Constraint programming for reservoir operation optimization of Bhumibol dam
The modern constraint programming (CP) was adopted to minimize water scarcity and excessive water which are the critical issues in reservoir operation of Bhumibol Dam (BB) to solve consecutive droughts in the Chao Phraya River Basin (CPYRB), Thailand. The situations of the severe droughts have been...
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| Published in | Applied water science Vol. 14; no. 6; pp. 142 - 13 |
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| Main Authors | , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Cham
Springer International Publishing
01.06.2024
Springer Nature B.V SpringerOpen |
| Subjects | |
| Online Access | Get full text |
| ISSN | 2190-5487 2190-5495 |
| DOI | 10.1007/s13201-024-02179-2 |
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| Abstract | The modern constraint programming (CP) was adopted to minimize water scarcity and excessive water which are the critical issues in reservoir operation of Bhumibol Dam (BB) to solve consecutive droughts in the Chao Phraya River Basin (CPYRB), Thailand. The situations of the severe droughts have been frequently occurred in a broad area of CPYRB due to an extremely low rainfall leading to unusually low water levels and inflow in major reservoirs. Therefore, multi-objective optimization was conducted to characterize the actual operation and physical reservoir system of BB Dam. Two different CP models with seasonal and yearly constraints were manipulated using MiniZinc programming language and the constraint solver IPOPT to find the optimal daily release scheme from 2000 to 2018 of BB Dam. The potential of downstream flow conditions was also considered to partially supply downstream water demand and store savable water in a reservoir for subsequent use during possible future droughts. The results reveal that CP models can diminish some extent of yearly reservoir release, while daily long-term release scheme conforms well with the actual operation particularly during dry and wet seasons in specific drought years. These mean that amount of reservoir water of approximately 47.12–103.83 MCM/year can be saved and stored in reservoir for subsequent use in CPYRB when CP models are deployed. This results in a reservoir storage increase of 7.10–7.94% at the end of the wet season for seasonal and yearly CP models, respectively. When potential side flow is considered, the increase climbs up to 10.49%. This envisages the higher possibility of supplying reservoir water for agricultural water needs over the dry season in the Greater Chao Phraya Irrigation Scheme. As the potential hydraulic head is subject to increased reservoir water storage, therefore, the increase in hydropower production is definitely found of ranging from + 6.10% to + 13.79% by these two sorts of CP models. In addition, handling with huge volumes of flood and drought by CP models is well managed as the specific release constraints during refilled and drawdown periods are used to define the constraint satisfaction problem. |
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| AbstractList | The modern constraint programming (CP) was adopted to minimize water scarcity and excessive water which are the critical issues in reservoir operation of Bhumibol Dam (BB) to solve consecutive droughts in the Chao Phraya River Basin (CPYRB), Thailand. The situations of the severe droughts have been frequently occurred in a broad area of CPYRB due to an extremely low rainfall leading to unusually low water levels and inflow in major reservoirs. Therefore, multi-objective optimization was conducted to characterize the actual operation and physical reservoir system of BB Dam. Two different CP models with seasonal and yearly constraints were manipulated using MiniZinc programming language and the constraint solver IPOPT to find the optimal daily release scheme from 2000 to 2018 of BB Dam. The potential of downstream flow conditions was also considered to partially supply downstream water demand and store savable water in a reservoir for subsequent use during possible future droughts. The results reveal that CP models can diminish some extent of yearly reservoir release, while daily long-term release scheme conforms well with the actual operation particularly during dry and wet seasons in specific drought years. These mean that amount of reservoir water of approximately 47.12–103.83 MCM/year can be saved and stored in reservoir for subsequent use in CPYRB when CP models are deployed. This results in a reservoir storage increase of 7.10–7.94% at the end of the wet season for seasonal and yearly CP models, respectively. When potential side flow is considered, the increase climbs up to 10.49%. This envisages the higher possibility of supplying reservoir water for agricultural water needs over the dry season in the Greater Chao Phraya Irrigation Scheme. As the potential hydraulic head is subject to increased