Determination of the Manning roughness coefficient influenced by vegetation in the river Aa and Biebrza river
The aim of this study was to investigate the variation of channel bed roughness in two rivers, as important parameter in hydraulic modelling especially with regard to flood control. The universities of Ghent (UG) and Antwerp (UA) are conducting scientific research in the river Aa in Belgium and the...
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| Published in: | Environmental fluid mechanics (Dordrecht, Netherlands : 2001) Vol. 9; no. 5; pp. 549 - 567 |
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| Abstract | The aim of this study was to investigate the variation of channel bed roughness in two rivers, as important parameter in hydraulic modelling especially with regard to flood control. The universities of Ghent (UG) and Antwerp (UA) are conducting scientific research in the river Aa in Belgium and the Biebrza river in Poland in order to better understand the phenomena involved and to come to a more accurate determination of the different parameters influencing flow. In this paper, the determination of the roughness coefficient ‘n' from the Manning equation is used. This coefficient is not easy to determine and is varying constantly. It is influenced by the meandering character of the river, the bed material and the average grain size, the channel bed forms, the channel obstructions, the geometry changes between sections and the vegetation in the channel. Furthermore, due to these parameters, the roughness of the channel is not equally distributed over the channel, the banks and the floodplains. So, using literature data does not always lead to satisfactory results, due to the different situation in the field (Werner et al. J Hydrol 314:139-157, 2005). Therefore, measurements are necessary to determine the variation of the Manning coefficient. The Manning coefficient is a function of the discharge, but will also vary over the time due to the mentioned influences. In a multidisciplinary research project on the fundamental exchange processes in river ecosystems, hydraulic measurements were performed on a regular base in the river Aa. During these measurement campaigns, velocity and discharge measurements were carried out in multiple cross-sections. Once a month, the discharge and the water levels were measured at the upstream and the downstream end of the test stretch. On the river Biebrza, similar intensive measurement campaigns took place along a 6 km stretch in the upstream part of the river. An accurate determination of the Manning coefficient according a seasonal variation is an important tool in hydraulic modelling. |
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| AbstractList | The aim of this study was to investigate the variation of channel bed roughness in two rivers, as important parameter in hydraulic modelling especially with regard to flood control. The universities of Ghent (UG) and Antwerp (UA) are conducting scientific research in the river Aa in Belgium and the Biebrza river in Poland in order to better understand the phenomena involved and to come to a more accurate determination of the different parameters influencing flow. In this paper, the determination of the roughness coefficient ‘n' from the Manning equation is used. This coefficient is not easy to determine and is varying constantly. It is influenced by the meandering character of the river, the bed material and the average grain size, the channel bed forms, the channel obstructions, the geometry changes between sections and the vegetation in the channel. Furthermore, due to these parameters, the roughness of the channel is not equally distributed over the channel, the banks and the floodplains. So, using literature data does not always lead to satisfactory results, due to the different situation in the field (Werner et al. J Hydrol 314:139-157, 2005). Therefore, measurements are necessary to determine the variation of the Manning coefficient. The Manning coefficient is a function of the discharge, but will also vary over the time due to the mentioned influences. In a multidisciplinary research project on the fundamental exchange processes in river ecosystems, hydraulic measurements were performed on a regular base in the river Aa. During these measurement campaigns, velocity and discharge measurements were carried out in multiple cross-sections. Once a month, the discharge and the water levels were measured at the upstream and the downstream end of the test stretch. On the river Biebrza, similar intensive measurement campaigns took place along a 6 km stretch in the upstream part of the river. An accurate determination of the Manning coefficient according a seasonal variation is an important tool in hydraulic modelling. The aim of this study was to investigate the