SlideShare a Scribd company logo

Wind energy

Download as PPTX, PDF
Ganesh Peketi
Ganesh Peketi

Construction and Working of Wind turbines.

Engineering
1 of 44
WIND ENERGY(C0NTENTS) • INTRODUCTION • ORIGIN OF WINDS • WIND DATA • VARIATION OF WIND SPEED WITH HEIGHT • HORIZONTAL AXIS WIND TURBINE (HAWT) ROTORS PITCH SYSTEM CONTROL NACELLE (IT’S COMPONENTS) YAW SYSTEM CONTROL TOWER (ACCESS LADDER) FOUNDATION (ELECTRIC GRID) • EFFICIENCY OF TURBINE • BETZ’S LAW • TIP SPEED RATIO • VERTICAL AXIS WIND TURBINE (VAWT)
INTRODUCTION • Winds are horizontal movement of AIR from an area of HIGH pressure(H) to an area of low pressure(L). • Wind energy is a kinetic energy associated with movement of large masses of air. • It is clean, cheap, and eco-friendly renewable source. • Wind energy is utilized as mechanical energy with the help of a wind turbine. • Moderate to high-speed winds, typically from 5m/s to about 25m/s are considered favorable for most wind turbines. • The electric power generation through wind was first proposed in Denmark in 1890
ORIGIN OF WINDS • The origin of winds may be traced basically to uneven heating of the earth’s surface due to sun. • This may lead to circulation of widespread winds on a global basis, producing planetary winds or may have a limited influence in a smaller area to cause local winds.
GLOBAL (OR PLANETARY) WINDS • Two major forces determine the speed and direction of wind on a global basis : i. Primary force : Due to differential heating of the earth at equatorial and polar regions. (Heat transfer) ii. Spinning of earth about its axis produces a Coriolis force, which is responsible for deviation of air currents. (deflects the direction of wind)
LOCAL WINDS (THAT BLOW OVER SHORT DISTANCES) • Localized uneven heating is responsible for local winds. Local winds are produced due to two mechanisms: i. Due to differential heating of land surface and water bodies due to solar radiation. ii. Due to differential heating of slopes on the hillsides and that of low lands.
FACTORS AFFECTING THE DISTRIBUTION OF WIND ENERGY ON THE SURFACE OF THE EARTH • Both global and local factors influence the availability of wind energy at particular site. i. On the planetary level, great mountain masses influence the circulation of air currents. ii. Surface roughness or friction, due to the resistance that different elements of the earth surface like hill’s, tall buildings, trees and similar obstructions impair streamline air flow. Wind velocity in horizontal direction gets markedly reduced. Frictional effect is less on smooth areas such as sea shore or large open areas and more in rough urban areas with tall building and trees. iii. Wind speed also increases while passing through narrow mountain gaps where it gets channeled.
• Wind speed is measured by an anemometer and wind direction is measured by a wind vane attached to the direction indicator. • A cup anemometer consists of three or four cups mounted symmetrically about a vertical axis. The speed of rotation indicates wind speed. • Wind speed measurement should be made at an effective height 10m above the ground. (WMO) • Wind rose Graph : An elegant method of describing average wind speed duration and direction on a single graph. Length of the bars represent the percentage of duration.Wind rose graph
VARIATION OF WIND SPEED WITH HEIGHT • Wind shear : Rate of change of wind speed with height • At the earth’s surface, wind speed is always zero. It increases with height above the ground. The wind near the earth’s surface is retarded by surface roughness.
ADVANTAGES OF WIND ENERGY i. It is a renewable source of energy. ii. Like all forms of solar energy, wind power systems are non- polluting, so it has no adverse influence on the environment. iii. Wind energy systems avoid fuel combustion and transport. iv. Cost free renewable resources.
DISADVANTAGES OF WIND ENERGY • Wind energy available is fluctuating in nature and it varies from zero to storm force.(unreliable) • Wind energy systems are noisy in operation; a large unit can be heard many kilometers away. • Birds and bats have been killed by flying into the rotors. • Good wind sites are often located in remote locations, far from cities where the electricity is needed. • Installation & Maintenance cost of wind turbine is high.
TYPES OF WIND TURBINES
HORIZONTAL AXIS WIND TURBINE (HAWT COMPONENTS) ROTOR  BLADES  HUB (BLADE PITCH CONTROL ) NACELLE  LOW SPEED SHAFT  GEAR BOX  BRAKE  HIGH SPEED SHAFT  GENERATOR  CONTROLLER  ANEMOMETER & WIND VANE YAW SYSTEM (WIND ORIENTATION CONTROL) TOWER (ACCESS LADDER ) FOUNDATION (CONNECTION TO THE ELECTRIC GRID)
ROTOR (BLADES & HUB ) BLADE • Turbine blades are made of high- density wood or glass fiber and epoxy composites. • The blades of the wind turbine are designed to be aerodynamic so that they are able to utilize wind energy more easily. • They have an airfoil type of cross section. • The blades are slightly twisted from the outer tip to the root. • The diameter of a typical, MW range, modern rotor may be of the order of 100m.
TYPES OF ROTORS • Wind turbines have been built with up to six propellers type blades but two and three- bladed propellers are most common. • A single blade rotor, with a balancing counterweight is economical, has simple controls but it is noisier and produces unbalanced forces. it is used for low power applications.
TWO AND THREE- BLADED ROTOR • The two-blade rotor is also simpler to erect, since it can be assembled on the ground and lifted to the shaft without complicated operation during the lift. • Compared to the two-blade design, the three-blade machine has smoother power output and balanced spinning force. • Adding a third blade increases the power output by about 5% only, while the weight and cost of a rotor increases by 50%. • Large HAWTs have been manufactured with two and three
SAIL TYPE, DUTCH TYPE, MULTI BLADE ROTOR • Sail wing type : it is of recent origin. The blade surface is made from cloth, nylon, or plastics arranged as mast and pole or sail wings. • Dutch type : it is one of the oldest designs. The blade surface are made from an array of wooden slats (sticks). • Multi blade type : made from sheet metal or aluminum. They have good power coefficient, high starting torque and add advantage of simplicity and low cost. • Both Dutch and Multi blade type are low- speed rotors and most suited for water-lifting applications, which require a high starting torque. They can capture power even very slow winds. SailWingTy pe Dutch type Multi Bladed type
HUB • The central solid portion of the rotor wheel is known as hub. All blades are attached to the hub. The mechanism for pitch angle control is also provided inside the hub. • Pitch angle control system is used to maximize the wind turbine efficiency by positioning the blades at the best possible angle. • The pitch motor is often found near the hub of the rotor.
NACELLE • The term nacelle is derived from the name for housing (casing) containing the engines of an wind turbine (Aerogenerator). • The rotor is attached to the nacelle, and mounted at top of a tower. It contains rotor brakes, gearbox, generator, low and high speed shafts, electrical switchgear and control.
• LOW SPEED SHAFT : The low speed shaft is turned by the motion of a wind turbines blades as they rotate. The low speed shaft transfers kinetic energy to the gearbox. • GEARBOX : The gearbox steps up the shaft rpm to suit the generator. It is a heavy and expensive piece of equipment that connects the low speed shaft to the high speed shaft. • HIGH SPEED SHAFT : The high speed shaft connects the gearbox to the generator and its sole purpose is to drive the generator so that it can produce electricity.
