Aerodynamics Considerations in Wind Turbine Blade Design
Blade design is one of the most important & complex process in the development of improved and more efficient wind turbines and hence the development of wind industry as such. Advances in aerodynamic design advances has over the years contributed towards that end.
Though ideally, to obtain best results from a perfect blade designed to extract maximum power
from wind, it should have a perfect aerodynamic design. Viewing the requirements of extracting
maximum power at minimum costs pragmatically, leads to necessitating numerous compromises, influenced by various factors.
The major factors that influence design of a practically adequate blade are:
– Economics to ensure costs under control
-Â Structural Strength to take care of bending stresses (maximum at root), aerodynamic &
structural dynamic loads
-Â Noise & Aesthetic considerations
-Â Choice of materials; carbon versus fibre glass; availability of desired material
-Â Manufacturing Processes adopted
The blade needs to be robust enough to survive forces acting on them due to the variability of wind, to include varying wind velocities, facing gusty conditions to an extent, centrifugal & centripetal forces and other conditions that are rarely optimal.
Over the years, with the continuous development of larger & more efficient Wind Turbines, a variety of blade designs & materials have got introduced, mainly through trial & error, resulting in the most popular 3-bladed composite blade designs, each better than the other.
The choice of blade aerofoils, chords, twist distribution, blade tip & root configurations, use of spoilers, use of vortex generators for noise control &/ or enhancing aerodynamic efficiencies, are a result of compromises being made from conflicting considerations. The dictating requirements could be, need for blade stiffness/ flexibility, Solidity of rotor disc, aerofoil thickness, maximising lift coefficients, minimising drag, roughness tolerance. To sum it all, the design considerations are numerous and at times conflicting leading to the need for an intelligent compromise.
The aerofoil is the foundation of wind turbine blade designs & hence its optimisation goes a long way in achieving the three objectives of aerofoil design, namely, aerodynamic performance of the blade, Noise control & its structural robustness.
Selection of Aerofoil Sections along the Blade Length
In the early stages of development of wind turbine blade designs, NACA series of aerofoils, which were basically developed for use in aviation industry were used mainly because of their inherent design of high lift Coefficients and low Drag Coefficients, (High Lift to Drag ratio). However, it was quickly recognised, that there were numerous drawbacks which glaringly stood out while they were being used for high performance blade designs wind turbines. This led to the development of a number of specially designed aerofoils for wind turbines. These included:
- American S Series airfoil
- Dutch DU Series
- Swedish FFA-W series
- Danish RisF series airfoil
While a number of research papers are available, describing the utility of each of the aerofoil sections, their suitability for use at specific Tip speeds, Lift coefficients, L/D ratios, structural properties, and noise characteristics, in order to grasp the nuances of each of these designs, certain basics of loads on a wind turbine blade and specifically an aerofoil section would be necessary and the same are briefly introduced in subsequent paragraphs.
Forces Acting on the Blade
Fig 1 : Forces Acting on Blade Section of a Horizontal Axis Wind Turbine
Figure 1 above depicts a wind turbine, viewed from top. (Plan View). Details are explained below:
– The direction of rotation is clockwise as seen from front end, as indicated.
– Aerofoil section of one blade has been shown.
– As it is understood, the turbine is designed to face the wind squarely and the ambient wind velocity vector impinging the aerofoil section is shown by the blue arrow.
– Since the blade is rotating, the instantaneous tangential velocity of blade is considered. The relative wind velocity vector due to motion of the blade will be opposite to the blade tangential velocity vector.
– Resultant of the two wind velocity vectors impinging on the aerofoil section, (the actual relative velocity vector) is shown as a red arrow.
– The angle between the chord of the aerofoil section and the relative velocity vector is called the angle of attack. (âº)
– Angle of Attack has a great significance on aerodynamic performance of an aerofoil. A brief
bringing out its significance is explained subsequently.
– Lift generated is perpendicular to the relative wind velocity vector, and perpendicular to the lift is the drag. (in the same direction of the relative wind velocity). The same are depicted in Figure 1.
– Resultant of Lift & Drag forces is the “Net Aerodynamic Force on Bladeâ€.
– This “Net Aerodynamic Force on Blade†is resolved into two mutually perpendicular forces. These are (a) the Torque Force that Rotates the Rotor & (b) the thrust force, which acts along the axis of rotation. This force is the design element for finalising the bearing design.
