Fundamental Design of Small Scale Solar Wind Hybrid System from Udemy

In this Course you will learn following topics in detail:

Grid Tie Solar Wind Hybrid System
Off-Grid Solar Wind Hybrid System
Components of solar-wind hybrid system
Solar Photovoltaic panels
Mini Wind Turbine
Aero-Wind Generator
Battery Bank
Maximum Power Point Tracking Hybrid Controller (MPPT)
PV Panel Trackers or Module Mounting Structure
Inverter Selection
Cables Selection
Benefits of Solar Wind Hybrid System
Cons of Installing A Hybrid Solar Wind System
Design Case Study of Solar Wind Hybrid System
Calculation of Daily and Annual Consumption of Consumer
Annual energy consumption
Wind Speed calculation at specific height
Sizing and selection of wind turbine
Friction coefficient ∝ for a variety of landscapes
Hellman equation
Coefficient of Performance
Capacity factor
Betz Limit
Wind Power density (power/unit area)
Actual wind power density to be converted to useful energy
Annual useful energy density
Calculation of Swept Area of Turbine
Calculation of Rotor Diameter
Power rating of the turbine
Actual rated power of the turbine rating
Selection of Wind Turbine
Small Scale Wind Turbine Component
Small Scale Wind Turbine Connections
Specification of Wind Turbine
Graph of Power v/s Wind Speed
Installation of Small Scale Wind Turbine
Sizing of Solar Power Plant
Daily Solar Power Needs to generate
Solar Plant Capacity required
Selection of Solar Panel
Calculation for No. of Solar Panels
Connection of solar panel and String Sizing
Voltage of System
Current of Solar Array
Installation of Solar Plant
Cable Sizing
Safety Check of Ampacity
Safety Check of Voltage Drop
Reading the datasheet of Cables
Sizing of Battery Bank
Total capacity of battery bank Ah
selected battery size
No. Of batteries in series
No. Of batteries in parallel
Wind Solar Hybrid Controller Selection factors
Selection of Inverter
Sizing of Inverter
Line Diagram of Solar Wind Hybrid System

What's inside

Learning objectives

Grid tie solar wind hybrid system
Off-grid solar wind hybrid system
Components of solar-wind hybrid system
Solar photovoltaic panels
Mini wind turbine
Aero-wind generator
Battery bank
Maximum power point tracking hybrid controller (mppt)
Pv panel trackers or module mounting structure
Inverter selection
Cables selection
Benefits of solar wind hybrid system
Cons of installing a hybrid solar wind system
Design case study of solar wind hybrid system
Calculation of daily and annual consumption of consumer
Annual energy consumption
Wind speed calculation at specific height
Sizing and selection of wind turbine
Friction coefficient ∝ for a variety of landscapes
Hellman equation
Coefficient of performance
Capacity factor
Betz limit
Wind power density (power/unit area)
Actual wind power density to be converted to useful energy
Annual useful energy density
Calculation of swept area of turbine
Calculation of rotor diameter
Power rating of the turbine
Actual rated power of the turbine rating

Selection of wind turbine
Small scale wind turbine component
Small scale wind turbine connections
Specification of wind turbine
Graph of power v/s wind speed
Installation of small scale wind turbine
Sizing of solar power plant
Daily solar power needs to generate
Solar plant capacity required
Selection of solar panel
Calculation for no. of solar panels
Connection of solar panel and string sizing
Voltage of system
Current of solar array
Installation of solar plant
Cable sizing
Safety check of ampacity
Safety check of voltage drop
Reading the datasheet of cables
Sizing of battery bank
Total capacity of battery bank ah
Selected battery size
No. of batteries in series
No. of batteries in parallel
Wind solar hybrid controller selection factors
Selection of inverter
Sizing of inverter
Line diagram of solar wind hybrid system
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Grid tie solar wind hybrid system
Off-grid solar wind hybrid system
Components of solar-wind hybrid system
Solar photovoltaic panels
Mini wind turbine
Aero-wind generator
Battery bank
Maximum power point tracking hybrid controller (mppt)
Pv panel trackers or module mounting structure
Inverter selection
Cables selection
Benefits of solar wind hybrid system
Cons of installing a hybrid solar wind system
Design case study of solar wind hybrid system
Calculation of daily and annual consumption of consumer
Annual energy consumption
Wind speed calculation at specific height
Sizing and selection of wind turbine
Friction coefficient ∝ for a variety of landscapes
Hellman equation
Coefficient of performance
Capacity factor
Betz limit
Wind power density (power/unit area)
Actual wind power density to be converted to useful energy
Annual useful energy density
Calculation of swept area of turbine
Calculation of rotor diameter
Power rating of the turbine
Actual rated power of the turbine rating
Selection of wind turbine
Small scale wind turbine component
Small scale wind turbine connections
Specification of wind turbine
Graph of power v/s wind speed
Installation of small scale wind turbine
Sizing of solar power plant
Daily solar power needs to generate
Solar plant capacity required
Selection of solar panel
Calculation for no. of solar panels
Connection of solar panel and string sizing
Voltage of system
Current of solar array
Installation of solar plant
Cable sizing
Safety check of ampacity
Safety check of voltage drop
Reading the datasheet of cables
Sizing of battery bank
Total capacity of battery bank ah
Selected battery size
No. of batteries in series
No. of batteries in parallel
Wind solar hybrid controller selection factors
Selection of inverter
Sizing of inverter
Line diagram of solar wind hybrid system
Show more
Show less