BRAKE : • Brakes are used to stop the rotor when power generation is not desired. Turbine do not operate at wind speed above about 25m/s because they might be damaged by high winds. • Generally drum brake or disk brake is used to stop turbine in emergency situation and at maintenance situations.
GENERATOR • Wind power generator converts wind energy (Mechanical energy) to electrical energy. • The generator is attached at one end to the wind turbine, which provides the mechanical energy and at other end is connected to the electrical grid. • The generator need to have a cooling system to make sure there is no over heating.
YAW-CONTROL MECHANISM • The mechanism to adjust the nacelle around the vertical axis to keep it facing the wind is provided at the base of the nacelle. The yaw-control system continuously orients the rotor in the direction of wind. • The yaw motor will be found inside the tower underneath the nacelle and will turn the nacelle and the rotor to face the current wind direction. (* Yaw means twist about vertical axis )
CONTROL SYSTEM (CONTROLLER) • The control system continuously adjusts the pitch to obtain optimal performance. • The controller starts up the machine at wind speed of about 5 m/s and shuts off the machine at about 25 m/s. • The control system is also the mechanism that will calculate the most efficient pitch and yaw for the turbine dependent on wind speed and direction. • Control system gets wind data (speed & direction ) from velocity
TOWER • The tower supports the nacelle and rotor. Its height approximately two to three times the blade length. But, practically maximum height is estimated to be roughly 60 m. • It is designed to withstand the wind load during gusts (strong rush of wind). • At the bottom level of the tower there will be step-up transformers for the connection to the Electrical Grid. • Inside of the tower there is a ladder to access to top of the tower for maintenance and setup processes and will also contain high voltage cables for transporting the electricity produced by the generator at the top of the turbine to its base.
TYPES OF TOWERS 1. The reinforced concrete tower, 2. The pole tower, 3. The built up shell-tube tower, and 4. The truss tower. Pole tower Truss tower
FOUNDATION • Wind turbines, by their nature, are very tall slender structures. • It must be designed mainly to transfer the vertical load (dead weight) & horizontal dynamic load (wind load) to the ground. • The turbines are sufficiently restrained against moment loads to operate efficiently.
WIND TURBINE EFFICIENCY • 𝜂 𝑜 = 𝑢𝑠𝑒𝑓𝑢𝑙 𝑜𝑢𝑡𝑝𝑢𝑡 𝑝𝑜𝑤𝑒𝑟 𝑤𝑖𝑛𝑑 𝑝𝑜𝑤𝑒𝑟 𝑖𝑛𝑝𝑢𝑡 𝜂 𝐴 × 𝜂 𝐺 × 𝜂 𝐶 × 𝜂𝐺𝑒𝑛 Where ; 𝜂 𝐴 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑎𝑒𝑟𝑜𝑡𝑢𝑟𝑏𝑖𝑛e 𝜂 𝐺 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑔𝑒𝑎𝑟𝑖𝑛𝑔 𝜂 𝐶 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑚𝑒𝑐ℎ𝑎𝑛𝑖𝑐𝑎𝑙𝑐𝑜𝑢𝑝𝑙𝑖𝑛𝑔 𝜂𝐺𝑒𝑛 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑔𝑒𝑛𝑒𝑟𝑎𝑡𝑜𝑟
BETZ’S LAW • This law states that no wind turbine can capture more than 16 27 or 59.3% of kinetic energy of the wind. • It gives the value of Theoretical maximum efficiency that a wind turbine can achieve.
TIP SPEED RATIO (TSR) • TSR is the ratio between the tangential speed of the tips of the turbine blades and the speed of the wind. (Tip Speed Ratio) 𝜆 = 𝑇𝑖𝑝 𝑠𝑝𝑒𝑒𝑑 𝑜𝑓 𝑏𝑙𝑎𝑑𝑒 𝑤𝑖𝑛𝑑 𝑠𝑝𝑒𝑒𝑑 • The tip-speed ratio is related to efficiency, with the optimum varying with blade design. Higher tip speeds result in higher noise levels and require stronger blades due to large centrifugal forces.
VERTICAL AXIS WIND TURBINE (VAWT) : The main attractions of a VAWT are : • It can accept wind from any direction, eliminating the need of yaw control, • The gearbox, generator, etc., are located at the ground , thus eliminating the heavy nacelle at the top of the tower, thus simplifying the design and installation of the whole structure, including the tower, • The inspection and maintenance also gets easier, and • It also reduces the overall cost
TOWER (OR ROTOR SHAFT) • The tower is a hollow vertical rotor shaft, which rotates freely about the vertical axis between the top and bottom bearings. • It is installed above a super structure. • The upper part of the tower is supported by guy ropes. • The height of the tower of a large turbine is around 100m.
BLADES • It has two or three thin, curved blades shaped like an egg beater in a profile, (Troposkien profile) with blades curved in a form that minimizes the bending stress caused by centrifugal forces. • The blades have an airfoil cross section with constant chord length. • The pitch of the blades cannot be changed. • The diameter of the rotor is slightly less than the tower height.
SUPPORT STRUCTURE • The support structure is provided at the ground to support the weight of the rotor. • Gearbox, generator, brakes, electrical switchgear and controls are housed within this structure.
TYPES OF ROTORS 1. Cup type rotor 2. Savonius or S-rotor 3. Darrieus rotor 4. Musgrove rotor 5. Evans rotor
CUP TYPE ROTOR • The simplest being a three-or four-cup structure attached symmetrically to a vertical shaft. • The drag force on the concave surface of the cup facing the wind is more than that on the convex surface. As a result, structure starts rotating. Some lift force also helps rotation. • However, it cannot carry a load and therefore cannot used as power source. • The main characteristic of this rotor is that its rotational frequency is linearly related to wind speed. i.e., it is used for measuring the wind speed and the apparatus is known as CUP ANEMOMETER.
SAVONIUS OR S-ROTOR • It consists of two half cylinders attached to a vertical axis and facing in opposite directions to form a two-vane rotor. • It has high starting torque, low speed and low efficiency. • It can extract power even from very slow wind, making it working most of the time. These are used for low-power applications. • A high starting torque particularly makes it suitable for pumping applications.
DARRIEUS ROTOR (HIGH SPEED, HIGH EFFICIENCY) • It is used for large-scale power generation. Its power coefficient is considerably better than that of an S- rotor. • Drawback : it is usually not self-starting. Movement may be initiated by using electrical generator as motor (or S-rotor). • As the pitch of the blade cannot change, the rotor frequency and, thus the output power cannot be controlled. Hence, at high wind speed it becomes difficult to control the output. • For better performance and safety of the blades, gearbox and generator, it is desirable to limit the output to a level much below its maximum possible value.
MUSGROVE ROTOR • He suggested the use of H-shaped rotor where blades with a fixed pitch are attached vertically to a horizontal cross arm. • Power control is achieved by controlled folding of the blades. • Inclining the blades to the vertical provides an effective means of altering the blade angle of attack and hence controlling the power output.
EVANS ROTOR (GYRO MILL) • It is an improvement over H-shaped rotor. • Here, the rotor geometry remains fixed (blades remains straight) , but the blades are hinged on a vertical axis and the blade pitch is varied cyclically (as the blade rotates about the vertical axis) to regulate the power output. • But the need to vary the pitch cyclically through every rotor revolution introduces considerable mechanical complexity.
ANIMATIONS OF HAWT (PITCH & YAW MECHANISM)
Wind energy

