Copper in renewable energy
Renewable energy sources such as solar, wind, tidal, hydro, biomass, and geothermal have become significant sectors of the energy market. The rapid growth of these sources in the 21st Century has been prompted by increasing costs of fossil fuels as well as their negative environmental impacts. While the average capacity of renewable energy sources was only 7% globally in 2010, most installation of new capacity has been with renewables. Few new installations were from fossil fuel‐based power plants. The trend towards new power capacity by renewables is expected to continue through 2020. Since renewable energy supplies offset the amount of fossil fuels that need to be combusted in power plants, the use of renewables indirectly helps to reduce CO2 emissions. Hence, renewable energy supplies enable societies to progress towards lower-carbon-based economies.
Copper plays an important role in renewable energy systems. Since copper is the highest rated thermal and electrical conductor among the engineering metals, power systems that utilize copper generate and transmit energy with maximum efficiency and with minimum environmental impacts. By using copper instead of other lower electrical energy-efficient metal conductors, less electricity needs to be generated to satisfy a given power demand.
This article discusses the role of copper in various renewable energy generation systems.
Overview of copper usage in renewable energy generation
Copper plays a larger role in renewable energy generation than in conventional thermal power plants, in terms of tonnage of copper per unit of installed power. While conventional power requires approximately 1 tonne of copper per installed megawatt (MW), renewable technologies such as wind and solar require four times more copper per installed MW.
Wind and solar photovoltaic energy systems have the highest copper content of all renewable energy technologies. Wind power and photovoltaic power are the fastest growing renewable-based markets. Significant growth is also expected in thermal concentrating solar power.
The total amount of copper used in renewable‐based and distributed electricity generation in 2011 was estimated to be 272 kilotonnes (kt). Cumulative copper use through 2011 was estimated to be 1,071 kt.
|Installed power in 2011||Cumulative installed power to 2011||Copper use in 2011||Cumulative copper use to 2011|
|Gigawatts (GW)||Gigawatts (GW)||Kilotons (kt)||Kilotons (kt)|
|Solar thermal electricity||0.46||1.76||2||7|
|Total for all three technologies||272||1071|
Copper conductors are used in major electrical renewable energy components, such as turbines, generators, transformers, inverters, cables, power electronics, and information cable. Copper usage is approximately the same in turbines/generators, transformers/inverters, and cables. Much less copper is used in power electronics.
Solar thermal heating and cooling energy systems rely on copper for their thermal energy efficiency benefits. Copper is also used as a special corrosion-resistant material in renewable energy systems in wet, humid, and saline corrosive environments.
Solar photovoltaic power generation
Solar photovoltaics (PV) is an important but still evolving technology that harnesses the Sun’s power to generate electricity. As sunlight hits a photovoltaic cell, it frees and stirs up electrons, which then collect on conductive plates to create electricity.
Of the 20,000 TWh of power consumed globally in a single year, approximately 90 TWh are generated from solar PV systems. While this is only a very small percentage of global energy consumption (0.6% of total installed electricity generating capacity worldwide), it is nevertheless sufficient to power the needs of more than 10 million people living at the standard of living in a developed country.
Various overlapping statistics regarding the growth of solar PVs have been cited. Solar PVs have been cited to have a 40% annual growth rate, which may grow even faster as the cost of the technology continues to decline. Another source cites operating capacity to have increased by an average of 58% annually from year end-2006 through 2011. Installed capacity estimates to 2020 suggest a rapid rise in solar PV generation, growing by a factor of five between 2010 and 2020.
Household PV systems are smaller and losses in transmission and distribution are lower than in large-scaled PV power stations. Households are able to generate their own electricity and use the electrical grid for support and reliability.
For these reasons, policy initiatives are taking place to enhance the deployment of solar photovoltaic energy installations. This would boost the steady expansion of PV markets by reducing the competitiveness gap of PVs compared to fossil fuel technologies. The goal at this point is to reach grid parity, where the cost of producing energy from rooftop panels over the course of their 25 year lifetime equates to the cost of retail electricity generated by conventional sources. This achievement has already been accomplished in some regions.
