Refinery Catalyst Market Shares, Strategies, and Forecasts, Worldwide, 2012 to 2018
WinterGreen Research announces that it has published a new study on refinery catalysts. The 2012 study has 683 pages, 188 tables and figures. Worldwide markets are poised to achieve steady growth as countries impose stricter environment controls on the manufacture and use of fossil fuels.
Hydroprocessing catalysts are used to create cleaner fuels--especially ULSD. Demand for cleaner fuels is driving the market. Refining catalysts are experiencing strong growth this year. New fuel standards are coupled with refinery increasing use of heavier and dirtier feedstocks and major additions to refining capacity. Refining catalysts are moving to a more balanced market. Producers of fluid catalytic cracking (FCC) catalysts had a surge in demand. The market is shifting from one characterized by oversupply to a more stable sales effort. Hydroprocessing catalyst supply-demand is evolving.
Hydroprocessing catalysts are the fastest-growing refinery catalysts. These catalysts help control and improve the operational efficiencies in the petroleum refining process. Demand is lower for the more mature FCC catalysts than the hydroprocessing catalysts. Hydroprocessing catalysts have passed FCC catalysts, becoming the largest segment of the refinery catalyst market.
Low sulfur regulations in developed countries, implementation of some sulfur restrictions in China, India and Mexico, and other countries is a significant market driving force. Increasingly higher sulfur-content is present in oil coming out of the ground.
The rapidly increasing demand for gasoline and diesel has increased the requirement for raw materials for their production. The limited supply of raw materials increases the overall cost of production.
Reforming catalysts are fundamental to the modernization of product reformate. They contain hydrocarbons with more complex molecular shapes having higher octane values than the hydrocarbons in the naphtha feedstock. The process separates hydrogen atoms from the hydrocarbon molecules and produces significant amounts of byproduct hydrogen gas.
Hydrogen is useful for fuel cells, meaning that refineries could become environments for generating electricity. Hydrogen is useful in stationary fuel cells that are evolving a market for providing local power in campus environments. Local power generation is becoming more valued as people realize that the cost of conditioning electricity for the grid is an unnecessary expense in local power environments.
Stationary fuel cells represent the base for distributed power generation worldwide. No more new coal plants, no mare extensions to the grid. Distributed power has become mainstream. Distributed generation (DG) refers to power generation at the point of consumption. The use of hydrogen and the manufacture of hydrogen in refinery environments could become significant aspect of markets.
According to Susan Eustis, the lead author of the study, 'These factors have attracted manufacturers to refinery catalysts, as these help extract relatively more diesel and gasoline from the same amount of crude oil. The refinery catalyst market is thus boosted by the fact that the efficient use of catalysts can help the manufacturers' better address the increasing energy demand. Hydroprocessing faces significant challenges as crude feeds get heavier; there will be more sulphur and nitrogen to extract; more aromatics to saturate; more metals to remove; and more coke to deal with. Refiners have ageing facilities, which may not be designed and optimized to meet new challenges.'
Generating power on-site, rather than centrally, eliminates the cost, complexity, interdependencies, and inefficiencies associated with transmission and distribution. Like distributed computing (i.e. the PC) and distributed telephony (i.e. the mobile phone), distributed power generation shifts control to the consumer.
As more capital investment is needed, costs for refining fossil fuels will rise, stimulating markets for renewable energy, making them more competitive with fossil fuels.
Refinery catalyst markets at $3.3 billion in 2011 are anticipated to reach $4.3 billion in 2018. Market growth comes in large part from demand for cleaner diesel fuel and the availability of newer technology and nanotechnology.
Hydrotreating catalysts will continue to achieve the best growth in the petroleum refining market, aided by the increasingly sour nature of the crude petroleum supplied to the market. Efforts by Brazil, China, India and Russia to improve their air quality by the introduction of low-sulfur fuels are ongoing. Hydrocracking and fluid catalytic cracking (FCC) catalysts achieve advances, particularly in Asia as the growing motor vehicle fleet stimulates new gasoline and diesel fuel demand.
WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software. The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, Bloomberg, and Thompson Financial.
Hydroprocessing catalysts are used to create cleaner fuels--especially ULSD. Demand for cleaner fuels is driving the market. Refining catalysts are experiencing strong growth this year. New fuel standards are coupled with refinery increasing use of heavier and dirtier feedstocks and major additions to refining capacity. Refining catalysts are moving to a more balanced market. Producers of fluid catalytic cracking (FCC) catalysts had a surge in demand. The market is shifting from one characterized by oversupply to a more stable sales effort. Hydroprocessing catalyst supply-demand is evolving.
Hydroprocessing catalysts are the fastest-growing refinery catalysts. These catalysts help control and improve the operational efficiencies in the petroleum refining process. Demand is lower for the more mature FCC catalysts than the hydroprocessing catalysts. Hydroprocessing catalysts have passed FCC catalysts, becoming the largest segment of the refinery catalyst market.
Low sulfur regulations in developed countries, implementation of some sulfur restrictions in China, India and Mexico, and other countries is a significant market driving force. Increasingly higher sulfur-content is present in oil coming out of the ground.
The rapidly increasing demand for gasoline and diesel has increased the requirement for raw materials for their production. The limited supply of raw materials increases the overall cost of production.
Reforming catalysts are fundamental to the modernization of product reformate. They contain hydrocarbons with more complex molecular shapes having higher octane values than the hydrocarbons in the naphtha feedstock. The process separates hydrogen atoms from the hydrocarbon molecules and produces significant amounts of byproduct hydrogen gas.
Hydrogen is useful for fuel cells, meaning that refineries could become environments for generating electricity. Hydrogen is useful in stationary fuel cells that are evolving a market for providing local power in campus environments. Local power generation is becoming more valued as people realize that the cost of conditioning electricity for the grid is an unnecessary expense in local power environments.
Stationary fuel cells represent the base for distributed power generation worldwide. No more new coal plants, no mare extensions to the grid. Distributed power has become mainstream. Distributed generation (DG) refers to power generation at the point of consumption. The use of hydrogen and the manufacture of hydrogen in refinery environments could become significant aspect of markets.
According to Susan Eustis, the lead author of the study, 'These factors have attracted manufacturers to refinery catalysts, as these help extract relatively more diesel and gasoline from the same amount of crude oil. The refinery catalyst market is thus boosted by the fact that the efficient use of catalysts can help the manufacturers' better address the increasing energy demand. Hydroprocessing faces significant challenges as crude feeds get heavier; there will be more sulphur and nitrogen to extract; more aromatics to saturate; more metals to remove; and more coke to deal with. Refiners have ageing facilities, which may not be designed and optimized to meet new challenges.'
Generating power on-site, rather than centrally, eliminates the cost, complexity, interdependencies, and inefficiencies associated with transmission and distribution. Like distributed computing (i.e. the PC) and distributed telephony (i.e. the mobile phone), distributed power generation shifts control to the consumer.
As more capital investment is needed, costs for refining fossil fuels will rise, stimulating markets for renewable energy, making them more competitive with fossil fuels.
Refinery catalyst markets at $3.3 billion in 2011 are anticipated to reach $4.3 billion in 2018. Market growth comes in large part from demand for cleaner diesel fuel and the availability of newer technology and nanotechnology.
Hydrotreating catalysts will continue to achieve the best growth in the petroleum refining market, aided by the increasingly sour nature of the crude petroleum supplied to the market. Efforts by Brazil, China, India and Russia to improve their air quality by the introduction of low-sulfur fuels are ongoing. Hydrocracking and fluid catalytic cracking (FCC) catalysts achieve advances, particularly in Asia as the growing motor vehicle fleet stimulates new gasoline and diesel fuel demand.
WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software. The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, Bloomberg, and Thompson Financial.
UTILITY WIND TURBINE EXECUTIVE SUMMARY
Wind Turbine Market Driving Forces
Local Generation of Wind Energy
Wind Energy Leverages Smart Grid
Wind Turbine Market Saturation In Areas of High Wind
High Energy Factories, Data Centers, And Commercial Plants Can Be Relocated
Significant Shift In Vendor Strategy
Global Warming Reaching A Point Where It Is Impossible To Ignore
Storage of Wind Generated Electricity: Hydrogen, Stationary Fuel Cells, Thin Film Batteries
