Optimal design of deep stormwater drainage tunnels to address urban flooding in Korea
Deep stormwater drainage tunnels play a crucial role in mitigating severe urban flooding in Korea, particularly as climate change leads to more extreme weather events. These tunnels typically consist of an entrance reservoir, a circular reinforced concrete culvert with a flat slope, a downstream res...
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| Published in | Scientific reports Vol. 14; no. 1; pp. 24896 - 29 |
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| Main Author | |
| Format | Journal Article |
| Language | English |
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Nature Publishing Group UK
22.10.2024
Nature Publishing Group Nature Portfolio |
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| Abstract | Deep stormwater drainage tunnels play a crucial role in mitigating severe urban flooding in Korea, particularly as climate change leads to more extreme weather events. These tunnels typically consist of an entrance reservoir, a circular reinforced concrete culvert with a flat slope, a downstream reservoir, and an outlet to a nearby river. In this system, the flow within the circular culvert is driven solely by the momentum of free-falling stormwater runoff. However, concerns have emerged within the Korean water resources engineering community about the drainage capacity of these tunnels, even with a substantial fall height of approximately 30 m. Intensified localized rainfall, the abrupt transition from flood waves to pressurized flow within the circular culvert, and trapped air pockets can also pose significant challenges to the tunnel’s drainage efficiency. Conventional design methods often fail to optimize the culvert’s diameter and spatial configuration, leading to suboptimal performance. In response, this study utilizes 3D numerical simulations with the interFoam solver from the OpenFOAM toolbox to address these issues. The results indicate that smaller culvert diameters—provided they do not exceed the maximum permissible flow velocity—enhance drainage capacity by reducing the impact of shock waves and stabilizing flow. These findings challenge the prevailing design practice in Korea, which holds that larger culverts inherently offer superior drainage capacity. Moreover, the simulations suggest that as culvert diameters increase, the size of trapped air pockets grows, further reducing efficiency. Although air chambers can help mitigate the retarding effects of trapped air pockets, their effectiveness diminishes if positioned near the origin of shock waves, where they risk being filled with stormwater. Based on these insights, several key recommendations are proposed: First, the design of deep stormwater tunnels should prioritize minimizing the extent of trapped air pockets, even when air chambers are used. Second, the current focus on detention capacity in design practices should be reevaluated, as excessive detention capacity may exacerbate air pocket formation. Finally, modifying the inlet channel to induce spiral flow within the entrance reservoir could reduce impulsive forces, lower maintenance costs related to armoring rocks at the reservoir bottom, and stabilize flow more quickly, thereby enhancing overall drainage capacity. |
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| AbstractList | Deep stormwater drainage tunnels play a crucial role in mitigating severe urban flooding in Korea, particularly as climate change leads to more extreme weather events. These tunnels typically consist of an entrance reservoir, a circular reinforced concrete culvert with a flat slope, a downstream reservoir, and an outlet to a nearby river. In this system, the flow within the circular culvert is driven solely by the momentum of free-falling stormwater runoff. However, concerns have emerged within the Korean water resources engineering community about the drainage capacity of these tunnels, even with a substantial fall height of approximately 30 m. Intensified localized rainfall, the abrupt transition from flood waves to pressurized flow within the circular culvert, and trapped air pockets can also pose