Copper in photovoltaic power systems
The usage of copper in photovoltaic systems is substantial, averaging around 4-5 tonnes per MW or higher if ribbons (conductive strips to connect individual PV cells) are considered. Copper is used in: 1) small wires that interconnect photovoltaic modules; 2) earthing grids in electrode earth pegs, horizontal plates, naked cables, and wires; 3) DC cables that connect photovoltaic modules to inverters; 4) low-voltage AC cables that connect inverters to metering systems and protection cabinets; 5) high-voltage AC cables; 6) communication cables; 7) inverters/power electronics; 8) ribbons; and 9) transformer windings.
Copper used in photovoltaic systems in 2011 was estimated to be 150 kt. Cumulative copper usage in photovoltaic systems through 2011 was estimated to be 350 kt.
Photovoltaic system configurations
Solar photovoltaic (PV) systems are highly scalable, ranging from the small rooftop residential system to large solar PV parks with 50 MW or more capacity. Residential and community‐based systems generally range in capacity from 10 kW to 1 MW.
PV cells are grouped together in modules. These modules are connected into photovoltaic arrays. In systems connected to the grid, arrays can form sub‐fields from which electricity is collected and transported towards the grid connection.
Copper solar cables connect modules (module cable), arrays (array cable), and sub-fields (field cable). Whether a system is connected to the grid or not, electricity collected from the PV cells needs to be converted from DC to AC and stepped up in voltage. This is done by inverters which contain copper windings, as well as with copper-containing power electronics.
Materials used for photovoltaic solar cells include mono-crystalline silicon, polycrystalline silicon, microcrystalline silicon, cadmium telluride, and copper indium selenide/sulfide. They typically convert 15% of incident sunlight into electricity, allowing the generation of 100 - 150 kWh per square meter of panel per year.
First‐generation multicrystalline silicon PV technology has a practical efficiency conversion rate limit of around 20%. To reduce costs of first generation silicon PV technology, copper-contacted silicon solar cells are emerging as an important alternative to silver as the preferred conductor material. Challenges with solar cell metallization lie in the creation of a homogenous and qualitatively high-value layer between silicon and copper to serves as a barrier against copper diffusion into the semiconductor. Copper-based front-side metallization in silicon solar cells is a significant step towards lower cost.
The second‐generation PV technology is thin‐film cells. These were lower cost but also lower in efficiency (6%‐10%) than first generation silicon PV technology. Costs per watt were also much lower. Thin film cell options currently under development include copper indium gallium selenide (CIGS), cadmium telluride (CdTe), amorphous silicon (aSi) and micromorphous silicon (mSi).
CIGS, which is actually copper (indium-gallium) diselenide, or Cu(InGa)Se2, differs from silicon in that it is a heterojunction semiconductor. It has the highest solar energy conversion efficiency (~20%) among thin film materials. Because CIGS strongly absorbs sunlight, a much thinner film is required than with other semiconductor materials.
A photovoltaic cell manufacturing process has been developed that makes it possible to print CIGS semi-conductors. This technology has the potential to reduce the price per solar watt delivered.
While copper is one of the components in CIGS solar cells, the copper content of the cell is actually small: about 50 kg of copper per MW of capacity.
Mono-dispersed copper sulfide nanocrystals are being researched as alternatives to conventional single crystals and thin films for photovoltaic devices. This technology, which is still in its infancy, has potential for dye-sensitized solar cells, all-inorganic solar cells, and hybrid nano-crystal-polymer composite solar cells.
Solar generation systems cover large areas. There are many connections among modules and arrays, and connections among arrays in sub‐fields and linkages to the network. Solar cables are used for wiring solar power plants. The importance of these cables should not be underestimated. The amount of cabling involved can be substantial. Typical diameters of copper cables used are 4‐6 mm2 for module cable, 6‐10 mm2 for array cable, and 30‐50 mm2 for field cable.
Energy efficiency and system design considerations
Energy efficiency and renewable energy are twin pillars of a sustainable energy future. However, there is little linking of these pillars despite their potential synergies. The more efficiently energy services are delivered, the faster renewable energy can become an effective and significant contributor of primary energy. The more energy is obtained from renewable sources, the less fossil fuel energy is required to provide that same energy demand. This linkage of renewable energy with energy efficiency relies in part on the electrical energy efficiency benefits of copper.