Wind Turbine Market Shares
Wind Turbine Market Forecasts
1. UTILITY GRADE WIND TURBINE MARKET DESCRIPTION AND DYNAMICS
1.1 Renewable Energy, Climate Change, And Energy Security
1.1.1 Wind Energy in California
1.1.2 Wind Farms Construction Phase
1.1.3 Turbine Heads Swivel
1.2 Wind Energy Environmental Impact
1.3 Predicted Effects Of Climate Change
1.4 Wind Farms Set To Become More Common
1.5 Benefits of Wind Power for Utilities
1.6 Wind Power Variable Nature
1.6.1 Cost to Integrate Wind Power
1.6.2 Key Benefits Utilities Are Realizing with Wind Power
2. UTILITY WIND TURBINE MARKET SHARES AND FORECASTS
2.1 Wind Turbine Market Driving Forces
2.1.1 Local Generation of Wind Energy
2.1.2 Wind Energy Leverages Smart Grid
2.1.3 Wind Turbine Market Saturation In Areas of High Wind
2.1.4 High Energy Factories, Data Centers, And Commercial Plants Can Be Relocated
2.1.5 Significant Shift In Vendor Strategy
2.1.6 Global Warming Reaching A Point Where It Is Impossible To Ignore
2.1.7 Storage of Wind Generated Electricity: Hydrogen, Stationary Fuel Cells, Thin Film Batteries
2.2 Wind Turbine Market Shares
2.2.1 Vestas
2.2.2 Siemens
2.2.3 Gamesa Corporacion Tecnologica S.A.
2.2.4 Gamesa Aims To Enable Reducing CoE For Customers
2.2.5 Suzlon in India
2.2.6 Sinovel
2.2.7 Sinovel Wind Co SL1500
2.2.8 Enercon GmbH
2.2.9 GE
2.2.10 Siemens Wind Power A/S
2.2.11 Entegrity Wind Systems Inc.
2.2.12 Acciona Energ A.S.A.
2.2.13 Acciona Working On Design
2.2.14 Goldwind Science & Technology
2.2.15 CSIC Holdings/HZ Windpower
2.2.16 Eoltec
2.2.17 Dezhou Kinglike Energy Technology Co., Ltd.
2.2.18 LM Wind Power
2.2.19 Dong
2.3 Wind Turbine Market Forecasts
2.3.1 Benchmark In Terms Of Cost of Energy (CoE)
2.3.2 Over Speed Control
2.3.3 Wind Turbine Price Reduction
2.3.4 Wind Turbine Market Shares, Shipped Megawatts And Dollars Per Turbine
2.3.5 Storage Needed to Accommodate the Variable Nature of Wind Power
2.3.6 Wind Energy Storage
2.3.7 Cost Of Wind Integration
2.4 Land And Offshore-Based Wind Generating Capacity
2.4.1 On-Shore Turbine Market Forecast
2.4.2 Offshore Wind Turbines Market Forecasts
2.4.3 Offshore Wind Power
2.4.4 Challenges For Offshore Wind
2.5 Turbine Blade Markets
2.5.1 LM Glasfiber Turbines
2.6 Mergers And Acquisitions
2.7 Wind Turbine Transport
2.8 Air Pollution
2.8.1 Cumulative & Annual Emission Reductions
2.9 Wind Electricity Transmission Expansion
2.10 Utility Scale Wind Turbine Regional Market Segments
2.10.1 US Wind Transmission
2.10.2 Wind Electricity Hydrogen Storage in California
2.10.3 Wind Turbine US and China Regional Analysis
2.10.4 GE 4.1-113 Offshore Wind Turbine
2.10.5 U.S. Offshore Wind Resources
2.10.6 US
2.10.7 Wind Penetration In the US
2.10.8 US Use of Wind Turbines
2.10.9 Iowa Leads In Terms Of Percentage Of Electricity From Wind Power, Getting 14% Of Its Power From The Wind
2.10.10 China
2.10.11 China Sinovel
2.10.12 Goldwind Science & Technology
2.10.13 India Suzlon
2.10.14 High Wind Penetration and Reliable Operation In Europe
2.10.15 European Use of Wind Turbines
2.10.16 Eurpoean Forecasts
2.10.17 Spain Gamesa Corporacion Tecnologica S.A.
2.10.18 Germany Enercon GmbH
2.10.19 France A Growing Photovoltaic Market.
2.10.20 Finland 2.10.21 General Electric
2.10.22 Emerging Markets Drive Growth
2.10.23 Gamesa Targets China, India, and the US
2.10.1 India Suzlon
2.10.2 Emerging Wind Turbine Markets Drive Growth: South America
2.10.3 Acciona Operational AW Wind Turbines Worldwide
3. UTILITY GRADE WIND TURBINE PRODUCT DESCRIPTION
3.1 Vestas Wind Systems A/S Large Wind Turbine Products
3.1.1 Vestas V52-850 kW
3.1.2 Vestas Pitch Regulated System
3.1.3 Vestas in China
3.1.4 Vestas Thanet Offshore Wind Farm Ramsgate Port
3.1.5 Vestas Dunkirk Port
3.1.6 Vestas Hydraulic Pitch
3.2 GE Wind Energy Primary Activities
3.2.1 1.5 - 77 Wind turbine
3.2.2 2.5 - 100 Wind turbine
3.2.3 GE2.5 MW Wind Turbine
3.2.4 GE 2.75 - 100 Wind turbine
3.2.5 GE 2.75 - 103 Wind turbine
3.2.6 GE Offers Slow-Wind Turbines
3.2.7 GE Energy
3.3 Siemens Wind Power A/S
3.3.1 Siemens Wind Turbine SWT-2.3-82 3.3.2 Siemens Wind Turbine SWT-3.6-120 3.3.3 Siemens SWT-3.6-107 Rotors
3.3.4 Siemens SWT-3.6-107 Blades
3.3.5 Siemens SWT-3.6-107 Gearbox and Brake
3.3.6 Siemens SWT-3.6-107 Generator
3.3.7 Siemens SWT-3.6-107 Tower
3.3.8 Siemens SWT-3.6-107 Controller
3.3.9 Siemens SWT-3.6-107 Operation
3.3.10 Siemens SWT-3.6-107 Safety System
3.3.11 Siemens Wind Turbine Design
3.3.12 Siemens Remote Control
3.3.13 Siemens Grid Compliance
3.4 Enercon GmbH
3.5 Gamesa Corporacion Tecnologica S.A.
3.5.1 Gamesa G5X 850 kW Wind Turbine
3.5.2 Gamesa Made AE-61-1320 KW Wind Turbine
3.5.3 Gamesa Made AE-61-1320 KW Wind Turbine Mechanical Design
3.5.4 Gamesa Made AE-61-1320 KW Wind Turbine Electrical Design
3.5.5 Gamesa Made AE-61-1320 KW Wind Turbine Guidance System
3.5.6 Gamesa Made AE-61-1320 KW Wind Turbine Foundation
3.5.7 Gamesa Made AE-61-1320 KW Wind Turbine Brake
3.5.8 Gamesa Made AE-61-1320 KW Wind Turbine Tower and Nacelle
3.5.9 Gamesa Made AE-61-1320 KW Wind Turbine Control system
3.5.10 Gamesa Wind Farms
3.6 Suzlon
3.6.1 Suzlon S52-600 kW
3.6.2 Suzlon S52-600 kW
3.6.3 Suzlon/REpower Systems AG
3.6.4 REpower Product Range
3.7 Nordex AG
3.7.1 Nordex N117 Wind Turbine
3.7.2 Nordex N150 (6 Megawatt) Offshore
3.7.3 Nordex N117 (2,4 Megawatt)
3.7.4 N100 (2.5 Megawatt)
3.7.5 Nordex N90 (2.5 Megawatt)
3.7.6 Nordex N82 (1.5 Megawatt)
3.7.7 Nordex N77 (1.5 Megawatt)
3.7.8 Nordex N150 (6 Megawatt) Offshore
3.7.9 Nordex N117 (2.4 Megawatt)
3.7.10 Nordex Third Generation Wind Turbines
3.7.11 Nordex N100 (2.5 Megawatt)
3.7.12 Nordex N100 (2.5 Megawatt)
3.7.13 Nordex Rotor
3.7.14 Nordex Drive train
3.7.15 Nordex Gearbox
3.7.16 Nordex Generator
3.7.17 Nordex Cooling And Filtration
3.7.18 Nordex Braking System
3.7.19 Nordex Nacelle
3.7.20 Nordex Yaw System
3.7.21 Nordex Tower
3.7.22 Nordex Control And Grid Connection
3.7.23 Nordex Lightning Protection
3.7.24 Nordex N90 (2.5 Megawatt)
3.7.25 Nordex N80 (2.5 Megawatt)
3.7.26 Nordex S82 (1.5 Megawatt)
3.7.27 Nordex S77 (1.5 Megawatt)
3.7.28 Nordex S70 (1.5 Megawatt)
3.8 Sinovel Wind Co., Ltd
3.8.1 Sinovel Wind Co SL6000
3.8.2 Sinovel Wind Co SL5000
3.8.3 Sinovel Wind Co SL1500
3.8.4 Sinovel SL3000 Series Wind Turbine
3.8.5 Sinovel SL1500 Series Wind Turbine
3.9 Acciona Wind Turbines
3.9.1 Acciona Windpower, A Global Supplier, Acciona Wind Turbines
3.9.2 Acciona Wind Turbine Assembly Plants
3.9.3 Acciona Wind turbines
3.9.4 Acciona Models
3.9.5 Acciona Working On Design
3.10 BP
3.10.1 BP Consortium Floating Wind Turbine Platform At Wave Hub Wave Energy Site On The South Coast Of England
3.11 United Technologies/Clipper
3.11.1 United Technologies/Clipper Liberty 2.5 MW Wind Turbine
3.12 Nacel Energy Corporation
3.13 Rooftop Wind Power
3.14 Urban Green Energy
3.15 CSIC Holdings/HZ Windpower Co., Ltd.
3.16 Wind Energy Solutions
3.17 Fuhrl nder Aktiengesellschaft
3.18 Winwind Ltd
3.19 Eoltec SAS
3.19.1 Wind Turbine Cost Reduction
3.19.2 Wind Turbine Prices
3.20 Goldwind Science & Technology
3.21 Kinglike Energy Technology
3.21.1 Dezhou Xinqu Renewable Energy Technology Co., ltd
3.22 LM Wind Power
3.22.1 LM Wind Power Group
3.23 Alaska Wind Turbine
3.24 Northern Power Systems
3.25 Qingdao Jintaida Industry&Trade Co., Ltd
3.26 LGC SkyRota
3.27 Nanjing Supermann Industrial &Trading Co., Ltd.
3.28 Wind Pacific (Aust) Pty Ltd
3.28.1 Wind Pacific Main Features of the MY1.5 series MW Wind Turbine
4. UTILITY SCALE WIND TURBINE TECHNOLOGY
4.1 Wind Turbines Take Over the Landscape
4.2 Design Of Wind Turbines
4.3 Wind Farms and Radar
4.4 Vestas Technologies Testing Capabilities
4.4.1 Vestas Blade Technology
4.4.2 Vestas Smart Controls
4.4.3 Vestas Research and Innovation
4.4.4 Vestas Stealth Research
4.4.5 Vestas Floating Foundations
4.5 Sinovel National Energy Offshore Wind Power
4.6 Enercon Wind Technology
4.7 Turbines Hybrid Gas-Wind Turbine System
4.8 How A Wind Turbine Works
4.8.1 Density Of Air
4.8.2 Rotor Area
4.8.3 Wind Speed
4.8.4 Centrifugal Pitch Control
4.8.5 Turbine Blade Materials
4.8.6 Wind Turbine Metal Components
4.8.7 Forged Parts
4.8.8 Cast Parts
4.8.9 Machined Parts
4.9 Barriers to Wind Turbine Market Entry
4.9.1 Wind Turbine Regulatory Concerns
4.9.2 Suzlon S52-600 kW Technology
4.10 US National Renewable Electricity Standard (RES)
4.10.1 A Renewable Electricity Standard (RES)
5. UTILITY GRADE WIND TURBINE COMPANY PROFILES
5.1 Mergers And Acquisitions
5.1.1 Suzlon’s Acquisition of REPower
5.1.2 Acciona Energy Sells 15% Share to Mitsubishi
5.1.3 United Technologies Completes Clipper Windpower Acquisition
5.1.4 Price Declines Drive Industry Consolidation
5.2 Acciona Energ a, s.a.
5.2.1 Acciona Wind Towers
5.2.2 Acciona Business Strategy
5.2.3 Acciona A World Leader In Renewables
5.2.4 Acciona (Navarre, Spain)
5.2.5 Ten Entities Finance Acciona's Eurus Windpark In Mexico With Usd375m
5.2.6 Acciona Energy Wind Parks in Mexico
5.2.7 Acciona Energy Wind power
5.2.8 Acciona Energy Implementation
5.2.9 Acciona Promoted Public-Private Alliances Between The UN And Business At The Davos Summit
5.2.10 Acciona Wind Park In Castilla-La Mancha (Spain)
5.2.11 Acciona 9M 2011 Results (January - September)
5.2.12 Acciona And Dhamma Energy Sign An Agreement To Develop 250 Mw Of Photovoltaic Power In France
5.2.13 Acciona Project Development
5.2.14 Acciona Wind Energy
5.2.15 Acciona Production
5.2.16 Acciona Photovoltaic
5.2.17 Acciona Other Facilities
5.2.18 Acciona Solar Thermal Power
5.2.19 AccionaFour Plants in Spain
5.2.20 Acciona Installations for Customers
5.2.21 Acciona Hydropower
5.3 AMSC
5.4 Blue Carbon Technology
5.5 BP
5.5.1 BP’s Operating US Wind Farms
5.5.2 Clipper Windpower And BP Alternative Energy Form Joint Venture To Develop Up To 5,050 Mw
5.5.3 British Energy BP Invests $800 Million In An Onshore Wind Farm In Kansas
5.6 CSIC holdings/HZ Windpower Co., Ltd.
5.7 Enercon
5.7.1 Enercon Wind Turbine Return on Investment (ROI)
5.8 Eolia Renovables
5.8.1 N+1 Eolia
5.9 Eoltec
5.10 Fuhrl nder Aktiengesellschaft
5.11 Gamesa Corporacion Tecnologica S.A.
5.11.1 Gamesa Integrated Response Presence In All Phases Of A Wind Project
5.11.2 Gamesa in Figures
5.11.3 Gamesa Strategic Vectors
5.11.4 Gamesa Installs A Further 52 MW in Spain
5.11.5 Gamesa Installs 10 MW in Mexico
5.11.6 Gamesa Wind Farm Business Plan
5.12 GE
5.12.1 GE Energy
5.12.2 GE Energy
5.12.3 General Electric Company Energy Infrastructure Revenues
5.12.4 GE Total Revenue
5.12.5 General Electric Geographic Revenues
5.12.6 GE and Göteborg Energi
5.12.7 GE‘s 4.1-113 Wind Turbine
5.12.8 General Electric Offers Wind Turbine Customers Clean Energy From Solar Panels
5.12.9 GE U.S. Wind Crash
5.12.10 GE Technology to Boost the Output of NextEra Energy Resources’ U.S. Fleet of Wind Turbines
5.12.11 GE Energy Financial Services
5.13 Goldwind
5.13.1 Goldwind Product Positioning
5.13.2 Goldwind Science & Technology Revenue
5.13.3 Goldwind 2011 3Q Revenue
5.13.4 Goldwind Acquires Two 10MW US Projects From Volkswind USA 5.13.5 Goldwind Signs Strategic Agreement with Export-Import Bank of China
5.14 Göteborg Kommunala/Göteborg Energi
5.15 Kinglike Energy Technology
5.16 LGC Skyrota Wind Energy
5.16.1 LGC Skyrota Wind Energy Acquires UK Wind Energy Business
5.17 LM Wind Power
5.18 Nacel Energy
5.18.1 Nacel Energy 200 Mw Gascoyne II Wind Power Project
5.19 Nanjing Supermann Industrial & Trading Co. Ltd.
5.20 NextEra
5.20.1 NextEra Energy Revenue
5.20.2 NextEra Energy Resources
5.21 Nordex AG
5.21.1 Nordex Awarded Contract For 30 MW Wind Farm in Spain
5.21.2 Nordex Revenue
5.22 Northern Power Systems
5.23 Qingdao
5.23.1 Qingdao Jintaida Industrial & Trade Co., Ltd.
5.24 Rooftop Wind Power
5.25 Siemens
5.25.1 Siemens Wind Power A/S –
5.25.2 Siemens Health Care Sector
5.25.3 Siemens Revenue
5.25.4 Siemens Geographic Analysis
5.25.5 Siemens Energy Revenue
5.26 Sinovel
5.26.1 Sinovel Contracts With Brazilian Renewable Power Generating Company Desenvix
5.26.2 Sinovel Revenue
5.26.3 Chinese Wind-Turbine Prices Have Declined
5.26.4 Sinovel Confronting Legal Claims Of More Than $1.2 Billion USD In End Of Relationship With American Superconductor Corporation (AMSC)