Significance of Angle of Attack
It can be appreciated that the aerofoil sections move at faster speeds as we move from root to the tip of the blade (V=r w). While the ambient wind speed remains the same. The effect of this would be, that the angle of attack at various aerofoil sections all along the length of the blade from root to tip will progressively change. The necessity of giving a twist to the blade as we move from the root to tip of the blade is shown in the Figure 2 below.
If there is no twist, the angle of attack would have large variations all along the length of the blade and hence, only a section of the blade will generate optimal lift and the most of it will be either stalled of producing low lift and therefore working at sub-optimal levels. By giving the twist, the most efficient angle of attack, (see Fig 3) for each aerofoil section all along the blade length is obtained. This leads to an overall performance level of the blade to be enhanced/ optimised.
Fig 2: Showing the necessity of twisting the blade
The production of lift force due to the aerodynamic shape of the blade depends on a number of factors like the blade profile, shape, thickness, camber, aspect ratio and the surface finish of the blade, which must be in consonance with the designed rpm, tip speed ratio, solidity and the magnitude of lift coefficient.
Fig: 3 Indicating that an aerofoil section performs at peak performance levels (at CL max) for a very narrow range of the value of Angle of Attack. Beyond the max level it stalls and before that the blade efficiency rapidly drops.
 The complete mechanism of production of lift and various other modifications to enhance blade aerodynamic performance will be covered in my next blog.
- Published in Uncategorized
What makes a good wind power site?
There are 5 key characteristics of a good wind power site that you need:
A high average wind speed. Typically the site would be on top of a hill or in a wide open space with no obstructions nearby.
Sufficient separation from noise-sensitive neighbours. Modern wind turbines are remarkably quiet, but even so there are very stringent maximum noise levels that have to be met to obtain planning consent. The minimum separation varies depending on the turbine size.
Good grid connection. All of the wind turbines require a suitable three-phase electrical supply to connect to. As a rough guide you will need an 11 kV transformer or substation that is roughly double the rated power output of the wind turbine you are considering, or an 11 kV three-phase power line passing close to the wind turbine site that can have a new transformer / substation connected to it.
The larger multi-MW turbines could grid connect to 33 kV power lines, though generally it is too expensive for sub-1MW wind turbine projects to connect at such a high voltage.
Good site access. Wind turbines are large and heavy, so the access roads and tracks to the site need to be capable of taking oversize loads with no weak bridges, excessively tight corners or steep gradients. Obviously as the proposed turbine gets larger, the size of the constituent parts that have to be delivered get larger and the access requirements more stringent. The smaller Endurance 55 kW turbine is delivered on standard articulated lorries, but all of the others come on special oversize trailers.
No special environmental or landscape designations. A lot of the older objections to wind turbines due to bird strikes have now been shown to be unfounded, but even so it would be good practice to not install a wind turbine(s) in an area that had special bird designations. Peat bog is also generally a no-go area for wind turbines.
Wind turbines are very visible within the landscape, so sites with landscape designations such as National Parks or Areas of Outstanding Natural Beauty (AONB) will have more difficulty obtaining planning consent, though it is still possible to get planning consent in AONBs.
Article source: https://www.renewablesfirst.co.uk/windpower/windpower-learning-centre/what-makes-a-good-wind-power-site/
- Published in Renewable Energy Sector News
RE Industry – PAA Awards 2019
PAA Award was all about honoring the O&M field workmen who with their own hands have developed the industry as well as developing their own profile. So this honor comes to them for which PAA Awards have been instated and PAA Award 2019. This function was held in Pune on 24th Oct.
Out of 500+ RE industry Nominations, 12 most deserving candidates were chosen by the jury panel of 9 and felicitated for their stupendous work.
Among the 12 Awardees, 5 have been honored gold, 4 silver and 2 as rising stars.
Here is the list of Awardees: –
- Mr. Tejas Sole – The Go-getter 2019: Gold Award
- Mr. Dhananjay Nandedkar – The Innovative Mind 2019: Gold Award
- Mr. Nivas Vallavan – The Troubleshooter 2019: Gold Award
- Mr. Bushan Palhade – The safety & Quality Combo 2019: Gold Award
- Mr. Yogesh Bochare – The Skill Developer 2019: Gold Award
- Mr. Manoj M.SÂ – The Go-getter 2019: Silver Award
- Raman Sharma (Currently with Siemens Gamesa)- The Go-getter 2019: Silver Award
- Mr. Agastya Sagar (Currently with Sagar Asia Private Limited)- The Innovative Mind – 2019: Silver Award
- Mr. Pankajkumar Bhagwan Suryawanshi (Currently with ReGen) – The Troubleshooter 2019: Silver Award
- Mr. Shanmukha Srinivasa Kumar Bathina (Currently with Greenko Wind Power) – The Skill Developer 2019: Silver Award .