Syllabus

Introduction to Solar Wind Hybrid System

Introduction to Course

Introduction to Grid Tie Solar Wind Hybrid System

Introduction to Off-Grid Solar Wind Hybrid System

Traffic lights

Read about what's good

what should give you pause

and possible dealbreakers

Covers practical aspects like cable sizing, battery bank sizing, and inverter selection, which are essential for hands-on implementation

Explores both grid-tie and off-grid solar wind hybrid systems, providing a comprehensive understanding of different application scenarios

Introduces concepts like Betz Limit, coefficient of performance, and capacity factor, which are fundamental in wind energy analysis

Details small-scale wind turbine components, connections, and installation, which may be useful for building a home system

Includes a design case study of a solar wind hybrid system, offering a practical example of system design and component selection

Requires learners to perform calculations for wind speed at specific heights using the Hellman equation, which may require some prior knowledge

Reviews summary

Design principles of small solar-wind systems

According to learners, this course provides a practical and fundamental understanding of small-scale solar wind hybrid systems. Students appreciated the design case study which helped illustrate the concepts. Many found the explanations on component selection and sizing particularly useful. While the course is seen as a good starting point for the topic, some reviewers felt certain sections could benefit from more in-depth coverage or clarification, suggesting it's best suited for beginners or those needing an overview.

Concepts explained effectively.

"The instructor explained the concepts clearly and logically."

"I found the explanations of complex calculations easy to follow."

"The course content was presented in an understandable manner."

"The breakdown of technical topics made them accessible."

Useful detail on key system parts.

"The detailed explanations on selecting and sizing components like panels, turbines, and batteries were very helpful."

"I learned a lot about how to properly size the battery bank and select the right inverter for a system."

"The modules on cable sizing and safety checks were particularly valuable for practical application."

"The breakdown of different components and their specifications was thorough."

Provides a solid foundational overview.

"The course is a good introduction to the fundamentals of solar wind hybrid systems."

"It gives a very good overview of the topic and covers all the basic components and considerations."

"I found this course to be a solid starting point for understanding hybrid renewable energy systems."

"It's suitable for beginners looking to grasp the basics of system design."

Helps illustrate design concepts.

"The design case study part is very practical, I really liked the way the calculation parts are explained with examples."

"The case study part on design really helped consolidate the information provided in the lectures."

"The practical case study helps tie everything together, making the theoretical knowledge more actionable."

"I appreciated the real-world application demonstrated through the design example."

Could benefit from more detail.

"While it covers the fundamentals, I felt some topics could have been explored in more depth."

"The course is good for an overview, but if you need advanced design techniques, you might need supplementary material."

"Some explanations felt a bit rushed, particularly in the calculation sections, leaving me wanting more detail."

"I hoped for a deeper dive into optimization or specific software tools for design."

Activities

Be better prepared before your course. Deepen your understanding during and after it. Supplement your coursework and achieve mastery of the topics covered in Fundamental Design of Small Scale Solar Wind Hybrid System with these activities:

Review Basic Electrical Engineering Concepts

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Reviewing fundamental electrical engineering concepts will provide a solid foundation for understanding the components and design principles of solar wind hybrid systems.

Browse courses on Electrical Circuits

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Review Ohm's Law and Kirchhoff's Laws.
Practice circuit analysis problems.
Understand voltage, current, and power relationships.

Review 'Renewable Energy Resources' by John Twidell and Tony Weir

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Reading this book will provide a broader and deeper understanding of the principles behind solar and wind energy, supplementing the course material.

View Renewable Energy Resources on Amazon

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Read the chapters on solar and wind energy.
Take notes on key concepts and equations.
Work through example problems.

