Joint RES and distribution network expansion planning under a demand response framework /

Joint RES and Distribution Network Expansion Planning under a Demand Response Framework explains the implementation of algorithms needed for joint expansion planning of distributed generation and the distribution network models. It discusses how to expand the generation and distribution network addi...

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Détails bibliographiques
Cote:Libro Electrónico
Auteurs principaux: Contreras, Javier (Auteur), Asensio, Miguel (Auteur)
Format: Électronique eBook
Langue:Inglés
Publié: London, UK : Academic Press is an imprint of Elsevier, [2016]
Sujets:
Electric power systems > Mathematical models.
Electric power production > Mathematical models.
Electric power distribution > Mathematical models.
R�eseaux �electriques (�Energie) > Mod�eles math�ematiques.
�Electricit�e > Production > Mod�eles math�ematiques.
TECHNOLOGY & ENGINEERING > Mechanical.
Electric power distribution > Mathematical models
Electric power production > Mathematical models
Electric power systems > Mathematical models
Accès en ligne:Texto completo
Table des matières:
  • Front Cover; Joint RES and Distribution Network Expansion Planning Under a Demand Response Framework; Copyright Page; Contents; 1 Introduction; 1.1 Historical Background and Motivation; 1.2 Outline; 2 Renewable Power Generation Models; 2.1 Photovoltaic Energy; 2.1.1 Introduction; 2.1.2 Power Output and I-V Curves; 2.1.3 Parameters and Operating Conditions; 2.1.4 Models for Photovoltaic Systems; 2.1.4.1 Progensa's Model [37]; 2.1.4.2 Atwa's Model [38]; 2.1.4.3 Borowy's Model [39]; 2.2 Wind Energy; 2.2.1 Introduction; 2.2.2 Impact of Height; 2.2.3 Wind Generation Model; 3 Uncertainty Modeling.
  • 3.1 Introduction3.2 Method Based on Load, Wind, and Irradiation Curves; 3.2.1 Step 1; 3.2.2 Step 2; 3.2.3 Step 3; 3.2.4 Step 4; 3.2.5 Step 5; 3.2.6 Step 6; 3.2.7 Step 7; 4 Demand Response Modeling; 4.1 Demand Response Modeling; 4.1.1 Incentive-Based Programs (IBP); 4.1.2 Price-Based Programs (PBP); 4.2 Formulation; 4.3 Methodologies to Include Short-Term DR Into Expansion Planning; 5 Energy Storage Systems Modeling; 5.1 Benefits Derived From the Use of ESS; 5.1.1 Technical Benefits; 5.1.2 Economic Benefits; 5.2 ESS Technologies; 5.3 Storage Unit Model; 6 Optimization Problem Formulation.
  • 6.1 Objective Function6.2 Constraints; 6.2.1 Integrality Constraints; 6.2.2 Balance Equations; 6.2.3 Kirchhoff's Voltage Law; 6.2.4 Voltage Limits; 6.2.5 Capacity Limits for Feeders; 6.2.6 Capacity Limits for Transformers; 6.2.7 Capacity Limits for Generators; 6.2.8 Unserved Energy; 6.2.9 DG Penetration Limit; 6.2.10 Capacity Limits for Storage; 6.2.11 Investment Constraints; 6.2.12 Utilization Constraints; 6.2.13 Investment Limits; 6.2.14 Radiality Constraints; 6.2.15 Demand Response to Load Level-Changing Prices; 6.2.16 Generic Storage Formulation; 6.3 Linearizations; 6.3.1 Energy Losses.
  • 6.3.2 Kirchhoff's Voltage Law7 Case Study; 7.1 La Graciosa Case Study; 7.2 Results Without DR and Hybrid Storage; 7.3 Results With DR; 7.4 Results With Hybrid Storage; 7.5 Results With DR and Hybrid Storage; 7.6 Impact of DR and Hybrid Storage in Generation and Distribution Expansion Planning; 7.7 Cost-Benefit Analysis; 8 Summary and Conclusions; 8.1 Summary; 8.2 Conclusions; Nomenclature; 1 Sets and Indexes; 2 Parameters; 3 Variables; References; Back Cover.

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