- Mr. Deepak Nair (Currently with Clean Max Enviro Energy Solutions Pvt Ltd.) – The Skill Developer 2019: Rising Star Award.
Apart from the RE industry Awardees, the inhouse 30 Power group members countrywide were also felicitated with respective PAA Awards in recognition of their contribution.
- Published in Uncategorized
How Much Wind Energy Need in Your City?
The world’s first floating wind farm is generating electricity off the coast of Scotland. Now, a new research project estimates the amount of sea-based wind generation that will be necessary to power major cities, giving leaders and citizens new data to assess their renewable energy options.
Researchers estimate that wind farms have the technical potential to produce up to 40 times the electricity the world consumes. Yet they provide only 4 percent of the world’s electricity today. Imagine having all that surplus energy. We could power carbon removal technologies with this excess electricity. We could remove the trillion tons in excess CO2 from the atmosphere with energy left to spare.
Improved infrastructure and higher voltage cables are driving wind power costs to new lows. It is predicted that by 2040, one-third of power will come from wind and solar.
Let’s take a look at how many wind turbines would be needed to power the world’s major cities. Call your legislators or city government to encourage them to explore the land- and ocean-based wind power for your community.
The top five places that need the most wind turbines to power their major city:
- Tokyo, Japan, needs 10,310 offshore wind turbines.
- New York City, U.S., needs 3,687 offshore wind turbines.
- Seoul, South Korea, needs 3,644 offshore wind turbines.
- Shanghai, China, needs 3,304 offshore wind turbines.
- Los Angeles, U.S., needs 1,818 offshore wind turbines.
The top five cities with the biggest offshore areas, in square kilometers (km2), of wind turbines needed to power them:
- Tokyo, Japan, would need 10,620 km2 of space to power the city with wind turbines.
- New York City, U.S., would need 3,797 km2 of space to power the city with wind turbines.
- Seoul, South Korea, would need 3,752 km2 of space to power the city with wind turbines.
- Shanghai, China, would need 3,402 km2 of space to power the city with wind turbines.
- Los Angeles, U.S., would need 1,872 km2 of space to power the city with wind turbines.
It seems that Asia is the continent that is most hungry for a renewable energy source; Tokyo, Seoul, and Shanghai are among the top five major cities that could use the most wind turbines to power their city.
But what about the cities that don’t need a lot to power them?
The top five cities with the smallest offshore areas (km2) of wind turbines needed to power them:
- Milan, Italy, would need 244 km2 of offshore space to power the city with wind turbines.
- Kuala Lumpur, Singapore, would need 293 km2 of offshore space to power the city with wind turbines.
- Barcelona, Spain, would need 307 km2 of offshore space to power the city with wind turbines.
- Mumbai, India, would need 355 km2 of offshore space to power the city with wind turbines.
- San Francisco, U.S., would need 373 km2 of offshore space to power the city with wind turbines.
The top five places that need the least wind turbines to power their major city:
- Milan, Italy, needs 238 offshore wind turbines.
- Kuala Lumpur, Singapore, needs 286 offshore wind turbines.
- Barcelona, Spain, needs 299 offshore wind turbines.
- Mumbai, India, needs 346 offshore wind turbines.
- San Francisco, U.S., needs 363 offshore wind turbines.
It may come as a surprise that San Francisco is one of the major cities that needs the least amount of wind turbines to power its population, as well as Mumbai, as they both have a very large population. Take a look at the following interactive graph and see where your nearest major city comes in at and how many wind farms it would take to power its population.
% of City Area
km2Â of wind turbines
- Published in Renewable Energy Sector News, Uncategorized
Turbine suppliers invest in multi-brand services as competition mounts
Wind turbine suppliers are investing in supply chain solutions and combining new technologies with data advantages to win service contracts for third-party turbines, leading suppliers told the Wind Operations Dallas 2019 conference.
As intense price competition squeezes margins, turbine suppliers are targeting a greater share of the growing operations and maintenance (O&M) market.
Annual investments in wind operations and maintenance (O&M) in U.S. and Canada will rise from a current level of $5 billion-$6 billion to $7.5 billion by 2021, eclipsing capex spending for the first time, IHS Markit said in a report published in 2018.
O&M providers are using economies of scale, improved spare parts strategies and the latest sensor and data analytics technologies to reduce costs.
