Optimal Operation for Integrated Electricity–Heat System with Improved Heat Pump and Storage Model to Enhance Local Energy Utilization

Chen, Yang; Zhang, Yao; Wang, Jianxue; Lu, Zelong

doi:10.3390/en13246729

Cited by 16 publications

(10 citation statements)

References 20 publications

(18 reference statements)

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“…This section considers the constraints described above based on the hourly output curve, then simulates the model with the maximum peak-shaving ability by the LSSDCM and the ADMM described in Ref. [33]. Algorithm comparison results are shown in Fig.…”

Section: B Peak-shaving Ability Modelmentioning

confidence: 99%

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Hybrid Time-Scale Optimal Scheduling Considering Multi-Energy Complementary Characteristic

et al. 2021

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Evaluating the potential utilization of hybrid energy systems and determining the multi-scale optimal operation strategy is critical to power system planning in the context of energy structure adjustment, especially for large-scale hybrid energy systems. Considering the long-term and short-term complementary characteristics, this paper puts forward a coordinated optimization framework for the integrated energy system in the world's largest multi-energy complementary base on Yellow River's upper reaches. The main procedures are as follows: 1) cross-correlation method is introduced for individually analyzing the long-and short-term complementary characteristics of wind power, photovoltaic, and hydropower in this multi-energy complementary base; 2) a double-layer model combining the long-term optimal operation model and short-term optimal operation model for determining the proportion of multiple energy and optimizing the maximum peak-shaving ability; 3) Large-Scale System Decomposition-Coordination Method is applied for solving the proposed double-layer operation model. The results show that wind power 23%, photovoltaic 35%, hydropower 42% can keep the most stable generation in the long-term complementary operation. This proportion results can improve the system peak regulation capacity with 50.8% (sunny day's morning peak) and 24.2% (rainy day's morning peak) in the optimal short-term operation.INDEX TERMS Hybrid time-scale; Large-scale energy; Multi-energy complementary characteristics; Optimal operation strategy;

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Section: B Peak-shaving Ability Modelmentioning

confidence: 99%

“…Ref. [33] discussed the cooperation of integrated electricity-heat systems, proposed a distributed algorithm based on the alternating direction method of multipliers (ADMM) to preserve the information privacy of separate systems. Ref.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Time-Scale Optimal Scheduling Considering Multi-Energy Complementary Characteristic

et al. 2021

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“…The thermal power of the heat source and heat load is related to the node water supply temperature, return water temperature, and hot water parameters in the pipeline, which can be expressed by Equation (7). In addition, the temperature of supply and return water should satisfy the design upper and lower limits of pipeline temperature, as shown in Equations ( 8) and (9).…”

Section: A Node Thermal Power Modelmentioning

confidence: 99%

“…With the application and development of combined heat and power (CHP) technology, the coupling effect of electrical energy and thermal energy has been gradually enhanced [4,5]. The interaction between the power system and the thermal system in IEHS plays an important role in facilitating the cost-effective transition to a low-carbon energy system with high penetration of renewable generation [6][7][8]. At present, it is urgent to establish a more perfect electro-thermal co-ordination dispatching mechanism, which can satisfy the requirements of heating load, reduce the operation cost of the system, and reduce the waste of wind and photovoltaic energy at the same time.…”

Section: Introductionmentioning

confidence: 99%

Optimal Dispatching of Integrated Electricity and Heating System with Multiple Functional Areas Considering Heat Network Flow Regulation

Zhang

Chen

et al. 2021

Energies

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The integrated electricity and heating system (IEHS) can satisfy the diversified energy demand and improve energy efficiency through electro-thermal synergy and complementarity, which is beneficial for energy transformation and global climate governance. To reduce the operation cost, renewable energy source (RES) abandonment, and purchased electricity of IEHS, an optimal dispatching method of IEHS with multiple functional areas considering the flow regulation of the heat network is proposed. Firstly, the functional area of IEHS is classified and the functional area’s load characteristics are analyzed. Secondly, a heat network model considering refined resistance and dynamic characteristics is constructed and the operation regulation modes of the heat network are analyzed. Thirdly, an optimal dispatching model of IEHS with multiple functional areas considering heat network flow regulation is established to minimize the operation cost of IEHS with multiple functional areas while considering the penalty cost of RES abandonment and time-of-use electricity price. Finally, a certain region in China is taken as a case study to verify the effectiveness of the proposed optimal dispatching model. The case study shows that the quality regulation mode of the heat network considering flow change in multiple stages can effectively reduce RES abandonment by 2.4%, purchased electricity by 5.4%, and the system operation cost by 1.7%. In addition, compared with the independent dispatching of each functional area, the joint dispatching of IEHS with multiple functional areas can reduce the amount of RES abandonment by 95.2% and purchased electricity by 66.5%, and lower the operation cost of IEHS by 23.6%.

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“…A SMG consists of energy generation, sensitive loads, and smart mechanisms to control electricity flow. 3,4 Benefits of SMG include improvement of reliability by providing self-healing characteristic at local distribution grid, reducing carbon emission using renewable energy resources, and earning efficiency in operation along with reduction of costs. 5,6 1.2 | GTEP in MGs using noncooperative game theory approach Power system planners use simultaneous GTEP to achieve a reliable, safe, and economical system.…”

Section: Mgs In Distribution Gridmentioning

confidence: 99%

Multi‐agent decentralized microgrids planning considering long‐term demand response model

Nemati

Hosseini

2021

Intl J of Energy Research

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Demand-side management resources, such as demand response programs (DRPs) are useful options for the reduction of energy cost according to the viewpoint of department of energy. Utilizing these resources in long-term studies like generation and transmission expansion planning (GTEP) needs longterm modeling. In this article, the GTEP was developed considering long-term model of DRPs using a cooperative game theory approach to minimize the total cost of microgrids (MGs). A two-level decision-making method was used to develop this model. On the top level, investment decisions were cooperatively made by MGs and a stochastic chance-constrained mixed integer linear programming formulation was modeled for investment decisions with operational uncertainties on the bottom level. The self-sufficiency index was also considered that guarantees supply of sensitive loads in islanding mode. Effec-

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Optimal Operation for Integrated Electricity–Heat System with Improved Heat Pump and Storage Model to Enhance Local Energy Utilization

Cited by 16 publications

References 20 publications

Hybrid Time-Scale Optimal Scheduling Considering Multi-Energy Complementary Characteristic

Hybrid Time-Scale Optimal Scheduling Considering Multi-Energy Complementary Characteristic

Optimal Dispatching of Integrated Electricity and Heating System with Multiple Functional Areas Considering Heat Network Flow Regulation

Multi‐agent decentralized microgrids planning considering long‐term demand response model

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