Contenido

Son aquellos en los que el eje de rotación del equipo se encuentra paralelo al suelo. Esta es la tecnología que se ha impuesto, por su eficiencia y confiabilidad y la capacidad de adaptarse a diferentes potencias.

Las partes principales de un aerogenerador de eje horizontal son:.

Todos los aerogeneradores de eje horizontal tienen su eje de rotación principal en la parte superior de la torre, que tiene que orientarse hacia el viento de alguna manera. Los aerogeneradores pequeños se orientan mediante una veleta, mientras que los más grandes utilizan un sensor de dirección y se orientan por servomotores o motorreductores.

Existen dos tipologías principales de generadores eléctricos: con y sin caja multiplicadora. Los primeros funcionan a velocidades del orden de 1000-2000 rpm. Dado que la velocidad de rotación de las aspas es baja (entre 8 y 30 rpm), requieren el uso de una caja multiplicadora para conseguir una velocidad de rotación adecuada. Los aerogeneradores que no precisan multiplicadora se conocen como direct-drive y sus generadores se llaman habitualmente multipolo, ya que para conseguir una frecuencia elevada con una baja velocidad de giro tienen más de una decena de polos.

En la mayoría de los casos la velocidad de giro del generador está relacionada con la frecuencia de la red eléctrica a la que se vierte la energía generada (50 o 60 Hz).

En general, las palas están emplazadas de tal manera que el viento, en su dirección de flujo, las encuentre antes que a la torre (rotor a barlovento). Esto disminuye las cargas adicionales que genera la turbulencia de la torre en el caso en que el rotor se ubique detrás de la misma (rotor a sotavento). Las palas se montan a una distancia razonable de la torre y tienen alta rigidez, de tal manera que al rotar y vibrar naturalmente no choquen con la torre en caso de vientos fuertes. El rotor suele estar inclinado entre 4 y 6 grados para evitar el impacto de las palas con la torre.

A pesar de la desventaja en el incremento de la turbulencia, se han construido aerogeneradores con el rotor localizado en la parte posterior de la torre, debido a que se orientan en contra del viento de manera natural, sin necesidad de usar un mecanismo de control. Sin embargo, la experiencia ha demostrado la necesidad de un sistema de orientación para orientar la máquina hacia el viento. Este tipo de montaje se justifica debido a la gran influencia que tiene la turbulencia en el desgaste de las aspas por fatiga. La mayoría de los aerogeneradores actuales son de este último modelo.

Wind power

The kinetic energy of air () depends on the square of the speed of air () and its density ():.

The power (), in watts per unit area, can be expressed as:.

Therefore, the wind power to which a turbine will be exposed is determined by multiplying the previous expression by the swept area of ​​the turbine, which is the circle covered by the blades.[5]​ For example, the swept area of ​​a wind turbine with a rotor of 82 meters in diameter will be 5,281 m².

However, not all the power of the air can be used by the wind turbine. The limit of power that can be extracted is given by the limit established by the physicist Albert Betz. This limit, which bears his name, is derived from the conservation of the mass and moment of inertia of the air flow. The Betz limit indicates that a wind turbine cannot harness more than 59.3% of the kinetic energy of the wind. The number (0.593) is known as the Betz coefficient. For example, if a wind turbine 82 meters in diameter were exposed to a wind of 15 m/s with an air density of 1.28 kg/m³, it could extract, assuming a perfect wind (without turbulence) and perfect performance, up to 6.76 MW of electrical energy.

Modern wind turbines obtain between 75 and 80% of the Betz limit.[6]​ One of the factors that most influences not reaching 100% of the Betz limit is the roughness of the ground. This roughness is influenced by the presence of vegetation or buildings on the ground, which reduce wind speed and increase air turbulence. Therefore, a greater height of the rotor and the installation in the sea ("offshore wind")) contribute to better use of the energy in the air.

Power control

In general, modern horizontal axis wind turbines are designed to work with wind speeds that vary between 3 and 25 m/s on average. The first is the so-called connection speed and the second is the cutting speed. Basically, the wind turbine begins producing electrical energy when the wind speed exceeds the connection speed and, as the wind speed increases, the power generated is greater, following the so-called power curve.