significant challenges to the tunnel’s drainage efficiency. Conventional design methods often fail to optimize the culvert’s diameter and spatial configuration, leading to suboptimal performance. In response, this study utilizes 3D numerical simulations with the interFoam solver from the OpenFOAM toolbox to address these issues. The results indicate that smaller culvert diameters—provided they do not exceed the maximum permissible flow velocity—enhance drainage capacity by reducing the impact of shock waves and stabilizing flow. These findings challenge the prevailing design practice in Korea, which holds that larger culverts inherently offer superior drainage capacity. Moreover, the simulations suggest that as culvert diameters increase, the size of trapped air pockets grows, further reducing efficiency. Although air chambers can help mitigate the retarding effects of trapped air pockets, their effectiveness diminishes if positioned near the origin of shock waves, where they risk being filled with stormwater. Based on these insights, several key recommendations are proposed: First, the design of deep stormwater tunnels should prioritize minimizing the extent of trapped air pockets, even when air chambers are used. Second, the current focus on detention capacity in design practices should be reevaluated, as excessive detention capacity may exacerbate air pocket formation. Finally, modifying the inlet channel to induce spiral flow within the entrance reservoir could reduce impulsive forces, lower maintenance costs related to armoring rocks at the reservoir bottom, and stabilize flow more quickly, thereby enhancing overall drainage capacity. Abstract Deep stormwater drainage tunnels play a crucial role in mitigating severe urban flooding in Korea, particularly as climate change leads to more extreme weather events. These tunnels typically consist of an entrance reservoir, a circular reinforced concrete culvert with a flat slope, a downstream reservoir, and an outlet to a nearby river. In this system, the flow within the circular culvert is driven solely by the momentum of free-falling stormwater runoff. However, concerns have emerged within the Korean water resources engineering community about the drainage capacity of these tunnels, even with a substantial fall height of approximately 30 m. Intensified localized rainfall, the abrupt transition from flood waves to pressurized flow within the circular culvert, and trapped air pockets can also pose significant challenges to the tunnel’s drainage efficiency. Conventional design methods often fail to optimize the culvert’s diameter and spatial configuration, leading to suboptimal performance. In response, this study utilizes 3D numerical simulations with the interFoam solver from the OpenFOAM toolbox to address these issues. The results indicate that smaller culvert diameters—provided they do not exceed the maximum permissible flow velocity—enhance drainage capacity by reducing the impact of shock waves and stabilizing flow. These findings challenge the prevailing design practice in Korea, which holds that larger culverts inherently offer superior drainage capacity. Moreover, the simulations suggest that as culvert diameters increase, the size of trapped air pockets grows, further reducing efficiency. Although air chambers can help mitigate the retarding effects of trapped air pockets, their effectiveness diminishes if positioned near the origin of shock waves, where they risk being filled with stormwater. Based on these insights, several key recommendations are proposed: First, the design of deep stormwater tunnels should prioritize minimizing the extent of trapped air pockets, even when air chambers are used. Second, the current focus on detention capacity in design practices should be reevaluated, as excessive detention capacity may exacerbate air pocket formation. Finally, modifying the inlet channel to induce spiral flow within the entrance reservoir could reduce impulsive forces, lower maintenance costs related to armoring rocks at the reservoir bottom, and stabilize flow more quickly, thereby enhancing overall drainage capacity. Deep stormwater drainage tunnels play a crucial