Renewable Energy Project Management Academy

At DEMS, we understand project managers’ critical role in the renewable energy industry. That is why we are here to equip your team with the necessary skills to thrive in today’s rapidly changing landscape. Our training program addresses the skill gaps in renewable energy project management, empowering your company to accelerate sustainability, embrace new energy solutions, and drive digital transformation.

To tackle the challenges and opportunities presented by climate change, upskilling and reskilling the workforce is crucial. That’s why DEMS has partnered with PMI Houston to advance professional development in the green economy. Together, we aim to prepare companies to address the demands of a changing world. #ClimateChange #ProfessionalDevelopment #GreenEconomy

Instructor

Why Choose DEMS?

  • Adaptability

    Our program focuses on developing a deep sense of adaptability among project managers. They will be equipped to embrace change, quickly adopt new methods, and easily navigate complex stakeholder ecosystems.

  • Digital Proficiency

    With the ever-evolving digital landscape, project managers must be digitally proficient. At DEMS, we ensure your team is trained to adopt, understand, troubleshoot, and develop new digital workflows and solutions. They will also learn to manage data securely, efficiently, and effectively.

  • Business Acumen

    In an industry marked by margin pressure, it is essential to have project managers who possess both technical proficiency and strong business sense. Our program instills a deep understanding of business strategies, enabling your team to make informed decisions that drive profit.

The Urgent Need for Transformation

As the renewable energy industry undergoes a transformative shift, capital projects are at the forefront of the global transition to net zero by 2050. To achieve this ambitious goal, companies must invest an average of $9.2 trillion annually in energy and land use systems.

Additionally, $1 trillion of existing spending must be reallocated from high to low emissions assets. DEMS recognizes the urgency of this transition and the need for systematic capability building.

Overcoming Challenges

Many companies face challenges in training the next generation of project managers. They express a desire to provide regular, comprehensive training but often feel overwhelmed by the sheer scope of the task. The renewable energy sector poses additional complexities as an inherently project-based, decentralized, and dynamic industry.

Project managers often rotate within companies and across the sector, necessitating the acquisition of new skills to adapt to the evolving project environment. Furthermore, acute labor shortages of project managers further complicate the capability-building process.

Shape the Future of Renewable Energy

DEMS is here to guide your company through the transformational journey toward sustainable success. Our broad capability-building program addresses the skill gaps in renewable energy project management, ensuring your team is ready to thrive in the next normal of complex capital projects.

DEMS Renewable Energy Project Management Training - Courses

Course #1: ESG Global Energy Transition and the Role of Renewables: A Project Management Perspective

Course Overview: This course is designed to provide project management professionals with a comprehensive understanding of the global energy transition and the pivotal role of renewables in the evolving landscape. The course will cover key concepts, methodologies, and strategies for successfully managing projects in the renewable energy sector. Participants will gain insights into project planning, execution, and monitoring within the context of the broader energy transition goals.

Note: This course would be adapted to different formats, including in-person classes, online courses, or a hybrid model. Additionally, guest lectures from industry experts and site visits to renewable energy projects would be engaged to enhance the learning experience.