5.26.5 Sinovel The Largest Producer Of Wind Turbines In China
5.26.6 Sinovel Wind Group Co., Ltd
5.26.7 Sinovel Provides Clean Energy And Power The World
5.27 Standard Steel Inc/Alaska Wind Turbine
5.27.1 Standard Steel/Alaskan Wind Industries
5.28 Suzlon Energy Limited
5.28.1 Suzlon Energy Limited Revenue
5.28.2 Suzlon Energy Limited
5.28.3 Suzlon Acquires REpower
5.28.4 Suzlon Starts In Textile Industry
5.28.5 Suzlon Wins 19.2 MW Repeat Order From The Baidyanath Group
5.28.6 Suzlon in India
5.28.7 Suzlon Supplies the Malpani Group
5.28.8 Suzlon/Repower/REpower Systems AG – REpower USA Corp.
5.28.9 Suzlon/REpower 5M Largest Wind Turbine Size Of Two Soccer Fields
5.28.10 Suzlon/REpower Renewable Projects
5.28.11 Suzlon/REpower International
5.29 Shanghai Donghai Bridge 102MW Offshore Wind Farm Pilot Project
5.30 The Switch
5.31 TuuliWatti Oy
5.32 United Technologies
5.32.1 United Technologies/Clipper Windpower
5.32.2 UTC/Clipper Wind Projects
5.32.3 Clipper Receives Warranty, Technology and Sales Support from UTC
5.32.4 Clipper Windpower
5.32.5 Clipper Windpower Liberty Wind Turbine
5.33 Urban Green Energy
5.34 Vestas
5.34.1 Vestas Revenue
5.34.2 Vestas World Leader In Wind Technology
5.34.3 Vestas Wind
5.34.4 Vestas Strengthens Its Position In Finland 5.34.5 Vestas Offshore Project in Belgium
5.34.6 Vestas Project in Kenya
5.34.7 Vestas Signs 51 MW Order in Poland 5.34.8 Vestas Orders From Key Account EDF Energies Nouvelles
5.34.9 Vestas Order For 18 Units Of The V90-3.0 Mw Wind Turbine For The UK.
5.34.10 Vestas Enters Pakistan with 50 MW Order From the Zorlu Energy Group
5.34.11 Vestas China V100 Order Is For A Total Of 48.6 MW
5.34.12 Vestas Order 570 MW in California, USA 5.34.13 Vestas Shipments
5.35 Wind Energy Solutions by Winwind
5.35.1 WinWinD
5.36 Yingli Green Energy
5.37 Selected Wind Industry Associations and Regulators
Wind Turbine Market Driving Forces
Local Generation of Wind Energy
Wind Energy Leverages Smart Grid
Wind Turbine Market Saturation In Areas of High Wind
High Energy Factories, Data Centers, And Commercial Plants Can Be Relocated
Significant Shift In Vendor Strategy
Global Warming Reaching A Point Where It Is Impossible To Ignore
Storage of Wind Generated Electricity: Hydrogen, Stationary Fuel Cells, Thin Film Batteries