role in mitigating severe urban flooding in Korea, particularly as climate change leads to more extreme weather events. These tunnels typically consist of an entrance reservoir, a circular reinforced concrete culvert with a flat slope, a downstream reservoir, and an outlet to a nearby river. In this system, the flow within the circular culvert is driven solely by the momentum of free-falling stormwater runoff. However, concerns have emerged within the Korean water resources engineering community about the drainage capacity of these tunnels, even with a substantial fall height of approximately 30 m. Intensified localized rainfall, the abrupt transition from flood waves to pressurized flow within the circular culvert, and trapped air pockets can also pose significant challenges to the tunnel's drainage efficiency. Conventional design methods often fail to optimize the culvert's diameter and spatial configuration, leading to suboptimal performance. In response, this study utilizes 3D numerical simulations with the interFoam solver from the OpenFOAM toolbox to address these issues. The results indicate that smaller culvert diameters-provided they do not exceed the maximum permissible flow velocity-enhance drainage capacity by reducing the impact of shock waves and stabilizing flow. These findings challenge the prevailing design practice in Korea, which holds that larger culverts inherently offer superior drainage capacity. Moreover, the simulations suggest that as culvert diameters increase, the size of trapped air pockets grows, further reducing efficiency. Although air chambers can help mitigate the retarding effects of trapped air pockets, their effectiveness diminishes if positioned near the origin of shock waves, where they risk being filled with stormwater. Based on these insights, several key recommendations are proposed: First, the design of deep stormwater tunnels should prioritize minimizing the extent of trapped air pockets, even when air chambers are used. Second, the current focus on detention capacity in design practices should be reevaluated, as excessive detention capacity may exacerbate air pocket formation. Finally, modifying the inlet channel to induce spiral flow within the entrance reservoir could reduce impulsive forces, lower maintenance costs related to armoring rocks at the reservoir bottom, and stabilize flow more quickly, thereby enhancing overall drainage capacity.Deep stormwater drainage tunnels play a crucial role in mitigating severe urban flooding in Korea, particularly as climate change leads to more extreme weather events. These tunnels typically consist of an entrance reservoir, a circular reinforced concrete culvert with a flat slope, a downstream reservoir, and an outlet to a nearby river. In this system, the flow within the circular culvert is driven solely by the momentum of free-falling stormwater runoff. However, concerns have emerged within the Korean water resources engineering community about the drainage capacity of these tunnels, even with a substantial fall height of approximately 30 m. Intensified localized rainfall, the abrupt transition from flood waves to pressurized flow within the circular culvert, and trapped air pockets can also pose significant challenges to the tunnel's drainage efficiency. Conventional design methods often fail to optimize the culvert's diameter and spatial configuration, leading to suboptimal performance. In response, this study utilizes 3D numerical simulations with the interFoam solver from the OpenFOAM toolbox to address these issues. The results indicate that smaller culvert diameters-provided they do not exceed the maximum permissible flow velocity-enhance drainage capacity by reducing the impact of shock waves and stabilizing flow. These findings challenge the prevailing design practice in Korea, which holds that larger culverts inherently offer superior drainage capacity. Moreover, the simulations suggest that as culvert diameters increase, the size of trapped air pockets grows, further reducing efficiency. Although air chambers can help mitigate the retarding effects of trapped air pockets, their effectiveness diminishes if positioned near