Recommended

Wind energy
Wind energyWind energy
Wind energyShri Mata Vaishno Devi University
 
WIND POWER GENERATION
WIND POWER GENERATIONWIND POWER GENERATION
WIND POWER GENERATIONAmit Meena
 
WIND ENERGY SYSTEM
WIND ENERGY SYSTEM WIND ENERGY SYSTEM
WIND ENERGY SYSTEM Power System Operation
 
EPG - Unit 04 - Wind Power Plant
EPG - Unit 04 - Wind Power PlantEPG - Unit 04 - Wind Power Plant
EPG - Unit 04 - Wind Power PlantPremanandDesai
 
Wind energy and Their Application
Wind energy and Their ApplicationWind energy and Their Application
Wind energy and Their ApplicationDr. Sanjay Singh Chouhan
 
Windmill
WindmillWindmill
Windmillabhisek das
 
Solar flat plate collector
Solar flat plate collectorSolar flat plate collector
Solar flat plate collectorBipin Gupta
 
Tidal energy
Tidal energyTidal energy
Tidal energyRamaraj90033
 

Recommended

Wind energy
Wind energyWind energy
Wind energyShri Mata Vaishno Devi University
 
WIND POWER GENERATION
WIND POWER GENERATIONWIND POWER GENERATION
WIND POWER GENERATIONAmit Meena
 
WIND ENERGY SYSTEM
WIND ENERGY SYSTEM WIND ENERGY SYSTEM
WIND ENERGY SYSTEM Power System Operation
 
EPG - Unit 04 - Wind Power Plant
EPG - Unit 04 - Wind Power PlantEPG - Unit 04 - Wind Power Plant
EPG - Unit 04 - Wind Power PlantPremanandDesai
 
Wind energy and Their Application
Wind energy and Their ApplicationWind energy and Their Application
Wind energy and Their ApplicationDr. Sanjay Singh Chouhan
 
Windmill
WindmillWindmill
Windmillabhisek das
 
Solar flat plate collector
Solar flat plate collectorSolar flat plate collector
Solar flat plate collectorBipin Gupta
 
Tidal energy
Tidal energyTidal energy
Tidal energyRamaraj90033
 
Wind power
Wind powerWind power
Wind powerAhmed Nabil
 
Wind turbine
Wind turbineWind turbine
Wind turbineNishant Ranjan
 
Wind energy basics
Wind energy basicsWind energy basics
Wind energy basicsNirav Daraniya
 
Wind turbine types
Wind turbine typesWind turbine types
Wind turbine typesTaral Soliya
 
wave power & wave energy
wave power & wave energywave power & wave energy
wave power & wave energysaqibsaqi123
 
wind energy Seminar
wind energy Seminar wind energy Seminar
wind energy Seminarashine288
 
Wind power plant
Wind power plant Wind power plant
Wind power plant Abhishek Choksi
 
Wind Energy
Wind EnergyWind Energy
Wind Energykushagra21
 
Wind Energy Presentation
Wind Energy PresentationWind Energy Presentation
Wind Energy PresentationDileep Singh
 
Solar energy storage
Solar energy storageSolar energy storage
Solar energy storageAshish Bandewar
 
Wind power plant
Wind power plantWind power plant
Wind power plantraxit varmora
 
Wind energy
Wind energyWind energy
Wind energysstms1
 
Renewable energy - Wind energy
Renewable energy - Wind energyRenewable energy - Wind energy
Renewable energy - Wind energyGeorge Thomas
 
Wave Energy
Wave Energy Wave Energy
Wave Energy esatoglu
 
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEM
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEMUnit 03 -SOLAR PHOTOVOLTAIC SYSTEM
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEMPremanandDesai
 
Wind Energy ppt
Wind Energy pptWind Energy ppt
Wind Energy ppttabi5
 
Wind Power Generation Schemes
Wind Power Generation SchemesWind Power Generation Schemes
Wind Power Generation SchemesVignesh Sekar
 
Wind Power Energy
Wind Power EnergyWind Power Energy
Wind Power EnergyChatar Singh Meena
 
Wind energy and its application
Wind energy and its applicationWind energy and its application
Wind energy and its applicationAjay Singh Lodhi
 
Ocean Thermal Energy Conversion
Ocean Thermal Energy ConversionOcean Thermal Energy Conversion
Ocean Thermal Energy ConversionKeshav Kumar Jha
 
Overview of Wind Energy
Overview of Wind EnergyOverview of Wind Energy
Overview of Wind EnergyJerilene
 
Wind Energy Project
Wind Energy ProjectWind Energy Project
Wind Energy ProjectTBC Corporation
 

More Related Content

What's hot

Wind turbine types
Wind turbine typesWind turbine types
Wind turbine typesTaral Soliya
 
wave power & wave energy
wave power & wave energywave power & wave energy
wave power & wave energysaqibsaqi123
 
wind energy Seminar
wind energy Seminar wind energy Seminar
wind energy Seminarashine288
 
Wind Energy Presentation
Wind Energy PresentationWind Energy Presentation
Wind Energy PresentationDileep Singh
 
Wind energy
Wind energyWind energy
Wind energysstms1
 
Renewable energy - Wind energy
Renewable energy - Wind energyRenewable energy - Wind energy
Renewable energy - Wind energyGeorge Thomas
 
Wave Energy
Wave Energy Wave Energy
Wave Energy esatoglu
 
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEM
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEMUnit 03 -SOLAR PHOTOVOLTAIC SYSTEM
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEMPremanandDesai
 
Wind Energy ppt
Wind Energy pptWind Energy ppt
Wind Energy ppttabi5
 
Wind Power Generation Schemes
Wind Power Generation SchemesWind Power Generation Schemes
Wind Power Generation SchemesVignesh Sekar
 
Wind energy and its application
Wind energy and its applicationWind energy and its application
Wind energy and its applicationAjay Singh Lodhi
 
Ocean Thermal Energy Conversion
Ocean Thermal Energy ConversionOcean Thermal Energy Conversion
Ocean Thermal Energy ConversionKeshav Kumar Jha
 

What's hot (20)