Wind Turbine Market Shares
Wind Turbine Market Forecasts
1. UTILITY GRADE WIND TURBINE MARKET DESCRIPTION AND DYNAMICS
1.1 Renewable Energy, Climate Change, And Energy Security
1.1.1 Wind Energy in California
1.1.2 Wind Farms Construction Phase
1.1.3 Turbine Heads Swivel
1.2 Wind Energy Environmental Impact
1.3 Predicted Effects Of Climate Change
1.4 Wind Farms Set To Become More Common
1.5 Benefits of Wind Power for Utilities
1.6 Wind Power Variable Nature
1.6.1 Cost to Integrate Wind Power
1.6.2 Key Benefits Utilities Are Realizing with Wind Power
2. UTILITY WIND TURBINE MARKET SHARES AND FORECASTS
2.1 Wind Turbine Market Driving Forces
2.1.1 Local Generation of Wind Energy
2.1.2 Wind Energy Leverages Smart Grid
2.1.3 Wind Turbine Market Saturation In Areas of High Wind
2.1.4 High Energy Factories, Data Centers, And Commercial Plants Can Be Relocated
2.1.5 Significant Shift In Vendor Strategy
2.1.6 Global Warming Reaching A Point Where It Is Impossible To Ignore
2.1.7 Storage of Wind Generated Electricity: Hydrogen, Stationary Fuel Cells, Thin Film Batteries
2.2 Wind Turbine Market Shares
2.2.1 Vestas
2.2.2 Siemens
2.2.3 Gamesa Corporacion Tecnologica S.A.
2.2.4 Gamesa Aims To Enable Reducing CoE For Customers
2.2.5 Suzlon in India
2.2.6 Sinovel
2.2.7 Sinovel Wind Co SL1500
2.2.8 Enercon GmbH
2.2.9 GE
2.2.10 Siemens Wind Power A/S
2.2.11 Entegrity Wind Systems Inc.
2.2.12 Acciona Energ A.S.A.
2.2.13 Acciona Working On Design
2.2.14 Goldwind Science & Technology
2.2.15 CSIC Holdings/HZ Windpower
2.2.16 Eoltec
2.2.17 Dezhou Kinglike Energy Technology Co., Ltd.
2.2.18 LM Wind Power
2.2.19 Dong
2.3 Wind Turbine Market Forecasts
2.3.1 Benchmark In Terms Of Cost of Energy (CoE)
2.3.2 Over Speed Control
2.3.3 Wind Turbine Price Reduction
2.3.4 Wind Turbine Market Shares, Shipped Megawatts And Dollars Per Turbine
2.3.5 Storage Needed to Accommodate the Variable Nature of Wind Power
2.3.6 Wind Energy Storage
2.3.7 Cost Of Wind Integration
2.4 Land And Offshore-Based Wind Generating Capacity
2.4.1 On-Shore Turbine Market Forecast
2.4.2 Offshore Wind Turbines Market Forecasts
2.4.3 Offshore Wind Power
2.4.4 Challenges For Offshore Wind
2.5 Turbine Blade Markets
2.5.1 LM Glasfiber Turbines
2.6 Mergers And Acquisitions
2.7 Wind Turbine Transport
2.8 Air Pollution
2.8.1 Cumulative & Annual Emission Reductions
2.9 Wind Electricity Transmission Expansion
2.10 Utility Scale Wind Turbine Regional Market Segments
2.10.1 US Wind Transmission
2.10.2 Wind Electricity Hydrogen Storage in California
2.10.3 Wind Turbine US and China Regional Analysis
2.10.4 GE 4.1-113 Offshore Wind Turbine
2.10.5 U.S. Offshore Wind Resources
2.10.6 US
2.10.7 Wind Penetration In the US
2.10.8 US Use of Wind Turbines
2.10.9 Iowa Leads In Terms Of Percentage Of Electricity From Wind Power, Getting 14% Of Its Power From The Wind
2.10.10 China
2.10.11 China Sinovel
2.10.12 Goldwind Science & Technology
2.10.13 India Suzlon
2.10.14 High Wind Penetration and Reliable Operation In Europe
2.10.15 European Use of Wind Turbines
2.10.16 Eurpoean Forecasts
2.10.17 Spain Gamesa Corporacion Tecnologica S.A.
2.10.18 Germany Enercon GmbH
2.10.19 France A Growing Photovoltaic Market.
2.10.20 Finland 2.10.21 General Electric
2.10.22 Emerging Markets Drive Growth
2.10.23 Gamesa Targets China, India, and the US
2.10.1 India Suzlon
2.10.2 Emerging Wind Turbine Markets Drive Growth: South America
2.10.3 Acciona Operational AW Wind Turbines Worldwide
3. UTILITY GRADE WIND TURBINE PRODUCT DESCRIPTION
3.1 Vestas Wind Systems A/S Large Wind Turbine Products
3.1.1 Vestas V52-850 kW
3.1.2 Vestas Pitch Regulated System
3.1.3 Vestas in China
3.1.4 Vestas Thanet Offshore Wind Farm Ramsgate Port
3.1.5 Vestas Dunkirk Port
3.1.6 Vestas Hydraulic Pitch
3.2 GE Wind Energy Primary Activities
3.2.1 1.5 - 77 Wind turbine
3.2.2 2.5 - 100 Wind turbine
3.2.3 GE2.5 MW Wind Turbine
3.2.4 GE 2.75 - 100 Wind turbine
3.2.5 GE 2.75 - 103 Wind turbine
3.2.6 GE Offers Slow-Wind Turbines
3.2.7 GE Energy
3.3 Siemens Wind Power A/S
3.3.1 Siemens Wind Turbine SWT-2.3-82 3.3.2 Siemens Wind Turbine SWT-3.6-120 3.3.3 Siemens SWT-3.6-107 Rotors
3.3.4 Siemens SWT-3.6-107 Blades
3.3.5 Siemens SWT-3.6-107 Gearbox and Brake
3.3.6 Siemens SWT-3.6-107 Generator
3.3.7 Siemens SWT-3.6-107 Tower
3.3.8 Siemens SWT-3.6-107 Controller
3.3.9 Siemens SWT-3.6-107 Operation
3.3.10 Siemens SWT-3.6-107 Safety System
3.3.11 Siemens Wind Turbine Design
3.3.12 Siemens Remote Control
3.3.13 Siemens Grid Compliance
3.4 Enercon GmbH
3.5 Gamesa Corporacion Tecnologica S.A.
3.5.1 Gamesa G5X 850 kW Wind Turbine
3.5.2 Gamesa Made AE-61-1320 KW Wind Turbine
3.5.3 Gamesa Made AE-61-1320 KW Wind Turbine Mechanical Design
3.5.4 Gamesa Made AE-61-1320 KW Wind Turbine Electrical Design
3.5.5 Gamesa Made AE-61-1320 KW Wind Turbine Guidance System
3.5.6 Gamesa Made AE-61-1320 KW Wind Turbine Foundation
3.5.7 Gamesa Made AE-61-1320 KW Wind Turbine Brake
3.5.8 Gamesa Made AE-61-1320 KW Wind Turbine Tower and Nacelle
3.5.9 Gamesa Made AE-61-1320 KW Wind Turbine Control system
3.5.10 Gamesa Wind Farms
3.6 Suzlon
3.6.1 Suzlon S52-600 kW
3.6.2 Suzlon S52-600 kW
3.6.3 Suzlon/REpower Systems AG
3.6.4 REpower Product Range
3.7 Nordex AG
3.7.1 Nordex N117 Wind Turbine
3.7.2 Nordex N150 (6 Megawatt) Offshore
3.7.3 Nordex N117 (2,4 Megawatt)
3.7.4 N100 (2.5 Megawatt)
3.7.5 Nordex N90 (2.5 Megawatt)
3.7.6 Nordex N82 (1.5 Megawatt)
3.7.7 Nordex N77 (1.5 Megawatt)
3.7.8 Nordex N150 (6 Megawatt) Offshore
3.7.9 Nordex N117 (2.4 Megawatt)
3.7.10 Nordex Third Generation Wind Turbines
3.7.11 Nordex N100 (2.5 Megawatt)
3.7.12 Nordex N100 (2.5 Megawatt)
3.7.13 Nordex Rotor
3.7.14 Nordex Drive train
3.7.15 Nordex Gearbox
3.7.16 Nordex Generator
3.7.17 Nordex Cooling And Filtration
3.7.18 Nordex Braking System
3.7.19 Nordex Nacelle
3.7.20 Nordex Yaw System
3.7.21 Nordex Tower
3.7.22 Nordex Control And Grid Connection
3.7.23 Nordex Lightning Protection
3.7.24 Nordex N90 (2.5 Megawatt)
3.7.25 Nordex N80 (2.5 Megawatt)
3.7.26 Nordex S82 (1.5 Megawatt)
3.7.27 Nordex S77 (1.5 Megawatt)
3.7.28 Nordex S70 (1.5 Megawatt)