the origin of shock waves, where they risk being filled with stormwater. Based on these insights, several key recommendations are proposed: First, the design of deep stormwater tunnels should prioritize minimizing the extent of trapped air pockets, even when air chambers are used. Second, the current focus on detention capacity in design practices should be reevaluated, as excessive detention capacity may exacerbate air pocket formation. Finally, modifying the inlet channel to induce spiral flow within the entrance reservoir could reduce impulsive forces, lower maintenance costs related to armoring rocks at the reservoir bottom, and stabilize flow more quickly, thereby enhancing overall drainage capacity. Deep stormwater drainage tunnels play a crucial role in mitigating severe urban flooding in Korea, particularly as climate change leads to more extreme weather events. These tunnels typically consist of an entrance reservoir, a circular reinforced concrete culvert with a flat slope, a downstream reservoir, and an outlet to a nearby river. In this system, the flow within the circular culvert is driven solely by the momentum of free-falling stormwater runoff. However, concerns have emerged within the Korean water resources engineering community about the drainage capacity of these tunnels, even with a substantial fall height of approximately 30 m. Intensified localized rainfall, the abrupt transition from flood waves to pressurized flow within the circular culvert, and trapped air pockets can also pose significant challenges to the tunnel’s drainage efficiency. Conventional design methods often fail to optimize the culvert’s diameter and spatial configuration, leading to suboptimal performance. In response, this study utilizes 3D numerical simulations with the interFoam solver from the OpenFOAM toolbox to address these issues. The results indicate that smaller culvert diameters—provided they do not exceed the maximum permissible flow velocity—enhance drainage capacity by reducing the impact of shock waves and stabilizing flow. These findings challenge the prevailing design practice in Korea, which holds that larger culverts inherently offer superior drainage capacity. Moreover, the simulations suggest that as culvert diameters increase, the size of trapped air pockets grows, further reducing efficiency. Although air chambers can help mitigate the retarding effects of trapped air pockets, their effectiveness diminishes if positioned near the origin of shock waves, where they risk being filled with stormwater. Based on these insights, several key recommendations are proposed: First, the design of deep stormwater tunnels should prioritize minimizing the extent of trapped air pockets, even when air chambers are used. Second, the current focus on detention capacity in design practices should be reevaluated, as excessive detention capacity may exacerbate air pocket formation. Finally, modifying the inlet channel to induce spiral flow within the entrance reservoir could reduce impulsive forces, lower maintenance costs related to armoring rocks at the reservoir bottom, and stabilize flow more quickly, thereby enhancing overall drainage capacity. |
| ArticleNumber | 24896 |
| Author | Cho, Yong Jun |
| Author_xml | – sequence: 1 givenname: Yong Jun surname: Cho fullname: Cho, Yong Jun email: young@uos.ac.kr organization: Department of Civil Engineering, University of Seoul |
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| Keywords | Stormwater drainage tunnel Air chamber Spiral flow Trapped air pocket Optimal design Inter-foam |
