2020
DOI: 10.1002/er.5307
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Cross‐regional integrated energy system scheduling optimization model considering conditional value at risk

Abstract: Integrated energy system is a very important way to improve energy efficiency. Based on the combined heating cooling and power system, combined with energy storage equipment, a cross-regional integrated energy system scheduling optimization problem is studied. An integrated energy system scheduling optimization model is established that meets the requirements of electrical, heating, and cooling load under a variety of energy sources while both considering the interaction of electrical, heating, and cooling loa… Show more

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Cited by 19 publications
(12 citation statements)
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“…In general, the actual wind speed characteristics follow the Rayleigh distribution, as described below 24 : fWT()v=()λ/γv/γλ1exp[]v/γλ, where v represents the actual wind speed, γ , λ are the scale and shape factors. Therefore, the output of the WT is calculated as shown below 41 : xitalicWT,i()v={0,9.5emv<vin,0.5emv>voutvvinvratedvinPWTrated,2emvin v vratedPWTrated,7.5emvrated<v<vout, where v rated , v in , v out are the rated speed, the minimum and maximum input wind speed. PWTrated represents the rated power.…”
Section: Problem Formulationmentioning
confidence: 99%
“…In general, the actual wind speed characteristics follow the Rayleigh distribution, as described below 24 : fWT()v=()λ/γv/γλ1exp[]v/γλ, where v represents the actual wind speed, γ , λ are the scale and shape factors. Therefore, the output of the WT is calculated as shown below 41 : xitalicWT,i()v={0,9.5emv<vin,0.5emv>voutvvinvratedvinPWTrated,2emvin v vratedPWTrated,7.5emvrated<v<vout, where v rated , v in , v out are the rated speed, the minimum and maximum input wind speed. PWTrated represents the rated power.…”
Section: Problem Formulationmentioning
confidence: 99%
“…Operation strategy Cooling Heating Electricity Thermal characteristics [6][7][8][9][10][11] Q Q √ No consideration Open-loop [6][7][8][9][10][11] [12-16] Q Q √ Converted to Q Open-loop, 12,[14][15][16] rolling operation strategy 13 [17][18][19][20][21] Q Q √ Modeled by T (networks, [17][18][19] buildings, 18,20 or ambient 20,21 ), or by T and q (networks) [17][18][19] Robust MPC, 17 open-loop, 18,19,21 chance constraint SMPC 20 This work q,T q ,T √ Modeled by T and q (devices, networks, and ambient simultaneously)…”
Section: Scheduling Modelmentioning
confidence: 99%
“…Similarly, Liu established a model in the forms of heat constraints of heat‐supplied devices to study the collaborative planning of IES 7 . Still not considering detailed thermal processes, a bi‐level model was proposed by Lu et al 8 Considerable studies have been carried out based on such a modeling idea that oversimplifies the process variables 9‐11 . However, with the intersected energy topologies, diverse energy processes, and interdependent energy flows, 22 the IES is unquestionably of high complexity.…”
Section: Introductionmentioning
confidence: 99%
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“…Whale optimization algorithm (WOA) [17] and real-coded genetic algorithm with improved Mu¨hlenbein mutation (RCGAIMM) [18] have been employed on this issue considering the effect of both transmission losses and valve-point. In [19], scheduling optimization model of the combined energy system has been developed to meet the requirements of heating, cooling, and electrical loads. In [20], a quasidynamic pipeline model for EPHD with start-stop schedule of heat exchange stations is developed.…”
Section: Introductionmentioning
confidence: 99%