The blades have a control system so that their angle of attack varies depending on the wind speed. This allows the rotation speed to be controlled to achieve a fixed rotation speed under different wind conditions.

Likewise, a rotation speed control system is necessary so that, in the event of excessively strong winds, which could endanger the installation, it rotates the rotor in such a way that the blades present the minimum opposition to the wind, which would cause the machine to stop.

For high-power wind turbines, some types of passive systems use aerodynamic characteristics of the blades that cause the rotor to stop even in very strong wind conditions. This is because it itself enters a regime called "aerodynamic stall".

Impact on the environment

This type of generators have quickly become popular as they are considered a clean source of energy, since they do not require, for energy production, combustion that produces polluting waste or gases involved in the greenhouse effect. However, its use is not free of environmental impact. Their location—frequently in remote places of high ecological value, such as mountain peaks, which because they are not inhabited, preserve their landscape and fauna richness—can cause harmful effects, such as the visual impact on the horizon line, the large surface area they occupy due to the necessary separation between them—between three[7]​ and ten[8]​ rotor diameters—or the intense noise generated by the blades, in addition to the effects caused by the infrastructure that must be built for transportation. of electrical energy to the points of consumption. Despite research to minimize them, bird deaths continue to occur due to them,[9]​ in addition to bat populations being affected.[10]​ In some wind power plants, about 14 birds and 40 bats die each year for every MW installed.[11]​ More recently, the possibility has been proposed that their widespread use could even contribute to global warming by blocking air currents.[12]​.

On the other hand, taking into account the greenhouse gases that are produced by the tasks derived from the construction, transportation and maintenance of the wind turbine, terrestrial wind energy, with 12 g of CO per kWh, is the second least polluting energy,[13]​ after hydroelectric energy (with 4 g of CO per kWh); This is followed by nuclear energy (with 16 g of CO per kWh), and solar thermal energy (with 22 g of CO per kWh). To this we must add the problem of shovels, which cease to be useful after about 20 years of use, and which usually end up in landfills (called "shovel cemeteries") due to the complexity of their recycling.[14]​.

They are those in which the axis of rotation is perpendicular to the ground. They are also called VAWT (Vertical Axis Wind Turbine*), as opposed to horizontal axis wind turbines or HAWT.[15] An example is the Savonius rotor.

In general, the advantages of VAWT are:[16]​.

Its disadvantages are:

There are different types of wind generators. The electrical part can be designed with both synchronous and asynchronous generators, and with various forms of connection of the generator, direct or indirect, to the grid. Direct grid connection means that the generator is connected directly to the alternating current grid (usually three-phase). Indirect connection to the grid means that the current coming from the alternator passes through a series of devices that adjust the current to match that of the grid (in asynchronous generators this happens automatically).

The doubly fed machine (DFIM), also known as the doubly fed generator (DFIG), is a type of electrical generator in which the terminals of the rotor windings are accessible. It is also characterized because the rotation speed of the rotor is slightly different from the synchronism speed. It is important to highlight the great usefulness of doubly fed asynchronous generators in wind generation configurations.

Its main feature is the incorporation of a frequency converter connected to the rotor that allows control of its voltages and intensities. Thanks to the control over these parameters, we ensure that the machine remains constantly synchronized with the network even if the revolution speeds vary.

This feature is extremely useful in variable speed configurations such as wind generation. The control that the frequency converter gives us allows the machine greater stability, as well as the ability to react to possible faults. On the other hand, compared to other configurations, doubly fed machines are not extremely expensive, since their most expensive component, the electronics, that is, the frequency converter, will not work at a high power (approximately 20% of the nominal of the generator).

The basic operating principle can be defined as the conversion of the power captured by the wind turbine into electrical power, thanks to the induction generator and its subsequent transmission to the grid through the stator and rotor windings.

The conversion system is made up of two three-phase converters. The first, called the machine side converter, will be the one connected to the rotor, while the grid side converter will be the one connected to the grid. Thus, this system interconnects the rotor and the network, allowing the flow of power between both.

A doubly fed asynchronous generator unifies the advantages of asynchronous generators and synchronous generators.

Microwind

They are wind turbines that are used for personal use. There are those that produce from 50 W to a few kilowatts. They are usually made by the owner.

