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European Guide to Power System Testing : The ERIGrid Holistic Approach for Evaluating Complex Smart Grid Configurations.

Bibliographic Details
Main Author: Strasser, Thomas I.
Other Authors: de Jong, Erik C. W., Sosnina, Maria.
Format: eBook
Language:English
Published: Cham : Springer International Publishing AG, 2020.
Edition:1st ed.
Subjects:
Electronic books.
Online Access:Click to View
Table of Contents:
  • Intro
  • Preface
  • Contents
  • Acronyms
  • Towards System-Level Validation
  • 1 Higher Complexity in Future Power Systems
  • 2 Needs for System-Level Validation
  • 2.1 Engineering and Validation Process
  • 2.2 Towards a System Validation Approach
  • 2.3 Illustrative Example
  • 3 Existing Approaches and Research Directions
  • 3.1 Suitable Methods and Tools
  • 3.2 Future Research Directions
  • 4 Overview of the ERIGrid Validation Approach
  • References
  • Test Procedure and Description for System Testing
  • 1 Introduction
  • 1.1 Testing Procedure and Test Description
  • 1.2 Holistic Testing for System Validation
  • 2 Toward Procedures for System Validation
  • 2.1 Purpose of Testing in the Development Process
  • 2.2 The Need for System Testing and Its Support
  • 2.3 A Generic Procedure for System Validation
  • 2.4 Testing Chain
  • 3 ERIGrid Holistic Test Description Methodology
  • 3.1 The Requirements and Semantics of Test Description
  • 3.2 The ERIGrid Test Description for System Validation
  • 3.3 Holistic Test Description: Key Concepts
  • 3.4 Remarks on Quantitative Assessment
  • 4 Application Examples
  • 4.1 Example 1: Testing Chain
  • 4.2 Example 2: Coordinated Voltage Control
  • 5 Conclusion
  • References
  • Simulation-Based Assessment Methods
  • 1 Introduction to Smart Grid Modelling and Simulation
  • 2 Co-simulation Based Assessment
  • 2.1 Introduction to Co-simulation, Goals, and Challenges
  • 2.2 Current Co-simulation Standards and Their Functionality
  • 3 Co-simulation Framework for Smart-Grid Assessment
  • 3.1 Co-simulation Interfaces Based on FMI
  • 3.2 Mosaik for Scenario Development and Simulation Orchestration
  • 4 Scaling Considerations
  • 5 Fault Ride-Through of a Wind Park Example
  • 5.1 Experiment Setup and Objectives
  • 5.2 Results
  • 6 Conclusion
  • References
  • Hardware-in-the-Loop Assessment Methods
  • 1 Introduction.
  • 2 HIL Techniques for Validation of Smart Grid Solutions
  • 2.1 Stability of HIL Experiments
  • 2.2 Stability Assessment
  • 2.3 Approaches for the Compensation of Time Delay
  • 3 Integration of HIL Techniques into a Holistic Framework
  • 3.1 Simulation Message-Bus Based Solutions: Lab-Link and OPSIM
  • 3.2 Online Integration with SCADA as a Service Approach
  • 3.3 Quasi-static PHIL/PSIL
  • 4 Coordinated Voltage Control of a Microgrid Example
  • 4.1 CHIL Implementation via Lab-Link
  • 4.2 Multi-platform CHIL Implementation via OpSim Architecture
  • 4.3 PHIL and PSIL Implementation in PRISMES Platform
  • 5 Summary
  • References
  • Laboratory Coupling Approach
  • 1 Introduction
  • 1.1 State-of-the-Art for Smart Grid Testing
  • 1.2 Multi-infrastructure Integration
  • 2 JaNDER Communication Platform for Lab-Coupling
  • 2.1 Features of the Cloud-Based Communication Platform
  • 2.2 Basic Data Sharing via JaNDER-L0
  • 2.3 IEC 61850-Based Communication Platform via JaNDER-L1
  • 2.4 CIM-based Communication Platform via JaNDER-L2
  • 3 Integrated Research Infrastructure
  • 3.1 Hardware/Software Integration Between Different Laboratories
  • 3.2 Virtual Research Infrastructure
  • 4 Examples of Laboratory Couplings
  • 4.1 Integration of a Remote OLTC Controller via IEC 61850
  • 4.2 State Estimator Web Service
  • 4.3 Geographically Distributed Real-Time Simulation
  • 4.4 Real-Time Geographically Distributed CHIL
  • 4.5 Real-Time Geographically Distributed PHIL
  • 5 Conclusion
  • References
  • From Scenarios to Use Cases, Test Cases and Validation Examples
  • 1 Test Scenario Descriptions
  • 2 ERIGrid Generic System Configurations
  • 3 Focal Use Cases
  • 4 Test Cases
  • 5 System Validation Examples
  • 5.1 Analysis of the Centralized Voltage Control for Rhodes Island
  • 5.2 Converter Controller Development
  • 6 Conclusions
  • References.
  • Experiences with System-Level Validation Approach
  • 1 Introduction to Users and Experiences
  • 2 Application of System-Level Validation Approach in Projects
  • 3 Evaluation of Representative Test Cases
  • 4 Evaluation of the Holistic Test Description Methodology
  • 4.1 Results of Work with ERIGrid Services Questionnaire
  • 4.2 Results of Data Specification Questionnaire
  • 5 Advantages and Shortcomings of Holistic Validation Methodology
  • 5.1 Advantages of the Holistic Validation Methodology
  • 5.2 Shortcomings of the Holistic Validation Methodology
  • 6 Conclusion
  • References
  • Education and Training Needs, Methods, and Tools
  • 1 Introduction
  • 2 Learning Needs for Modern Power and Energy Education
  • 3 Laboratory Education
  • 3.1 Real-Time Simulation for Laboratory Education
  • 3.2 Remote Laboratories
  • 4 Simulation-Based Tools
  • 4.1 Co-simulation Tools
  • 4.2 Interactive (Jupyter) Notebooks
  • 5 Outreach Activities
  • 5.1 Webinars
  • 5.2 Training Schools and Workshops
  • 6 Conclusions
  • References
  • Summary and Outlook
  • 1 Conclusions
  • 2 Future Work
  • References.

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