Module 1: Introduction to Global Energy Transition (Weeks 1-2)
  • Overview of the Global Energy Landscape
  • Drivers and Challenges of Energy Transition
  • International Agreements and Commitments
  • Interplay between Policy, Economics, and Technology
Module 2: Fundamentals of Renewable Energy (Weeks 3-5)
  • Types of Renewable Energy Sources
  • Renewable Energy Technologies and Innovations
  • Environmental and Economic Impacts
  • Market Trends and Opportunities
Module 3: Project Management Basics (Weeks 6-8)
  • Introduction to Project Management
  • Project Lifecycle and Methodologies
  • Stakeholder Analysis and Engagement
  • Risk Management in Renewable Energy Projects
Module 4: Planning Renewable Energy Projects (Weeks 9-11)
  • Project Scope and Objectives
  • Resource Planning and Allocation
  • Budgeting and Financial Analysis
  • Regulatory Compliance and Permitting
Module 5: Executing and Controlling Renewable Energy Projects (Weeks 12-14)
  • Procurement and Contract Management
  • Quality Assurance and Control
  • Monitoring and Evaluation
  • Project Documentation and Reporting
Module 6: Case Studies and Best Practices (Weeks 15-16)
  • Analyzing Successful Renewable Energy Projects
  • Learning from Project Failures
  • Best Practices in Project Management for Energy Transition
Module 7: Future Trends and Innovations (Weeks 17-18)
  • Emerging Technologies in Renewable Energy
  • The Role of Digitalization in Project Management
  • Future Challenges and Opportunities
Final Project: Renewable Energy Project Management Plan (Weeks 19-20)
  • Applying Project Management Principles to a Renewable Energy Project
  • Developing a Comprehensive Project Management Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analysis
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of project management principles is recommended but not mandatory. 
  • Open to professionals in project management, energy sector, and individuals interested in renewable energy project management.
Module 1: Introduction to Renewable Energy (Weeks 1-2)
  • Overview of Renewable Energy Sources
  • Global and Regional Renewable Energy Trends
  • Environmental and Economic Impacts
  • Policy and Regulatory Frameworks
Module 2: Project Development Lifecycle (Weeks 3-5)
  • Feasibility Studies and Site Assessment
  • Project Planning and Design
  • Permitting and Regulatory Compliance
  • Financial Modeling and Funding Sources
Module 3: Renewable Energy Technologies (Weeks 6-8)
  • Solar Photovoltaic (PV) Systems
  • Wind Power Generation
  • Hydropower and Ocean Energy
  • Biomass and Bioenergy
Module 4: Program Management Fundamentals (Weeks 9-11)
  • Introduction to Program Management
  • Stakeholder Engagement and Communication
  • Risk Management in Renewable Energy Programs
  • Program Governance and Compliance
Module 5: Financing and Investment Strategies (Weeks 12-14)
  • Financial Structuring of Renewable Energy Projects
  • Public and Private Funding Mechanisms
  • Investment Analysis and Return on Investment (ROI)
  • Insurance and Risk Mitigation
Module 6: Regulatory Compliance and Policy Considerations (Weeks 15-16)
  • Understanding Regulatory Requirements
  • Navigating Environmental Impact Assessments (EIAs)
  • Policy Support Mechanisms
  • Compliance and Reporting
Module 7: Social and Community Engagement (Weeks 17-18)
  • Community Outreach and Engagement Strategies
  • Social and Environmental Impact Assessment
  • Corporate Social Responsibility (CSR) in Renewable Energy Programs
Module 8: Emerging Trends and Innovations (Weeks 19-20)
  • Energy Storage Technologies
  • Smart Grids and Microgrids
  • Digitalization and Internet of Things (IoT) in Renewable Energy
  • Circular Economy in the Renewable Energy Sector
Final Project: Renewable Energy Program Management Plan (Weeks 21-24)
  • Application of Program Management Principles
  • Development of a Comprehensive Program Management Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of energy concepts and project management principles is recommended but not mandatory.
  • Suitable for professionals in program management, renewable energy, and individuals seeking a holistic understanding of renewable energy program management.

Course #2: ESG Renewable Energy Program Management

Course Overview: This course is designed to equip professionals with the knowledge and skills necessary to effectively manage and lead renewable energy programs. Participants will gain a comprehensive understanding of the renewable energy landscape, project development lifecycle, regulatory frameworks, and key considerations for successful program management.

Note: This course would be adapted to different formats, including in-person classes, online courses, or a hybrid model. Incorporating guest lectures from industry experts and real-world case studies would be introduced to enhance the learning experience.

Course #3: ESG Financing Renewable Energy Capital Projects

Course Overview: This course is designed to provide a comprehensive understanding of the financial aspects associated with financing renewable energy capital projects. Participants will explore various financing models, investment strategies, risk mitigation techniques, and the regulatory landscape governing renewable energy finance.