Create a Simple Solar Wind Hybrid System Model in Simulink

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Building a simulation model will allow you to apply the concepts learned in the course and visualize the behavior of a solar wind hybrid system.

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Model the solar panel characteristics.
Model the wind turbine characteristics.
Integrate the models with a battery storage system.
Simulate the system under different load conditions.

Four other activities

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Practice Wind Speed Calculations at Varying Heights

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Practicing wind speed calculations using the Hellman equation will reinforce your understanding of wind resource assessment.

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Find sample wind speed data at a reference height.
Calculate wind speed at different heights using the Hellman equation.
Vary the friction coefficient and observe the impact.

Design a Solar Wind Hybrid System for a Specific Location

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Designing a system for a real-world location will solidify your understanding of the design process and the factors that influence system performance.

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Select a location and gather weather data.
Calculate the energy consumption of a target consumer.
Size the solar and wind components.
Select appropriate battery storage and inverters.
Create a system diagram and cost estimate.

Create a Presentation on the Benefits and Cons of Hybrid Systems

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Creating a presentation will help you synthesize the information learned in the course and communicate it effectively to others.

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Research the advantages and disadvantages of solar wind hybrid systems.
Organize the information into a clear and concise presentation.
Include visuals and examples to illustrate key points.

Review 'Solar and Wind Energy: A Sustainable Approach' by Mukund R. Patel

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This book provides a deeper dive into the technical and economic aspects of solar and wind energy, enhancing your understanding of sustainable energy solutions.

View Wind and Solar Power Systems on Amazon

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Read the chapters on system design and performance analysis.
Analyze the economic considerations discussed in the book.
Compare and contrast different solar and wind energy technologies.

Career center

Learners who complete Fundamental Design of Small Scale Solar Wind Hybrid System will develop knowledge and skills that may be useful to these careers:

Renewable Energy Engineer

A Renewable Energy Engineer focuses on designing, developing, and implementing renewable energy solutions. These engineers are involved in projects related to solar, wind, and hybrid systems. This course, with its detailed exploration of grid tie and off-grid solar wind hybrid systems, components, and design case studies, helps build a strong foundation for anyone pursuing a career as a Renewable Energy Engineer. The course's coverage of practical aspects like turbine selection, solar panel sizing, battery bank sizing, and inverter selection are directly applicable to the tasks a Renewable Energy Engineer undertakes daily.

See salaries and explore the career path for Renewable Energy Engineer

Hybrid Power System Technician

A Hybrid Power System Technician specializes in installing and maintaining hybrid power systems that combine multiple energy sources, such as solar and wind. This course directly correlates with the job, since it delves into grid tie and off-grid solar wind hybrid systems. The course's detailed exploration of system components, design case studies, and installation processes gives someone becoming a Hybrid Power System Technician a robust skill set. The course's coverage of hybrid controllers, inverters, and battery banks will prove invaluable in the field.

See salaries and explore the career path for Hybrid Power System Technician

Solar Energy System Designer

A Solar Energy System Designer plans and designs solar energy systems for residential, commercial, and utility-scale applications. This role involves selecting appropriate solar panels, inverters, and other components to meet energy requirements. This course fits perfectly, as it dives deep into solar photovoltaic panels, sizing of solar power plants, calculation of the number of solar panels, and string sizing. A Solar Energy System Designer benefits from the course's hands-on approach, covering topics from cable sizing to safety checks, ensuring the designed systems are efficient, safe, and reliable. The course's clear explanations and comprehensive syllabus are especially useful.

See salaries and explore the career path for Solar Energy System Designer

Electrical Design Engineer

An Electrical Design Engineer creates electrical systems and components, and in the renewable energy field this often entails working on solar and wind power projects. This course fits well into the learning journey of an Electrical Design Engineer, with its extensive coverage of cable sizing, voltage drop calculations, and reading cable datasheets. The course's practical focus on component selection, system design, and safety checks helps build the skills an Electrical Design Engineer needs. The detailed line diagrams of solar wind hybrid systems presented in the course can be particularly useful.

See salaries and explore the career path for Electrical Design Engineer

Renewable Energy Consultant

A Renewable Energy Consultant advises clients on adopting renewable energy solutions. This role requires a broad understanding of different renewable energy technologies and their applications. This course helps to build that knowledge, since it covers grid tie and off-grid solar wind hybrid systems, their benefits, and their cons. The course's design case study of a solar wind hybrid system helps someone becoming a Renewable Energy Consultant evaluate and recommend appropriate solutions to clients. The knowledge gained from this course is directly applicable to assessing the feasibility and suitability of hybrid systems for various applications.