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| References | Syrakos, A. & Goulas, A. Estimate of the truncation error of finite volume discretization of the Navier-Stokes equations on co-located grids. Int. J. Numer. Methods Fluids 50, 103–130 (2006). Kissling, K. et al. A coupled pressure based solution algorithm based on the volume-of-fluid approach for two or more immiscible fluids. ECCOMAS CFD: 5th European Conf. on Computational Fluid Dynamics (2010). ChoiHGHanKYYiJEChoWHStudy on installation of underground detention facilities for reducing the flood damageJ. Korean Soc. Hazard. Mitig20121241151231:CAS:528:DC%2BC3sXjslGmu7c%3D10.9798/KOSHAM.2012.12.4.115(in Korean) PilliodJEJrPuckettEGSecond-order accurate volume-of-fluid algorithms for tracking material interfacesJ. Comput. Phys.20041994655022004JCoPh.199..465P20919051:CAS:528:DC%2BD2cXntlarsb8%3D10.1016/j.jcp.2003.12.023 DeshpandeSSAnumoluLTrujilloMFEvaluating the performance of the two-phase flow solver interFoamComput. Sci. Discov20121140161405110.1088/1749-4699/5/1/014016 JasakHOpenfoam: open source CFD in research and industryInt. J. Nav Archit. Ocean. Eng.200918994 GopalaVRvan WachemBGMVolume of fluid methods for immiscible-fluid and free-surface flowsChem. Eng. J.20081412042211:CAS:528:DC%2BD1cXntFKnsbs%3D10.1016/j.cej.2007.12.035 Municipal Government of Seoul. Feasibility Study for Enhancing Flood Defense Facilities Against Climate Change (in Korean) (2007). USA Army Corps of Engineering. Engineering and Design Tunnels and Shaft in Rock, EM1110-2-2901, CECW-EG (1997). Sussman, M. A second order coupled level set and volume-of-fluid method for computing growth and collapse of vapor bubbles. J. Comput. Phys. 187, 110–136 (2003). Municipal Government of Seoul. Technical Report on Detailed Design for the Expansion of Disaster Prevention Facilities, Including Shinwol Stormwater Runoff Detention/Drainage Facilities (in Korean) (2014). Mulligan, S., Plant, J., Nash, S. & Clifford, E. Vortex drop shaft structures: state of the art and future trends, E-proceedings of the 38th IAHR World Congress September 1–6, 2019, Panama City, Panama. (2019). WangZYangJKooFSternBA coupled level set and volume-of-fluid method for sharp interface simulation of plunging breaking wavesInt. J. Multiph. Flow.2009352272462009IJMF...35..227W1:CAS:528:DC%2BD1MXht1aktLc%3D10.1016/j.ijmultiphaseflow.2008.11.004 OpenFOAM-1.5. Openfoam: The Open Source CFD Toolbox (2008). http://www.openfoam.com/. Accessed 21 October 2023. LeeJTLimTSHurSCParkSSA study on the determination of optimal location and size for underground sluiceway designJ. Korean Soc. Hazard. Mitig20088513714510.9798/KOSHAM.2018.18.5.137(in Korean) SmithDPJrBedientPBDetention for urban flood controlJ. Water Resour. Plan. Manage. Div. ASCE1980106WR241342510.1061/JWRDDC.0000163 OpenFOAM, U. Guide. http://www.openfoam.org/docs/ (2008). Accessed 21 October 2023. HernandezJLopezJGomezPZanziCFauraFA new volume of fluid method in three dimensions. I: Multidimensional advection method with face-matched flux polyhedralInt. J. Numer. Methods Fluids2008588979212008IJNMF..58..897H10.1002/fld.1776 UbbinkOIssaRIA method for capturing sharp fluid interfaces on arbitrary meshesJ. Comput. Phys.199915326501999JCoPh.153...26U170364810.1006/jcph.1999.6276 Municipal Government of Seoul. Master Plan for Construction of Shinweol Storm Detention Facilities and Flood Management Facilities (in Korean) (2012). JoYJChoYJHow the beach restoration process, driven by bound mode infra-gravity waves underlying swells in a mild sea, is affected by the presence of LCB: a numerical studyJ. Coast. Res.202316618622 WangZYangJSternFA new volume-of-fluid method with a constructed distance function on general structured gridsJ. Comput. Phys.20122313703370222012JCoPh.231.3703W290241510.1016/j.jcp.2012.01.022 ChoYJDevelopment of physics-based morphology model with an emphasis on the interaction of incoming waves with transient bed profile due to scouring and accretion using dynamic meshJ. Coast. Disaster Prevent.20218421121910.20481/kscdp.2021.8.4.211(in Korean) Pope, S. B. Turbulent Flow (Cambridge University Press, Cambridge, 2000). Cho, Y. J. Reliability-based design optimization for a vertical-type breakwater with multiple limit-state equations under Korean marine environments varying from sea to sea. Sci. Rep. 14(1) (2024). ChoYJNumerical analysis of the beach stabilization effect of an asymmetric ripple matJ. Korean Soc. Coast Ocean. Eng.2019314283910.9765/KSCOE.2019.31.1.28(in Korean) Tharamapalan, J. & Awadhi, F. A. A. Dubai’s Deep Tunnel Storm Water System—Engineering for Sustainability, ITA-AITES World Tunnel Congress, WTC2020 and 46th General Assembly Kuala Lumpur, Malaysia 11–17 September 2020 (2020). Jasak, H. & Weller, H. G. Interface-tracking capabilities