Increasing the diameter of a copper cable increases its electrical energy efficiency (see: Copper wire and cable). Thicker cables reduce IR2 energy losses due to lower cable warming. Thicker cables also enable the generation of more kWs and improve the lifetime profitability of PV system investments. Complex cost evaluations, factoring extra costs for materials, the amount of solar radiation directed towards solar modules per year (accounting for diurnal and seasonal variations, subsidies, tariffs, payback periods, etc.) are necessary to determine whether higher initial investments for thicker cables are justified.
Depending upon circumstances, some conductors in PV systems can be specified with either copper or aluminum. As with other electrical conducting systems, there are advantages to each (see: Copper wire and cable). Copper is the preferred material when high electrical conductivity characteristics and flexibility of the cable are of paramount importance. Also, copper is more suitable for small roof facilities, in smaller cable trays, and when ducting in steel or plastic pipes.
Cable ducting is not needed in smaller power facilities where copper cables are less than 25mm2. Without duct work, installation costs are lower with copper than with aluminum.
Data communications networks rely on copper, optical fiber, and/or radio links. Each material has its advantages and disadvantages. Copper is more reliable than radio links. Signal attenuation with copper wires and cables can be resolved with signal amplifiers.
Concentrating solar thermal power
The Sun’s solar energy can also be harnessed for its heat. When the Sun’s energy heats a fluid in a closed system, its pressure and temperature rise. When introduced to a turbine, the fluid expands, turning the turbine and producing electrical power.
Concentrating solar power (CSP), also known as solar thermal electricity (STE), uses arrays of mirrors that concentrate the sun’s rays to temperatures between 4000C -10000C. Electrical power is produced when the concentrated light is converted to heat, which drives a heat engine (usually a steam turbine) connected to an electrical power generator.
CSP facilities can produce large-scale power and hold much promise in areas with plenty of sunshine and clear skies. Poised to make Sun-powered grids a reality, CSP is currently capable of providing power and dispatchability on a scale similar to that of fossil fuel or nuclear electrical power plants.
The electrical output of CSP facilities match shifting daily demand for electricity in places where air conditioning systems are spreading. When backed by thermal storage facilities and combustible fuel, CSP offers utilities electricity that can be dispatched when required, enabling it to be used for base, shoulder and peak loads.
Industry groups have estimated that the technology could generate a quarter of the world’s electricity needs by 2050. For this reason, plans for future CSP facilities are ambitious. A timeline of CSP deployment around the world is available. Total installed power is forecasted to increase exponentially through 2025, creating as much as 130,000 jobs.
In 2010, Spain, the world leader of CSP technology, was constructing or planning to build some 50 large CSP plants. That nation has a total installed base of 1581 MW of power plus an additional 774 MW nearing completion for installation. Other countries in southern Europe also have CSP facilities, as do countries in emerging markets, such as Chile, India, Morocco, Saudi Arabia, South Africa, and the United Arab Emirates.
Unlike wind energy, photovoltaics, and most distributed power, the main advantage of CSP is its thermal storage capability and hybridization possibilities. Storage systems range from 4 hours in the most typical plants to more than 20 hours when base load is required. This can complement variable generation of other renewable power sources.
CSP systems are sometimes combined with fossil fueled steam turbine generation, but interest is growing in pure CSP technology. Further information on concentrating solar power is available from the Global Solar Thermal Energy Council.
Copper in concentrating solar thermal power facilities
A CSP system consists of: 1) a concentrator or collector containing mirrors that reflect solar radiation and deliver it to the receiver; 2) a receiver that absorbs concentrated sunlight and transfers heat energy to a working fluid (usually a mineral oil, or more rarely, molten salts, metals, steam or air); 3) a transport and storage system that passes the fluid from the receiver to the power conversion system; and 4) a steam turbine that converts thermal power to electricity on demand.
Copper is used in field power cables, grounding networks, and motors for tracking and pumping fluids, as well as in the main generator and high voltage transformers. Typically, there is about 200 tonnes copper for a 50 MW power plant.