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Energy Storage Specialist

An Energy Storage Specialist focuses on the design, implementation, and maintenance of energy storage solutions, often involving batteries. This course helps build a foundation for this role, especially with its detailed coverage of battery bank sizing and selection. The course explains calculating total battery bank capacity, sizing individual batteries, and determining the number of batteries in series and parallel. An Energy Storage Specialist will use this knowledge to ensure efficient and reliable energy storage system design.

See salaries and explore the career path for Energy Storage Specialist

Wind Energy Technician

A Wind Energy Technician installs, maintains, and repairs wind turbines. This job demands a strong understanding of wind turbine components, connections, and specifications. This course may be particularly helpful, since it covers mini wind turbines, aero-wind generators, and small-scale wind turbine components. It also explains how to perform small-scale wind turbine connections and read wind turbine specifications. For anyone aspiring to be a Wind Energy Technician, this course provides foundational knowledge, especially with its practical focus on installation and troubleshooting.

See salaries and explore the career path for Wind Energy Technician

Power Systems Engineer

Power Systems Engineers design, develop, and maintain electrical power systems. In the renewable energy sector, this includes hybrid solar wind systems. This course may be beneficial due to its focus on grid tie and off-grid systems, component selection, and system design. The course covers inverter sizing, cable selection, and overall system layout, mirroring essential tasks a Power Systems Engineer handles. The course could provide a valuable foundation for understanding the nuances of integrating renewable sources into the grid.

See salaries and explore the career path for Power Systems Engineer

Energy Efficiency Analyst

An Energy Efficiency Analyst assesses energy use and recommends ways to reduce consumption and improve efficiency. This course may be helpful, teaching about component selection, system design, and real-world applications. By understanding how hybrid systems work, an Energy Efficiency Analyst can better evaluate their impact on energy use and make informed recommendations. The course provides a foundation for analyzing the performance and efficiency of solar wind hybrid systems.

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Sustainability Manager

A Sustainability Manager develops and implements sustainability initiatives for organizations. This role requires a broad understanding of renewable energy technologies. This course may be valuable because it covers solar wind hybrid systems. Knowing about these systems and their benefits helps someone becoming a Sustainability Manager make informed decisions about renewable energy adoption within an organization. The course may equip individuals with the knowledge to advocate for and implement hybrid solutions.

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Project Manager

A Project Manager is responsible for planning, executing, and closing projects. This course may be helpful in managing renewable energy projects, especially those involving solar wind hybrid systems. It could potentially help someone becoming a Project Manager understand the technical aspects of these projects, including component selection, system design, and installation processes. The knowledge gained in this course can facilitate better communication with technical teams and stakeholders, leading to more successful project outcomes.

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Research and Development Engineer

A Research and Development Engineer designs and develops new technologies, often focused on improving existing systems or creating entirely new ones. This course may be beneficial due to its foundational instruction in renewable energy systems, component specifics, and integration methodologies. This can help spur innovation or improvements to hybrid systems. The course may also help someone becoming a Research and Development Engineer understand the current state of the art, identifying areas for improvement and innovation.

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Energy Auditor

An Energy Auditor assesses energy consumption in buildings and facilities, recommending measures to improve efficiency. The course may be beneficial for learning about various renewable energy sources and hybrid systems. It could potentially help someone becoming an Energy Auditor better assess the potential for integrating these systems into existing infrastructure. Understanding the components and design considerations of solar wind hybrid systems allows for more comprehensive energy audits and recommendations.

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Environmental Engineer

An Environmental Engineer works to protect the environment through the design of solutions to environmental problems. This course may be beneficial for understanding the role of renewable energy in reducing environmental impact. It could potentially help someone becoming an Environmental Engineer assess the environmental benefits of solar wind hybrid systems and promote their adoption as sustainable energy solutions. The detailed coverage of system design and component selection provides a technical foundation for understanding the environmental implications of these systems.

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Technical Sales Engineer

A Technical Sales Engineer sells complex technical products or services to businesses or organizations. This course may be beneficial for learning the technical details of solar wind hybrid systems. By understanding the components, design considerations, and benefits of these systems, someone becoming a Technical Sales Engineer can more effectively communicate their value to potential customers. The practical knowledge gained in this course helps build credibility and trust with clients, leading to increased sales success.

See salaries and explore the career path for Technical Sales Engineer

Fundamental Design of Small Scale Solar Wind Hybrid System

What's inside

Learning objectives

Syllabus

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Reviews summary

Design principles of small solar-wind systems

Activities

Career center

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