of the inter-gamma differencing scheme. Technical report, Imperial College, University of London, London (1995). Choi, Y. S. Analysis of Effect of Flooding Mitigation by Deep Stormwater Detention-Drainage Facilities. Master Thesis, Dept. of Civil Engineering, Hanyang University, Seoul, Korea (in Korean) (2015). SaitoKSrinivasanVSalazarAJModeling the disintegration of modulated liquid jets using volume-of fluid (VOF) methodologyAppl. Math. Model.20113537103730279365810.1016/j.apm.2011.01.040 ChoiJGChoYJBeach stabilization effect of an asymmetric ripple-shaped mat: a numerical studyJ. Coast. Res.2023116628632 LeeJLChoYJNumerical analysis of sediment transport rates from rip currents at an open inlet between low crested breakwaters (LCB): the role of infra-gravity wavesJ. Coast. Res.202111448949310.2112/JCR-SI114-099.1 HirtCWNicholsBDVolume of fluid method for the dynamics of free boundariesJ. Comput. Phys.1981392012251981JCoPh..39..201H10.1016/0021-9991(81)90145-5 ChoYJDevelopment of the physics-based morphology model as the platform for the optimal design of beach nourishment project: a numerical studyJ. Mar. Sci. Eng.2020882810.3390/jmse8100828 Streeter, V. L. & Wylie, E. B. Fluid Mechanics (McGraw-Hill, USA, 1975). AhnJHKwonYCHeoJHJeongCSMethod for establishing a flood management of urban watershed with underground sluicewayJ. Korean Soc. Hazard. Mitig201515520120810.9798/KOSHAM.2015.15.5.201(in Korean) DiskinBThomasJLNotes on accuracy of finite-volume discretization schemes on irregular gridsAppl. Numer. Math.201060224260260267410.1016/j.apnum.2009.12.001 Smith, J. A., Phillips, B. C. & Yu, S. 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| References_xml | – reference: Pope, S. B. Turbulent Flow (Cambridge University Press, Cambridge, 2000). – reference: DiskinBThomasJLNotes on accuracy of finite-volume discretization schemes on irregular gridsAppl. Numer. Math.201060224260260267410.1016/j.apnum.2009.12.001 – reference: LeeJTLimTSHurSCParkSSA study on the determination of optimal location and size for underground sluiceway designJ. Korean Soc. Hazard. Mitig20088513714510.9798/KOSHAM.2018.18.5.137(in Korean) – reference: ChoYJNumerical analysis of the beach stabilization effect of an asymmetric ripple matJ. Korean Soc. Coast Ocean. Eng.2019314283910.9765/KSCOE.2019.31.1.28(in Korean) – reference: Cho, Y. J. Reliability-based design optimization for a vertical-type breakwater with multiple limit-state equations under Korean marine environments varying from sea to sea. Sci. Rep. 14(1) (2024). – reference: WangZYangJSternFA new volume-of-fluid method with a constructed distance function on general structured gridsJ. Comput. Phys.20122313703370222012JCoPh.231.3703W290241510.1016/j.jcp.2012.01.022 – reference: Syrakos, A. & Goulas, A. Estimate of the truncation error of finite volume discretization of the Navier-Stokes equations on co-located grids. Int. J. Numer. Methods Fluids 50, 103–130 (2006). – reference: ChoYJDevelopment of physics-based morphology model with an emphasis on the interaction of incoming waves with transient bed profile due to scouring and accretion using dynamic meshJ. Coast. Disaster Prevent.20218421121910.20481/kscdp.2021.8.4.211(in Korean) – reference: DeshpandeSSAnumoluLTrujilloMFEvaluating the performance of the two-phase flow solver interFoamComput. Sci. Discov20121140161405110.1088/1749-4699/5/1/014016 – reference: WangZYangJKooFSternBA coupled level set and volume-of-fluid method for sharp interface simulation of plunging breaking wavesInt. J. Multiph. Flow.2009352272462009IJMF...35..227W1:CAS:528:DC%2BD1MXht1aktLc%3D10.1016/j.ijmultiphaseflow.2008.11.004 – reference: ChoYJDevelopment of the physics-based morphology model as the platform for the optimal design of beach nourishment project: a numerical studyJ. Mar. Sci. Eng.2020882810.3390/jmse8100828 – reference: ChoiHGHanKYYiJEChoWHStudy on installation of underground detention facilities for reducing the flood damageJ. Korean Soc. Hazard. Mitig20121241151231:CAS:528:DC%2BC3sXjslGmu7c%3D10.9798/KOSHAM.2012.12.4.115(in Korean) – reference: LeeJLChoYJNumerical analysis of sediment transport rates from rip currents at an open inlet between