3.8 Sinovel Wind Co., Ltd
3.8.1 Sinovel Wind Co SL6000
3.8.2 Sinovel Wind Co SL5000
3.8.3 Sinovel Wind Co SL1500
3.8.4 Sinovel SL3000 Series Wind Turbine
3.8.5 Sinovel SL1500 Series Wind Turbine
3.9 Acciona Wind Turbines
3.9.1 Acciona Windpower, A Global Supplier, Acciona Wind Turbines
3.9.2 Acciona Wind Turbine Assembly Plants
3.9.3 Acciona Wind turbines
3.9.4 Acciona Models
3.9.5 Acciona Working On Design
3.10 BP
3.10.1 BP Consortium Floating Wind Turbine Platform At Wave Hub Wave Energy Site On The South Coast Of England
3.11 United Technologies/Clipper
3.11.1 United Technologies/Clipper Liberty 2.5 MW Wind Turbine
3.12 Nacel Energy Corporation
3.13 Rooftop Wind Power
3.14 Urban Green Energy
3.15 CSIC Holdings/HZ Windpower Co., Ltd.
3.16 Wind Energy Solutions
3.17 Fuhrl nder Aktiengesellschaft
3.18 Winwind Ltd
3.19 Eoltec SAS
3.19.1 Wind Turbine Cost Reduction
3.19.2 Wind Turbine Prices
3.20 Goldwind Science & Technology
3.21 Kinglike Energy Technology
3.21.1 Dezhou Xinqu Renewable Energy Technology Co., ltd
3.22 LM Wind Power
3.22.1 LM Wind Power Group
3.23 Alaska Wind Turbine
3.24 Northern Power Systems
3.25 Qingdao Jintaida Industry&Trade Co., Ltd
3.26 LGC SkyRota
3.27 Nanjing Supermann Industrial &Trading Co., Ltd.
3.28 Wind Pacific (Aust) Pty Ltd
3.28.1 Wind Pacific Main Features of the MY1.5 series MW Wind Turbine
4. UTILITY SCALE WIND TURBINE TECHNOLOGY
4.1 Wind Turbines Take Over the Landscape
4.2 Design Of Wind Turbines
4.3 Wind Farms and Radar
4.4 Vestas Technologies Testing Capabilities
4.4.1 Vestas Blade Technology
4.4.2 Vestas Smart Controls
4.4.3 Vestas Research and Innovation
4.4.4 Vestas Stealth Research
4.4.5 Vestas Floating Foundations
4.5 Sinovel National Energy Offshore Wind Power
4.6 Enercon Wind Technology
4.7 Turbines Hybrid Gas-Wind Turbine System
4.8 How A Wind Turbine Works
4.8.1 Density Of Air
4.8.2 Rotor Area
4.8.3 Wind Speed
4.8.4 Centrifugal Pitch Control
4.8.5 Turbine Blade Materials
4.8.6 Wind Turbine Metal Components
4.8.7 Forged Parts
4.8.8 Cast Parts
4.8.9 Machined Parts
4.9 Barriers to Wind Turbine Market Entry
4.9.1 Wind Turbine Regulatory Concerns
4.9.2 Suzlon S52-600 kW Technology
4.10 US National Renewable Electricity Standard (RES)
4.10.1 A Renewable Electricity Standard (RES)
5. UTILITY GRADE WIND TURBINE COMPANY PROFILES
5.1 Mergers And Acquisitions
5.1.1 Suzlon’s Acquisition of REPower
5.1.2 Acciona Energy Sells 15% Share to Mitsubishi
5.1.3 United Technologies Completes Clipper Windpower Acquisition
5.1.4 Price Declines Drive Industry Consolidation
5.2 Acciona Energ a, s.a.
5.2.1 Acciona Wind Towers
5.2.2 Acciona Business Strategy
5.2.3 Acciona A World Leader In Renewables
5.2.4 Acciona (Navarre, Spain)
5.2.5 Ten Entities Finance Acciona's Eurus Windpark In Mexico With Usd375m
5.2.6 Acciona Energy Wind Parks in Mexico
5.2.7 Acciona Energy Wind power
5.2.8 Acciona Energy Implementation
5.2.9 Acciona Promoted Public-Private Alliances Between The UN And Business At The Davos Summit
5.2.10 Acciona Wind Park In Castilla-La Mancha (Spain)
5.2.11 Acciona 9M 2011 Results (January - September)
5.2.12 Acciona And Dhamma Energy Sign An Agreement To Develop 250 Mw Of Photovoltaic Power In France
5.2.13 Acciona Project Development
5.2.14 Acciona Wind Energy
5.2.15 Acciona Production
5.2.16 Acciona Photovoltaic
5.2.17 Acciona Other Facilities
5.2.18 Acciona Solar Thermal Power
5.2.19 AccionaFour Plants in Spain
5.2.20 Acciona Installations for Customers
5.2.21 Acciona Hydropower
5.3 AMSC
5.4 Blue Carbon Technology
5.5 BP
5.5.1 BP’s Operating US Wind Farms
5.5.2 Clipper Windpower And BP Alternative Energy Form Joint Venture To Develop Up To 5,050 Mw
5.5.3 British Energy BP Invests $800 Million In An Onshore Wind Farm In Kansas
5.6 CSIC holdings/HZ Windpower Co., Ltd.
5.7 Enercon
5.7.1 Enercon Wind Turbine Return on Investment (ROI)
5.8 Eolia Renovables
5.8.1 N+1 Eolia
5.9 Eoltec
5.10 Fuhrl nder Aktiengesellschaft
5.11 Gamesa Corporacion Tecnologica S.A.
5.11.1 Gamesa Integrated Response Presence In All Phases Of A Wind Project
5.11.2 Gamesa in Figures
5.11.3 Gamesa Strategic Vectors
5.11.4 Gamesa Installs A Further 52 MW in Spain
5.11.5 Gamesa Installs 10 MW in Mexico
5.11.6 Gamesa Wind Farm Business Plan
5.12 GE
5.12.1 GE Energy
5.12.2 GE Energy
5.12.3 General Electric Company Energy Infrastructure Revenues
5.12.4 GE Total Revenue
5.12.5 General Electric Geographic Revenues
5.12.6 GE and Göteborg Energi
5.12.7 GE‘s 4.1-113 Wind Turbine
5.12.8 General Electric Offers Wind Turbine Customers Clean Energy From Solar Panels
5.12.9 GE U.S. Wind Crash
5.12.10 GE Technology to Boost the Output of NextEra Energy Resources’ U.S. Fleet of Wind Turbines
5.12.11 GE Energy Financial Services
5.13 Goldwind
5.13.1 Goldwind Product Positioning
5.13.2 Goldwind Science & Technology Revenue
5.13.3 Goldwind 2011 3Q Revenue
5.13.4 Goldwind Acquires Two 10MW US Projects From Volkswind USA 5.13.5 Goldwind Signs Strategic Agreement with Export-Import Bank of China
5.14 Göteborg Kommunala/Göteborg Energi
5.15 Kinglike Energy Technology
5.16 LGC Skyrota Wind Energy
5.16.1 LGC Skyrota Wind Energy Acquires UK Wind Energy Business
5.17 LM Wind Power
5.18 Nacel Energy
5.18.1 Nacel Energy 200 Mw Gascoyne II Wind Power Project
5.19 Nanjing Supermann Industrial & Trading Co. Ltd.
5.20 NextEra
5.20.1 NextEra Energy Revenue
5.20.2 NextEra Energy Resources
5.21 Nordex AG
5.21.1 Nordex Awarded Contract For 30 MW Wind Farm in Spain
5.21.2 Nordex Revenue
5.22 Northern Power Systems
5.23 Qingdao
5.23.1 Qingdao Jintaida Industrial & Trade Co., Ltd.
5.24 Rooftop Wind Power
5.25 Siemens
5.25.1 Siemens Wind Power A/S –
5.25.2 Siemens Health Care Sector
5.25.3 Siemens Revenue
5.25.4 Siemens Geographic Analysis
5.25.5 Siemens Energy Revenue
5.26 Sinovel
5.26.1 Sinovel Contracts With Brazilian Renewable Power Generating Company Desenvix
5.26.2 Sinovel Revenue
5.26.3 Chinese Wind-Turbine Prices Have Declined
5.26.4 Sinovel Confronting Legal Claims Of More Than $1.2 Billion USD In End Of Relationship With American Superconductor Corporation (AMSC)