Wind power
Wind powerWind power
Wind power
 
Wind turbine
Wind turbineWind turbine
Wind turbine
 
Wind energy basics
Wind energy basicsWind energy basics
Wind energy basics
 
Wind turbine types
Wind turbine typesWind turbine types
Wind turbine types
 
wave power & wave energy
wave power & wave energywave power & wave energy
wave power & wave energy
 
wind energy Seminar
wind energy Seminar wind energy Seminar
wind energy Seminar
 
Wind power plant
Wind power plant Wind power plant
Wind power plant
 
Wind Energy
Wind EnergyWind Energy
Wind Energy
 
Wind Energy Presentation
Wind Energy PresentationWind Energy Presentation
Wind Energy Presentation
 
Solar energy storage
Solar energy storageSolar energy storage
Solar energy storage
 
Wind power plant
Wind power plantWind power plant
Wind power plant
 
Wind energy
Wind energyWind energy
Wind energy
 
Renewable energy - Wind energy
Renewable energy - Wind energyRenewable energy - Wind energy
Renewable energy - Wind energy
 
Wave Energy
Wave Energy Wave Energy
Wave Energy
 
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEM
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEMUnit 03 -SOLAR PHOTOVOLTAIC SYSTEM
Unit 03 -SOLAR PHOTOVOLTAIC SYSTEM
 
Wind Energy ppt
Wind Energy pptWind Energy ppt
Wind Energy ppt
 
Wind Power Generation Schemes
Wind Power Generation SchemesWind Power Generation Schemes
Wind Power Generation Schemes
 
Wind Power Energy
Wind Power EnergyWind Power Energy
Wind Power Energy
 
Wind energy and its application
Wind energy and its applicationWind energy and its application
Wind energy and its application
 
Ocean Thermal Energy Conversion
Ocean Thermal Energy ConversionOcean Thermal Energy Conversion
Ocean Thermal Energy Conversion
 

Viewers also liked

Overview of Wind Energy
Overview of Wind EnergyOverview of Wind Energy
Overview of Wind EnergyJerilene
 
Environmental Engineering Lab Manual for Civil Engineering Stream
Environmental Engineering Lab Manual for Civil Engineering StreamEnvironmental Engineering Lab Manual for Civil Engineering Stream
Environmental Engineering Lab Manual for Civil Engineering StreamGanesh Peketi
 
Wind Power Point Presentation
Wind Power Point PresentationWind Power Point Presentation
Wind Power Point PresentationKurt Kublbeck
 
Wind power plant
Wind power plantWind power plant
Wind power plantshrey1993
 
Wind Energy Power Point Presentation
Wind Energy Power Point PresentationWind Energy Power Point Presentation
Wind Energy Power Point Presentationrclassic
 
Measurement of speed of wind
Measurement of speed of windMeasurement of speed of wind
Measurement of speed of windPooja Dubey
 
Presentation on Solar energy, Wind energy and Nuclear energy.
Presentation on Solar energy, Wind energy and Nuclear energy.Presentation on Solar energy, Wind energy and Nuclear energy.
Presentation on Solar energy, Wind energy and Nuclear energy.Ishan Trivedi
 
Renewable Energy - Intro ppt
Renewable Energy - Intro pptRenewable Energy - Intro ppt
Renewable Energy - Intro pptSaurabh Mehta
 
Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...
Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...
Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...ertekg
 
Real Time and Wireless Smart Faults Detection Device for Wind Turbines
Real Time and Wireless Smart Faults Detection Device for Wind TurbinesReal Time and Wireless Smart Faults Detection Device for Wind Turbines
Real Time and Wireless Smart Faults Detection Device for Wind Turbineschokrio
 
International Journal of Engineering Research and Development
International Journal of Engineering Research and DevelopmentInternational Journal of Engineering Research and Development
International Journal of Engineering Research and DevelopmentIJERD Editor
 
PHM Application for Utility-scale Wind Turbines
PHM Application for Utility-scale Wind TurbinesPHM Application for Utility-scale Wind Turbines
PHM Application for Utility-scale Wind TurbinesRenewable NRG Systems
 
Lesson 7 wind system
Lesson 7 wind systemLesson 7 wind system
Lesson 7 wind system27Symon
 
Emerging Technologies for Wind Drivetrain Condition Monitoring
Emerging Technologies for Wind Drivetrain Condition MonitoringEmerging Technologies for Wind Drivetrain Condition Monitoring
Emerging Technologies for Wind Drivetrain Condition MonitoringRich Wurzbach
 
Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...
Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...
Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...Parker Hannifin Corporation
 

Viewers also liked (20)

Overview of Wind Energy
Overview of Wind EnergyOverview of Wind Energy
Overview of Wind Energy
 
Wind Energy Project
Wind Energy ProjectWind Energy Project
Wind Energy Project
 
Environmental Engineering Lab Manual for Civil Engineering Stream
Environmental Engineering Lab Manual for Civil Engineering StreamEnvironmental Engineering Lab Manual for Civil Engineering Stream
Environmental Engineering Lab Manual for Civil Engineering Stream
 
Wind Power Point Presentation
Wind Power Point PresentationWind Power Point Presentation
Wind Power Point Presentation
 
Wind power plant
Wind power plantWind power plant
Wind power plant
 
Wind power plant
Wind power plantWind power plant
Wind power plant
 
Wind Energy Power Point Presentation
Wind Energy Power Point PresentationWind Energy Power Point Presentation
Wind Energy Power Point Presentation
 
Measurement of speed of wind
Measurement of speed of windMeasurement of speed of wind
Measurement of speed of wind
 
Presentation on Solar energy, Wind energy and Nuclear energy.
Presentation on Solar energy, Wind energy and Nuclear energy.Presentation on Solar energy, Wind energy and Nuclear energy.
Presentation on Solar energy, Wind energy and Nuclear energy.
 
Renewable Energy - Intro ppt
Renewable Energy - Intro pptRenewable Energy - Intro ppt
Renewable Energy - Intro ppt
 
Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...
Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...
Insights into the Efficiencies of On-Shore Wind Turbines: A Data-Centric Anal...
 
Real Time and Wireless Smart Faults Detection Device for Wind Turbines
Real Time and Wireless Smart Faults Detection Device for Wind TurbinesReal Time and Wireless Smart Faults Detection Device for Wind Turbines
Real Time and Wireless Smart Faults Detection Device for Wind Turbines
 
International Journal of Engineering Research and Development
International Journal of Engineering Research and DevelopmentInternational Journal of Engineering Research and Development
International Journal of Engineering Research and Development
 
Dc ac link champ energy products-ch1.5 - copy
Dc ac link champ energy products-ch1.5 - copyDc ac link champ energy products-ch1.5 - copy
Dc ac link champ energy products-ch1.5 - copy
 
Wind Data Analysis
Wind Data AnalysisWind Data Analysis
Wind Data Analysis
 
PHM Application for Utility-scale Wind Turbines
PHM Application for Utility-scale Wind TurbinesPHM Application for Utility-scale Wind Turbines
PHM Application for Utility-scale Wind Turbines
 
Lesson 7 wind system
Lesson 7 wind systemLesson 7 wind system
Lesson 7 wind system
 
Emerging Technologies for Wind Drivetrain Condition Monitoring
Emerging Technologies for Wind Drivetrain Condition MonitoringEmerging Technologies for Wind Drivetrain Condition Monitoring
Emerging Technologies for Wind Drivetrain Condition Monitoring
 
Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...
Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...
Wind Turbine Condition Monitoring - Wear Debris Monitoring of Wind Turbine Ge...
 