Note: This course would be adapted to different formats, including in-person classes, online courses, or a hybrid model. Guest lectures from industry experts and discussions on current market trends would be introduced to enhance the learning experience.

Module 1: Introduction to Renewable Energy Financing (Weeks 1-2)
  • Overview of Renewable Energy Capital Projects
  • Importance of Financing in the Renewable Energy Sector
  • Key Stakeholders in Renewable Energy Finance
  • Current Global and Regional Trends
Module 2: Financial Analysis and Modeling (Weeks 3-5)
  • Financial Metrics for Renewable Energy Projects
  • Cash Flow Analysis and Projections
  • Sensitivity Analysis and Risk Assessment
  • Comparative Financial Analysis of Different Renewable Technologies
  •  
Module 3: Financing Models (Weeks 6-8)
  • Project Finance vs. Corporate Finance
  • Public-Private Partnerships (PPPs)
  • Green Bonds and Sustainable Financing
  • Crowdfunding and Community Investment
Module 4: Investment Strategies and Funding Sources (Weeks 9-11)
  • Equity and Debt Financing
  • Tax Equity Financing
  • Multilateral and Bilateral Funding
  • Venture Capital and Private Equity
Module 5: Risk Mitigation in Renewable Energy Finance (Weeks 12-14)
  • Regulatory and Policy Risks
  • Technological and Operational Risks
  • Market Risks and Price Volatility
  • Insurance and Risk Transfer Mechanisms
Module 6: Government Incentives and Subsidies (Weeks 15-16)
  • Overview of Government Incentives
  • Feed-in Tariffs and Power Purchase Agreements (PPAs)
  • Tax Credits and Grants
  • Renewable Portfolio Standards (RPS)
Module 7: Environmental, Social, and Governance (ESG) Considerations (Weeks 17-18)
  • Importance of ESG in Renewable Energy Financing
  • Corporate Social Responsibility (CSR)
  • Social Impact Investing
  • Reporting and Certification

 

Module 8: Case Studies and Real-world Applications (Weeks 19-20)
  • Analysis of Successful Renewable Energy Financing Cases
  • Learning from Project Failures
  • Adapting Strategies to Different Regions and Technologies
Final Project: Renewable Energy Financing Plan (Weeks 21-24)
  • Application of Financial Principles to a Renewable Energy Capital Project
  • Development of a Comprehensive Financing Plan
  • Presentation and Peer Review
Assessments:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Prerequisites: Basic understanding of finance and renewable energy concepts is recommended but not mandatory.
  • Suitable for professionals in finance, renewable energy, and individuals interested in the financial aspects of renewable energy capital projects.
Module 1: Introduction to Digital Transformation in Renewable Energy (Weeks 1-2)
  • Overview of Digital Transformation
  • Importance of Digitalization in Renewable Energy Projects
  • Key Digital Technologies in the Renewable Energy Sector
  • Current Global and Regional Trends in Digital Transformation
  •  
Module 2: Project Lifecycle Automation (Weeks 3-5)
  • Digital Tools for Project Planning and Design
  • Automation in Feasibility Studies and Site Assessment
  • Smart Project Management Platforms
  • Integration of Building Information Modeling (BIM) in Renewable Projects
Module 3: IoT and Sensor Technologies (Weeks 6-8)
  • Applications of IoT in Renewable Energy
  • Sensor Technologies for Monitoring and Control
  • Real-time Data Collection and Analysis
  • Predictive Maintenance and Fault Detection
Module 4: Artificial Intelligence (AI) and Machine Learning (ML) in Renewable Energy (Weeks 9-11)
  • Applications of AI and ML in Energy Forecasting
  • Predictive Analytics for Operation and Maintenance
  • AI in Resource Assessment and Optimization
  • Risk Management and Decision Support Systems
Module 5: Blockchain Technology in Renewable Energy (Weeks 12-14)
  • Overview of Blockchain in Energy Transactions
  • Decentralized Energy Markets
  • Supply Chain Traceability and Transparency
  • Smart Contracts in Renewable Energy Projects
Module 6: Cybersecurity and Data Privacy (Weeks 15-16)
  • Importance of Cybersecurity in Renewable Energy
  • Data Privacy and Compliance
  • Risk Mitigation Strategies in Digitalized Projects
  • Ethical Considerations in Data Management
Module 7: Integration of Renewable Energy with Smart Grids (Weeks 17-18)
  • Role of Smart Grids in Renewable Energy Integration
  • Automation and Control in Smart Grids
  • Demand Response and Energy Storage
  • Resilience and Reliability in Smart Grid Systems
Module 8: Case Studies and Best Practices (Weeks 19-20)
  • Analysis of Successful Digital Transformation Cases
  • Learning from Project Failures
  • Best Practices in Renewable Energy Project Automation
Final Project: Digital Transformation Implementation Plan (Weeks 21-24)
  • Application of Digital Transformation Principles to a Renewable Energy Capital Project
  • Development of a Comprehensive Digital Transformation Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of renewable energy concepts and project management is recommended but not mandatory. Suitable for professionals in renewable energy, technology, and individuals interested in the digital transformation of capital projects.