5.26.5 Sinovel The Largest Producer Of Wind Turbines In China
5.26.6 Sinovel Wind Group Co., Ltd
5.26.7 Sinovel Provides Clean Energy And Power The World
5.27 Standard Steel Inc/Alaska Wind Turbine
5.27.1 Standard Steel/Alaskan Wind Industries
5.28 Suzlon Energy Limited
5.28.1 Suzlon Energy Limited Revenue
5.28.2 Suzlon Energy Limited
5.28.3 Suzlon Acquires REpower
5.28.4 Suzlon Starts In Textile Industry
5.28.5 Suzlon Wins 19.2 MW Repeat Order From The Baidyanath Group
5.28.6 Suzlon in India
5.28.7 Suzlon Supplies the Malpani Group
5.28.8 Suzlon/Repower/REpower Systems AG – REpower USA Corp.
5.28.9 Suzlon/REpower 5M Largest Wind Turbine Size Of Two Soccer Fields
5.28.10 Suzlon/REpower Renewable Projects
5.28.11 Suzlon/REpower International
5.29 Shanghai Donghai Bridge 102MW Offshore Wind Farm Pilot Project
5.30 The Switch
5.31 TuuliWatti Oy
5.32 United Technologies
5.32.1 United Technologies/Clipper Windpower
5.32.2 UTC/Clipper Wind Projects
5.32.3 Clipper Receives Warranty, Technology and Sales Support from UTC
5.32.4 Clipper Windpower
5.32.5 Clipper Windpower Liberty Wind Turbine
5.33 Urban Green Energy
5.34 Vestas
5.34.1 Vestas Revenue
5.34.2 Vestas World Leader In Wind Technology
5.34.3 Vestas Wind
5.34.4 Vestas Strengthens Its Position In Finland 5.34.5 Vestas Offshore Project in Belgium
5.34.6 Vestas Project in Kenya
5.34.7 Vestas Signs 51 MW Order in Poland 5.34.8 Vestas Orders From Key Account EDF Energies Nouvelles
5.34.9 Vestas Order For 18 Units Of The V90-3.0 Mw Wind Turbine For The UK.
5.34.10 Vestas Enters Pakistan with 50 MW Order From the Zorlu Energy Group
5.34.11 Vestas China V100 Order Is For A Total Of 48.6 MW
5.34.12 Vestas Order 570 MW in California, USA 5.34.13 Vestas Shipments
5.35 Wind Energy Solutions by Winwind
5.35.1 WinWinD
5.36 Yingli Green Energy
5.37 Selected Wind Industry Associations and Regulators
LIST OF TABLES AND FIGURES
Table ES-1 Wind Turbine Market Driving Forces
Figure ES-2 Utility Grade Wind Turbine Market Shares, Dollars, 2011
Figure ES-3 Utility Scale Wind Turbine Market Shipments Forecasts Dollars, Worldwide, 2012-2018
Figure 1-1 Wind Farm Generates Electricity
Figure 1-2 Wind Turbine Size Range
Figure 1-3 How a Wind Turbine Comes Together
Table 1-4 Benefits of Wind Power for Utilities
Table 2-1 Wind Turbine Market Driving Forces
Figure 2-2 Utility Grade Wind Turbine Market Shares, Dollars, 2011
Table 2-3 Utility Grade Wind Turbine Market Shares, Dollars, Worldwide, 2011
Figure 2-4 Wind Turbine Market Shares, Shipped Turbines, Installed Turbines, Installed Megawatts, Worldwide, 2010 and 2011
Figure 2-5 Wind Turbine Market Shares, Shipped Turbines, Installed Turbines, Installed Megawatts, Worldwide, 2009 and H1 2010
Table 2-6 Wind Turbine Market Shares, Shipped Megawatts and Dollars Per Worldwide, 2011
Figure 2-7 Gamesa Wind Energy Market Outlook
Table 2-8 Eoltec Instrument Realizations And Measurement Solutions
Figure 2-9 Utility Scale Wind Turbine Market Shipments Forecasts Dollars, Worldwide, 2012-2018
Table 2-10 Wind Turbine Market Forecasts, Dollars, Worldwide, 2012-2018
Figure 2-11 Cost of Energy Analysis
Figure 2-12 Gamesa Capacity Adjustment Outlook and Risks
Figure 2-13 Gamesa Cost of Energy Analysis
Table 2-13a Wind Turbine Market Shares, Shipped Megawatts and Dollars Per Turbine Worldwide, 2012
Table 2-14 Utility Scale On Shore and Off Shore Wind Turbines Dollars and Percent, Worldwide, 2012-2018
Figure 2-15 Onshore Utility Scale Wind Turbines Market Forecasts Dollars, Worldwide, 2011-2018
Figure 2-16 Offshore Utility Scale Wind Turbines Market Forecasts Dollars, Worldwide, 2011-2018
Figure 2-17 US Wind Power Transmission of 400 Gigawatts
Figure 2-18 Utility Scale Wind Turbine Regional Market Segments, 2009
Table 2-19 Utility Scale Wind Turbine Regional Market Segments, 2011
Figure 2-20 Texas Cost Benefits of Wind Transmission
Table 2-21 States With The Largest Percentage Of Wind Generation
Table 2-22 US State Percentage of Electricity from Wind Generation In 2011
Figure 2-23 US Wind Turbine Capacity
Figure 2-24 German wind Turbine Market Participation, Enercon Leadership Position Illsutrated
Figure 2-25 Emerging Wind Turbine Markets Drive Growth
Figure 2-26 Gamesa Targets China, India, and the US
Figure 2-27 Gamesa View of Wind Turbine Emerging Market and World Market Opportunity
Figure 2-28 Emerging Wind Turbine Markets Drive Growth: India
Figure 2-29 Emerging Wind Turbine Markets Drive Growth: Latin America
Figure 2-30 Gamesa Emerging Wind Turbine Markets Drive Growth: India and Latin America
Figure 2-31 Acciona Operational Aw Wind Turbines Worldwide
Figure 3-1 Vestas Pitch Regulated System
Table 3-2 Vestas V52-850 kW Turbine Specifications
Table 3-2 (Continued) Vestas V52-850 kW Turbine Specifications
Figure 3-3 Vestas Onshore Wind Power Systems
Figure 3-4 Vestas On Shore – Off Shore Wind Generator Positioning
Figure 3-5 Vesta Offshore Wind Power Systems
Figure 3-6 Vestas Offshore Wind Power Systems
Figure 3-7 Vestas Offshore Wind Power Systems Specifications
Figure 3-8 Vestas Handling Wind Turbine Blades
Figure 3-9 Vestas Thanet Offshore
Figure 3-10 Vestas Geography of the Thanet Offshore Wind Farm
Table 3-11 GE Wind Turbine Products
Figure 3-12 GE 2.5 - 100 Wind turbine
Figure 3-13 GE2.5 MW Wind Turbine
Figure 3-14 GE 2.75 - 100 Wind Turbine
Table 3-15 GE 2.75 - 100 Wind Turbine Features
Figure 3-16 GE 2.75 - 103 Wind Turbine
Table 3-17 Wind Energy at GE Positioning
Table 3-18 Siemens Wind Turbine Product Set
Figure 3-19 Siemens Wind Turbine Design
Figure 3-20 Enercon Wind Turbine
Figure 3-21 Enercon E-82 Table 3-22 Enercon E82 Specifications
Table 3-22 (Continued) Enercon E82 Specifications
Figure 3-23 Enercon Drive Train With Generator
Figure 3-24 Gamesa Wind Turbine
Figure 3-25 Gamesa Wind Turbines
Table 3-26 Gamesa. Platform models
Table 3-27 Advantages of the Gamesa G10X-4.5 MW Platform
Table 3-28 Gamesa G5X 850 kW Wind Turbine
Table 3-29 Advantages of the Gamesa G5X-850 kW Platform
Table 3-30 Gamesa Made AE-61-1320 KW Wind Turbine Benefits
Figure 3-31 Gamesa Wind Farms
Figure 3-32 Gamesa Outlook: Higher Energy Security, Lower CO2 Emissions
Figure 3-33 Suzlon S52-600 kW
Figure 3-34 Suzlon Wind Turbines
Figure 3-35 Suzlon S52-600 kW Wind Turbine Specifications
Figure 3-36 Nordex N117 Wind Turbine
Figure 3-37 Nordex N150 (6 Megawatt) Offshore Wind Turbine
Table 3-38 Nordex N117/2400 Wind Turbine For Low-Wind Sites
Table 3-38 (Continued) Nordex N117/2400 Wind Turbine For Low-Wind Sites
Table 3-38 (Continued) Nordex N117/2400 Wind Turbine For Low-Wind Sites
Figure 3-39 Nordex N100/2500 Largest Turbine In The Product Line
Figure 3-40 Sinovel Wind Turbine
Figure 3-41 Sinovel SL6000 Wind Turbine
Figure 3-42 Sinovel SL5000 Wind Turbine
Figure 3-43 Sinovel SL6000 Wind Turbine
Figure 3-44 Sinovel Wind Turbines
Table 3-45 AW Turbine Family Functions
Figure 3-46 Acciona AW-3000 Wind Turbine
Figure 3-47 Acciona AW-1500 Wind Turbine
Figure 3-48 Acciona AW-1500 Wind Turbine
Figure 3-49 Acciona AW-3000 Wind Turbine
Figure 3-50 Acciona AW-3000 Wind Turbine Features
Figure 3-51 Acciona AW-3000 Wind Turbine
Figure 3-52 Acciona AW-3000 Wind Turbine Interior Components
Figure 3-53 BP Energy Sherbino Mesa Wind Project
Figure 3-54 BP Floating Wind Turbine Platform
Figure 3-55 Clipper Wind Turbine Manufacturing
Table 3-56 United Technologies/Clipper Liberty 2.5 MW Wind Turbine Design Components
Figure 3-57 United Technologies/Liberty Wind Turbine at a Glance
Figure 3-58 United Technologies/Clipper Wind Turbine Features
Figure 3-59 Rooftop Wind Power Building Design
Figure 3-60 Rooftop Wind Power Commercial Installation
Figure 3-61 Urban Green Energy Eddy
Figure 3-62 Urban Green Energy Wind Turbine Energy Generated
Figure 3-63 CSIC Holdings/HZ Windpower Turbine
Figure 3-64 CSIC Holdings/HZ Windpower Turbine 2MW, Double-Fed, Germanisher Lloyd Certified Wind Turbines.