The ideal configuration of a wind turbine is on a mast without the need for anchor cables and in a location exposed to the wind. Many conventional wind turbine designs are not recommended for mounting in buildings. However, if the only site available is the roof of a building, installing a small wind system may be feasible if it is high enough to minimize turbulence, or if the wind regime at that particular site is favorable.[17]​.

Most wind energy systems[18]​ available require owner intervention during operation. Many manufacturers offer maintenance services for the wind turbines they install. The manufacturer must, in any case, provide detailed information about maintenance procedures.

Along with the investment costs, an economic evaluation must be carried out that includes the following aspects:.

In addition to the advantages of wind energy, microwind energy is more efficient if electricity is generated close to the place where it is consumed, since transportation losses are minimized. It is also possible, in these cases, to store the energy in batteries for use in the absence of wind.

In Spain, there are microwind manufacturers, such as Bornay Aerogeneradores.[19]​.

Mini wind power

There is no defined border between micro wind and mini wind. Generally, microwind can be considered to comprise a single wind turbine, while the upper limit of miniwind is defined by power, and should not exceed 100 kW.[20]​ They are also called domestic or small-power wind turbines.[21]​[22]​.

Applications:[23]​.

Where to place a small power wind turbine:[24]​ you must know the dominant winds that exist in the area and the way in which they can vary throughout the year. Generally, the highest point of the terrain is the one that receives the most wind, although this rule can be altered by the presence of rivers, valleys or forested areas, as well as obstacles that exist around it such as buildings or trees. These can vary both the speed and direction of the wind.

It is recommended to install the small power wind turbine at least 10 meters above any obstacle and at twice its height.

Rise of micro and mini wind

The World Wind Energy Association,[25][26]​ in the World Report on Small Wind Power,[27]​ has published that at the end of 2011 small wind power reached 576 MW, which represents 27% more installed power than the previous year. More than 330 manufacturers of small wind turbines operate in 40 countries around the world.[28]​.

Wind energy is energy that is generated thanks to the kinetic energy produced by moving air masses. This energy, which is still in the process of development, was born in response to a greater demand for energy consumption, the need to guarantee the continuity of supply in areas that are net importers of energy resources and the search for sustainability in the use of resources.

In general, the best wind areas are found on the coast due to thermal currents between sea and land, large continental plains, for similar reasons, and mountainous areas, where local acceleration effects occur.

Contenido

Son aquellos en los que el eje de rotación del equipo se encuentra paralelo al suelo. Esta es la tecnología que se ha impuesto, por su eficiencia y confiabilidad y la capacidad de adaptarse a diferentes potencias.

Las partes principales de un aerogenerador de eje horizontal son:.

Todos los aerogeneradores de eje horizontal tienen su eje de rotación principal en la parte superior de la torre, que tiene que orientarse hacia el viento de alguna manera. Los aerogeneradores pequeños se orientan mediante una veleta, mientras que los más grandes utilizan un sensor de dirección y se orientan por servomotores o motorreductores.

Existen dos tipologías principales de generadores eléctricos: con y sin caja multiplicadora. Los primeros funcionan a velocidades del orden de 1000-2000 rpm. Dado que la velocidad de rotación de las aspas es baja (entre 8 y 30 rpm), requieren el uso de una caja multiplicadora para conseguir una velocidad de rotación adecuada. Los aerogeneradores que no precisan multiplicadora se conocen como direct-drive y sus generadores se llaman habitualmente multipolo, ya que para conseguir una frecuencia elevada con una baja velocidad de giro tienen más de una decena de polos.

En la mayoría de los casos la velocidad de giro del generador está relacionada con la frecuencia de la red eléctrica a la que se vierte la energía generada (50 o 60 Hz).

En general, las palas están emplazadas de tal manera que el viento, en su dirección de flujo, las encuentre antes que a la torre (rotor a barlovento). Esto disminuye las cargas adicionales que genera la turbulencia de la torre en el caso en que el rotor se ubique detrás de la misma (rotor a sotavento). Las palas se montan a una distancia razonable de la torre y tienen alta rigidez, de tal manera que al rotar y vibrar naturalmente no choquen con la torre en caso de vientos fuertes. El rotor suele estar inclinado entre 4 y 6 grados para evitar el impacto de las palas con la torre.

