Combined Dispatching of Hydropower and Wind Power Based on the Hedging Theory
Abstract
:1. Introduction
2. Materials and Methods
2.1. Hedging Theory
2.2. Application of Hedging Rules in Reservoir Operation
2.3. Analysis of Multi-Objective Hedging Relationship in Hydropower and Wind Power Joint Dispatching
2.4. Dynamic Decision-Making Process for Joint Dispatch of Hydropower and Wind Power Based on Hedging Theory
2.5. Calculation of Water Storage Benefit and Flood Control Risk Considering the Uncertainty of Forecast Information
2.5.1. Calculation of Flood Control Risk Considering the Uncertainty of Forecast Information
2.5.2. Calculation of Benefits of Water Storage
2.6. Establishment of Dispatching Model of Hydropower and Wind Power Based on Hedging Theory
2.6.1. Objective Functions
2.6.2. Constraints
- Hydropower output constraint
- Wind power output constraint
- Combined system power generation output constraint
- Reservoir capacity constraint
- Water balance constraint
- Discharge flow of the reservoir constraint
- Water level constraint
- Hydropower output climbing constraintLimiting the range of changes in the output of hydropower stations in adjacent periods.
2.7. Solution to the Dispatching Model of Hydropower and Wind Power Based on Hedging Theory
3. Results
3.1. Problem Description
3.2. Determine Some Indicators and Parameters
3.3. Analysis of the Dispatch of Hydropower and Wind Power Based on Hedging Theory
4. Conclusions
- The joint dispatching of hydropower and wind power is a multi-objective conflict problem, and the hedging theory can be introduced into the joint dispatching problem of hydropower and wind power for analysis.
- On the basis of considering the uncertainty of wind power and the uncertainty of the interval flow, an optimal dispatching model of hydropower and wind power based on the hedging theory is constructed during the flood season,
- The NSGA2 algorithm is used to solve the specific calculation examples. In the scheduling plan finally solved by the model built in this paper, the peak-valley difference of joint output ranges from 125.00 MW to 35.66 MW. It can effectively solve the problem of wind power volatility and improve the capacity of wind power utilization. Simultaneously, the water storage level was raised by 0.7 m, and the flood control risk is controlled below 1.63 × 10−3. The optimal water storage capacity decision is obtained, and the water storage benefit is as large as possible on the basis of ensuring flood control risks.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
Variables | |
the water discharge | |
the hydropower output | |
the water inflow | |
the inflow of water from the reservoir and downstream section | |
the water storage of stage | |
the wind power output | |
the flood control risk of stage | |
total incoming water for stage | |
safe water volume of stage | |
reservoir capacity of stage | |
flood limit water level | |
incoming water error in stage 2 | |
incoming water error of the downstream control station of stage 2 | |
probability density function | |
added value of water storage benefit | |
benefit difference | |
storage capacity corresponding to normal storage level | |
corresponding storage capacity of flood limit water level | |
the combined total power generation of hydropower and wind power | |
the hydropower generation | |
the wind power generation | |
the output of the wind power station | |
SOP | the Standard Operation Policy |
HR | the Hedging Rules |
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Total Storage Capacity (×106 m3) | Beneficial Reservoir Capacity (×106 m3) | Dead Storage Capacity (×106 m3) | Normal Water Level (m) |
3660 | 2400 | 1380 | 588 |
Dead Water Level (m) | Flood Limit Water Level (m) | Installed Capacity (MW) | Guaranteed Output (MW) |
570 | 583 | 280 | 65 |
Goals | Optimal Decision of Reservoir’s Water Storage Benefit | Optimal Decision of Downstream Flood Control Risk | Optimal Decision on Volatility of Combined Power Generation | Optimal Decision with the Highest Degree of Satisfaction |
---|---|---|---|---|
Water storage benefit difference | 6.38 × 10−3 | 7.07 × 10−3 | 6.58 × 10−3 | 6.65 × 10−3 |
Flood control risk | 5.56 × 10−3 | 1.14 × 10−4 | 2.48 × 10−3 | 1.63 × 10−3 |
Joint output volatility | 8.11 | 21.3 | 0.56 | 3.57 |
Method | Water Storage Benefit | Flood Risk |
---|---|---|
Result based on the hedging theory plan | 6.65 × 10−3 | 1.63 × 10−3 |
The result of the conventional plan | 6.562 × 10−3 | 3.65 × 10−3 |
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Zhang, K.; Xie, M.; Zhang, G.; Xie, T.; Li, X.; He, X. Combined Dispatching of Hydropower and Wind Power Based on the Hedging Theory. Water 2021, 13, 1319. https://doi.org/10.3390/w13091319
Zhang K, Xie M, Zhang G, Xie T, Li X, He X. Combined Dispatching of Hydropower and Wind Power Based on the Hedging Theory. Water. 2021; 13(9):1319. https://doi.org/10.3390/w13091319
Chicago/Turabian StyleZhang, Kaoshe, Mengyan Xie, Gang Zhang, Tuo Xie, Xin Li, and Xin He. 2021. "Combined Dispatching of Hydropower and Wind Power Based on the Hedging Theory" Water 13, no. 9: 1319. https://doi.org/10.3390/w13091319
APA StyleZhang, K., Xie, M., Zhang, G., Xie, T., Li, X., & He, X. (2021). Combined Dispatching of Hydropower and Wind Power Based on the Hedging Theory. Water, 13(9), 1319. https://doi.org/10.3390/w13091319