Aurich, Germany
Aurich, Germany

Enercon GmbH, based in Aurich, Lower Saxony, Germany, is the fourth-largest wind turbine manufacturer in the world and has been the market leader in Germany since the mid-nineties. Enercon has production facilities in Germany , Sweden, Brazil, India, Canada, Turkey and Portugal. In June 2010, Enercon announced that they would be setting up Irish headquarters in Tralee.As of July 2011, Enercon had installed more than 22,000 wind turbines, with a power generating capacity exceeding 32.9 GW. The most-often installed model is the E-40, which pioneered the gearbox-less design in 1993. As of July 2011, Enercon has a market share of 7.2% world-wide and 59.2% in Germany.Enercon currently supplies wind turbines to the British electricity company Ecotricity, including one billed as the UK's most visible turbine, an E-70 at Green Park Business Park. Wikipedia.

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Wulff A.,Applied Information Sciences | Wunck C.,Applied Information Sciences | Backhuss T.,Enercon Gmbh
Proceedings of the International Conference on Industrial Engineering and Operations Management | Year: 2017

Collecting, processing and analyzing massive amounts of data embodies a steadily growing challenge for many companies. The ability to generate new knowledge from big data volumes nowadays represents a critical success factor. However, the capacity, capabilities and programming methods of currently existing IT-systems are unsuitable to handle big data processing and analysis tasks. An augmentation of traditional IT-systems with solutions that are sufficient for big-data storage and analysis is difficult and expensive. Furthermore existing IT-staff usually lacks the necessary expertise in installing and operating big data computing centers and applications. Therefore, it seems obvious to adopt a cloud approach. Several providers of cloud-based services meanwhile offer comprehensive big data solutions and appropriate analysis services. A study conducted since 2014 examines the applicability of selected cloud platforms for data analysis tasks under special consideration of functionality, service models, costs, security, performance and scalability. The results deliver a catalogue of selection criteria and a comparison of analysis services for selected cloud platforms. The well-documented comparison is conducted on the basis of the use case "Analysis of failure data from wind energy plants". It delivers templates for cloud-based big data analysis operation, but also depicts risks and limitations of cloud-based solutions. © IEOM Society International.


Engelken S.,WRD GmbH | Mendonca A.,WRD GmbH | Fischer M.,Enercon Gmbh
IET Renewable Power Generation | Year: 2017

Requirements for inertial response (IR) from wind turbines (WTs) have been implemented or drafted by power systems (PSs) operators worldwide. This is a response to the replacement of conventional power plants using synchronous generators by non-synchronous, power electronics-based generation and the resulting effect on frequency dynamics in the case of contingency events. The additional active power provided during operation in IR mode must be drawn from the rotating masses. A re-acceleration accompanied by reduced active power output follows the activation phase. The allowed depth and duration of the post-inertial recovery will be regulated in future versions of grid codes, e.g. in Québec and Ireland. This study describes an improved version of an IR control system that enables a more PSs-friendly provision of such short-term frequency support. The new controls allow adjusting the duration of the recovery period. Potential negative effects of IR from WTs on the PS in the form of a second frequency nadir during the recovery phase can be minimised. The outcome of simulations and of field testing will be presented. All results shown in this study include the initial and the future inertia emulation performance which allows easy comparison of the two controls. © 2017 The Institution of Engineering and Technology.


