Source-Grid-Load Cross-Area Coordinated Optimization Model Based on IGDT and Wind-Photovoltaic-Photothermal System
Abstract
:1. Introduction
2. Cross-Area Interconnection System Model
Sending-End Power System
3. Economic Dispatch Model of a Cross-Regional Interconnected System
3.1. Objective Function
3.2. Constraints
- (1)
- Sending-end system constraints
- (a)
- Energy balance constraints
- (b)
- The upper and lower output constraints of other units
- (c)
- Energy storage device constraints
- (d)
- Network security constraints
- (2)
- Receiving-end system constraints
3.3. Optimization Model Based on IGDT
3.4. Model Solution
4. Example Analysis
4.1. Input Data and Scenario Setup
- (1)
- Input data
- (2)
- Scenario setup
4.2. Operation Analysis
- (1)
- Scheduling results
- (2)
- Analysis of CSP plants’ capacity
- (3)
- Impact of IGDT on scheduling results
5. Conclusions
- (1)
- The source-grid-load coordinated scheduling can more reasonably formulate the scheduling plan according to the regulation period and regulation characteristics of the three sides of the peaking resources so as to effectively realize the coordination and complementarity of the peaking resources on each side. At the same time, the comprehensive operating cost of the system is reduced.
- (2)
- The introduction of information gap decision theory can reduce the impact of load uncertainty on the system scheduling results. Based on IGDT theory, this paper proposes a coordinated inter-area scheduling strategy for source-network-load of the wind-photovoltaic-photothermal system, including both risk-seeking and risk-averse strategies, which can provide decision-making references for the scheduling strategy makers.
- (3)
- The ADMM algorithm is introduced into the solution of the cross-area power trading model, which can prevent the model from falling into the local optimal solution and improve the solution efficiency.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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Installation | Capacity | Proportion |
---|---|---|
Wind Power | 1200 | 23.24% |
Photovoltaic | 900 | 17.43% |
Photothermal | 1800 | 34.86% |
Thermal Power | 1163 | 22.53% |
Gas boilers | 100 | 1.94% |
Final Assembly Machine | 5163 | 100.00% |
Scenario | 1 | 2 | 3 |
---|---|---|---|
CSP plant | √ | √ | √ |
IGDT (risk-seeking strategy) | × | √ | √ |
IGDT (risk-averse strategy) | × | × | √ |
Scenario | Scenario 1 | Scenario 2 | Scenario 3 |
---|---|---|---|
Electricity Trading Volume/MW | 2875.44 | 2114.40 | 1304.11 |
Sending-end system cost/CNY | 28,766 | 17,690 | 32,854 |
Receiving-end system cost/CNY | 128,662 | 81,030 | 72,297 |
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Xu, Y.; Hu, Z. Source-Grid-Load Cross-Area Coordinated Optimization Model Based on IGDT and Wind-Photovoltaic-Photothermal System. Sustainability 2024, 16, 2056. https://doi.org/10.3390/su16052056
Xu Y, Hu Z. Source-Grid-Load Cross-Area Coordinated Optimization Model Based on IGDT and Wind-Photovoltaic-Photothermal System. Sustainability. 2024; 16(5):2056. https://doi.org/10.3390/su16052056
Chicago/Turabian StyleXu, Yilin, and Zeping Hu. 2024. "Source-Grid-Load Cross-Area Coordinated Optimization Model Based on IGDT and Wind-Photovoltaic-Photothermal System" Sustainability 16, no. 5: 2056. https://doi.org/10.3390/su16052056
APA StyleXu, Y., & Hu, Z. (2024). Source-Grid-Load Cross-Area Coordinated Optimization Model Based on IGDT and Wind-Photovoltaic-Photothermal System. Sustainability, 16(5), 2056. https://doi.org/10.3390/su16052056