variation of channel bed roughness in two rivers, as important parameter in hydraulic modelling especially with regard to flood control. The universities of Ghent (UG) and Antwerp (UA) are conducting scientific research in the river Aa in Belgium and the Biebrza river in Poland in order to better understand the phenomena involved and to come to a more accurate determination of the different parameters influencing flow. In this paper, the determination of the roughness coefficient 'n' from the Manning equation is used. This coefficient is not easy to determine and is varying constantly. It is influenced by the meandering character of the river, the bed material and the average grain size, the channel bed forms, the channel obstructions, the geometry changes between sections and the vegetation in the channel. Furthermore, due to these parameters, the roughness of the channel is not equally distributed over the channel, the banks and the floodplains. So, using literature data does not always lead to satisfactory results, due to the different situation in the field (Werner etal. J Hydrol 314:139-157, 2005). Therefore, measurements are necessary to determine the variation of the Manning coefficient. The Manning coefficient is a function of the discharge, but will also vary over the time due to the mentioned influences. In a multidisciplinary research project on the fundamental exchange processes in river ecosystems, hydraulic measurements were performed on a regular base in the river Aa. During these measurement campaigns, velocity and discharge measurements were carried out in multiple cross-sections. Once a month, the discharge and the water levels were measured at the upstream and the downstream end of the test stretch. On the river Biebrza, similar intensive measurement campaigns took place along a 6km stretch in the upstream part of the river. An accurate determination of the Manning coefficient according a seasonal variation is an important tool in hydraulic modelling. The aim of this study was to investigate the variation of channel bed roughness in two rivers, as important parameter in hydraulic modelling especially with regard to flood control. The universities of Ghent (UG) and Antwerp (UA) are conducting scientific research in the river Aa in Belgium and the Biebrza river in Poland in order to better understand the phenomena involved and to come to a more accurate determination of the different parameters influencing flow. In this paper, the determination of the roughness coefficient 'n' from the Manning equation is used. This coefficient is not easy to determine and is varying constantly. It is influenced by the meandering character of the river, the bed material and the average grain size, the channel bed forms, the channel obstructions, the geometry changes between sections and the vegetation in the channel. Furthermore, due to these parameters, the roughness of the channel is not equally distributed over the channel, the banks and the floodplains. So, using literature data does not always lead to satisfactory results, due to the different situation in the field (Werner et al. J Hydrol 314:139-157, 2005). Therefore, measurements are necessary to determine the variation of the Manning coefficient. The Manning coefficient is a function of the discharge, but will also vary over the time due to the mentioned influences. In a multidisciplinary research project on the fundamental exchange processes in river ecosystems, hydraulic measurements were performed on a regular base in the river Aa. During these measurement campaigns, velocity and discharge measurements were carried out in multiple cross-sections. Once a month, the discharge and the water levels were measured at the upstream and the downstream end of the test stretch. On the river Biebrza, similar intensive measurement campaigns took place along a 6 km stretch in the upstream part of the river. An accurate determination of the Manning coefficient according a seasonal variation is an important tool in hydraulic modelling. (PUBLICATION ABSTRACT) The aim of this study was to investigate the variation of channel bed roughness in two rivers, as important parameter in hydraulic modelling especially with regard to flood control. The universities of Ghent (UG) and Antwerp (UA) are conducting scientific research in the river Aa in Belgium and the Biebrza river in Poland in order to better understand the phenomena involved and to come to a more accurate determination of the different parameters influencing flow. In this paper, the determination of the roughness coefficient ‘ n ’ from the Manning equation is used. This coefficient is not easy to determine and is varying constantly. It is influenced by the meandering character of the river, the bed material and the average grain size, the channel bed forms, the channel obstructions, the