Energy IoT Architecture: From Theory to Practice

go to link Energy IoT Architecture: From Theory to Practice Contents Preface Acknowledgments 1 Energy IoT: Get Your Head in the Cloud 1.1 Driver 1: Societal Mandate for Clean Energy 1.2 Driver 2: The Economic Advantage of Renewable Energy 1.3 Driver 3: Technological Change Is Accelerating 1.4 It Is Time to Act 1.5 Disruption Ahead References 2 Architectural Challenges to the Energy Transformation 2.1 Think of Everything as a Microgrid 2.1.1 What’s Wrong with the Architecture We Have Now? 2.2 Challenges with Today’s Electric Power Industry Architecture 2.2.1 Reliable and Affordable Electricity 2.2.2 Fair and Equitable for Large and Small Alike 2.2.3 Democratic, Secure, Trusted, Reliable, Resilient, and Safe 2.2.4 Decarbonization and Deep Electrification 2.2.5 Business Model Innovation 2.2.6 Sustainable Energy Future 2.3 Utility’s Siloed Systems References 3 Technical and Regulatory Barriers to the Energy Transformation 3.1 Legacy Technology Mindset Is Based on Incrementalism 3.2 The Challenges of SCADA Systems 3.3 The Challenges with Energy Management Systems (EMS), Distribution Management Systems (DMS), and Distributed Energy Resource Management Systems (DERMS) 3.4 The Challenges with Regulation 3.5 The Biggest Technology Challenge Is Scale 3.5.1 Digital Cloud Platforms Provide the Solution to Scaling Issues 3.6 Crossing the Technology Chasm 3.7 Conclusion 4 Energy IoT Reference Architecture Big Picture 4.1 What Is Happening Here? 4.2 The Energy IoT Stack View 4.3 DER Device/OT Domain 4.4 Energy Business Systems (SaaS) Domain 4.5 Energy IoT Digital Energy Platform Services Domain (The Green Cloud) 4.6 Conclusion 5 Energy OT Domain: Evolving Towards a Neural Grid 5.1 The Neural Grid 5.2 Sensors and Measurement 5.3 Gateways and Local Controllers 5.4 DERs 5.4.1 Energy Storage DER 5.5 Telecommunication Infrastructure 5.6 Microgrids 5.7 Security 5.8 Bulk Generation 5.9 Smart Homes, Buildings, and Cities 5.9.1 EVs 5.10 EV Supply Equipment Charging Infrastructure 5.10.1 EV Fleet Charging 5.11 Conclusion References 6 Energy Business Systems (SaaS) Domain 6.1 Planning Systems 6.1.1 Long-Term Planning (LTP) 6.1.2 Short-Term Planning (STP) 6.1.3 Weather and Load Forecasting 6.2 Customer Systems 6.2.1 Customer Programs 6.2.2 Metering Systems 6.2.3 Interconnect System 6.2.4 M&V System 6.2.5 Customer Information (CIS), Settlement, and Billing Systems 6.3 Operations Systems 6.3.1 Transmission Systems 6.3.2 DGO Systems 6.3.3 DERMS 6.4 Market Systems 6.4.1 Wholesale/Transmission Markets 6.4.2 Retail/Distribution Markets 6.4.3 Carbon Markets 6.5 Communications and Security 6.5.1 Cybersecurity 6.5.2 Network and Telecom Management 6.5.3 Physical Security 6.6 Construction and Maintenance 6.6.1 Asset Management Systems 6.6.2 Workforce Management Systems 6.6.3 Geospatial Information System (GIS) 6.7 Conclusion References 7 Digital Energy Platform Services Domain: The Green Cloud 7.1 Architectural Principles of the Green Cloud 7.1.1 The Principle of Scalability 7.1.2 The Principle of Abstraction and Interoperability 7.1.3 The Principle of Reduced Complexity 7.1.4 The Principle of Loose Coupling 7.1.5 The Principle of Business Model Innovation 7.2 Green Cloud Characteristics 7.3 Green Cloud Architectural Components 7.4 Cloud Microservices and Container Technologies 7.5 DevOps Software Development and Source Code Management 7.6 Event Management and Low Code Workflow Automation 7.7 Data Services 7.7.1 Smart Contracts, Digital Ledger Technology (DLT) 7.7.2 Structured Data 7.7.3 Unstructured Data 7.8 Security and Identity Management 7.9 Asset Registry 7.10 AI and Optimization 7.11 Digital Twin Agent 7.11.1 There Are Probably at Least Two Types of Digital Twins 7.12 Aggregators and VPPs 7.13 Community Choice Aggregation 7.14 Adapters 7.15 SOA, Message Buses, and Message Payloads 7.16 Conclusion References 8 Mapping the IEEE 2030.5 Protocol to the Energy IoT Reference Architecture 8.1 History 8.2 IEEE 2030.5 Architecture 8.2.1 CPUC Rule 8.2.2 IEEE 2030.5 Features and Supported Grid Services 8.2.3 Discovery 8.2.4 Supported Grid Services 8.3 IEEE 2030.5 Certification and Testing Tools 8.3.1 Test Tools 8.3.2 CSIP Certification 8.3.3 IEEE 2030.5 Architecture Mapped to Energy IoT Reference Architecture 8.3.4 Where to Find IEEE 2030.5 Documentation 8.4 Conclusion References 9 Developing Energy IoT Rapid Solution Architectures 9.1 Developing Energy IoT Rapid Solution Architectures 9.1.1 Energy IoT Rapid Solution Architecture Methodology 9.1.2 Benefits of Energy IoT Rapid Solution Architecture Methodology 9.2 Example Use Case 9.2.1 Step 1: Create a Layered Template 9.2.2 Step 2: Identify Energy IoT Reference Architecture Components for the Use Case 9.2.3 Step 3: Add Necessary Features to Support the Use Case 9.2.4 Step 4: Collaborate with Others 9.2.5 Step 5 and Beyond: Create Supporting Architectural Drawings 9.3 Real-Life Examples of an Energy IoT Approach in Australia 9.3.1 The HP DER Integration Experiment 9.4 Conclusion Reference 10 PNNL’s Grid Architecture 10.1 Laminar Decomposition 10.2 Grid Architecture Framework Qualities and Properties 10.3 Other PNNL Grid Architecture Framework Features 10.4 Conclusion Reference 11 The Path to Decarbonization Requires Integrated DER 11.1 Utilities’ Path to Decarbonization 11.2 The Pattern for Utility Decarbonization 11.2.1 Step 1: Vision and Strategy 11.2.2 Step 2: Real-Time Technology 11.2.3 Step 3: Organizational Skills 11.2.4 Step 4: Scalability 11.3 Conclusion 12 The Road Forward 12.1 A Call to Action 12.2 The Big Picture Has to Work Together 12.3 Leveraging DER to Provide Resilience 12.4 The Way Forward 12.4.1 Align the Partners 12.4.2 Build the Services 12.4.3 Pilot the Approach 12.4.4 Implement at Scale 12.5 Will You Be Part of the Solution? Reference Appendix: Relevant Communication Protocols and Standards A.1 IEEE 2030.5 A.2 OpenFMB A.3 IEC A.4 Open Automated Demand Response (OpenADR) A.5 IEEE A.6 Modbus and SunSpec Modbus A.7 OCPP OSCP A.8 IEEE 2030.7 List of Acronyms About the Author Index