low crested breakwaters (LCB): the role of infra-gravity wavesJ. Coast. Res.202111448949310.2112/JCR-SI114-099.1 – reference: OpenFOAM-1.5. Openfoam: The Open Source CFD Toolbox (2008). http://www.openfoam.com/. Accessed 21 October 2023. – reference: PilliodJEJrPuckettEGSecond-order accurate volume-of-fluid algorithms for tracking material interfacesJ. Comput. Phys.20041994655022004JCoPh.199..465P20919051:CAS:528:DC%2BD2cXntlarsb8%3D10.1016/j.jcp.2003.12.023 – reference: Sussman, M. A second order coupled level set and volume-of-fluid method for computing growth and collapse of vapor bubbles. J. Comput. Phys. 187, 110–136 (2003). – reference: Municipal Government of Seoul. Feasibility Study for Enhancing Flood Defense Facilities Against Climate Change (in Korean) (2007). – reference: AhnJHKwonYCHeoJHJeongCSMethod for establishing a flood management of urban watershed with underground sluicewayJ. Korean Soc. Hazard. Mitig201515520120810.9798/KOSHAM.2015.15.5.201(in Korean) – reference: OpenFOAM, U. Guide. http://www.openfoam.org/docs/ (2008). Accessed 21 October 2023. – reference: Jasak, H. & Weller, H. G. Interface-tracking capabilities of the inter-gamma differencing scheme. Technical report, Imperial College, University of London, London (1995). – reference: Choi, Y. S. Analysis of Effect of Flooding Mitigation by Deep Stormwater Detention-Drainage Facilities. Master Thesis, Dept. of Civil Engineering, Hanyang University, Seoul, Korea (in Korean) (2015). – reference: Municipal Government of Seoul. Master Plan for Construction of Shinweol Storm Detention Facilities and Flood Management Facilities (in Korean) (2012). – reference: Smith, J. A., Phillips, B. C. & Yu, S. Modelling Overland Flows and Drainage Augmentation in Dubbo, 46th Floodplain Management Authorities Conference, Lismore, February 28–March 2, 2006 (2006). – reference: Mulligan, S., Plant, J., Nash, S. & Clifford, E. Vortex drop shaft structures: state of the art and future trends, E-proceedings of the 38th IAHR World Congress September 1–6, 2019, Panama City, Panama. (2019). – reference: ChoiJGChoYJBeach stabilization effect of an asymmetric ripple-shaped mat: a numerical studyJ. Coast. Res.2023116628632 – reference: HernandezJLopezJGomezPZanziCFauraFA new volume of fluid method in three dimensions. I: Multidimensional advection method with face-matched flux polyhedralInt. J. Numer. Methods Fluids2008588979212008IJNMF..58..897H10.1002/fld.1776 – reference: SmithDPJrBedientPBDetention for urban flood controlJ. Water Resour. Plan. Manage. Div. ASCE1980106WR241342510.1061/JWRDDC.0000163 – reference: Municipal Government of Seoul. Technical Report on Detailed Design for the Expansion of Disaster Prevention Facilities, Including Shinwol Stormwater Runoff Detention/Drainage Facilities (in Korean) (2014). – reference: HirtCWNicholsBDVolume of fluid method for the dynamics of free boundariesJ. Comput. Phys.1981392012251981JCoPh..39..201H10.1016/0021-9991(81)90145-5 – reference: UbbinkOIssaRIA method for capturing sharp fluid interfaces on arbitrary meshesJ. Comput. Phys.199915326501999JCoPh.153...26U170364810.1006/jcph.1999.6276 – reference: SaitoKSrinivasanVSalazarAJModeling the disintegration of modulated liquid jets using volume-of fluid (VOF) methodologyAppl. Math. Model.20113537103730279365810.1016/j.apm.2011.01.040 – reference: Kissling, K. et al. A coupled pressure based solution algorithm based on the volume-of-fluid approach for two or more immiscible fluids. ECCOMAS CFD: 5th European Conf. on Computational Fluid Dynamics (2010). – reference: JoYJChoYJHow the beach restoration process, driven by bound mode infra-gravity waves underlying swells in a mild sea, is affected by the presence of LCB: a numerical studyJ. Coast. Res.202316618622 – reference: USA Army Corps of Engineering. Engineering and Design Tunnels and Shaft in Rock, EM1110-2-2901, CECW-EG (1997). – reference: JasakHOpenfoam: open source CFD in research and industryInt. J. Nav Archit. Ocean. Eng.200918994 – reference: Streeter, V. L. & Wylie, E. B. Fluid Mechanics (McGraw-Hill, USA, 1975). – reference: Tharamapalan, J. & Awadhi, F. A. A. Dubai’s Deep Tunnel Storm Water System—Engineering for