It has been estimated that copper usage in concentrated solar thermal power plants was 2 kt in 2011. Cumulative copper usage in these plants through 2011 was estimated to be 7 kt.
There are four main types of CSP technologies, each containing a different amount of copper: parabolic trough plants, tower plants, distributed linear absorber systems including linear Fresnel plants, and dish Stirling plants. The use of copper in these plants is described here.
Parabolic trough plants
Parabolic trough plants are the most common CSP technology, representing about 94% of power installed in Spain. These plants collect solar energy in parabolic trough concentrators with linear collector tubes. The heat transfer fluids are typically synthetic oil that circulates through tubes at inlet outlet/temperatures of 3000C to 4000C. The typical storage capacity of a 50 MW facility is 7 hours at nominal power. A plant of this size and storage capacity can generate 160 GWh/year in a region like Spain.
In parabolic trough plants, copper is specified in the solar collector field (power cables, signals, earthing, electrical motors); steam cycle (water pumps, condenser fans, cabling to consumption points, control signal and sensors, motors), electricity generators (alternator, transformer), and storage systems (circulating pumps, cabling to consumption points). A 50 MW plant with 7.5 hours of storage contains approximately 196 tonnes of copper, of which 131,500 kg are in cables and 64,700 kg are in various equipment (generators, transformers, mirrors, and motors). This translates to about 3.9 tonnes/MW, or, in other terms, 1.2 tonnes/GWh/year. A plant of the same size without storage can have 20% less copper in the solar field and 10% less in the electronic equipment. A 100 MW plant will have 30% less relative copper content per MW in the solar field and 10% less in electronic equipment.
Copper quantities also vary according to design. The solar field of a typical 50 MW power plant with 7 hours of storage capacity consists of 150 loops and 600 motors, while a similar plant without storage uses 100 loops and 400 motors. Motorized valves for mass flow control in the loops rely on more copper. Mirrors use a small amount of copper to provide galvanic corrosion protection to the reflective silver layer. Changes in the size of the plants, size of collectors, efficiencies of heat transfer fluids will also affect material volumes.
Tower plants, also called central tower power plants, may become the preferred CSP technology in the future. They collect solar energy concentrated by the heliostat field in a central receiver mounted at the top of the tower. Each heliostat tracks the Sun along two axes (azimuth and elevation). Therefore, two motors per unit are required.
Copper is required in the heliostat field (power cables, signal, earthing, motors), receiver (trace heating, signal cables), storage system (circulating pumps, cabling to consumption points), electricity generation (alternator, transformer), steam cycle (water pumps, condenser fans), cabling to consumption points, control signal and sensors, and motors.
A 50 MW solar tower facility with 7.5 hours of storage uses about 219 tonnes of copper. This translates to 4.4 tonnes of copper/MW, or, in other terms, 1.4 tonnes/GWh/year. Of this amount, cables account for approximately 154,720 kg. Electronic equipment, such as generators, transformers, and motors, account for approximately 64,620 kg of copper. A 100 MW plant has slightly more copper per MW in the solar field because the efficiency of the heliostat field diminishes with the size. A 100 MW plant will have somewhat less copper per MW in process equipment.
Linear Fresnel plants
Linear Fresnel plants use linear reflectors to concentrate the Sun’s rays in an absorber tube similar to parabolic trough plants. Since the concentration factor is less than in parabolic trough plants, the temperature of the heat transfer fluid is lower. This is why most plants use saturated steam as the working fluid in both the solar field and the turbine.
A 50 MW linear Fresnel power plant requires about 1,960 tracking motors. The power required for each motor is much lower than the parabolic trough plant. A 50 MW lineal Fresnel plant without storage will contain about 127 tonnes of copper. This translates to 2.6 tonnes of copper/MW, or in other terms, 1.3 tonnes of copper/GWh/year. Of this amount, 69,960 kg of copper are in cables from process area, solar field, earthing and lightning protection and controls. Another 57,300 kg of copper is in equipment (transformers, generators, motors, mirrors, pumps, fans).
Dish Stirling plants
These plants are an emerging technology that has potential as a solution for decentralized applications. The technology does not require water for cooling in the conversion cycle. These plants are non-dispatchable. Energy production ceases when clouds pass overhead. Research is being conducted on advanced storage and hybridization systems.