Course #4: ESG Renewable Energy Capital Project Automation and Digital Transformation

Course Overview: This course is designed to equip professionals with the knowledge and skills needed to leverage automation and digital technologies for efficient and effective management of renewable energy capital projects. Participants will explore various digital tools, data analytics, and automation strategies to optimize project development, execution, and ongoing operations.

Note: This course can be adapted to different formats, including in-person classes, online courses, or a hybrid model. Guest lectures from industry experts and hands-on exercises with digital tools would be introduced to enhance the learning experience.

Course #5: ESG Regulatory Regime in Renewable Energy Capital Projects

Course Overview: This course provides a comprehensive exploration of the regulatory landscape governing renewable energy capital projects. Participants will gain insights into the legal and policy frameworks, permitting processes, compliance requirements, and stakeholder engagement strategies necessary for successful project development and implementation.

Note: This course can be adapted to different formats, including in-person classes, online courses, or a hybrid model. Guest lectures from legal experts, regulatory authorities, and interactive workshops on compliance processes would be introduced to enhance the learning experience.

Module 1: Introduction to Regulatory Environment in Renewable Energy (Weeks 1-2)
  • Overview of Regulatory Regime in Renewable Energy
  • Importance of Regulatory Compliance
  • Key Regulatory Bodies and Agencies
  • Global and Regional Regulatory Trends
Module 2: Legal and Policy Frameworks (Weeks 3-5)
  • Renewable Energy Laws and Regulations
  • National and Regional Energy Policies
  • International Agreements and Commitments
  • Legal Considerations for Renewable Energy Project Development
Module 3: Permitting Processes (Weeks 6-8)
  • Environmental Impact Assessment (EIA)
  • Land Use and Zoning Permits
  • Water and Air Quality Permits
  • Streamlining Permitting Processes for Renewable Projects
Module 4: Grid Connection and Interconnection Agreements (Weeks 9-11)
  • Grid Connection Process
  • Interconnection Agreements and Requirements
  • Grid Codes and Standards
  • Challenges and Opportunities in Grid Integration
Module 5: Feed-in Tariffs and Power Purchase Agreements (PPAs) (Weeks 12-14)
  • Overview of Feed-in Tariffs
  • Power Purchase Agreements (PPAs)
  • Contractual and Regulatory Aspects
  • Tariff Structures and Incentives
Module 6: Community and Stakeholder Engagement (Weeks 15-16)
  • Importance of Community Engagement
  • Stakeholder Identification and Analysis
  • Public Consultation and Communication Strategies
  • Social License to Operate
Module 7: Regulatory Compliance and Reporting (Weeks 17-18)
  • Monitoring and Reporting Requirements
  • Compliance Audits and Inspections
  • Regulatory Enforcement Mechanisms
  • Strategies for Maintaining Compliance
Module 8: Emerging Regulatory Issues (Weeks 19-20)
  • Evolving Regulatory Landscape
  • Climate Change and Renewable Energy
  • Regulatory Challenges and Innovations
  • Future Trends in Renewable Energy Regulation
Final Project: Regulatory Compliance Plan for a Renewable Energy Project (Weeks 21-24)
  • Application of Regulatory Principles to a Renewable Energy Capital Project
  • Development of a Comprehensive Regulatory Compliance Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of renewable energy concepts and project development is recommended but not mandatory.
  • Suitable for professionals in regulatory affairs, legal, and individuals interested in navigating the regulatory aspects of renewable energy capital projects.
