Stochastic model predictive control operation strategy of integrated energy system based on temperature‐flowrate scheduling model considering detailed thermal characteristics

Wei, Shangshang; Li, Yiguo; Sun, Li; Zhang, Junli; Shen, Jiong; Li, Zuyi

doi:10.1002/er.6069

Cited by 13 publications

(7 citation statements)

References 34 publications

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“…In order to prove the superiorities of the proposed model, a comparative study is conducted by applying two models. Case 1 is the scheduling model in [32] and Case 2 is our proposed method, the essential difference is: Case 1: temperature and flowrate are taken as decision variables, but all the performance parameters are all treated as constants. The COP i EC , COP i HP , η GT , η W HB are assumed to be 6.0, 5.0, 28%, and 80%, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…Lv [30] established an optimal operation of heat network and buildings in the form of the temperature and flowrate, and Gu [31] proposed a scheduling model considering the transmission process together with the thermal inertia of buildings with temperature parameters. Wei [32] proposed a temperature-flowrate based scheduling model that directly adopted temperature and flowrate as decision variables. Although the studies above have significant merits, this scheduling model still specified all performance parameters as constants.…”

Section: Introductionmentioning

confidence: 99%

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A Variable Performance Parameters Temperature–Flowrate Scheduling Model for Integrated Energy Systems

et al. 2021

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Optimal scheduling strategy of integrated energy systems (IES) with combined cooling, heating and power (CCHP) has become increasingly important. In order to make the scheduling strategy fit to the practical implementation, this paper proposes a variable performance parameters temperature–flowrate scheduling model for IES with CCHP. The novel scheduling model is established by taking flowrate and temperature as decision variables directly. In addition, performance parameters are treated as variables rather than constants in the proposed model. Specifically, the efficiencies of the gas turbine and the waste heating boiler are estimated with the partial load factor, and the coefficient of performance (COP) of the electrical chillers and heat pumps are estimated with the partial load factor and outlet water temperature. Then, to deal with the model nonlinearities caused by considering the variability of COPs, the COP-expansion method is developed by adopting a specific representation of the COP and the expansion of the outlet water temperature. Finally, case studies show that the variable performance parameters’ temperature–flowrate scheduling model can account for the variation of performance parameters, especially the impacts of water temperature and the part load factor on the COP. Therefore, the proposed scheduling model can obtain more adequate and feasible operation strategy, thereby suggesting its applicability in engineering practice.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Variable Performance Parameters Temperature–Flowrate Scheduling Model for Integrated Energy Systems

et al. 2021

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“…e planning and design of comprehensive energy supply systems mostly take the economy as the planning goal, supplemented by indicators such as carbon emissions, energy efficiency, and reliability, to arrive at a comprehensive and optimal plan [12]. Wei et al established a nonlinear model considering the configuration of system equipment and optimized operation on the basis of the optimal annual cost and proposed a corresponding evaluation system and evaluation configuration plan [13]. Hung et al proposed two levels of system planning optimization and operation scheduling optimization for the planning model of the integrated energy supply system, constructed a two-level planning mathematical model considering the economy and environmental protection, and used particle swarm optimization as the solution method [14].…”

Section: Introductionmentioning

confidence: 99%

Rapid Identification of Economic Indicators of Integrated Energy Systems Based on Data Analysis

He¹,

Liu

et al. 2022

Mathematical Problems in Engineering

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The construction of integrated energy systems has received widespread attention. In addition to system design and operating optimization, clarifying the internal relationship between the project’s own characteristics and its economic indicators is also important for high-value project selection and implementation. Based on various energy prices and the climatic characteristics of typical cities, 60 integrated energy supply projects in 4 typical cities were used as a case study, and the cold and heat source system solutions with the shortest investment payback period for each project were calculated through a system optimization model. We calculated the correlation coefficient between the initial investment of system equipment, annual energy supply, annual energy sales revenue, annual equivalent full-load energy supply hours, initial equipment investment indicators for annual unit energy supply, and the project’s static investment payback period. The key factors affecting the static investment payback period of the project were identified. The results show that, under the optimal system scheme, even for buildings of the same type in the same area, the economic indicators of different integrated energy projects are still quite different. Under the current design, operation, and operation conditions, load distribution is the decisive factor for the economic feasibility of the project. The static investment payback period of the project can be quickly calculated based on the equivalent full-load energy supply hours of the project throughout the year. Compared with the current numerical and system dynamics model for point-to-point single system optimizing modeling, the proposed statistical regression model can help reveal the main factors of integrated energy system’s economically feasible.

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“…1,2 In this context, integrated energy systems appear an attractive solution to meet the energy requests of various users, [3][4][5] increase efficiency and flexibility, [6][7][8] and reduce emissions. [9][10][11] Among the available technologies, internal combustion engines (ICE), 12,13 and organic Rankine cycles (ORC) 14,15 are in the spotlight of the industry and research community. 16,17 Particularly, the internal combustion engine is a well-known and reliable technology with the prospect to maintain a preeminent role in the next future.…”

Section: Introductionmentioning

confidence: 99%

Integration of biodiesel internal combustion engines and transcritical organic Rankine cycles for waste‐heat recovery in small‐scale applications

Falbo

Perrone

Morrone

et al. 2021

Intl J of Energy Research

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The aim of the work is the analysis of a novel integrated energy system for small-scale combined heat and power (CHP) generation. The system consists of a topping biodiesel-fired internal combustion engine (ICE) and a bottoming transcritical organic Rankine cycle (TORC) for waste-heat recovery. Specifically, the engine exhaust gas provides energy to the TORC sub-system, while the energy contribution of the ICE cooling circuit assures low-temperature heat generation. Furthermore, a thermal energy storage (TES) unit for the exploitation of the thermal surplus and an auxiliary boiler are present. A mathematical model is developed to evaluate the main performances at full and partial load in terms of thermal and electric production, efficiency, fuel consumption, and primary energy saving. A preliminary analysis is carried out to find the proper organic working fluid for the TORC sub-system. Afterwards, the biodiesel ICE-TORC combined system is adopted to satisfy thermal and electric requests of a commercial centre. To this purpose, hourly energy balances are evaluated, and a techno-economic analysis is performed on an annual basis. The investigated system guarantees a 16.7% primary energy saving and an 8.4 years payback time.

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Stochastic model predictive control operation strategy of integrated energy system based on temperature‐flowrate scheduling model considering detailed thermal characteristics

Cited by 13 publications

References 34 publications

A Variable Performance Parameters Temperature–Flowrate Scheduling Model for Integrated Energy Systems

A Variable Performance Parameters Temperature–Flowrate Scheduling Model for Integrated Energy Systems

Rapid Identification of Economic Indicators of Integrated Energy Systems Based on Data Analysis

Integration of biodiesel internal combustion engines and transcritical organic Rankine cycles for waste‐heat recovery in small‐scale applications

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