Ultimate Wind Energy Course for Electrical Engineering from Udemy

"Ultimate Wind Energy Course for Electrical Engineering"

The only course out there with everything you need to know about Wind Energy from A to Z

Throughout the course, you will learn:

Types of wind turbines.
Rotor solidity and selection of the number of rotor blades.
Gearbox in wind turbines.
The power extracted by the turbine from the wind.
Betz limit and maximum rotor efficiency.
Factors affecting wind speed and density.
Applied force on the wind turbine, torque coefficient, and the importance of the TSR.
Wind turbine generator characteristics.
Effect of the rotor diameter and generator size on power.
Wind turbines spacing.
Wind farm feasibility study.
Weibull and Rayleigh probability density functions.
Determination of Weibull parameters.
Determination of Weibull parameters using the graphical method.
Aerodynamics of wind turbines.
Pitch-controlled wind turbines.
Passive stall-controlled wind turbines.
Active stall-controlled wind turbines.
Maximum power point tracking in wind turbines.
Tip speed ratio (TSR) control.
Optimal torque control (OT) MPPT algorithm.
Power signal feedback (PSF) control.
Perturbation and observation (P&O) or hill-climb searching (HCS).
Electricity generation using wind turbines.
Permanent magnet synchronous generator (PMSG).
Wound rotor synchronous generator (WRSG).
Doubly-fed induction generator (DFIG).
Brushless permanent magnet DC generator (PMDC).
Squirrel-cage induction generator.
Wound rotor induction generator.
Tubular steel wind turbine tower.
Lattice wind turbine tower.
Concrete wind turbine tower.
Hybrid wind turbine tower.
Brakes in the wind turbine.
Rotor brakes in the wind turbine.
Pitch drive or aerodynamic brakes in the wind turbine.
Simulation of a wind turbine system using the ETAP program.
MATLAB simulation of the wind turbine.
Cp plotting and lookup table in MATLAB.
MPPT in MATLAB Simulink.

After Taking This Course, You Will Be Able To

Understand everything about wind energy systems, such as the basic components, factors affecting wind generation, the different probability distribution functions used to represent wind data, and wind feasibility study.
Understand different control systems used in the wind turbine and the types of electrical generators utilized.
You will be able to simulate the wind turbine system in both ETAP and MATLAB programs.

Bonus Gift:

You will also get the slides for the Wind Energy Course for those who are interested in them or have them as a revision for themselves

231 Pages of Wind Energy Course Slides.

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What's inside

Learning objectives

Types of wind turbines
Rotor solidity and selection of number of rotor blades
Power extracted by the turbine from the wind
Betz limit and maximum rotor efficiency
Factors affecting wind speed and density
Applied force on the wind turbine, torque coefficient, and the importance of the tsr
Wind turbine generator characteristics
Effect of rotor diameter and generator size on power
Wind turbines spacing
Wind farm feasibility study
Weibull and rayleigh probability density functions
Determination of weibull parameters
Determination of weibull parameters using the graphical method
Aerodynamics of wind turbines
Pitch-controlled wind turbines
Passive stall controlled wind turbines
Active stall controlled wind turbines
Maximum power point tracking in wind turbines
Tip speed ratio (tsr) control
Optimal torque control (ot) mppt algorithm
Power signal feedback (psf) control