Module 1: Introduction to Supply Chain and Risk Management in Renewable Energy (Weeks 1-2)
  • Overview of Supply Chain Management
  • Importance of Supply Chain in Renewable Energy Projects
  • Key Components of Risk Management
  • Global and Regional Supply Chain Trends
Module 2: Renewable Energy Project Supply Chain (Weeks 3-5)
  • Supply Chain Planning and Strategy
  • Procurement and Supplier Selection
  • Logistics and Transportation in Renewable Projects
  • Inventory Management and Warehousing
Module 3: Risk Identification and Assessment (Weeks 6-8)
  • Identifying Risks in Renewable Energy Projects
  • Quantitative and Qualitative Risk Assessment
  • Scenario Analysis and Sensitivity Analysis
  • Risk Tolerance and Appetite
Module 4: Contractual Risk Management (Weeks 9-11)
  • Importance of Contractual Risk Allocation
  • Contractual Risk Mitigation Strategies
  • Insurance and Bonding in Renewable Projects
  • Legal Considerations in Contractual Risk Management
Module 5: Technology and Operational Risks (Weeks 12-14)
  • Identifying Technology Risks
  • Operational Risk Management Strategies
  • Performance Monitoring and Optimization
  • Data Security in Renewable Energy Projects
Module 6: Environmental and Regulatory Risks (Weeks 15-16)
  • Environmental Risk Assessment
  • Regulatory Compliance and Permitting Risks
  • Political and Policy Risks
  • Community and Social Risks
Module 7: Supply Chain Resilience (Weeks 17-18)
  • Building Resilient Supply Chains
  • Strategies for Managing Supply Chain Disruptions
  • Diversification and Redundancy in Renewable Projects
  • Supplier Relationship Management
Module 8: Case Studies and Best Practices (Weeks 19-20)
  • Analysis of Successful Supply Chain and Risk Management Cases
  • Learning from Project Failures
  • Best Practices in Renewable Energy Project Supply Chain and Risk Management
Final Project: Supply Chain and Risk Management Plan for a Renewable Energy Project (Weeks 21-24)
  • Application of Supply Chain and Risk Management Principles
  • Development of a Supply Chain and Risk Management Comprehensive Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of renewable energy concepts and project management is recommended but not mandatory.
  • Suitable for professionals in supply chain management, risk management, and individuals interested in the complexities of renewable energy capital projects.

Course #6: ESG Renewable Energy Capital Project Supply Chain and Risk Management

Course Overview: This course is designed to provide professionals with the knowledge and skills necessary to effectively manage the supply chain and mitigate risks associated with renewable energy capital projects. Participants will explore supply chain strategies, risk identification and assessment, and best practices for successful project execution.

Note: This course can be adapted to different formats, including in-person classes, online courses, or a hybrid model. Incorporating industry guest speakers and site visits to key supply chain nodes would be introduced to enhance the learning experience.

Course #7: ESG Renewable Energy Capital Project Standards & Standardization

Course Overview: This course is designed to provide professionals with a comprehensive understanding of the standards and standardization processes essential for the successful development and implementation of renewable energy capital projects. Participants will explore international, national, and industry-specific standards, as well as the importance of conformity to ensure quality, safety, and interoperability.

Note: This course can be adapted to different formats, including in-person classes, online courses, or a hybrid model. Guest lectures from industry experts involved in standards development and practical exercises would be introduced to enhance the learning experience.