Figure 3-65 WES, Wind Energy Solutions BV Wind Turbine
Figure 3-66 Eoltec's 6KW Wind Turbine
Table 3-67 Eoltec Product Features
Figure 3-68 Eoltec Aerodynamic Design, Simulation And Analysis:
Figure 3-69 Eoltec Sealed Slewing Rings For Blades And Yawing, Sealed Centrifugal Pitch
Figure 3-70 Goldwind Science & Technology Wind Turbine
Figure 3-71 Goldwind Wind Farms
Figure 3-72 Dezhou Kinglike Energy Technology Co., Ltd. Hybrid Solar and Wind Units
Figure 3-73 Alaska Wind Turbine Examples
Figure 3-73 (Continued) Alaska Wind Turbine Examples
Figure 3-74 Qingdao Jintaida Industry&Trade Wind Turbine
Figure 3-75 Qingdao Jintaida Industry&Trade Vertical Wind Turbine, Source: Qingdao Jintaida Industry&Trade
Figure 3-76 Qingdao Jintaida Industry&Trade Wind Turbines
Figure 3-77 Wind Pacific (Aust) Pty Ltd Wind Turbine
Figure 3-78 Wind Pacific (Aust) Pty Ltd
Figure 3-79 Wind Pacific (Aust) Pty Ltd Turbine Components
Figure 4-1 US Wind Energy Capacity
Figure 4-2 Enercon Wind Technology
Figure 4-3 Kinetic Energy From Wind Converted to Electrical Energy
Figure 4-4 Key Components of a Wind Turbine
Table 4-5 Barriers to Wind Turbine Market Entry
Figure 4-6 Wind Turbine Regulatory and Government Support Outlook
Figure 4-7 Wind Turbine Regulatory and Government Support Outlook: Asia
Figure 4-8 Wind Turbine Regulatory and Government Support Outlook: Latin America and Africa
Figure 4-9 Wind Turbine Regulatory Concerns
Figure 4-10 Value of Renewable Wind Energy as Resource
Figure 4-11 Suzlon S52-600 kW Technology Power Curve
Figure 5-1 Acciona Energy Sells 15% Share to Mitsubishi
Table 5-2 Acciona Three Lines Of Business
Table 5-3 Acciona Range Of Renewable Energy Sources
Figure 5-4 Acciona Energy Operational AW Wind Turbines Worldwide
Figure 5-5 Acciona Corporate Structure
Figure 5-6 Acciona Breakdown of Installed Capacity and Production by Technology
Figure 5-7 Acciona Total Wind Installations
Figure 5-8 Acciona Energy Sells 15% Share to Mitsubishi
Table 5-9 Wind Power Capacity Installed By Acciona Energy By Country
Table 5-10 Photovoltaic Capacity Installed By Acciona Solar (MWp)
Table 5-11 CSP Plants Operated by Acciona Energy
Table 5-12 Hydropower Capacity Owned by Acciona Energy in Spain
Table 5-13 Acciona Divisions
Figure 5-14 BP Wind Power Farms
Figure 5-15 CSIC Holdings/HZ Windpower Turbine
Figure 5-16 CSIC Holdings/HZ Windpower Turbine 2MW, Double
Fed, Germanisher Lloyd Certified Wind Turbines.
Table 5-17 Enercon Production Statistics
Table 5-18 Enercon Installed Base Worldwide
Figure 5-19 Enercon Installed Capacity
Figure 5-20 Enercon Wind Turbine Return on Investment (ROI)
Figure 5-21 Gamesa Managing Complexity
Figure 5-22 Gamesa Product Portfolio Key to Delivery of Volume Growth
Figure 5-23 Gamesa Wind Farm Business Plan
Figure 5-24 Gamesa Wind Farm CoE Optiimization
Figure 5-25 Gamesa Wind New Market Opening Linked to CoE Optimization
Figure 5-26 Gamesa Wind Key Milestones
Figure 5-27 Gamesa Wind Farm Efficiency
Table 5-28 Gamesa Key Performance Indicators
Table 5-29 Gamesa Key Performance Indicators, 2010
Figure 5-30 Nordex Efficiency Class
Figure 5-31 Nordex Efficiency Class Wind Turbines
Figure 5-32 Nordex Wind Market Development
Figure 5-33 Rooftop Wind Power Building Design
Figure 5-34 Rooftop Wind Power Commercial Installation
Figure 5-35 Exciting and Challenging Time in Healthcare for Siemens
Figure 5-36 Siemens Geographic Analysis
Figure 5-37 Siemens Revenue by Industry Segment
Table 5-38 Sinovel Key Development Strategies
Figure 5-39 Sinovel Technology R&D
Figure 5-40 Sinovel Factory
Figure 5-41 Suzlon/REpower Exclusive Turbine Supplier of Talisman Energy (UK) and Scottish & Southern Energy (SSE) Project
Figure 5-42 United Technologies Revenue by Segment, 2011
Figure 5-43 Clipper Windpower Manufacturing
Figure 5-44 Vestas Wind Generators
Table 5-45 Vestas Revenue for 2011
Figure 5-46 Vestas Wind Generator
Figure 5-47 Vestas Wind Turbines
Figure 5-48 Vestas Wind Generators
Figure 5-49 Wind Pacific (Aust) Pty Ltd Turbine Features
Table ES-1 Wind Turbine Market Driving Forces
Figure ES-2 Utility Grade Wind Turbine Market Shares, Dollars, 2011
Figure ES-3 Utility Scale Wind Turbine Market Shipments Forecasts Dollars, Worldwide, 2012-2018
Figure 1-1 Wind Farm Generates Electricity
Figure 1-2 Wind Turbine Size Range
Figure 1-3 How a Wind Turbine Comes Together
Table 1-4 Benefits of Wind Power for Utilities
Table 2-1 Wind Turbine Market Driving Forces
Figure 2-2 Utility Grade Wind Turbine Market Shares, Dollars, 2011
Table 2-3 Utility Grade Wind Turbine Market Shares, Dollars, Worldwide, 2011
Figure 2-4 Wind Turbine Market Shares, Shipped Turbines, Installed Turbines, Installed Megawatts, Worldwide, 2010 and 2011
Figure 2-5 Wind Turbine Market Shares, Shipped Turbines, Installed Turbines, Installed Megawatts, Worldwide, 2009 and H1 2010
Table 2-6 Wind Turbine Market Shares, Shipped Megawatts and Dollars Per Worldwide, 2011
Figure 2-7 Gamesa Wind Energy Market Outlook
Table 2-8 Eoltec Instrument Realizations And Measurement Solutions
Figure 2-9 Utility Scale Wind Turbine Market Shipments Forecasts Dollars, Worldwide, 2012-2018
Table 2-10 Wind Turbine Market Forecasts, Dollars, Worldwide, 2012-2018
Figure 2-11 Cost of Energy Analysis
Figure 2-12 Gamesa Capacity Adjustment Outlook and Risks
Figure 2-13 Gamesa Cost of Energy Analysis
Table 2-13a Wind Turbine Market Shares, Shipped Megawatts and Dollars Per Turbine Worldwide, 2012
Table 2-14 Utility Scale On Shore and Off Shore Wind Turbines Dollars and Percent, Worldwide, 2012-2018
Figure 2-15 Onshore Utility Scale Wind Turbines Market Forecasts Dollars, Worldwide, 2011-2018
Figure 2-16 Offshore Utility Scale Wind Turbines Market Forecasts Dollars, Worldwide, 2011-2018
Figure 2-17 US Wind Power Transmission of 400 Gigawatts
Figure 2-18 Utility Scale Wind Turbine Regional Market Segments, 2009
Table 2-19 Utility Scale Wind Turbine Regional Market Segments, 2011
Figure 2-20 Texas Cost Benefits of Wind Transmission
Table 2-21 States With The Largest Percentage Of Wind Generation
Table 2-22 US State Percentage of Electricity from Wind Generation In 2011
Figure 2-23 US Wind Turbine Capacity
Figure 2-24 German wind Turbine Market Participation, Enercon Leadership Position Illsutrated
Figure 2-25 Emerging Wind Turbine Markets Drive Growth
Figure 2-26 Gamesa Targets China, India, and the US
Figure 2-27 Gamesa View of Wind Turbine Emerging Market and World Market Opportunity
Figure 2-28 Emerging Wind Turbine Markets Drive Growth: India
Figure 2-29 Emerging Wind Turbine Markets Drive Growth: Latin America
Figure 2-30 Gamesa Emerging Wind Turbine Markets Drive Growth: India and Latin America
Figure 2-31 Acciona Operational Aw Wind Turbines Worldwide
Figure 3-1 Vestas Pitch Regulated System
Table 3-2 Vestas V52-850 kW Turbine Specifications
Table 3-2 (Continued) Vestas V52-850 kW Turbine Specifications
Figure 3-3 Vestas Onshore Wind Power Systems
Figure 3-4 Vestas On Shore – Off Shore Wind Generator Positioning