Anemometer
AnemometerAnemometer
Anemometer
 

Similar to Wind energy

wind turbine detailed presentation .ppt
wind turbine detailed presentation .pptwind turbine detailed presentation .ppt
wind turbine detailed presentation .pptpaktracks
 
Wind energy system
Wind energy systemWind energy system
Wind energy systemDony Sunny
 
windenergy-210626034246.pdf
windenergy-210626034246.pdfwindenergy-210626034246.pdf
windenergy-210626034246.pdfAhmedAdel369285
 
Wind Power & Wind Turbine
Wind Power & Wind TurbineWind Power & Wind Turbine
Wind Power & Wind TurbineRidwanul Hoque
 
WIND TURBINE turbine development Wind turbines are classified into two genera...
WIND TURBINE turbine development Wind turbines are classified into two genera...WIND TURBINE turbine development Wind turbines are classified into two genera...
WIND TURBINE turbine development Wind turbines are classified into two genera...Mohan313217
 
Types of Wind Energy Systems.pdf
Types of Wind Energy Systems.pdfTypes of Wind Energy Systems.pdf
Types of Wind Energy Systems.pdfGowthamPl1
 
Renewableandnon renewable energysources.pdf
Renewableandnon renewable energysources.pdfRenewableandnon renewable energysources.pdf
Renewableandnon renewable energysources.pdfssuserca5764
 
Wind Turbine operation & Maintenance.pptx
Wind Turbine operation & Maintenance.pptxWind Turbine operation & Maintenance.pptx
Wind Turbine operation & Maintenance.pptxAbdUllahEET
 
Wind turbine (bhaw nath jha)
Wind turbine (bhaw nath jha)Wind turbine (bhaw nath jha)
Wind turbine (bhaw nath jha)Bhawnath Jha
 
LEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptx
LEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptxLEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptx
LEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptxmuhammadfawadn
 

Similar to Wind energy (20)

wind turbine detailed presentation .ppt
wind turbine detailed presentation .pptwind turbine detailed presentation .ppt
wind turbine detailed presentation .ppt
 
Wind energy system
Wind energy systemWind energy system
Wind energy system
 
Wind energy
Wind energyWind energy
Wind energy
 
windenergy-210626034246.pdf
windenergy-210626034246.pdfwindenergy-210626034246.pdf
windenergy-210626034246.pdf
 
Wind energy
Wind energyWind energy
Wind energy
 
CH 5 Wind Energy
CH 5 Wind EnergyCH 5 Wind Energy
CH 5 Wind Energy
 
Wind Power & Wind Turbine
Wind Power & Wind TurbineWind Power & Wind Turbine
Wind Power & Wind Turbine
 
MODULE - 4.pptx
MODULE - 4.pptxMODULE - 4.pptx
MODULE - 4.pptx
 
Wind energ
Wind energWind energ
Wind energ
 
WIND TURBINE turbine development Wind turbines are classified into two genera...
WIND TURBINE turbine development Wind turbines are classified into two genera...WIND TURBINE turbine development Wind turbines are classified into two genera...
WIND TURBINE turbine development Wind turbines are classified into two genera...
 
Wind Energy
Wind EnergyWind Energy
Wind Energy
 
Wind energy
Wind energyWind energy
Wind energy
 
Types of Wind Energy Systems.pdf
Types of Wind Energy Systems.pdfTypes of Wind Energy Systems.pdf
Types of Wind Energy Systems.pdf
 
Renewableandnon renewable energysources.pdf
Renewableandnon renewable energysources.pdfRenewableandnon renewable energysources.pdf
Renewableandnon renewable energysources.pdf
 
Wind Turbine operation & Maintenance.pptx
Wind Turbine operation & Maintenance.pptxWind Turbine operation & Maintenance.pptx
Wind Turbine operation & Maintenance.pptx
 
Windpower
WindpowerWindpower
Windpower
 
Wind turbine (bhaw nath jha)
Wind turbine (bhaw nath jha)Wind turbine (bhaw nath jha)
Wind turbine (bhaw nath jha)
 
UNIT-III-WIND ENERGY.pptx
UNIT-III-WIND ENERGY.pptxUNIT-III-WIND ENERGY.pptx
UNIT-III-WIND ENERGY.pptx
 
LEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptx
LEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptxLEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptx
LEC-4-5 WIND ENERGY RESOURCES for ERU subject.pptx
 
wind.pdf
wind.pdfwind.pdf
wind.pdf
 

Recently uploaded

An experimental study in using natural admixture as an alternative for chemic...
An experimental study in using natural admixture as an alternative for chemic...An experimental study in using natural admixture as an alternative for chemic...
An experimental study in using natural admixture as an alternative for chemic...Chandu841456
 
Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)
Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)
Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)dollysharma2066
 
Work Experience-Dalton Park.pptxfvvvvvvv
Work Experience-Dalton Park.pptxfvvvvvvvWork Experience-Dalton Park.pptxfvvvvvvv
Work Experience-Dalton Park.pptxfvvvvvvvLewisJB
 
Arduino_CSE ece ppt for working and principal of arduino.ppt
Arduino_CSE ece ppt for working and principal of arduino.pptArduino_CSE ece ppt for working and principal of arduino.ppt
Arduino_CSE ece ppt for working and principal of arduino.pptSAURABHKUMAR892774
 
Why does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsync
Why does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsyncWhy does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsync
Why does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsyncssuser2ae721
 
Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...
Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...
Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...srsj9000
 
Software and Systems Engineering Standards: Verification and Validation of Sy...
Software and Systems Engineering Standards: Verification and Validation of Sy...Software and Systems Engineering Standards: Verification and Validation of Sy...
Software and Systems Engineering Standards: Verification and Validation of Sy...VICTOR MAESTRE RAMIREZ
 
Application of Residue Theorem to evaluate real integrations.pptx
Application of Residue Theorem to evaluate real integrations.pptxApplication of Residue Theorem to evaluate real integrations.pptx
Application of Residue Theorem to evaluate real integrations.pptx959SahilShah
 
TechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor Catchers
TechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor CatchersTechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor Catchers
TechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor Catcherssdickerson1
 
Sachpazis Costas: Geotechnical Engineering: A student's Perspective Introduction
Sachpazis Costas: Geotechnical Engineering: A student's Perspective IntroductionSachpazis Costas: Geotechnical Engineering: A student's Perspective Introduction
Sachpazis Costas: Geotechnical Engineering: A student's Perspective IntroductionDr.Costas Sachpazis
 