Perturbation and observation (p&o) or hill-climb searching (hcs)
Electricity generation using wind turbines
Permanent magnet synchronous generator (pmsg)
Wound rotor synchronous generator (wrsg)
Doubly-fed induction generator (dfig)
Brushless permanent magnet dc generator (pmdc)
Squirrel-cage induction generator
Wound rotor induction generator
Tubular steel wind turbine tower
Lattice wind turbine tower
Concrete wind turbine tower
Hybrid wind turbine tower
Brakes in the wind turbine
Rotor brakes in the wind turbine
Pitch drive or aerodynamic brakes in the wind turbine
Simulation of a wind turbine system using the etap program
Matlab simulation of the wind turbine
Cp plotting and lookup table in matlab
Mppt in matlab simulink
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Types of wind turbines
Rotor solidity and selection of number of rotor blades
Power extracted by the turbine from the wind
Betz limit and maximum rotor efficiency
Factors affecting wind speed and density
Applied force on the wind turbine, torque coefficient, and the importance of the tsr
Wind turbine generator characteristics
Effect of rotor diameter and generator size on power
Wind turbines spacing
Wind farm feasibility study
Weibull and rayleigh probability density functions
Determination of weibull parameters
Determination of weibull parameters using the graphical method
Aerodynamics of wind turbines
Pitch-controlled wind turbines
Passive stall controlled wind turbines
Active stall controlled wind turbines
Maximum power point tracking in wind turbines
Tip speed ratio (tsr) control
Optimal torque control (ot) mppt algorithm
Power signal feedback (psf) control
Perturbation and observation (p&o) or hill-climb searching (hcs)
Electricity generation using wind turbines
Permanent magnet synchronous generator (pmsg)
Wound rotor synchronous generator (wrsg)
Doubly-fed induction generator (dfig)
Brushless permanent magnet dc generator (pmdc)
Squirrel-cage induction generator
Wound rotor induction generator
Tubular steel wind turbine tower
Lattice wind turbine tower
Concrete wind turbine tower
Hybrid wind turbine tower
Brakes in the wind turbine
Rotor brakes in the wind turbine
Pitch drive or aerodynamic brakes in the wind turbine
Simulation of a wind turbine system using the etap program
Matlab simulation of the wind turbine
Cp plotting and lookup table in matlab
Mppt in matlab simulink
Show more
Show less

Syllabus

Basics of Wind Turbine

Introduction to Wind Energy

Selection of Type of Wind Turbine

Rotor Solidity and Selection of Number of Rotor Blades

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Read about what's good

what should give you pause

and possible dealbreakers

Covers a wide range of topics, from wind turbine types and aerodynamics to electrical generators and control systems, which is essential for electrical engineers

Includes simulation of wind turbine systems using ETAP and MATLAB, which are industry-standard software tools for electrical engineering and power systems analysis

Explores maximum power point tracking (MPPT) algorithms, such as tip speed ratio (TSR) control and optimal torque control (OT), which are crucial for optimizing wind turbine performance

Examines Weibull and Rayleigh probability density functions, which are used in wind farm feasibility studies to model wind speed and predict energy production

Requires learners to use ETAP and MATLAB, which may require a license or subscription that may pose a barrier to some students who do not have access

Includes a section on solar energy basics, which may be outside the scope of the core focus on wind energy for electrical engineering students

Reviews summary

Comprehensive wind energy for electrical engineers

According to learners, this course provides a very good and comprehensive overview of wind energy systems, particularly valuable for electrical engineering students and professionals. Many students highlight the practical examples and detailed explanations of key concepts like Betz limit and MPPT. The inclusion of ETAP and MATLAB simulations is frequently mentioned as a significant strength, offering hands-on application. While the course covers a wide range of topics from A to Z, some reviews suggest that specific sections could benefit from more depth for advanced learners or potential updates regarding software versions or newer technologies. The provided course materials, especially the slides, are highly appreciated as a study aid.

Slides and bonus materials are helpful resources.

"The course material slides are very helpful for revision."

"Loved having the bonus PDF slides to follow along and review."

"The extra solar energy lecture was a nice bonus."

Relevant and beneficial for electrical engineers.

"This course is very useful for electrical engineering students."

"Highly relevant for anyone in the electrical engineering field interested in wind energy."

"I am an electrical engineer, and I found the content directly applicable."

Difficult concepts are explained simply.

"Instructor explains well, making complex topics understandable."

"He explains very well, making it easy to grasp the material."

"The explanation of concepts like Betz limit and MPPT was very clear."

ETAP and MATLAB simulations are valuable additions.

"The inclusion of ETAP and MATLAB simulations is a great plus."

"Simulation parts helped me understand the practical application of the concepts."

"Really helpful to see the concepts demonstrated in ETAP and MATLAB."

Covers fundamental wind energy concepts thoroughly.

"This course is very good and comprehensive overview of wind energy systems."

"The course really does go from A to Z, covering all necessary fundamentals."

"I found it very comprehensive, covering many aspects of wind energy."

Some areas could be explored more deeply.

"While broad, some topics could use more in-depth discussion."

"A bit too basic in certain parts; could go deeper into control strategies."

"It's a great introduction, but not sufficient for highly advanced study without other resources."

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 Ultimate Wind Energy Course for Electrical Engineering with these activities:

Review Electrical Generator Fundamentals

Show steps

Strengthen your understanding of electrical generators, which are a core component of wind turbines, before diving into the course material.