geometry changes between sections and the vegetation in the channel. Furthermore, due to these parameters, the roughness of the channel is not equally distributed over the channel, the banks and the floodplains. So, using literature data does not always lead to satisfactory results, due to the different situation in the field (Werner et al. J Hydrol 314:139–157, 2005). Therefore, measurements are necessary to determine the variation of the Manning coefficient. The Manning coefficient is a function of the discharge, but will also vary over the time due to the mentioned influences. In a multidisciplinary research project on the fundamental exchange processes in river ecosystems, hydraulic measurements were performed on a regular base in the river Aa. During these measurement campaigns, velocity and discharge measurements were carried out in multiple cross-sections. Once a month, the discharge and the water levels were measured at the upstream and the downstream end of the test stretch. On the river Biebrza, similar intensive measurement campaigns took place along a 6 km stretch in the upstream part of the river. An accurate determination of the Manning coefficient according a seasonal variation is an important tool in hydraulic modelling. |
| Author | Troch, P Meire, P Bal, K De Doncker, L Verhoeven, R Quintelier, J |
| Author_xml | – sequence: 1 fullname: De Doncker, L – sequence: 2 fullname: Troch, P – sequence: 3 fullname: Verhoeven, R – sequence: 4 fullname: Bal, K – sequence: 5 fullname: Meire, P – sequence: 6 fullname: Quintelier, J |
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| Cites_doi | 10.1002/rrr.3450010303 10.1016/j.jhydrol.2005.03.012 10.1016/j.envsoft.2005.04.027 10.1002/rra.1240 |
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| Keywords | Ecohydraulics Manning roughness coefficient Hydraulic measurements Environmental engineering Vegetated rivers Grain size rivers Speed measurement inundations vegetation Cross section (collision) bedforms Water level roughness seasonal variations meanders |
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| References_xml | – ident: 9149_CR1 – ident: 9149_CR3 – volume-title: Open channel hydraulics year: 1959 ident: 9149_CR4 contributor: fullname: VT Chow – volume: 1 start-page: 211 year: 1987 ident: 9149_CR25 publication-title: Regul Rivers Res Manag doi: 10.1002/rrr.3450010303 contributor: fullname: D Watson – ident: 9149_CR12 – start-page: 236 volume-title: Leidraad voor ecologisch beekherstel year: 1995 ident: 9149_CR22 contributor: fullname: P Verdonschot – volume: 10 start-page: 239 issue: 3–4 year: 1984 ident: 9149_CR27 publication-title: Pol Ecol Stud contributor: fullname: S Zurek – ident: 9149_CR14 – ident: 9149_CR10 – ident: 9149_CR19 – ident: 9149_CR20 – volume: 314 start-page: 139 year: 2005 ident: 9149_CR26 publication-title: J Hydrol doi: 10.1016/j.jhydrol.2005.03.012 contributor: fullname: M Werner – ident: 9149_CR9 – ident: 9149_CR17 – ident: 9149_CR7 – ident: 9149_CR24 – volume: 21 start-page: 1290 year: 2006 ident: 9149_CR2 publication-title: Environ Model Softw doi: 10.1016/j.envsoft.2005.04.027 contributor: fullname: B Anderson – volume: 65 start-page: 232 year: 2005 ident: 9149_CR13 publication-title: Adv Water Resour contributor: fullname: J Green – ident: 9149_CR15 – ident: 9149_CR11 – ident: 9149_CR21 – volume: 32 start-page: 77 year: 1994 ident: 9149_CR18 publication-title: J Aquat Plant Manag contributor: fullname: T Marshall – ident: 9149_CR23 – ident: 9149_CR16 – ident: 9149_CR8 doi: 10.1002/rra.1240 – volume: 37 start-page: 473 issue: 7 year: 1956 ident: 9149_CR6 publication-title: Agric Eng contributor: fullname: W Cowan – volume-title: Applied hydrology year: 1988 ident: 9149_CR5 contributor: fullname: VT Chow |
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| Snippet | The aim of this study was to investigate the variation of channel bed roughness in two rivers, as important parameter in hydraulic modelling especially with... |
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| SubjectTerms | Aquatic ecosystems Classical Mechanics Earth and Environmental Science Earth Sciences Earth, ocean, space Ecohydraulics environmental engineering Environmental Physics Exact sciences and technology External geophysics Flood control Floodplains Fluid mechanics Freshwater Hydraulic measurements Hydrogeology Hydrology/Water Resources Manning roughness coefficient Mannings equation Meteorology Multidisciplinary research Oceanography Original Article Research projects River beds Rivers Roughness coefficient Seasonal variations Sedimentary structures Studies Upstream Vegetated rivers Vegetation Water levels |
| Title | Determination of the Manning roughness coefficient influenced by vegetation in the river Aa and Biebrza river |
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