A pesar de la desventaja en el incremento de la turbulencia, se han construido aerogeneradores con el rotor localizado en la parte posterior de la torre, debido a que se orientan en contra del viento de manera natural, sin necesidad de usar un mecanismo de control. Sin embargo, la experiencia ha demostrado la necesidad de un sistema de orientación para orientar la máquina hacia el viento. Este tipo de montaje se justifica debido a la gran influencia que tiene la turbulencia en el desgaste de las aspas por fatiga. La mayoría de los aerogeneradores actuales son de este último modelo.

Wind power

The kinetic energy of air () depends on the square of the speed of air () and its density ():.

The power (), in watts per unit area, can be expressed as:.

Therefore, the wind power to which a turbine will be exposed is determined by multiplying the previous expression by the swept area of ​​the turbine, which is the circle covered by the blades.[5]​ For example, the swept area of ​​a wind turbine with a rotor of 82 meters in diameter will be 5,281 m².

However, not all the power of the air can be used by the wind turbine. The limit of power that can be extracted is given by the limit established by the physicist Albert Betz. This limit, which bears his name, is derived from the conservation of the mass and moment of inertia of the air flow. The Betz limit indicates that a wind turbine cannot harness more than 59.3% of the kinetic energy of the wind. The number (0.593) is known as the Betz coefficient. For example, if a wind turbine 82 meters in diameter were exposed to a wind of 15 m/s with an air density of 1.28 kg/m³, it could extract, assuming a perfect wind (without turbulence) and perfect performance, up to 6.76 MW of electrical energy.

Modern wind turbines obtain between 75 and 80% of the Betz limit.[6]​ One of the factors that most influences not reaching 100% of the Betz limit is the roughness of the ground. This roughness is influenced by the presence of vegetation or buildings on the ground, which reduce wind speed and increase air turbulence. Therefore, a greater height of the rotor and the installation in the sea ("offshore wind")) contribute to better use of the energy in the air.

Power control

In general, modern horizontal axis wind turbines are designed to work with wind speeds that vary between 3 and 25 m/s on average. The first is the so-called connection speed and the second is the cutting speed. Basically, the wind turbine begins producing electrical energy when the wind speed exceeds the connection speed and, as the wind speed increases, the power generated is greater, following the so-called power curve.

The blades have a control system so that their angle of attack varies depending on the wind speed. This allows the rotation speed to be controlled to achieve a fixed rotation speed under different wind conditions.

Likewise, a rotation speed control system is necessary so that, in the event of excessively strong winds, which could endanger the installation, it rotates the rotor in such a way that the blades present the minimum opposition to the wind, which would cause the machine to stop.

For high-power wind turbines, some types of passive systems use aerodynamic characteristics of the blades that cause the rotor to stop even in very strong wind conditions. This is because it itself enters a regime called "aerodynamic stall".

Impact on the environment

This type of generators have quickly become popular as they are considered a clean source of energy, since they do not require, for energy production, combustion that produces polluting waste or gases involved in the greenhouse effect. However, its use is not free of environmental impact. Their location—frequently in remote places of high ecological value, such as mountain peaks, which because they are not inhabited, preserve their landscape and fauna richness—can cause harmful effects, such as the visual impact on the horizon line, the large surface area they occupy due to the necessary separation between them—between three[7]​ and ten[8]​ rotor diameters—or the intense noise generated by the blades, in addition to the effects caused by the infrastructure that must be built for transportation. of electrical energy to the points of consumption. Despite research to minimize them, bird deaths continue to occur due to them,[9]​ in addition to bat populations being affected.[10]​ In some wind power plants, about 14 birds and 40 bats die each year for every MW installed.[11]​ More recently, the possibility has been proposed that their widespread use could even contribute to global warming by blocking air currents.[12]​.

On the other hand, taking into account the greenhouse gases that are produced by the tasks derived from the construction, transportation and maintenance of the wind turbine, terrestrial wind energy, with 12 g of CO per kWh, is the second least polluting energy,[13]​ after hydroelectric energy (with 4 g of CO per kWh); This is followed by nuclear energy (with 16 g of CO per kWh), and solar thermal energy (with 22 g of CO per kWh). To this we must add the problem of shovels, which cease to be useful after about 20 years of use, and which usually end up in landfills (called "shovel cemeteries") due to the complexity of their recycling.[14]​.