reservoir water storage, therefore, the increase in hydropower production is definitely found of ranging from + 6.10% to + 13.79% by these two sorts of CP models. In addition, handling with huge volumes of flood and drought by CP models is well managed as the specific release constraints during refilled and drawdown periods are used to define the constraint satisfaction problem. Abstract The modern constraint programming (CP) was adopted to minimize water scarcity and excessive water which are the critical issues in reservoir operation of Bhumibol Dam (BB) to solve consecutive droughts in the Chao Phraya River Basin (CPYRB), Thailand. The situations of the severe droughts have been frequently occurred in a broad area of CPYRB due to an extremely low rainfall leading to unusually low water levels and inflow in major reservoirs. Therefore, multi-objective optimization was conducted to characterize the actual operation and physical reservoir system of BB Dam. Two different CP models with seasonal and yearly constraints were manipulated using MiniZinc programming language and the constraint solver IPOPT to find the optimal daily release scheme from 2000 to 2018 of BB Dam. The potential of downstream flow conditions was also considered to partially supply downstream water demand and store savable water in a reservoir for subsequent use during possible future droughts. The results reveal that CP models can diminish some extent of yearly reservoir release, while daily long-term release scheme conforms well with the actual operation particularly during dry and wet seasons in specific drought years. These mean that amount of reservoir water of approximately 47.12–103.83 MCM/year can be saved and stored in reservoir for subsequent use in CPYRB when CP models are deployed. This results in a reservoir storage increase of 7.10–7.94% at the end of the wet season for seasonal and yearly CP models, respectively. When potential side flow is considered, the increase climbs up to 10.49%. This envisages the higher possibility of supplying reservoir water for agricultural water needs over the dry season in the Greater Chao Phraya Irrigation Scheme. As the potential hydraulic head is subject to increased reservoir water storage, therefore, the increase in hydropower production is definitely found of ranging from + 6.10% to + 13.79% by these two sorts of CP models. In addition, handling with huge volumes of flood and drought by CP models is well managed as the specific release constraints during refilled and drawdown periods are used to define the constraint satisfaction problem. |
| ArticleNumber | 142 |
| Author | Sawangphol, Wudhichart Kraisangka, Jidapa Phankamolsil, Yutthana Rittima, Areeya Tabucanon, Allan Sriratana Talaluxmana, Yutthana Vudhivanich, Varawoot |
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| Cites_doi | 10.3390/hydrology6010005 10.1007/978-3-540-74970-738 10.1007/s11831-021-09701-8 10.1007/s10107-004-0559-y 10.1109/ACCESS.2019.2929196 10.1016/j.ijsrc.2015.10.001 10.1287/mnsc.6.1.73 10.1007/s11269-021-02841-3 10.3390/w10081031 10.4186/ej.2022.26.10.39 10.1007/s11356-018-1867-8 10.1016/S1574-6526(06)80006-4 10.1029/2021WR029927 10.1071/MF10047 10.1007/s12205-018-2095-y 10.46647/ijetms.2023.v07i05.043 10.3390/su7021558 10.5281/zenodo.18254 10.3390/w13162146 10.1016/j.ejor.2003.08.068 10.1007/s11269-005-9011-1 10.1016/j.esr.2022.100883 10.1623/hysj.53.2.434 10.1016/j.jhydrol.2018.07.024 |
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| Keywords | Chao Phraya river basin MiniZinc modelling language Reservoir operation Constraint programming Bhumibol dam |
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| Snippet | The modern constraint programming (CP) was adopted to minimize water scarcity and excessive water which are the critical issues in reservoir operation of... Abstract The modern constraint programming (CP) was adopted to minimize water scarcity and excessive water which are the critical issues in reservoir operation... |
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| SubjectTerms | Aquatic Pollution Bhumibol dam Chao Phraya river basin Comparative Law Constraint programming Dams Downstream Drawdown Drought Dry season Earth and Environmental Science Earth Sciences Flood management Hydroelectric power Hydrogeology Industrial and Production Engineering Inflow International & Foreign Law MiniZinc modelling language Multiple objective analysis Nanotechnology Optimization Original Article Piezometric head Private International Law Programming languages Rainfall Rainy season Reservoir operation Reservoir storage River basins Seasons Waste Water Technology Water demand Water Industry/Water Technologies Water inflow Water levels Water Management Water Pollution Control Water scarcity Water storage Wet season |
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| Title | Constraint programming for reservoir operation optimization of Bhumibol dam |
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