Figure 3-5 Vesta Offshore Wind Power Systems
Figure 3-6 Vestas Offshore Wind Power Systems
Figure 3-7 Vestas Offshore Wind Power Systems Specifications
Figure 3-8 Vestas Handling Wind Turbine Blades
Figure 3-9 Vestas Thanet Offshore
Figure 3-10 Vestas Geography of the Thanet Offshore Wind Farm
Table 3-11 GE Wind Turbine Products
Figure 3-12 GE 2.5 - 100 Wind turbine
Figure 3-13 GE2.5 MW Wind Turbine
Figure 3-14 GE 2.75 - 100 Wind Turbine
Table 3-15 GE 2.75 - 100 Wind Turbine Features
Figure 3-16 GE 2.75 - 103 Wind Turbine
Table 3-17 Wind Energy at GE Positioning
Table 3-18 Siemens Wind Turbine Product Set
Figure 3-19 Siemens Wind Turbine Design
Figure 3-20 Enercon Wind Turbine
Figure 3-21 Enercon E-82 Table 3-22 Enercon E82 Specifications
Table 3-22 (Continued) Enercon E82 Specifications
Figure 3-23 Enercon Drive Train With Generator
Figure 3-24 Gamesa Wind Turbine
Figure 3-25 Gamesa Wind Turbines
Table 3-26 Gamesa. Platform models
Table 3-27 Advantages of the Gamesa G10X-4.5 MW Platform
Table 3-28 Gamesa G5X 850 kW Wind Turbine
Table 3-29 Advantages of the Gamesa G5X-850 kW Platform
Table 3-30 Gamesa Made AE-61-1320 KW Wind Turbine Benefits
Figure 3-31 Gamesa Wind Farms
Figure 3-32 Gamesa Outlook: Higher Energy Security, Lower CO2 Emissions
Figure 3-33 Suzlon S52-600 kW
Figure 3-34 Suzlon Wind Turbines
Figure 3-35 Suzlon S52-600 kW Wind Turbine Specifications
Figure 3-36 Nordex N117 Wind Turbine
Figure 3-37 Nordex N150 (6 Megawatt) Offshore Wind Turbine
Table 3-38 Nordex N117/2400 Wind Turbine For Low-Wind Sites
Table 3-38 (Continued) Nordex N117/2400 Wind Turbine For Low-Wind Sites
Table 3-38 (Continued) Nordex N117/2400 Wind Turbine For Low-Wind Sites
Figure 3-39 Nordex N100/2500 Largest Turbine In The Product Line
Figure 3-40 Sinovel Wind Turbine
Figure 3-41 Sinovel SL6000 Wind Turbine
Figure 3-42 Sinovel SL5000 Wind Turbine
Figure 3-43 Sinovel SL6000 Wind Turbine
Figure 3-44 Sinovel Wind Turbines
Table 3-45 AW Turbine Family Functions
Figure 3-46 Acciona AW-3000 Wind Turbine
Figure 3-47 Acciona AW-1500 Wind Turbine
Figure 3-48 Acciona AW-1500 Wind Turbine
Figure 3-49 Acciona AW-3000 Wind Turbine
Figure 3-50 Acciona AW-3000 Wind Turbine Features
Figure 3-51 Acciona AW-3000 Wind Turbine
Figure 3-52 Acciona AW-3000 Wind Turbine Interior Components
Figure 3-53 BP Energy Sherbino Mesa Wind Project
Figure 3-54 BP Floating Wind Turbine Platform
Figure 3-55 Clipper Wind Turbine Manufacturing
Table 3-56 United Technologies/Clipper Liberty 2.5 MW Wind Turbine Design Components
Figure 3-57 United Technologies/Liberty Wind Turbine at a Glance
Figure 3-58 United Technologies/Clipper Wind Turbine Features
Figure 3-59 Rooftop Wind Power Building Design
Figure 3-60 Rooftop Wind Power Commercial Installation
Figure 3-61 Urban Green Energy Eddy
Figure 3-62 Urban Green Energy Wind Turbine Energy Generated
Figure 3-63 CSIC Holdings/HZ Windpower Turbine
Figure 3-64 CSIC Holdings/HZ Windpower Turbine 2MW, Double-Fed, Germanisher Lloyd Certified Wind Turbines.
Figure 3-65 WES, Wind Energy Solutions BV Wind Turbine
Figure 3-66 Eoltec's 6KW Wind Turbine
Table 3-67 Eoltec Product Features
Figure 3-68 Eoltec Aerodynamic Design, Simulation And Analysis:
Figure 3-69 Eoltec Sealed Slewing Rings For Blades And Yawing, Sealed Centrifugal Pitch
Figure 3-70 Goldwind Science & Technology Wind Turbine
Figure 3-71 Goldwind Wind Farms
Figure 3-72 Dezhou Kinglike Energy Technology Co., Ltd. Hybrid Solar and Wind Units
Figure 3-73 Alaska Wind Turbine Examples
Figure 3-73 (Continued) Alaska Wind Turbine Examples
Figure 3-74 Qingdao Jintaida Industry&Trade Wind Turbine
Figure 3-75 Qingdao Jintaida Industry&Trade Vertical Wind Turbine, Source: Qingdao Jintaida Industry&Trade
Figure 3-76 Qingdao Jintaida Industry&Trade Wind Turbines
Figure 3-77 Wind Pacific (Aust) Pty Ltd Wind Turbine
Figure 3-78 Wind Pacific (Aust) Pty Ltd
Figure 3-79 Wind Pacific (Aust) Pty Ltd Turbine Components
Figure 4-1 US Wind Energy Capacity
Figure 4-2 Enercon Wind Technology
Figure 4-3 Kinetic Energy From Wind Converted to Electrical Energy
Figure 4-4 Key Components of a Wind Turbine
Table 4-5 Barriers to Wind Turbine Market Entry
Figure 4-6 Wind Turbine Regulatory and Government Support Outlook
Figure 4-7 Wind Turbine Regulatory and Government Support Outlook: Asia
Figure 4-8 Wind Turbine Regulatory and Government Support Outlook: Latin America and Africa
Figure 4-9 Wind Turbine Regulatory Concerns
Figure 4-10 Value of Renewable Wind Energy as Resource
Figure 4-11 Suzlon S52-600 kW Technology Power Curve
Figure 5-1 Acciona Energy Sells 15% Share to Mitsubishi
Table 5-2 Acciona Three Lines Of Business
Table 5-3 Acciona Range Of Renewable Energy Sources
Figure 5-4 Acciona Energy Operational AW Wind Turbines Worldwide
Figure 5-5 Acciona Corporate Structure
Figure 5-6 Acciona Breakdown of Installed Capacity and Production by Technology
Figure 5-7 Acciona Total Wind Installations
Figure 5-8 Acciona Energy Sells 15% Share to Mitsubishi
Table 5-9 Wind Power Capacity Installed By Acciona Energy By Country
Table 5-10 Photovoltaic Capacity Installed By Acciona Solar (MWp)
Table 5-11 CSP Plants Operated by Acciona Energy
Table 5-12 Hydropower Capacity Owned by Acciona Energy in Spain
Table 5-13 Acciona Divisions
Figure 5-14 BP Wind Power Farms
Figure 5-15 CSIC Holdings/HZ Windpower Turbine
Figure 5-16 CSIC Holdings/HZ Windpower Turbine 2MW, Double
Fed, Germanisher Lloyd Certified Wind Turbines.
Table 5-17 Enercon Production Statistics
Table 5-18 Enercon Installed Base Worldwide
Figure 5-19 Enercon Installed Capacity
Figure 5-20 Enercon Wind Turbine Return on Investment (ROI)
Figure 5-21 Gamesa Managing Complexity
Figure 5-22 Gamesa Product Portfolio Key to Delivery of Volume Growth
Figure 5-23 Gamesa Wind Farm Business Plan
Figure 5-24 Gamesa Wind Farm CoE Optiimization
Figure 5-25 Gamesa Wind New Market Opening Linked to CoE Optimization
Figure 5-26 Gamesa Wind Key Milestones
Figure 5-27 Gamesa Wind Farm Efficiency
Table 5-28 Gamesa Key Performance Indicators
Table 5-29 Gamesa Key Performance Indicators, 2010
Figure 5-30 Nordex Efficiency Class
Figure 5-31 Nordex Efficiency Class Wind Turbines
Figure 5-32 Nordex Wind Market Development
Figure 5-33 Rooftop Wind Power Building Design
Figure 5-34 Rooftop Wind Power Commercial Installation
Figure 5-35 Exciting and Challenging Time in Healthcare for Siemens
Figure 5-36 Siemens Geographic Analysis
Figure 5-37 Siemens Revenue by Industry Segment
Table 5-38 Sinovel Key Development Strategies
Figure 5-39 Sinovel Technology R&D
Figure 5-40 Sinovel Factory
Figure 5-41 Suzlon/REpower Exclusive Turbine Supplier of Talisman Energy (UK) and Scottish & Southern Energy (SSE) Project
Figure 5-42 United Technologies Revenue by Segment, 2011
Figure 5-43 Clipper Windpower Manufacturing
Figure 5-44 Vestas Wind Generators
Table 5-45 Vestas Revenue for 2011
Figure 5-46 Vestas Wind Generator
Figure 5-47 Vestas Wind Turbines
Figure 5-48 Vestas Wind Generators
Figure 5-49 Wind Pacific (Aust) Pty Ltd Turbine Features
