Environmental Footprint of Wind Energy

Part

Function

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Blades

Airfoil aiming to capture energy from fast and strong wind, being lightweight, durable and corrosion resistant

Rotor

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Uses contact area of wind and is rotating around the generator with the help of the low speed shaft

Gear box

Aims to magnify the energy output of the rotor, located between the generator and the rotor

Generator

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Produces electricity from the rotation of the rotor

Nacelle

Aims the sealing and protection of the generator against other elements and harsh environment

Tower / Foundation

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Carries the nacelle and the rotor, foundation of structure

Figure 1: Schematic of components ()

For the purpose of studying accurately the environmental impact of wind turbines, it is important to identify the material used for the production of each element of wind turbines, the production process, as well as, its respective mass. For the mass calculation of the onshore as well as, for the offshore wind turbine, contribution of material and mass from foundation pile and basement is taken into consideration, as it is one of the most important parameters influencing mass and energy consumed. The following accumulation is only a measure of the wind turbines and not for the structures supporting them on the site. From technical point of view, onshore and offshore turbines, of 2MW and 5 MW respectively, are considered to be manufactured by the same components, with equal materials and processing. Their actual difference lies on the coating and tower structure and foundation which is implying additional mass at the offshore scenario.

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Table 2: Onshore wind turbine materials, processing and mass accumulation ((2)) ((1))

Table 3: Offshore wind turbine materials, processing and mass accumulation ((3))

At the present LCA the system’s boundary conditions assumed are analytically the following: material extraction or production, turbine and components manufacturing, transportation to work site, installation, operation and maintenance during safe life operation, disassembly at the end of life and finally end of life or partial disposal and recycling to the first stages. The analysis is a commutative work, intending to identify the final sum of energy and material requirements, as well as CO₂ emissions, during the life span of 25 years.

Figure 2: System Boundaries Diagram

Figure 3: System’s input and outputs ()

The first stage of the production is initiating from raw materials extraction and production, including mining and processing. Materials used mainly are steel, cast iron, copper, aluminum, glass fiber, reinforced plastic (prepreg) and auxiliary material. ((1)) Onshore and offshore blades differentiate significantly in material at their foundation, where onshore wind turbines consist of concrete based foundation, with small percentage of reinforced steel, in contrast with offshore wind turbines, where the foundation consists mainly of steel structures, specially design to allow wear and corrosion resistance. Blades differ in the type of coating.

The next stage of the production is the actual turbine manufacturing, which is a result of a gate – to – gate analysis, since material produced or extracted is entering the manufacturing process, to give shape to the final parts of the system (tower, rotor, blade). At the end of this stage the parts are ready to be transported to the work site. The main environmental burden of this stage is the energy consumed during production, to reach the final parts.

Transportation is also a process causing high environmental footprint. The main transportational burden happens after final part production at the factory, aiming to transport them to the final work site. The burden is associated with the energy required to cover the distance and is calculated as the product of the distance in km, by the weight in kg. However, in calculations is also accounted the energy needed to transfer the material to the production site, before the final part reaches the wind farm. Onshore turbine blades and foundations are mainly transported with trucks to the farm. The average distance travelled for the nacelle, the hub and the blades is about 10,000 km. Offshore turbines are manufactured in locations with good proximity to ports, in order to avoid any complications, and finally they are shipped to the offshore farm, using two self – propelled jack – ups, operating as barge, equipped with cranes to allow the installation of preassembled parts. The average distance from shore in the case of locating offshore turbines assuming deep water installation is 70 km from shore. In Table 4, data concerning distance travelled in km and vehicle used are provided.

Table 4: Distance travelled in km and used vehicle- onshore, offshore ((1))

The next step is the installation of the wind turbine. Onshore wind turbines require conventional construction equipment for setup. Offshore wind turbines require further equipment. The reverse but identical procedure is required while dismantling the units before disposal. Τable 5 and Table 6 provide data about the entire fuel consumption considering both transportation and setup needs.

Table 5: Fuel requirements for transportation and setup on site for onshore wind turbines ((1))

Table 6: Fuel requirements for transportation and setup on site for offshore wind turbines ((1))

During operation and maintenance technical studies prove that the energy requirements, thus the environmental footprint, are very low. Regular inspection and maintenance procedures account only as 2% of the overall energy requirements, including activities, such as oil change, lubrication, etc. The current study is assuming no serious parts replacement due to unexpected, early failure, except of the gearbox being replaced after 10 years of usual lifetime. Routine inspection is assumed to be carried out every year and oil change every three years.

The last stage of the analysis is concerned about the end of the life of the turbine. Wind turbines are consisted of steel at about 70% of their total mass, and typically are installed using tubular steel structures that may be recycled several times. Table 7 presents the disposal methods for all materials used in wind turbine production. Disposal methods for the given material is assumed to be common for onshore and onshore wind turbines

Table 7: Disposal and recycling strategy per material

Table 8 provides a summary of the accounted energy requirements as a function of material, production method and stage of life. For the end of life of onshore turbines two scenarios have been considered, recycling and landfill. The most energy consuming and CO₂ emitting stage is clearly the material extraction phase, followed in case of recycling by the end of life procedure.

Table 8: Energy requirements and CO₂ emissions – landfill, onshore wind turbines ((2))