2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment

Flexible river training structures such as tetrahedron frames (`porcupines') can be attractive for control of braided river channel networks in regions where permanent control structures (e.g. groynes or dams) are too expensive or potentially inefficient, such as systems with highly dynamic flo...

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Bibliographic Details
Main Author: Irving, Meghan (author)
Other Authors: Blom, A. (graduation committee), Sloff, C.J. (mentor), Bricker, J.D. (graduation committee), Schuurman, Filip (graduation committee), Delft University of Technology (degree granting institution)
Format: Master Thesis
Language:English
Published: 2020
Subjects:
Porcupines
Ayeyarwady River
Delft3D
Morphology
Hydrodynamics
Porcupine River
Online Access:http://resolver.tudelft.nl/uuid:94aeae3d-e78b-4dc7-b517-8f66b629c21f
id fttudelft:oai:tudelft.nl:uuid:94aeae3d-e78b-4dc7-b517-8f66b629c21f
record_format openpolar
spelling fttudelft:oai:tudelft.nl:uuid:94aeae3d-e78b-4dc7-b517-8f66b629c21f 2023-07-30T04:06:28+02:00 2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment Irving, Meghan (author) Blom, A. (graduation committee) Sloff, C.J. (mentor) Bricker, J.D. (graduation committee) Schuurman, Filip (graduation committee) Delft University of Technology (degree granting institution) 2020-11-30 http://resolver.tudelft.nl/uuid:94aeae3d-e78b-4dc7-b517-8f66b629c21f en eng http://resolver.tudelft.nl/uuid:94aeae3d-e78b-4dc7-b517-8f66b629c21f © 2020 Meghan Irving Porcupines Ayeyarwady River Delft3D Morphology Hydrodynamics master thesis 2020 fttudelft 2023-07-08T20:37:42Z Flexible river training structures such as tetrahedron frames (`porcupines') can be attractive for control of braided river channel networks in regions where permanent control structures (e.g. groynes or dams) are too expensive or potentially inefficient, such as systems with highly dynamic flow regimes and morphology. Porcupines provide hydraulic resistance, generating energy loss and reducing velocities that may further encourage sediment deposition. Porcupine systems have seen increasing implementation, especially for bed or bank protection, but were also recently implemented in a channel-control pilot project on the Ayeyarwady River in Myanmar. Many porcupine systems to date are designed by trial and error due to lack of quantitative design criteria. The 2019 pilot project used large-scale numerical modelling of resistance areas to evaluate the potential impacts of porcupine structures; however, how to best incorporate the impacts of porcupine structures on flow and sediment transport in numerical models has not been systematically evaluated. Improved models or better estimates of uncertainties could facilitate future porcupine system design. Therefore, this study examines methods for incorporating porcupine fields into numerical models and interpreting those models to make informed design choices. Data and observations from the 2019 pilot project implementation, a 2018 porcupine flume experiment, and extensive literature review have been used to examine the expected hydrodynamic and morphodynamic impacts of porcupine systems that need to be accurately captured in large-scale numerical models. A 2DV model using two resistance formulations representing porcupines was elaborated and tested against experimental porcupine performance. The Uittenbogaard (2003) rigid cylinder model was found to replicate well porcupine behavior for less dense systems under limited flow conditions; however further verification is needed for more dense systems, variable flow regimes, wider boundary conditions and mobile beds. The ... Master Thesis Porcupine River Delft University of Technology: Institutional Repository
institution Open Polar
collection Delft University of Technology: Institutional Repository
op_collection_id fttudelft
language English
topic Porcupines
Ayeyarwady River
Delft3D
Morphology
Hydrodynamics
spellingShingle Porcupines
Ayeyarwady River
Delft3D
Morphology
Hydrodynamics
Irving, Meghan (author)
2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment
topic_facet Porcupines
Ayeyarwady River
Delft3D
Morphology
Hydrodynamics
description Flexible river training structures such as tetrahedron frames (`porcupines') can be attractive for control of braided river channel networks in regions where permanent control structures (e.g. groynes or dams) are too expensive or potentially inefficient, such as systems with highly dynamic flow regimes and morphology. Porcupines provide hydraulic resistance, generating energy loss and reducing velocities that may further encourage sediment deposition. Porcupine systems have seen increasing implementation, especially for bed or bank protection, but were also recently implemented in a channel-control pilot project on the Ayeyarwady River in Myanmar. Many porcupine systems to date are designed by trial and error due to lack of quantitative design criteria. The 2019 pilot project used large-scale numerical modelling of resistance areas to evaluate the potential impacts of porcupine structures; however, how to best incorporate the impacts of porcupine structures on flow and sediment transport in numerical models has not been systematically evaluated. Improved models or better estimates of uncertainties could facilitate future porcupine system design. Therefore, this study examines methods for incorporating porcupine fields into numerical models and interpreting those models to make informed design choices. Data and observations from the 2019 pilot project implementation, a 2018 porcupine flume experiment, and extensive literature review have been used to examine the expected hydrodynamic and morphodynamic impacts of porcupine systems that need to be accurately captured in large-scale numerical models. A 2DV model using two resistance formulations representing porcupines was elaborated and tested against experimental porcupine performance. The Uittenbogaard (2003) rigid cylinder model was found to replicate well porcupine behavior for less dense systems under limited flow conditions; however further verification is needed for more dense systems, variable flow regimes, wider boundary conditions and mobile beds. The ...
author2 Blom, A. (graduation committee)
Sloff, C.J. (mentor)
Bricker, J.D. (graduation committee)
Schuurman, Filip (graduation committee)
Delft University of Technology (degree granting institution)
format Master Thesis
author Irving, Meghan (author)
author_facet Irving, Meghan (author)
author_sort Irving, Meghan (author)
title 2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment
title_short 2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment
title_full 2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment
title_fullStr 2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment
title_full_unstemmed 2D Model Parameterization of Porcupine River Training Structures: Hydrodynamic and Morphological Impact Assessment
title_sort 2d model parameterization of porcupine river training structures: hydrodynamic and morphological impact assessment
publishDate 2020
url http://resolver.tudelft.nl/uuid:94aeae3d-e78b-4dc7-b517-8f66b629c21f
genre Porcupine River
genre_facet Porcupine River
op_relation http://resolver.tudelft.nl/uuid:94aeae3d-e78b-4dc7-b517-8f66b629c21f
op_rights © 2020 Meghan Irving
_version_ 1772819088447373312

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