The largest dish Sterling installation has a total power of 1.5 MW. Relatively more copper is needed in the solar field than other CSP technologies because electricity is actually generated there. Based on existing 1.5 MW plants, the copper content is 4 tonnes/MW, or, in other terms, 2.2 tonnes of copper/GWh/year. A 1.5 MW power plant has some 6,060 kg of copper in cables, induction generators, drives, field and grid transformers, earthing and lightning protection.
Solar water heaters (solar domestic hot water systems)
Solar hot water collectors are used by more than 200 million households as well as many public and commercial buildings worldwide. The total installed capacity of solar thermal heating and cooling units in 2010 was 185 GW-thermal.
Solar heating capacity increased by an estimated 27% in 2011 to reach approximately 232 GWth, excluding unglazed swimming pool heating. Most solar thermal is used for water heating, but solar space heating and cooling are gaining ground, particularly in Europe.
There are two types of solar water heating systems: active, which have circulating pumps and controls, and passive, which don't. Passive solar techniques do not require working electrical or mechanical elements. They include the selection of materials with favorable thermal properties, designing spaces that naturally circulate air, and referencing the position of a building to the Sun.
Copper is an important component of solar thermal heating and cooling systems because of its high heat conductivity, resistance to atmospheric and water corrosion, sealing and joining by soldering, and mechanical strength. Copper is used both in receivers and primary circuits (pipes and heat exchangers for water tanks).
Three types of solar thermal collectors are used for residential applications: flat plate collectors, integral collector-storage, and evacuated-tube solar collectors. They can be direct circulation (i.e., heats water and brings it directly to the home for use) or indirect circulation (i.e., pumps heat a transfer fluid through a heat exchanger, which then heats water that flows into the home) systems.
In an evacuated tube solar hot water heater with an indirect circulation system, evacuated tubes contain a glass outer tube and metal absorber tube attached to a fin. Solar thermal energy is absorbed within the evacuated tubes and is converted into usable concentrated heat. Copper heat pipes transfer thermal energy from within the solar tube into a copper header. A thermal transfer fluid (water or glycol mixture) is pumped through the copper header. As the solution circulates through the copper header, the temperature rises. The evacuated glass tubes have a double layer. The outer layer is fully transparent to allow solar energy to pass through unimpeded. The inner layer is treated with a selective optical coating that absorbs energy without reflection. The inner and outer layers are fused at the end, leaving an empty space between the inner and outer layers. All air is pumped out of the space between the two layers (evacuation process), thereby creating the thermos effect which stops conductive and convective transfer of heat that might otherwise escape into the atmosphere. Heat loss is further reduced by the low-emissivity of the glass that is used. Inside the glass tube is the copper heat pipe. It is a sealed hollow copper tube that contains a small amount of proprietary liquid, which under low pressure boils at a very low temperature. Other components include a solar heat exchanger tank and a solar pumping station, with pumps and controllers.
Wind power is the conversion of wind energy into a useful form of energy, such as using wind turbines to make electricity, windmills for mechanical power, windpumps for water pumping or drainage, or sails to propel ships. In a wind turbine, the wind’s kinetic energy is converted into mechanical energy to drive a generator, which in turn generates electricity.
Wind energy is one of the fastest growing energy technologies. Wind power capacity increased from a very small base of around 0.6 GW in 1996 to around 160 GW in 2009. It has also been reported that wind power capacity increased by 20% in 2011 to approximately 238 GW by 2012. This was the largest addition in capacity of any of the renewable energy technologies. It is anticipated that the growth of wind energy will continue to rise dramatically. Moderate estimates for global capacity by 2020 are 711 GW.
Some 50 countries operated wind power facilities in 2010.
Traditionally, wind power has been generated on land. But higher wind speeds are available offshore compared to land. Technologies are being improved to exploit the potential of wind power in offshore environments. The offshore wind power market is expanding with the use of larger turbines and installations farther from shore.