What are the advantages and disadvantages of membrane structures.pptx
What are the advantages and disadvantages of membrane structures.pptxWhat are the advantages and disadvantages of membrane structures.pptx
What are the advantages and disadvantages of membrane structures.pptxwendy cai
 
CCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdf
CCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdfCCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdf
CCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdfAsst.prof M.Gokilavani
 
Introduction to Machine Learning Unit-3 for II MECH
Introduction to Machine Learning Unit-3 for II MECHIntroduction to Machine Learning Unit-3 for II MECH
Introduction to Machine Learning Unit-3 for II MECHC Sai Kiran
 
8251 universal synchronous asynchronous receiver transmitter
8251 universal synchronous asynchronous receiver transmitter8251 universal synchronous asynchronous receiver transmitter
8251 universal synchronous asynchronous receiver transmitterShivangiSharma879191
 
Electronically Controlled suspensions system .pdf
Electronically Controlled suspensions system .pdfElectronically Controlled suspensions system .pdf
Electronically Controlled suspensions system .pdfme23b1001
 
Oxy acetylene welding presentation note.
Oxy acetylene welding presentation note.Oxy acetylene welding presentation note.
Oxy acetylene welding presentation note.eptoze12
 
complete construction, environmental and economics information of biomass com...
complete construction, environmental and economics information of biomass com...complete construction, environmental and economics information of biomass com...
complete construction, environmental and economics information of biomass com...asadnawaz62
 

Recently uploaded (20)

An experimental study in using natural admixture as an alternative for chemic...
An experimental study in using natural admixture as an alternative for chemic...An experimental study in using natural admixture as an alternative for chemic...
An experimental study in using natural admixture as an alternative for chemic...
 
Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)
Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)
Call Us ≽ 8377877756 ≼ Call Girls In Shastri Nagar (Delhi)
 
Work Experience-Dalton Park.pptxfvvvvvvv
Work Experience-Dalton Park.pptxfvvvvvvvWork Experience-Dalton Park.pptxfvvvvvvv
Work Experience-Dalton Park.pptxfvvvvvvv
 
Arduino_CSE ece ppt for working and principal of arduino.ppt
Arduino_CSE ece ppt for working and principal of arduino.pptArduino_CSE ece ppt for working and principal of arduino.ppt
Arduino_CSE ece ppt for working and principal of arduino.ppt
 
Why does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsync
Why does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsyncWhy does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsync
Why does (not) Kafka need fsync: Eliminating tail latency spikes caused by fsync
 
POWER SYSTEMS-1 Complete notes examples
POWER SYSTEMS-1 Complete notes examplesPOWER SYSTEMS-1 Complete notes examples
POWER SYSTEMS-1 Complete notes examples
 
Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...
Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...
Gfe Mayur Vihar Call Girls Service WhatsApp -> 9999965857 Available 24x7 ^ De...
 
Software and Systems Engineering Standards: Verification and Validation of Sy...
Software and Systems Engineering Standards: Verification and Validation of Sy...Software and Systems Engineering Standards: Verification and Validation of Sy...
Software and Systems Engineering Standards: Verification and Validation of Sy...
 
Application of Residue Theorem to evaluate real integrations.pptx
Application of Residue Theorem to evaluate real integrations.pptxApplication of Residue Theorem to evaluate real integrations.pptx
Application of Residue Theorem to evaluate real integrations.pptx
 
9953056974 Call Girls In South Ex, Escorts (Delhi) NCR.pdf
9953056974 Call Girls In South Ex, Escorts (Delhi) NCR.pdf9953056974 Call Girls In South Ex, Escorts (Delhi) NCR.pdf
9953056974 Call Girls In South Ex, Escorts (Delhi) NCR.pdf
 
TechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor Catchers
TechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor CatchersTechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor Catchers
TechTAC® CFD Report Summary: A Comparison of Two Types of Tubing Anchor Catchers
 
Sachpazis Costas: Geotechnical Engineering: A student's Perspective Introduction
Sachpazis Costas: Geotechnical Engineering: A student's Perspective IntroductionSachpazis Costas: Geotechnical Engineering: A student's Perspective Introduction
Sachpazis Costas: Geotechnical Engineering: A student's Perspective Introduction
 
What are the advantages and disadvantages of membrane structures.pptx
What are the advantages and disadvantages of membrane structures.pptxWhat are the advantages and disadvantages of membrane structures.pptx
What are the advantages and disadvantages of membrane structures.pptx
 
CCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdf
CCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdfCCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdf
CCS355 Neural Network & Deep Learning UNIT III notes and Question bank .pdf
 
Introduction to Machine Learning Unit-3 for II MECH
Introduction to Machine Learning Unit-3 for II MECHIntroduction to Machine Learning Unit-3 for II MECH
Introduction to Machine Learning Unit-3 for II MECH
 
8251 universal synchronous asynchronous receiver transmitter
8251 universal synchronous asynchronous receiver transmitter8251 universal synchronous asynchronous receiver transmitter
8251 universal synchronous asynchronous receiver transmitter
 
Electronically Controlled suspensions system .pdf
Electronically Controlled suspensions system .pdfElectronically Controlled suspensions system .pdf
Electronically Controlled suspensions system .pdf
 
Oxy acetylene welding presentation note.
Oxy acetylene welding presentation note.Oxy acetylene welding presentation note.
Oxy acetylene welding presentation note.
 
complete construction, environmental and economics information of biomass com...
complete construction, environmental and economics information of biomass com...complete construction, environmental and economics information of biomass com...
complete construction, environmental and economics information of biomass com...
 
Exploring_Network_Security_with_JA3_by_Rakesh Seal.pptx
Exploring_Network_Security_with_JA3_by_Rakesh Seal.pptxExploring_Network_Security_with_JA3_by_Rakesh Seal.pptx
Exploring_Network_Security_with_JA3_by_Rakesh Seal.pptx
 

