experiments of a moored vertical cylinder are carried out with the partial aim to provide validation data for the coupled VOF-RANS-Moody model. The validation shows very good agreement between experimental and numerical results of surge and heave motion, from which we conclude that the coupling is working as expected. We get a good match in mooring force response, but the pitch response is shown to be more sensitive to model input parameters. Validation of high-fidelity models puts tough requirements on experimental data quality, which are difficult to meet in small scales.The experiments also assess the performance of three types of mooring configurations for WECs. Results show how cable slack-snap events are important for the dynamic range of mooring force response in survival conditions. As the steepness of the waves increase, the response amplitude per wave height decreases in the resonance region for all three configurations. This nonlinear effect is consistently seen throughout the results from experiments and coupled simulations of both model scale and full-scale geometries. Although paid for with a substantial computational effort, we conclude that the high-fidelity VOF-RANS-Moody model is able to predict the fully nonlinear response of WECs with good accuracy
DA - 2017/01//
PY - 2017
SP - 19
PB - Chalmers University of Technology
UR - https://search.proquest.com/openview/0a5c744532c40d9ca8b9594dc0b5672c/1?pq-origsite=gscholar&cbl=18750&diss=y
LA - English
M3 - PhD Thesis
KW - Wave
KW - Mooring
ER -

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Abstract

This work aims to increase the modelling accuracy of two important problems for the wave energy industry. One concerns the mooring dynamics in the presence of snap loads (shock waves in cable tension). The other is related to nonlinear effects in the resonance region of moored wave energy converters (WECs).

The thesis describes the development of Moody, a high-order discontinuous Galerkin (DG) model for mooring dynamics aimed at capturing snap loads. Two different DG formulations are presented. The first version uses the local DG method, while the second is based on the Lax-Friedrich (LF) approximative Riemann solver. Exponential convergence for smooth cases and excellent agreement with experimental data are shown for both versions. The LF-based solver is extended to include shock-identifiers, slope limiters and hpadaptive mesh refinement. Computational results show good shock resolution in both linear and nonlinear cable materials. We further develop an automated program interface to provide dynamic mooring response to volume of fluid Reynolds averaged NavierStokes (VOF-RANS) simulations of WECs in OpenFOAM®.

Model scale experiments of a moored vertical cylinder are carried out with the partial aim to provide validation data for the coupled VOF-RANS-Moody model. The validation shows very good agreement between experimental and numerical results of surge and heave motion, from which we conclude that the coupling is working as expected. We get a good match in mooring force response, but the pitch response is shown to be more sensitive to model input parameters. Validation of high-fidelity models puts tough requirements on experimental data quality, which are difficult to meet in small scales.

The experiments also assess the performance of three types of mooring configurations for WECs. Results show how cable slack-snap events are important for the dynamic range of mooring force response in survival conditions. As the steepness of the waves increase, the response amplitude per wave height decreases in the resonance region for all three configurations. This nonlinear effect is consistently seen throughout the results from experiments and coupled simulations of both model scale and full-scale geometries. Although paid for with a substantial computational effort, we conclude that the high-fidelity VOF-RANS-Moody model is able to predict the fully nonlinear response of WECs with good accuracy