Offshore installation, as yet, is a comparatively small market, probably accounting for little more than 10% of installation globally. The location of new wind farms increasingly will be offshore, especially in Europe. Offshore wind farms are normally much larger, often with over 100 turbines with ratings up to 3 MW and above per turbine. The harsh environment means that the individual components need to be more rugged and corrosion protected than their onshore components. Increasingly long connections to shore with subsea MV and HV cables are required at this time. The need for corrosion protection favors copper nickel cladding as the preferred alloy for the towers.
Wind power installations vary in scale and type. Large wind farm installations linked to the electrical grid are at one end of the spectrum. These may be located either onshore or offshore. At the other end of the spectrum are small individual turbines that provide electricity to individual premises or electricity-using installations. These are often in rural and grid‐isolated sites.
The basic components of a wind power system consist of a tower with rotating blades containing an electricity generator and a transformer to step up voltage for electricity transmission to a substation on the grid. Cabling and electronics are also important components.
Copper in wind power generation
It has been estimated that the amount of copper used for wind energy systems in 2011 was 120 kt. The cumulative amount of copper installed through 2011 was estimated to be 714 kt.
Copper is primarily used in coil windings in the stator and rotor portions of generators (which convert mechanical energy into electrical energy), in low voltage cable conductors including the vertical electrical cable that connects the nacelle to the base of the wind turbine, in the coils of transformers (which steps up low voltage AC to high voltage AC compatible with the grid), and in gearboxes (which convert the slow revolutions per minute of the rotor blades to faster rpms). Copper may also be used in the nacelle (the housing of the wind turbine that rests on the tower containing all the main components), auxiliary motors (motors used to rotate the nacelle as well as control the angle of the rotor blades), cooling circuits (cooling configuration for the entire drive train), and power electronics (which enable the wind turbine systems to perform like a power plant).
In the coils of wind generators, electric current suffers from losses that are proportional to the resistance of the wire that carries the current. This resistance, called copper losses, causes energy to be lost by heating up the wire. In wind power systems, this resistance can be reduced with thicker copper wire and with a cooling system for the generator, if required.
Copper in the generators
The amount of copper in generators will vary according to the type of generator, its power rating, and its configuration. The weight of copper has an almost linear relationship to the power rating of the generator. The average capacity of a wind generator installed in Europe was estimated to be 1.5 MW in 2004 and 2 MW in 2009. The average capacity is forecasted to increase to 2.5 MW in 2015 and to 3 MW in 2020.
A generator in a direct drive configuration could be 3.5- to 6-times heavier than in a geared configuration, depending on the type of generator.
Five different types of generator technologies are used in wind generation: 1) double-fed asynchronous generators (DFAG), 2) conventional asynchronous generators (CAG), 3) conventional synchronous generators (CSG), 4) permanent magnet synchronous generators (PMSG), and 5) high-temperature superconductor generators (HTSG). The amount of copper in each of these generator types is summarized here.
|Technology||Average copper content (kg/MW)||Notes|
|Double-Fed Asynchronous Generator (DFAG)||650||Geared; most common wind generator in Europe (70% in 2009; Strong demand until 2015; then neutral as high cost of maintenance and servicing and need for power correction equipment for grid compliance will make these less popular in next 10 years.|
|Conventional asynchronous generators (CAG)||390||Geared; Neutral demand until 2015; will become negligible by 2020.|
|Conventional synchronous generators (CSG)||330-4000||Geared and direct; will become much more popular by 2020.|
|Permanent magnet synchronous generators (PMSG)||600-2150||Market expected to develop by 2015.|
|High-temperature superconductor generators (HTSG)||325||Nascent stage of development. It is expected that these machines will attain more power than other WTGs. Offshore could be the most suitable niche application.|
Direct drive configurations of the synchronous type machines contain the most amount of copper. Conventional synchronous generators (CSG) direct drive machines have the highest per-unit copper content. The share of CSGs will increase from 2009 to 2020, especially for direct drive machines. DFAGs accounted for highest number of unit sales in 2009.
The variation in the copper content of CSG generators depends upon whether they are coupled with single-stage (heavier) or three-stage (lighter) gearboxes. Similarly, the difference in copper content in PMSG generators depends on whether the turbines are medium speed, which are heavier, or high speed turbines, which are lighter.