Sustainability, ITA-AITES World Tunnel Congress, WTC2020 and 46th General Assembly Kuala Lumpur, Malaysia 11–17 September 2020 (2020). – reference: GopalaVRvan WachemBGMVolume of fluid methods for immiscible-fluid and free-surface flowsChem. Eng. J.20081412042211:CAS:528:DC%2BD1cXntFKnsbs%3D10.1016/j.cej.2007.12.035 – volume: 199 start-page: 465 year: 2004 ident: 76471_CR30 publication-title: J. Comput. Phys. doi: 10.1016/j.jcp.2003.12.023 – ident: 76471_CR28 – volume: 116 start-page: 628 year: 2023 ident: 76471_CR33 publication-title: J. Coast. Res. – ident: 76471_CR3 – volume: 1 start-page: 89 year: 2009 ident: 76471_CR18 publication-title: Int. J. Nav Archit. Ocean. Eng. – volume: 8 start-page: 137 issue: 5 year: 2008 ident: 76471_CR6 publication-title: J. Korean Soc. Hazard. Mitig doi: 10.9798/KOSHAM.2018.18.5.137 – ident: 76471_CR1 – ident: 76471_CR26 doi: 10.1016/S0021-9991(03)00087-1 – ident: 76471_CR13 doi: 10.1038/s41598-024-59396-7 – volume: 106 start-page: 413 issue: WR2 year: 1980 ident: 76471_CR10 publication-title: J. Water Resour. Plan. Manage. Div. ASCE doi: 10.1061/JWRDDC.0000163 – volume: 35 start-page: 227 year: 2009 ident: 76471_CR21 publication-title: Int. J. Multiph. Flow. doi: 10.1016/j.ijmultiphaseflow.2008.11.004 – volume: 8 start-page: 828 year: 2020 ident: 76471_CR32 publication-title: J. Mar. Sci. Eng. doi: 10.3390/jmse8100828 – volume: 16 start-page: 618 year: 2023 ident: 76471_CR34 publication-title: J. Coast. Res. – ident: 76471_CR17 – volume: 231 start-page: 3703 year: 2012 ident: 76471_CR22 publication-title: J. Comput. Phys. doi: 10.1016/j.jcp.2012.01.022 – ident: 76471_CR11 – ident: 76471_CR14 doi: 10.3850/38WC092019-1813 – ident: 76471_CR27 doi: 10.1002/fld.1038 – ident: 76471_CR8 – volume: 141 start-page: 204 year: 2008 ident: 76471_CR20 publication-title: Chem. Eng. J. doi: 10.1016/j.cej.2007.12.035 – ident: 76471_CR25 – volume: 153 start-page: 26 year: 1999 ident: 76471_CR38 publication-title: J. Comput. Phys. doi: 10.1006/jcph.1999.6276 – volume: 39 start-page: 201 year: 1981 ident: 76471_CR19 publication-title: J. Comput. Phys. doi: 10.1016/0021-9991(81)90145-5 – ident: 76471_CR2 – volume: 12 start-page: 115 issue: 4 year: 2012 ident: 76471_CR4 publication-title: J. Korean Soc. Hazard. Mitig doi: 10.9798/KOSHAM.2012.12.4.115 – volume: 1 start-page: 14016 year: 2012 ident: 76471_CR15 publication-title: Comput. Sci. Discov doi: 10.1088/1749-4699/5/1/014016 – volume: 8 start-page: 211 issue: 4 year: 2021 ident: 76471_CR36 publication-title: J. Coast. Disaster Prevent. doi: 10.20481/kscdp.2021.8.4.211 – volume: 15 start-page: 201 issue: 5 year: 2015 ident: 76471_CR5 publication-title: J. Korean Soc. Hazard. Mitig doi: 10.9798/KOSHAM.2015.15.5.201 – ident: 76471_CR37 – ident: 76471_CR9 – volume: 114 start-page: 489 year: 2021 ident: 76471_CR35 publication-title: J. Coast. Res. doi: 10.2112/JCR-SI114-099.1 – ident: 76471_CR16 – volume: 35 start-page: 3710 year: 2011 ident: 76471_CR23 publication-title: Appl. Math. Model. doi: 10.1016/j.apm.2011.01.040 – volume: 58 start-page: 897 year: 2008 ident: 76471_CR24 publication-title: Int. J. Numer. Methods Fluids doi: 10.1002/fld.1776 – volume: 60 start-page: 224 year: 2010 ident: 76471_CR29 publication-title: Appl. Numer. Math. doi: 10.1016/j.apnum.2009.12.001 – ident: 76471_CR12 – volume: 31 start-page: 28 issue: 4 year: 2019 ident: 76471_CR31 publication-title: J. Korean Soc. Coast Ocean. Eng. doi: 10.9765/KSCOE.2019.31.1.28 – ident: 76471_CR7 |
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| SubjectTerms | 639/166 704/4111 Air chamber Climate change Culverts Design Drainage Extreme weather Flood waves Flooding Floods Flow velocity Humanities and Social Sciences Inter-foam Maintenance costs multidisciplinary Optimal design Outlets Reinforced concrete Reservoirs Science Science (multidisciplinary) Shock waves Spiral flow Storm runoff Stormwater Stormwater drainage tunnel Stormwater management Trapped air pocket Tunnels Water resources |
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| Title | Optimal design of deep stormwater drainage tunnels to address urban flooding in Korea |
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