Module 1: Introduction to Standards and Standardization in Renewable Energy (Weeks 1-2)
  • Overview of Standards in the Renewable Energy Sector
  • Importance of Standardization in Project Development
  • Key International and National Standards Organizations
  • Global and Regional Trends in Standardization
  •  
Module 2: Industry-Specific Standards (Weeks 3-5)
  • Overview of Renewable Energy Industry Standards
  • IEC Standards for Wind and Solar Energy
  • ASTM Standards for Bioenergy and Biomass
  • ISO Standards for Energy Management and Environmental Sustainability
Module 3: Safety and Quality Standards (Weeks 6-8)
  • Occupational Health and Safety Standards
  • Quality Management Systems (ISO 9001)
  • Environmental Management Systems (ISO 14001)
  • Safety Standards for Wind, Solar, and Hydropower Projects
Module 4: Grid Integration Standards (Weeks 9-11)
  • Grid Codes and Interconnection Standards
  • Communication Protocols for Smart Grids
  • Cybersecurity Standards in Renewable Energy
  • Interoperability Standards for Energy Storage
Module 5: Certification and Conformity Assessment (Weeks 12-14)
  • Certification Processes for Renewable Energy Projects
  • Conformity Assessment and Compliance
  • Accreditation Bodies and Certification Agencies
  • Challenges and Best Practices in Certification
Module 6: Project Design and Engineering Standards (Weeks 15-16)
  • Design Standards for Solar PV and Wind Farms
  • Engineering Standards for Biomass and Hydropower Projects
  • Building Information Modeling (BIM) Standards
  • Standards for Energy Storage Systems
  •  
Module 7: Emerging Standards and Innovations (Weeks 17-18)
  • Evolving Standards in Renewable Energy
  • Integration of Digitalization and IoT in Standards
  • Standards for Circular Economy in the Energy Sector
  • Future Trends in Renewable Energy Standardization
Module 8: Case Studies and Best Practices (Weeks 19-20)
  • Analysis of Successful Standards Implementation Cases
  • Learning from Standardization Challenges
  • Best Practices in Renewable Energy Project Standards
Final Project: Standards Implementation Plan for a Renewable Energy Project (Weeks 21-24)
  • Application of Standardization Principles
  • Development of a Comprehensive Standards Implementation Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of renewable energy concepts and project management is recommended but not mandatory.
  • Suitable for professionals in quality management, project development, and individuals interested in ensuring compliance with industry standards.
Module 1: Introduction to Renewable CCUS and Hydrogen Technologies (Weeks 1-2)
  • Overview of CCUS and Hydrogen Technologies
  • Importance of Carbon Capture and Hydrogen in Renewable Energy
  • Key Technologies and Processes
  • Global and Regional Trends in CCUS and Hydrogen Development
Module 2: Technical Fundamentals of CCUS and Hydrogen Production (Weeks 3-5)
  • Carbon Capture Technologies: Post-combustion, Pre-combustion, and Oxy-fuel
  • Hydrogen Production Technologies: Electrolysis, Steam Methane Reforming (SMR), and Biomass Gasification
  • Storage and Transport of Captured Carbon and Hydrogen
  • Integration with Renewable Energy Systems
Module 3: Economic and Financial Aspects (Weeks 6-8)
  • Cost-Benefit Analysis for CCUS and Hydrogen Projects
  • Funding Mechanisms and Financial Incentives
  • Business Models for Commercialization
  • Economic Viability and Investment Considerations
Module 4: Regulatory and Policy Frameworks (Weeks 9-11)
  • Regulatory Considerations for CCUS and Hydrogen Deployment
  • Policy Support Mechanisms and Incentives
  • Environmental Impact Assessments (EIA)
  • Compliance with Climate and Energy Policies
Module 5: Integration with Renewable Energy Systems (Weeks 12-14)
  • CCUS and Hydrogen Integration in Renewable Power Generation
  • Synergies with Wind, Solar, and Hydropower
  • Power-to-X Concepts and Applications
  • Hybrid Renewable Energy Projects
Module 6: Commercialization and Market Trends (Weeks 15-16)
  • Market Landscape for CCUS and Hydrogen Technologies
  • Commercialization Strategies
  • Market Potential and Growth Projections
  • Market Challenges and Opportunities
Module 7: Case Studies and Project Development (Weeks 17-18)
  • Analysis of Successful CCUS and Hydrogen Projects
  • Learning from Project Failures
  • Best Practices in Project Development
  • Real-world Applications and Lessons Learned
Module 8: Future Trends and Innovations (Weeks 19-20)
  • Emerging Technologies in CCUS and Hydrogen
  • Innovations in Storage and Transport
  • Future Integration with Industries and Transportation
  • Role in Achieving Global Climate Goals
Final Project: CCUS and Hydrogen Project Development Plan (Weeks 21-24)
  • Application of Course Concepts to a Renewable CCUS and Hydrogen Project
  • Development of a Comprehensive Project Development Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Prerequisites: Basic understanding of renewable energy concepts and project management is recommended but not mandatory. Suitable for professionals in energy, environmental sciences, and individuals interested in the development and deployment of CCUS and hydrogen technologies.