News Article | November 21, 2016
Site: www.newsmaker.com.au

Global Wind Energy market is estimated to be $155 billion in 2015 growing at a CAGR of 9.9% to reach $301.3 billion by the year 2022. The rising applications of wind energy technology and depletion of fossil fuel has lead to high growth of the wind energy market. Lack of technical people and high initial costs are the factors hindering the market growth. Asia Pacific accounted for the largest share in the market due to growing electricity consumption in developing countries such as Russia, Brazil and India. The offshore market is expected to be the largest market segment. Some of the key players in global wind energy market include Sinovel Wind Co.Ltd, China Mingyang Wind Power Group Ltd., Gamesa Corporation Technologica, Guodian United Power Technology Co., Ltd., CSIC Haizuhang Windpower equipment co.ltd., Vestas Wind Systems A/S, Goldwind Science & technology co.ltd , Enercon Gmbh, Suzlon Energy Ltd., GE Energy, Siemens Wind Power A/S and Nordex SE . Applications Covered:  • Large, non-grid connected  • Large, Grid connected  • Small, non-grid connected  • Small, grid connected  Regions Covered:  • North America  o US  o Canada  o Mexico  • Europe  o Germany  o France  o Italy  o UK  o Spain  o Rest of Europe  • Asia Pacific  o Japan  o China  o India  o Australia  o New Zealand  o Rest of Asia Pacific  • Rest of the World  o Middle East  o Brazil  o Argentina  o South Africa  o Egypt What our report offers:  - Market share assessments for the regional and country level segments  - Market share analysis of the top industry players  - Strategic recommendations for the new entrants  - Market forecasts for a minimum of 7 years of all the mentioned segments, sub segments and the regional markets  - Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)  - Strategic recommendations in key business segments based on the market estimations  - Competitive landscaping mapping the key common trends  - Company profiling with detailed strategies, financials, and recent developments  - Supply chain trends mapping the latest technological advancements About Us Wise Guy Reports is part of the Wise Guy Consultants Pvt. Ltd. and offers premium progressive statistical surveying, market research reports, analysis & forecast data for industries and governments around the globe. Wise Guy Reports understand how essential statistical surveying information is for your organization or association. Therefore, we have associated with the top publishers and research firms all specialized in specific domains, ensuring you will receive the most reliable and up to date research data available.


News Article | December 2, 2016
Site: www.newsmaker.com.au

According to Stratistics MRC, the Global Wind Energy market is estimated to be $155 billion in 2015 growing at a CAGR of 9.9% to reach $301.3 billion by the year 2022. The rising applications of wind energy technology and depletion of fossil fuel has lead to high growth of the wind energy market. Lack of technical people and high initial costs are the factors hindering the market growth. Asia Pacific accounted for the largest share in the market due to growing electricity consumption in developing countries such as Russia, Brazil and India. The offshore market is expected to be the largest market segment. http://www.strategymrc.com/report/wind-energy-market-2016 Some of the key players in global wind energy market include Sinovel Wind Co.Ltd, China Mingyang Wind Power Group Ltd., Gamesa Corporation Technologica, Guodian United Power Technology Co., Ltd., CSIC Haizuhang Windpower equipment co.ltd., Vestas Wind Systems A/S, Goldwind Science & technology co.ltd , Enercon Gmbh, Suzlon Energy Ltd., GE Energy, Siemens Wind Power A/S and Nordex SE. Types Covered: • Onshore • Offshore Turbine Types Covered: • Savonius    • Vertical axis • Giromill • Horizontal Axis • Vortexis • Darrieus Applications Covered: • Large, non-grid connected • Large, Grid connected • Small, non-grid connected • Small, grid connected     Regions Covered: • North America o US o Canada o Mexico • Europe o Germany o France o Italy o UK  o Spain      o Rest of Europe  • Asia Pacific o Japan        o China        o India        o Australia        o New Zealand       o Rest of Asia Pacific       • Rest of the World o Middle East o Brazil o Argentina o South Africa o Egypt What our report offers: - Market share assessments for the regional and country level segments - Market share analysis of the top industry players - Strategic recommendations for the new entrants - Market forecasts for a minimum of 7 years of all the mentioned segments, sub segments and the regional markets - Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations) - Strategic recommendations in key business segments based on the market estimations - Competitive landscaping mapping the key common trends - Company profiling with detailed strategies, financials, and recent developments - Supply chain trends mapping the latest technological advancements


Grant
Agency: European Commission | Branch: FP7 | Program: CP | Phase: ENERGY-2007-2.3-04 | Award Amount: 6.17M | Year: 2008