There is increasing demand for synchronous machines and direct drive configurations. CSG direct and geared DFAGs will lead the demand for copper. The highest growth in demand is expected to be the direct PMSGs, which is forecasted to account for 7.7% of the total demand for copper in wind power systems in 2015.
Locations with high speed turbulent winds are better suited for variable speed wind turbine generators with full-scale power converters due to the greater reliability and availability they offer in such conditions. Of the variable-speed wind turbine options, PMSGs could be preferred over DFAGs in such locations. In conditions with low wind speed and turbulence, DFAGs could be preferred to PMSGs.
Generally, PMSGs deal better with grid-related faults and they could eventually offer higher efficiency, reliability, and availability than geared counterparts. This could be achieved by reducing the number of mechanical components in their design. Currently, however, geared wind turbine generators have been more thoroughly field-tested and are less expensive due to the greater volumes produced.
The current trend is for PMSG hybrid installations with a single-stage or 2-stage gearbox. The most recent wind turbine generator by Vestas is geared drive. The most recent wind turbine generator by Siemens is a hybrid. Over the medium-term, if the cost of power electronics continues to decrease, direct-drive PMSG are expected to become more attractive. High-temperature superconductors (HTSG) technology is currently under development. It is expected that these machines will be able to attain more power than other wind turbine generators. If the offshore market follows the trend of larger unit machines, offshore could be the most suitable niche for HTSGs.
Copper in other components
For a 2 MW turbine system, the following amounts of copper were estimated for components other than the generator:
|Component||Average Cu content (kg)|
|Auxiliary motors (pitch and yaw drives)||75|
|Other parts of the nacelle||<50|
|Power electronics (converter)||150|
|Earthing and lightning protection||750|
Cabling is the second largest copper-containing component after the generator. A wind tower system with the transformer next to the generator will have medium-voltage (MV) power cables running from the top to the bottom of the tower, then to a collection point for a number of wind towers and on to the grid substation, or direct to the substation. The tower assembly will incorporate wire harnesses and control/signal cables, while low-voltage (LV) power cables are required to power the working parts throughout the system.
For a 2 MW wind turbine, the vertical cable could range from 1,000-1,500 kg of copper, depending upon its type. Copper is the dominant material in underground cables.
Copper in grounding systems
Copper is vital to the electrical grounding system for wind turbine farms. Turbine masts attract lightning strikes, so they require lightning protection systems. When lightning strikes a turbine blade, current passes along the blade, through the blade hub in the nacelle (gearbox/ generator enclosure) and down the mast to a grounding system. The blade incorporates a large cross-section copper conductor that runs along its length and allows current to pass along the blade without deleterious heating effects. The nacelle is protected by a lightning conductor, often copper. The grounding system, at the base of the mast, consists of a thick copper ring conductor bonded to the base or located within a meter of the base. The ring is attached to two diametrically opposed points on the mast base. Copper leads extend outward from the ring and connect to copper grounding electrodes. The grounding rings at turbines on wind farms are inter-connected, providing a networked system with an extremely small aggregate resistance.
Solid copper wire has been traditionally deployed for grounding and lightning equipment due to its excellent electrical conductivity. However, manufacturers are moving towards less expensive bi-metal copper clad or aluminum grounding wires and cables. Copper-plating wire is being explored. Current disadvantages of copper plated wire include lower conductivity, size, weight, flexibility and current carrying capability.
Copper in other equipment
After generators and cable, minor amounts of copper are used in the remaining equipment. In yaw and pitch auxiliary motors, the yaw drive uses a combination of induction motors and multi-stage planetary gearboxes with minor amounts of copper. Power electronics have minimal amounts of copper compared to other equipment. As turbine capacities increase, converter ratings also increase from low voltage (<1kV) to medium voltage (1kV-5kV). Most wind turbines have full power converters, which have the same power rating as the generator, except the DFAG that has a power converter that is 30% of the rating of the generator. Finally, minor amounts of copper are used in air/oil and water cooled circuits on gearboxes or generators.
Superconducting materials are being tested within and outside of wind turbines. They offer higher electrical efficiencies, the ability to carry higher currents, and lighter weights. These materials are, however, much more expensive than copper at this time.
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