Course #8: ESG Renewable CCUS and Hydrogen Technologies Development, Commercialization and Deployment

Course Overview: This course is designed to provide professionals with a comprehensive understanding of Carbon Capture, Utilization, and Storage (CCUS) and hydrogen technologies in the context of renewable energy. Participants will explore the development, commercialization, and deployment of these technologies, addressing technical, economic, and regulatory aspects.

Note: This course can be adapted to different formats, including in-person classes, online courses, or a hybrid model. Incorporating industry guest speakers, site visits, and hands-on projects would be introduced to enhance the learning experience.

Course #9: ESG Renewable Onshore, Offshore & Floating Wind Technologies

Course Overview: This course is designed to provide professionals with a comprehensive understanding of onshore, offshore, and floating wind technologies. Participants will explore the development, design, and deployment of wind energy systems, addressing technical, economic, and environmental considerations.

Note: This course can be adapted to different formats, including in-person classes, online courses, or a hybrid model. Incorporating industry guest speakers, site visits to wind farms, and hands-on projects would be introduced to enhance the learning experience.

Module 1: Introduction to Wind Energy (Weeks 1-2)
  • Overview of Wind Energy
  • Importance of Wind Power in the Renewable Energy Mix
  • Historical Development of Wind Turbines
  • Global and Regional Trends in Wind Energy
Module 2: Onshore Wind Technologies (Weeks 3-5)
  • Types of Onshore Wind Turbines
  • Wind Resource Assessment and Site Selection
  • Design and Components of Onshore Wind Farms
  • Integration with Power Grids and Energy Storage
Module 3: Offshore Wind Technologies (Weeks 6-8)
  • Overview of Offshore Wind Farms
  • Types of Offshore Wind Turbines
  • Design Challenges and Innovations
  • Installation and Maintenance Considerations
Module 4: Floating Wind Technologies (Weeks 9-11)
  • Introduction to Floating Wind Turbines
  • Advantages and Challenges of Floating Wind Farms
  • Design and Components of Floating Wind Platforms
  • Case Studies of Floating Wind Projects
  •  
Module 5: Technical Aspects and Innovations (Weeks 12-14)
  • Innovations in Wind Turbine Technology
  • Advances in Rotor Design and Control Systems
  • Grid Connection and Power Transmission
  • Energy Storage Integration with Wind Power
Module 6: Economic and Financial Considerations (Weeks 15-16)
  • Cost Structures of Onshore, Offshore, and Floating Wind Projects
  • Funding Mechanisms and Financial Incentives
  • Business Models for Wind Energy
  • Economic Viability and Investment Considerations
Module 7: Environmental Impact and Sustainability (Weeks 17-18)
  • Environmental Impact Assessment (EIA) for Wind Projects
  • Biodiversity and Wildlife Considerations
  • Carbon Footprint and Life Cycle Analysis
  • Sustainability and Corporate Social Responsibility
Module 8: Regulatory and Policy Frameworks (Weeks 19-20)
  • Regulatory Considerations for Wind Energy Projects
  • Permitting and Compliance Requirements
  • Policy Support Mechanisms and Incentives
  • Compliance with Climate and Energy Policies
Final Project: Wind Energy Project Development Plan (Weeks 21-24)
  • Application of Course Concepts to a Wind Energy Project
  • Development of a Comprehensive Project Development Plan
  • Presentation and Peer Review
Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of renewable energy concepts is recommended but not mandatory.
  • Suitable for professionals in energy, engineering, and individuals interested in onshore, offshore, and floating wind technologies.