This action focuses on demonstrating the development of a cost-effective large scale high capacity wind park using new state-of-the-art multi megawatt turbines coupled with innovative technology used to stabilize the grid. A key objective of the 7-MW-WEC-by-11 project is to introduce a new power class of large-scale Wind Energy Converters, the 7MW WEC, onto the market which has the potential to significantly contribute to higher market penetration levels for wind electricity in Europe. The new 7MW WEC will be designed and demonstrated at a large scale: eleven such WECs will be demonstrated in a 77 MW wind park close to Estinnes (Belgium). The wind park will be the first large-scale on-shore wind park in Belgium and the first in the world that will consist of this mega turbine power class. Key challenges related to wind power will be addressed in this demonstration action ranging from technical issues (network stability and security), to financial aspects (cost effectiveness) to environmental issues (landscape pollution). First, the mega turbines will be developed and installed in series; this is envisioned to significantly reduce costs and increase the market value. Second, new power electronics technology and improved wind forecasting will be used to stabilise the grid in the high capacity wind park. Improved forecasting is envisioned to furthermore improve the cost-effectiveness of the high capacity wind park (reduced imbalance costs, improved commercial value). Third, the 7MW turbines will be used to maximize wind energy capacity, while reducing landscape pollution and environmental impact: such a WEC generates more than double the energy in the same given area when compared to conventional 2MW turbines and requires the placement of fewer turbines when compared to conventionally used wind turbines. Lessons learned in developing the high capacity Estinnes wind park will be adapted to a different national context with a weak grid system, Cyprus.


News Article | November 7, 2016
Site: marketersmedia.com

— The Global Wind Tower Market Research Report to 2021 is a professional and in-depth study on the current state of the Wind Tower Market. This report studies Wind Tower in Global market, especially in North America, China, Europe, Southeast Asia, Japan, India focuses on top manufacturers in global market, with production, price, revenue and market share for each manufacturer, covering CS Wind Corp, Enercon Gmbh, Shanghai Taisheng Wind Power Equipment, Trinity Structural Towers, Vestas A/S and Windar Renovables. Market Segment by Region, this report splits Global into several key Region, with sales, revenue, market share and growth rate of Wind Tower in these regions, from 2011 to 2021 (forecast), like North America, China, Europe, Japan, India, Southeast Asia. Wind Tower Market Split by application, this report focuses on consumption, market share and growth rate of Wind Tower in each application, can be divided into Application 1, Application 2, Application 3. View more details about this report @ http://www.reportsweb.com/global-wind-tower-market-research-report-2016 . Few points from Table of Contents 4 Global Wind Tower Supply (Production), Consumption, Export, Import by Regions (2011-2016) 4.1 Global Wind Tower Consumption by Regions (2011-2016) 4.2 North America Wind Tower Production, Consumption, Export, Import by Regions (2011-2016) 4.3 Europe Wind Tower Production, Consumption, Export, Import by Regions (2011-2016) 4.4 China Wind Tower Production, Consumption, Export, Import by Regions (2011-2016) 4.5 Japan Wind Tower Production, Consumption, Export, Import by Regions (2011-2016) 4.6 Southeast Asia Wind Tower Production, Consumption, Export, Import by Regions (2011-2016) 4.7 India Wind Tower Production, Consumption, Export, Import by Regions (2011-2016) 5 Global Wind Tower Production, Revenue (Value), Price Trend by Type 5.1 Global Wind Tower Production and Market Share by Type (2011-2016) 5.2 Global Wind Tower Revenue and Market Share by Type (2011-2016) 5.3 Global Wind Tower Price by Type (2011-2016) 5.4 Global Wind Tower Production Growth by Type (2011-2016) 6 Global Wind Tower Market Analysis by Application 6.1 Global Wind Tower Consumption and Market Share by Application (2011-2016) 6.2 Global Wind Tower Consumption Growth Rate by Application (2011-2016) 6.3 Market Drivers and Opportunities 6.3.1 Potential Applications 6.3.2 Emerging Markets/Countries 7 Global Wind Tower Manufacturers Profiles/Analysis 7.1 CS Wind Corp 7.1.1 Company Basic Information, Manufacturing Base and Its Competitors 7.1.2 Wind Tower Product Type, Application and Specification 7.1.2.1 Type I 7.1.2.2 Type II 7.1.3 CS Wind Corp Wind Tower Production, Revenue, Price and Gross Margin (2015 and 2016) 7.1.4 Main Business/Business Overview 7.2 Enercon Gmbh 7.2.1 Company Basic Information, Manufacturing Base and Its Competitors 7.2.2 Wind Tower Product Type, Application and Specification 7.2.2.1 Type I 7.2.2.2 Type II 7.2.3 Enercon Gmbh Wind Tower Production, Revenue, Price and Gross Margin (2015 and 2016) 7.2.4 Main Business/Business Overview 7.3 Shanghai Taisheng Wind Power Equipment 7.3.1 Company Basic Information, Manufacturing Base and Its Competitors 7.3.2 Wind Tower Product Type, Application and Specification 7.3.2.1 Type I 7.3.2.2 Type II 7.3.3 Shanghai Taisheng Wind Power Equipment Wind Tower Production, Revenue, Price and Gross Margin (2015 and 2016) 7.3.4 Main Business/Business Overview For more information, please visit http://www.reportsweb.com/global-wind-tower-market-research-report-2016