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Review the principles of electromagnetic induction.
Study the different types of electrical generators.
Practice solving problems related to generator operation.

Review 'Wind Energy Explained: Theory, Design and Application'

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Gain a solid foundation in wind energy principles by studying a well-regarded textbook.

View Wind Energy Explained: On Land and Offshore on Amazon

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Read the chapters related to wind turbine aerodynamics and generator types.
Work through the example problems in the book.
Summarize the key concepts from each chapter.

Practice Weibull Distribution Calculations

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Reinforce your ability to work with Weibull and Rayleigh distributions, which are essential for wind resource assessment.

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Find datasets of wind speed measurements.
Calculate Weibull parameters from the datasets.
Estimate the average wind speed and power density.

Four other activities

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Show all seven activities

Create a Presentation on Wind Turbine Control Systems

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Deepen your understanding of wind turbine control by researching and presenting on different MPPT algorithms.

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Research different MPPT algorithms used in wind turbines.
Prepare slides explaining the principles of each algorithm.
Present your findings to a peer or study group.

Review 'Electric Machines and Drives: A First Course'

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Solidify your understanding of electrical machines and drives, which are critical components in wind turbines.

View Electric Machines and Drives on Amazon

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Read the chapters related to synchronous and induction machines.
Work through the example problems in the book.
Relate the concepts to wind turbine generator types.

Simulate a Wind Turbine in MATLAB Simulink

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Apply your knowledge by building a simulation of a wind turbine system in MATLAB Simulink.

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Model the wind turbine aerodynamics and generator.
Implement a control system for MPPT.
Test the simulation under different wind conditions.

Contribute to an Open-Source Wind Energy Project

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Gain practical experience by contributing to an open-source project related to wind energy.

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Find an open-source project related to wind energy simulation or analysis.
Identify a bug or feature to work on.
Contribute code or documentation to the project.

Career center

Learners who complete Ultimate Wind Energy Course for Electrical Engineering will develop knowledge and skills that may be useful to these careers:

Wind Energy Engineer

A wind energy engineer designs, develops, and implements wind energy projects. This involves assessing potential wind resources, selecting appropriate turbine technology, and optimizing wind farm layouts. This course in particular helps one understand wind turbine generator characteristics. It also helps to familiarize with wind farm feasibility study and wind turbines spacing, which are crucial aspects of the job. Also, a course taker will be able to simulate wind turbine system in both ETAP and MATLAB programs, which is helpful to wind energy engineers.

See salaries and explore the career path for Wind Energy Engineer

MATLAB Simulation Engineer

MATLAB simulation engineers develop simulations in MATLAB for various applications. This course helps to prepare one for a role in MATLAB simulation as it will allow to simulate wind turbine system. It is also beneficial for an engineer to be familiar with Cp plotting and lookup table in MATLAB. The course also explains maximum power point tracking in MATLAB Simulink.

See salaries and explore the career path for MATLAB Simulation Engineer

Wind Farm Developer

Wind farm developers identify potential sites for wind farms, negotiate land leases, and manage the permitting process. They also oversee the construction and operation of wind farms. This course is directly relevant for anyone in this field. The course includes wind farm feasibility study. The course explains wind turbines spacing, which is an important topic. The course enhances knowledge of factors affecting wind speed and density.

See salaries and explore the career path for Wind Farm Developer

Wind Energy Research Scientist

A wind energy research scientist conducts research to improve wind energy technologies and optimize the performance of wind farms. This role typically requires an advanced degree in engineering or a related field. This course will help one to explore the basic components and factors affecting wind generation. Gaining knowledge of probability distribution functions used to represent wind data will also be helpful. Learning about wind feasibility study will also be necessary.

See salaries and explore the career path for Wind Energy Research Scientist

ETAP Simulation Engineer

ETAP simulation engineers develop simulations in ETAP for electrical power systems. This course helps to prepare one for a role in ETAP simulation as it will allow to simulate a wind turbine system using the ETAP program. This skill is helpful to power systems engineers, electrical engineers, and wind energy engineers.