They are those in which the axis of rotation is perpendicular to the ground. They are also called VAWT (Vertical Axis Wind Turbine*), as opposed to horizontal axis wind turbines or HAWT.[15] An example is the Savonius rotor.

In general, the advantages of VAWT are:[16]​.

Its disadvantages are:

There are different types of wind generators. The electrical part can be designed with both synchronous and asynchronous generators, and with various forms of connection of the generator, direct or indirect, to the grid. Direct grid connection means that the generator is connected directly to the alternating current grid (usually three-phase). Indirect connection to the grid means that the current coming from the alternator passes through a series of devices that adjust the current to match that of the grid (in asynchronous generators this happens automatically).

The doubly fed machine (DFIM), also known as the doubly fed generator (DFIG), is a type of electrical generator in which the terminals of the rotor windings are accessible. It is also characterized because the rotation speed of the rotor is slightly different from the synchronism speed. It is important to highlight the great usefulness of doubly fed asynchronous generators in wind generation configurations.

Its main feature is the incorporation of a frequency converter connected to the rotor that allows control of its voltages and intensities. Thanks to the control over these parameters, we ensure that the machine remains constantly synchronized with the network even if the revolution speeds vary.

This feature is extremely useful in variable speed configurations such as wind generation. The control that the frequency converter gives us allows the machine greater stability, as well as the ability to react to possible faults. On the other hand, compared to other configurations, doubly fed machines are not extremely expensive, since their most expensive component, the electronics, that is, the frequency converter, will not work at a high power (approximately 20% of the nominal of the generator).

The basic operating principle can be defined as the conversion of the power captured by the wind turbine into electrical power, thanks to the induction generator and its subsequent transmission to the grid through the stator and rotor windings.

The conversion system is made up of two three-phase converters. The first, called the machine side converter, will be the one connected to the rotor, while the grid side converter will be the one connected to the grid. Thus, this system interconnects the rotor and the network, allowing the flow of power between both.

A doubly fed asynchronous generator unifies the advantages of asynchronous generators and synchronous generators.

Microwind

They are wind turbines that are used for personal use. There are those that produce from 50 W to a few kilowatts. They are usually made by the owner.

The ideal configuration of a wind turbine is on a mast without the need for anchor cables and in a location exposed to the wind. Many conventional wind turbine designs are not recommended for mounting in buildings. However, if the only site available is the roof of a building, installing a small wind system may be feasible if it is high enough to minimize turbulence, or if the wind regime at that particular site is favorable.[17]​.

Most wind energy systems[18]​ available require owner intervention during operation. Many manufacturers offer maintenance services for the wind turbines they install. The manufacturer must, in any case, provide detailed information about maintenance procedures.

Along with the investment costs, an economic evaluation must be carried out that includes the following aspects:.

In addition to the advantages of wind energy, microwind energy is more efficient if electricity is generated close to the place where it is consumed, since transportation losses are minimized. It is also possible, in these cases, to store the energy in batteries for use in the absence of wind.

In Spain, there are microwind manufacturers, such as Bornay Aerogeneradores.[19]​.

Mini wind power

There is no defined border between micro wind and mini wind. Generally, microwind can be considered to comprise a single wind turbine, while the upper limit of miniwind is defined by power, and should not exceed 100 kW.[20]​ They are also called domestic or small-power wind turbines.[21]​[22]​.

Applications:[23]​.

Where to place a small power wind turbine:[24]​ you must know the dominant winds that exist in the area and the way in which they can vary throughout the year. Generally, the highest point of the terrain is the one that receives the most wind, although this rule can be altered by the presence of rivers, valleys or forested areas, as well as obstacles that exist around it such as buildings or trees. These can vary both the speed and direction of the wind.

It is recommended to install the small power wind turbine at least 10 meters above any obstacle and at twice its height.

Rise of micro and mini wind

The World Wind Energy Association,[25][26]​ in the World Report on Small Wind Power,[27]​ has published that at the end of 2011 small wind power reached 576 MW, which represents 27% more installed power than the previous year. More than 330 manufacturers of small wind turbines operate in 40 countries around the world.[28]​.