Wind energy

  • 1.
  • 2. WIND ENERGY(C0NTENTS) • INTRODUCTION • ORIGIN OF WINDS • WIND DATA • VARIATION OF WIND SPEED WITH HEIGHT • HORIZONTAL AXIS WIND TURBINE (HAWT) ROTORS PITCH SYSTEM CONTROL NACELLE (IT’S COMPONENTS) YAW SYSTEM CONTROL TOWER (ACCESS LADDER) FOUNDATION (ELECTRIC GRID) • EFFICIENCY OF TURBINE • BETZ’S LAW • TIP SPEED RATIO • VERTICAL AXIS WIND TURBINE (VAWT)
  • 3. INTRODUCTION • Winds are horizontal movement of AIR from an area of HIGH pressure(H) to an area of low pressure(L). • Wind energy is a kinetic energy associated with movement of large masses of air. • It is clean, cheap, and eco-friendly renewable source. • Wind energy is utilized as mechanical energy with the help of a wind turbine. • Moderate to high-speed winds, typically from 5m/s to about 25m/s are considered favorable for most wind turbines. • The electric power generation through wind was first proposed in Denmark in 1890
  • 4. ORIGIN OF WINDS • The origin of winds may be traced basically to uneven heating of the earth’s surface due to sun. • This may lead to circulation of widespread winds on a global basis, producing planetary winds or may have a limited influence in a smaller area to cause local winds.
  • 5. GLOBAL (OR PLANETARY) WINDS • Two major forces determine the speed and direction of wind on a global basis : i. Primary force : Due to differential heating of the earth at equatorial and polar regions. (Heat transfer) ii. Spinning of earth about its axis produces a Coriolis force, which is responsible for deviation of air currents. (deflects the direction of wind)
  • 6. LOCAL WINDS (THAT BLOW OVER SHORT DISTANCES) • Localized uneven heating is responsible for local winds. Local winds are produced due to two mechanisms: i. Due to differential heating of land surface and water bodies due to solar radiation. ii. Due to differential heating of slopes on the hillsides and that of low lands.
  • 7. FACTORS AFFECTING THE DISTRIBUTION OF WIND ENERGY ON THE SURFACE OF THE EARTH • Both global and local factors influence the availability of wind energy at particular site. i. On the planetary level, great mountain masses influence the circulation of air currents. ii. Surface roughness or friction, due to the resistance that different elements of the earth surface like hill’s, tall buildings, trees and similar obstructions impair streamline air flow. Wind velocity in horizontal direction gets markedly reduced. Frictional effect is less on smooth areas such as sea shore or large open areas and more in rough urban areas with tall building and trees. iii. Wind speed also increases while passing through narrow mountain gaps where it gets channeled.
  • 8. • Wind speed is measured by an anemometer and wind direction is measured by a wind vane attached to the direction indicator. • A cup anemometer consists of three or four cups mounted symmetrically about a vertical axis. The speed of rotation indicates wind speed. • Wind speed measurement should be made at an effective height 10m above the ground. (WMO) • Wind rose Graph : An elegant method of describing average wind speed duration and direction on a single graph. Length of the bars represent the percentage of duration.Wind rose graph
  • 9. VARIATION OF WIND SPEED WITH HEIGHT • Wind shear : Rate of change of wind speed with height • At the earth’s surface, wind speed is always zero. It increases with height above the ground. The wind near the earth’s surface is retarded by surface roughness.
  • 10. ADVANTAGES OF WIND ENERGY i. It is a renewable source of energy. ii. Like all forms of solar energy, wind power systems are non- polluting, so it has no adverse influence on the environment. iii. Wind energy systems avoid fuel combustion and transport. iv. Cost free renewable resources.
  • 11. DISADVANTAGES OF WIND ENERGY • Wind energy available is fluctuating in nature and it varies from zero to storm force.(unreliable) • Wind energy systems are noisy in operation; a large unit can be heard many kilometers away. • Birds and bats have been killed by flying into the rotors. • Good wind sites are often located in remote locations, far from cities where the electricity is needed. • Installation & Maintenance cost of wind turbine is high.
  • 12. TYPES OF WIND TURBINES
  • 13. HORIZONTAL AXIS WIND TURBINE (HAWT COMPONENTS) ROTOR  BLADES  HUB (BLADE PITCH CONTROL ) NACELLE  LOW SPEED SHAFT  GEAR BOX  BRAKE  HIGH SPEED SHAFT  GENERATOR  CONTROLLER  ANEMOMETER & WIND VANE YAW SYSTEM (WIND ORIENTATION CONTROL) TOWER (ACCESS LADDER ) FOUNDATION (CONNECTION TO THE ELECTRIC GRID)
  • 14. ROTOR (BLADES & HUB ) BLADE • Turbine blades are made of high- density wood or glass fiber and epoxy composites. • The blades of the wind turbine are designed to be aerodynamic so that they are able to utilize wind energy more easily. • They have an airfoil type of cross section. • The blades are slightly twisted from the outer tip to the root. • The diameter of a typical, MW range, modern rotor may be of the order of 100m.
  • 15. TYPES OF ROTORS • Wind turbines have been built with up to six propellers type blades but two and three- bladed propellers are most common. • A single blade rotor, with a balancing counterweight is economical, has simple controls but it is noisier and produces unbalanced forces. it is used for low power applications.
  • 16. TWO AND THREE- BLADED ROTOR • The two-blade rotor is also simpler to erect, since it can be assembled on the ground and lifted to the shaft without complicated operation during the lift. • Compared to the two-blade design, the three-blade machine has smoother power output and balanced spinning force. • Adding a third blade increases the power output by about 5% only, while the weight and cost of a rotor increases by 50%. • Large HAWTs have been manufactured with two and three
  • 17. SAIL TYPE, DUTCH TYPE, MULTI BLADE ROTOR • Sail wing type : it is of recent origin. The blade surface is made from cloth, nylon, or plastics arranged as mast and pole or sail wings. • Dutch type : it is one of the oldest designs. The blade surface are made from an array of wooden slats (sticks). • Multi blade type : made from sheet metal or aluminum. They have good power coefficient, high starting torque and add advantage of simplicity and low cost. • Both Dutch and Multi blade type are low- speed rotors and most suited for water-lifting applications, which require a high starting torque. They can capture power even very slow winds. SailWingTy pe Dutch type Multi Bladed type
  • 18.
  • 19. HUB • The central solid portion of the rotor wheel is known as hub. All blades are attached to the hub. The mechanism for pitch angle control is also provided inside the hub. • Pitch angle control system is used to maximize the wind turbine efficiency by positioning the blades at the best possible angle. • The pitch motor is often found near the hub of the rotor.
  • 20. NACELLE • The term nacelle is derived from the name for housing (casing) containing the engines of an wind turbine (Aerogenerator). • The rotor is attached to the nacelle, and mounted at top of a tower. It contains rotor brakes, gearbox, generator, low and high speed shafts, electrical switchgear and control.
  • 21. • LOW SPEED SHAFT : The low speed shaft is turned by the motion of a wind turbines blades as they rotate. The low speed shaft transfers kinetic energy to the gearbox. • GEARBOX : The gearbox steps up the shaft rpm to suit the generator. It is a heavy and expensive piece of equipment that connects the low speed shaft to the high speed shaft. • HIGH SPEED SHAFT : The high speed shaft connects the gearbox to the generator and its sole purpose is to drive the generator so that it can produce electricity.