See salaries and explore the career path for ETAP Simulation Engineer

Control Systems Engineer

Control systems engineers design and implement control systems for various applications, including wind turbines. This involves developing algorithms and software to optimize the performance and efficiency of these systems. This course will help control systems engineers become familiar with maximum power point tracking in wind turbines. It also helps to build a strong foundation in tip speed ratio control. The course will also discuss optimal torque control and power signal feedback control.

See salaries and explore the career path for Control Systems Engineer

Power Systems Engineer

Power systems engineers are responsible for the design, operation, and maintenance of electrical power grids and related infrastructure. This involves ensuring the reliable and efficient delivery of electricity from generation sources to consumers. This course helps one to understand the principles behind wind power generation – including electricity generation using wind turbines – and the ways in which wind farms can be integrated into the grid. Additionally, the course will improve knowledge of wind turbine generator characteristics.

See salaries and explore the career path for Power Systems Engineer

Sustainability Consultant

Sustainability consultants advise organizations on how to reduce their environmental impact and improve their sustainability practices. This course may be useful for a sustainability consultant who wishes to advise specifically on sustainability projects involving wind generation. The course may be beneficial in developing knowledge about wind farm feasibility study. The course can also enhance familiarity about wind turbines spacing.

See salaries and explore the career path for Sustainability Consultant

Renewable Energy Consultant

Renewable energy consultants advise clients on the feasibility and implementation of renewable energy projects. This often involves analyzing energy needs, evaluating different renewable energy options, and developing strategies for integrating renewable energy sources into existing systems. This course may be helpful to a renewable energy consultant in understanding types of wind turbines as well as understanding different control systems used in the wind turbine and the types of electrical generators utilized. Moreover, the course explains wind farm feasibility study.

See salaries and explore the career path for Renewable Energy Consultant

Electrical Engineer

Electrical engineers design, develop, test, and supervise the manufacturing of electrical equipment. This includes power generation systems, control systems, and electrical components. This course may allow electrical engineers to broaden their skill set into the renewable energy sector. The course may in particular be helpful in understanding different electrical generators, which is an important skill for an electrical engineer. Furthermore, the course covers electrical characteristics of wind turbines.

See salaries and explore the career path for Electrical Engineer

Renewable Energy Project Manager

A renewable energy project manager is responsible for overseeing the planning, execution, and completion of renewable energy projects. This includes managing budgets, schedules, and resources. This course may allow them to understand the feasibility and implementation of projects. The course may be useful in understanding types of wind turbines as well as control systems. The course also explains wind farm feasibility study.

See salaries and explore the career path for Renewable Energy Project Manager

Wind Turbine Technician

Wind turbine technicians install, maintain, and repair wind turbines. This involves climbing wind turbines to inspect components, troubleshoot problems, and perform maintenance tasks. This course may be helpful for wind turbine technicians wishing to expand their knowledge about the operation of wind turbines. The course may be beneficial in gaining knowledge of brakes in the wind turbine. The course also explains the types of wind turbines.

See salaries and explore the career path for Wind Turbine Technician

Energy Storage Specialist

An energy storage specialist focuses on the design, development, and implementation of energy storage solutions, often in conjunction with renewable energy systems. This course provides a foundation in wind energy generation, enabling specialists to understand how energy storage systems can be effectively integrated with wind power. A solid understanding can be gained in wind turbine generator characteristics. The course introduces wind farm feasibility studies, which can inform energy storage planning.

See salaries and explore the career path for Energy Storage Specialist

Renewable Energy Sales

A renewable energy sales representative sells renewable energy products and services to customers. This course helps one gain a deeper understanding of wind energy – including types of wind turbines – enabling you to communicate the benefits effectively. The course will also improve knowledge of wind turbine generator characteristics. Grasping concepts such as wind farm feasibility study and wind turbines spacing may also be helpful in this role.

See salaries and explore the career path for Renewable Energy Sales

HVAC Engineer

HVAC engineers design, develop, and maintain heating, ventilation, and air conditioning systems. This course may be helpful for an HVAC engineer who wishes to broaden their skill set into renewable energy. This course may be useful as it enhances familiarity with different types of towers, such as tubular steel wind turbine tower, lattice wind turbine tower, concrete wind turbine tower, and hybrid wind turbine tower.

See salaries and explore the career path for HVAC Engineer

Ultimate Wind Energy Course for Electrical Engineering

What's inside

Learning objectives

Syllabus

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Reviews summary

Comprehensive wind energy for electrical engineers

Activities

Career center

Reading list

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