A hydropower plant has been operating again in Bremen-Hemelingen since 2011. Due to the tidal range at the Weserwehr, the turbine technology was designed to meet constant changes in fall height as well as to adjust too large flow changes during the course of the year. This paper comprises the specifics of the location and illustrates the operating experience gathered from the prototype of the ENERCON S-pipe turbine since commissioning.


Quitmann E.,Enercon Gmbh | Erdmann E.,Enercon Gmbh
IET Renewable Power Generation | Year: 2015

Grid codes are the key for the technical performance of any new installed generating plant. In order to successfully manage the transition towards a more sustainable power system (PS), the technical rules applied to all kinds of generation must be suitable still in years and decades from now. The challenge is to estimate today which technical feature will be crucial for the stable operation of the PS, in light of a generation mix that changes from centralised, relatively large power plants using synchronous generators connected to the transmission grid, towards a decentralised, mainly inverter-based generation mix, that uses volatile renewable sources. This study is based on experiences in central Europe and several countries overseas. It does not refer to one specific market but attempts to learn from the past and give qualitative ideas how the technical system needs of today and the future should be addressed in any PS. A quantitative analysis of future PS needs is what the authors wish to encourage as a next step. © The Institution of Engineering and Technology 2015.


Trademark
Enercon Gmbh | Date: 2011-08-16

Metal hanger system comprised of steel cables and connectors used to suspend lights, electrical and mechanical components within structures.


Trademark
Enercon Gmbh | Date: 2011-03-22

Wind turbines and parts and components therefor, namely, wind and diesel driven electrical energy apparatus for conversion of wind to electric energy in the nature of wind-powered electricity generators, frequency converters, inverter motors, electrical generators, and electrical motors; pylons, hubs, rotor blades and rotors all specially adapted for use with wind turbines; repair cranes. Connecting parts for electric lines, namely, electrical connectors, aerials, electrical transformers, power lines in the nature of electric cables, electrical circuit closers, circuit breakers, ampere meters, electroacoustic transducers, commutators, electric controllers for wind turbines, electric control panels for wind farms, electrical wires, inverters, switching equipment for wind turbines and wind-powered electricity generators, electrolysis equipment for electroplating purposes, storage devices for electrical power, namely, batteries, capacitors, accumulators, and condensers, electric cables, telecommunication towers all of the foregoing goods for assembling and operating wind farms, solar power plants, and water power plants, and for connecting wind farms, solar power plants, and water power plants to the power grid, and for managing wind farms, solar power plants, and water power plants. Concrete building materials, namely, blocks, bricks, posts, poles, slabs, panels and pylons, all of the foregoing for the construction of wind turbines and water power plants; fireproof building materials of concrete, namely, blocks, bricks, posts, poles, slabs, panels, pylons, and door and window casings, all of the foregoing for the construction of wind turbines and water power plants; non-metal posts, non-metal utility pole masts, non-metal fences, non-metal pipes and tubes of concrete, and non-metal cladding, all of the foregoing for the construction of wind turbines and water power plants.

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