A multi-reservoir based water-hydroenergy management model for identifying the risk horizon of regional resources-energy policy under uncertainties

[Display omitted] •A multi-reservoir system can handle water/energy deficit, flood and sediment damage.•A MWH model is developed for planning a water allocation and energy generation issue.•A mixed fuzzy-stochastic risk analysis method (MFSR) can handle uncertainties in MWH.•A hybrid MWH model can p...

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Bibliographic Details
Published in:Energy conversion and management 2017-07, Vol.143, p.66-84
Main Authors: Zeng, X.T., Zhang, S.J., Feng, J., Huang, G.H., Li, Y.P., Zhang, P., Chen, J.P., Li, K.L.
Format: Article
Language:English
Subjects:
A multi-reservoir system
A risk control method (RAM)
Deposition
Economic development
Electricity
Energy conservation
Energy management
Energy policy
Flood control
Floodwater
Hyper-concentration river basin
Reservoirs
Resource management
Risk analysis
Risk levels
Risk management
River basins
Rivers
Schedules
Sedimentation
Sediments
Stochastic-fuzzy programming
Stochasticity
Uncertainties
Uncertainty
Water allocation
Water allocation and hydroenergy generation (WAHG)
Water damage
Water deficit
Water resources management
Water supply
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Summary:[Display omitted] •A multi-reservoir system can handle water/energy deficit, flood and sediment damage.•A MWH model is developed for planning a water allocation and energy generation issue.•A mixed fuzzy-stochastic risk analysis method (MFSR) can handle uncertainties in MWH.•A hybrid MWH model can plan human-recourse-energy with a robust and effective manner.•Results can support adjusting water-energy policy to satisfy increasing demands. In this study, a multi-reservoir based water-hydroenergy management (MWH) model is developed for planning water allocation and hydroenergy generation (WAHG) under uncertainties. A mixed fuzzy-stochastic risk analysis method (MFSR) is introduced to handle objective and subjective uncertainties in MWH model, which can couple fuzzy credibility programming and risk management within a general two-stage context, with aim to reflect the infeasibility risks between expected targets and random second-stage recourse costs. The developed MWH model (embedded by MFSR method) can be applied to a practical study of WAHG issue in Jing River Basin (China), which encounters conflicts between human activity and resource/energy crisis. The construction of water-energy nexus (WEN) is built to reflect integrity of economic development and resource/energy conservation, as well as confronting natural and artificial damages such as water deficit, electricity insufficient, floodwater, high sedimentation deposition contemporarily. Meanwhile, the obtained results with various credibility levels and target-violated risk levels can support generating a robust plan associated with risk control for identification of the optimized water-allocation and hydroenergy-generation alternatives, as well as flood controls. Moreover, results can be beneficial for policymakers to discern the optimal water/sediment release routes, reservoirs’ storage variations (impacted by sediment deposition), electricity supply schedules and system benefit plans with an effective/sustainable manner.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2017.02.020