Module 1: Introduction to Renewable Energy Portfolio Management (Weeks 1-2)
  • Overview of Renewable Energy Portfolios
  • Importance of Portfolio Management in the Energy Sector
  • Key Components and Types of Renewable Energy Assets
  • Global and Regional Trends in Renewable Energy Portfolios
Module 2: Strategic Planning for Renewable Energy Portfolios (Weeks 3-5)
  • Defining Portfolio Objectives and Goals
  • Portfolio Diversification Strategies
  • Geographic and Technology Allocation
  • Balancing Risk and Returns
Module 3: Optimization and Performance Monitoring (Weeks 6-8)
  • Energy Production Forecasting and Optimization
  • Asset Performance Monitoring and Reporting
  • Data Analytics for Portfolio Optimization
  • Machine Learning Applications in Portfolio Management
Module 4: Financial Management of Renewable Energy Portfolios (Weeks 9-11)
  • Financial Metrics for Portfolio Analysis
  • Valuation and Risk Assessment
  • Revenue Modeling and Forecasting
  • Budgeting and Financial Reporting
Module 5: Risk Management in Renewable Energy Portfolios (Weeks 12-14)
  • Identifying and Assessing Risks in Renewable Energy Projects
  • Hedging Strategies for Price and Volume Risks
  • Insurance and Risk Mitigation Techniques
  • Regulatory and Policy Risks
Module 6: Environmental, Social, and Governance (ESG) Considerations (Weeks 15-16)
  • Importance of ESG in Renewable Energy Portfolio Management
  • Corporate Social Responsibility (CSR)
  • Social Impact Investing
  • Reporting and Certification
Module 7: Regulatory and Policy Frameworks (Weeks 17-18)
  • Regulatory Considerations for Renewable Energy Portfolios
  • Policy Support Mechanisms and Incentives
  • Compliance with Climate and Energy Policies
  • Navigating International Regulations
Module 8: Case Studies and Best Practices (Weeks 19-20)
  • Analysis of Successful Renewable Energy Portfolios
  • Learning from Portfolio Challenges
  • Best Practices in Portfolio Management
  • Real-world Applications and Lessons Learned
Final Project: Renewable Energy Portfolio Management Plan (Weeks 21-24)

  • Application of Portfolio Management Principles

  • Development of a Comprehensive Portfolio Management Plan

  • Presentation and Peer Review

Assessment:
  • Weekly quizzes and discussions
  • Mid-term and final exams
  • Participation in case study analyses
  • Final project presentation and submission
Prerequisites: 
  • Basic understanding of renewable energy concepts and finance is recommended but not mandatory.
  • Suitable for professionals in energy management, finance, and individuals interested in the strategic management of renewable energy portfolios.

Course #10: ESG Renewable Energy Portfolio Management

Course Overview: This course is designed to provide professionals with the knowledge and skills required for effective management of renewable energy portfolios. Participants will explore the strategic planning, optimization, risk management, and financial aspects associated with diverse renewable energy assets within a portfolio context.

Note: This course can be adapted to different formats, including in-person classes, online courses, or a hybrid model. Guest lectures from industry experts and interactive simulations would be introduced to enhance the learning experience.

Enroll Now:

Please use the form below to apply now. Limited space is available, so apply today. Please note, depending on the preferred location of the course selected, we need a minimum of 10 people to hold a class. Accept payment via the Paypal link below: PayPal.

The processing fee if you are paying with credit card and debit card card is $150 per transaction. To avoid paying processing fee, please, pay via Zelle: payment@demsengineering.com.