  • 22. BRAKE : • Brakes are used to stop the rotor when power generation is not desired. Turbine do not operate at wind speed above about 25m/s because they might be damaged by high winds. • Generally drum brake or disk brake is used to stop turbine in emergency situation and at maintenance situations.
  • 23. GENERATOR • Wind power generator converts wind energy (Mechanical energy) to electrical energy. • The generator is attached at one end to the wind turbine, which provides the mechanical energy and at other end is connected to the electrical grid. • The generator need to have a cooling system to make sure there is no over heating.
  • 24. YAW-CONTROL MECHANISM • The mechanism to adjust the nacelle around the vertical axis to keep it facing the wind is provided at the base of the nacelle. The yaw-control system continuously orients the rotor in the direction of wind. • The yaw motor will be found inside the tower underneath the nacelle and will turn the nacelle and the rotor to face the current wind direction. (* Yaw means twist about vertical axis )
  • 25. CONTROL SYSTEM (CONTROLLER) • The control system continuously adjusts the pitch to obtain optimal performance. • The controller starts up the machine at wind speed of about 5 m/s and shuts off the machine at about 25 m/s. • The control system is also the mechanism that will calculate the most efficient pitch and yaw for the turbine dependent on wind speed and direction. • Control system gets wind data (speed & direction ) from velocity
  • 26. TOWER • The tower supports the nacelle and rotor. Its height approximately two to three times the blade length. But, practically maximum height is estimated to be roughly 60 m. • It is designed to withstand the wind load during gusts (strong rush of wind). • At the bottom level of the tower there will be step-up transformers for the connection to the Electrical Grid. • Inside of the tower there is a ladder to access to top of the tower for maintenance and setup processes and will also contain high voltage cables for transporting the electricity produced by the generator at the top of the turbine to its base.
  • 27. TYPES OF TOWERS 1. The reinforced concrete tower, 2. The pole tower, 3. The built up shell-tube tower, and 4. The truss tower. Pole tower Truss tower
  • 28. FOUNDATION • Wind turbines, by their nature, are very tall slender structures. • It must be designed mainly to transfer the vertical load (dead weight) & horizontal dynamic load (wind load) to the ground. • The turbines are sufficiently restrained against moment loads to operate efficiently.
  • 29. WIND TURBINE EFFICIENCY • 𝜂 𝑜 = 𝑢𝑠𝑒𝑓𝑢𝑙 𝑜𝑢𝑡𝑝𝑢𝑡 𝑝𝑜𝑤𝑒𝑟 𝑤𝑖𝑛𝑑 𝑝𝑜𝑤𝑒𝑟 𝑖𝑛𝑝𝑢𝑡 𝜂 𝐴 × 𝜂 𝐺 × 𝜂 𝐶 × 𝜂𝐺𝑒𝑛 Where ; 𝜂 𝐴 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑎𝑒𝑟𝑜𝑡𝑢𝑟𝑏𝑖𝑛e 𝜂 𝐺 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑔𝑒𝑎𝑟𝑖𝑛𝑔 𝜂 𝐶 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑚𝑒𝑐ℎ𝑎𝑛𝑖𝑐𝑎𝑙𝑐𝑜𝑢𝑝𝑙𝑖𝑛𝑔 𝜂𝐺𝑒𝑛 = 𝐸𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 𝑜𝑓 𝑔𝑒𝑛𝑒𝑟𝑎𝑡𝑜𝑟
  • 30. BETZ’S LAW • This law states that no wind turbine can capture more than 16 27 or 59.3% of kinetic energy of the wind. • It gives the value of Theoretical maximum efficiency that a wind turbine can achieve.
  • 31. TIP SPEED RATIO (TSR) • TSR is the ratio between the tangential speed of the tips of the turbine blades and the speed of the wind. (Tip Speed Ratio) 𝜆 = 𝑇𝑖𝑝 𝑠𝑝𝑒𝑒𝑑 𝑜𝑓 𝑏𝑙𝑎𝑑𝑒 𝑤𝑖𝑛𝑑 𝑠𝑝𝑒𝑒𝑑 • The tip-speed ratio is related to efficiency, with the optimum varying with blade design. Higher tip speeds result in higher noise levels and require stronger blades due to large centrifugal forces.
  • 32.
  • 33. VERTICAL AXIS WIND TURBINE (VAWT) : The main attractions of a VAWT are : • It can accept wind from any direction, eliminating the need of yaw control, • The gearbox, generator, etc., are located at the ground , thus eliminating the heavy nacelle at the top of the tower, thus simplifying the design and installation of the whole structure, including the tower, • The inspection and maintenance also gets easier, and • It also reduces the overall cost
  • 34. TOWER (OR ROTOR SHAFT) • The tower is a hollow vertical rotor shaft, which rotates freely about the vertical axis between the top and bottom bearings. • It is installed above a super structure. • The upper part of the tower is supported by guy ropes. • The height of the tower of a large turbine is around 100m.
  • 35. BLADES • It has two or three thin, curved blades shaped like an egg beater in a profile, (Troposkien profile) with blades curved in a form that minimizes the bending stress caused by centrifugal forces. • The blades have an airfoil cross section with constant chord length. • The pitch of the blades cannot be changed. • The diameter of the rotor is slightly less than the tower height.
  • 36. SUPPORT STRUCTURE • The support structure is provided at the ground to support the weight of the rotor. • Gearbox, generator, brakes, electrical switchgear and controls are housed within this structure.
  • 37. TYPES OF ROTORS 1. Cup type rotor 2. Savonius or S-rotor 3. Darrieus rotor 4. Musgrove rotor 5. Evans rotor
  • 38. CUP TYPE ROTOR • The simplest being a three-or four-cup structure attached symmetrically to a vertical shaft. • The drag force on the concave surface of the cup facing the wind is more than that on the convex surface. As a result, structure starts rotating. Some lift force also helps rotation. • However, it cannot carry a load and therefore cannot used as power source. • The main characteristic of this rotor is that its rotational frequency is linearly related to wind speed. i.e., it is used for measuring the wind speed and the apparatus is known as CUP ANEMOMETER.
  • 39. SAVONIUS OR S-ROTOR • It consists of two half cylinders attached to a vertical axis and facing in opposite directions to form a two-vane rotor. • It has high starting torque, low speed and low efficiency. • It can extract power even from very slow wind, making it working most of the time. These are used for low-power applications. • A high starting torque particularly makes it suitable for pumping applications.
  • 40. DARRIEUS ROTOR (HIGH SPEED, HIGH EFFICIENCY) • It is used for large-scale power generation. Its power coefficient is considerably better than that of an S- rotor. • Drawback : it is usually not self-starting. Movement may be initiated by using electrical generator as motor (or S-rotor). • As the pitch of the blade cannot change, the rotor frequency and, thus the output power cannot be controlled. Hence, at high wind speed it becomes difficult to control the output. • For better performance and safety of the blades, gearbox and generator, it is desirable to limit the output to a level much below its maximum possible value.
  • 41. MUSGROVE ROTOR • He suggested the use of H-shaped rotor where blades with a fixed pitch are attached vertically to a horizontal cross arm. • Power control is achieved by controlled folding of the blades. • Inclining the blades to the vertical provides an effective means of altering the blade angle of attack and hence controlling the power output.
  • 42. EVANS ROTOR (GYRO MILL) • It is an improvement over H-shaped rotor. • Here, the rotor geometry remains fixed (blades remains straight) , but the blades are hinged on a vertical axis and the blade pitch is varied cyclically (as the blade rotates about the vertical axis) to regulate the power output. • But the need to vary the pitch cyclically through every rotor revolution introduces considerable mechanical complexity.
  • 43. ANIMATIONS OF HAWT (PITCH & YAW MECHANISM)