Rising turbine capacities are also reducing maintenance costs and widening the range of operational technology. The number of turbine models installed in the U.S. rose from around 100 in 2010 to 146 in 2018.
Original Equipment Manufacturers (OEMs) are now focusing on multi-brand service contracts to increase their share of the O&M market, leading OEM groups told the conference in Dallas on April 16.
OEMs are expanding data and supply chain capabilities and widening training programs to accommodate multiple turbine brands, the groups said.
“Multi-brand is a key focus for our customers,” Marco Molina, Americas Services Sales Director at GE Renewable Energy, said.
“We are in the process over the past year of listening, developing and shaping responses to work in that arena,” he said.
Maintenance focus
Falling capital costs have increased the importance of wind O&M and boosted competition in the services sector.
Global prices for initial full-service contracts fell from an average $26,400/MW/year in 2016 to $18,100/MW/yr in 2018, according to the BloombergNEF (BNEF) Wind O&M Pricing Index. In some markets, contracts are trading at far lower levels, BNEF data shows.
In the O&M market, OEMs compete against independent service providers (ISPs) and operators’ in-house O&M teams.
New speciality O&M suppliers are also emerging, focusing services on certain major components such as gearboxes, generators or blades, Oliver Metcalfe, wind power analyst at BloombergNEF (BNEF), told the Wind O&M EU 2019 conference in February.
The emergence of these firms allows asset managers to sign a lower cost O&M contract and call on the specialist maintenance groups to perform major component work when necessary, Metcalfe noted.
“This means that if you are an asset manager, you can optimize your operations and maintenance strategy according to your desired level of risk,” he said.
Forecast North American wind opex vs capex
OEM service providers benefit from growing global databases of learnings from deployed assets. Combined with data analytics this enables them to maximize gains from preventative and predictive maintenance.
Leading suppliers are also investing in advanced automation and robotics technologies and solutions which remove crane requirements.
New technologies such as thermal imaging blade inspection equipment are providing valuable insights, Denver Bane, Onshore Wind Services Strategy Leader at GE Renewable Energy, told the Dallas conference.
Machine learning can be used to process the images and provide a report to customers within 24 to 48 hours which shows which blades have anomalies and provides recommended remedies, Bane said.
“This technology is incredible…it allows you to inspect blades that are actually running… With that thermal capability we can see subsurface and surface anomalies,” he said.
Going forward, GE aims to use advanced sensors and automation to develop prognostics for all failure modes, Bane said.
“In the next one to five years you are going to see turbines coming online with more sensors and capabilities in that regard than ever before and we are going to have better analytics and machine learning to make sense of that data stream,” he said.
Supply challenge
OEMs must implement efficient processes to procure third-party turbine parts to minimize downtimes for multi-brand services, Darnell Walker, CEO Services Americas at Siemens Gamesa Renewable Energy, said.
“Supply chain is one of the key issues that we have had to deal with,” Darnell said.
Siemens Gamesa currently maintains 900 turbines supplied by other manufacturers, including some U.S. assets. The contracts represent over 1 GW of global installed capacity.
On April 4, Siemens Gamesa signed its first full-scope multi-brand service contract for the 34 MW Lukaszow and 24 MW Modlikowice wind farms in western Poland. The wind farms comprise of 29 Vestas V90 wind turbines which have been operational since 2012.
Siemens Gamesa will provide O&M services for 23 years, guaranteeing the life of the turbines for a total of 30 years.
The technical engineering of third-party turbine components has been less of a challenge than expected, but expansion into new regions requires efficient local sourcing processes, Darnell told the conference.
“The thing that we felt that we have to really get honed in on is locally sourcing parts…[so that] we get those manufactured by local people in the region that we service,” he said.
Training up
OEMs are also expanding repair capabilities to reduce downtimes and widen O&M opportunities.
In one example, GE has invested in training and tooling for gearbox repairs at its Wind Energy Learning Center in Niskayuna, NY, Molina said.
“We have a dedicated team- a repairs engineering team. They are partnered with the product line and they are constantly working to develop expanded capabilities in that space,” he said.
Going forward, suppliers will need to pursue a diversified approach to services, incorporating hybrid plant technologies as well as multiple wind turbine models, Michael Petersen, Director of Services, Canada & Eastern USA at Siemens Gamesa Renewable Energy, said.
Wind technicians may need to develop competencies in solar and battery systems, he noted.
Hybrid wind, PV and storage plants are on the rise as owners look to maximize returns and mitigate intermittency amid growing wind and solar capacity.
In February, Portland General Electric (PGE) and NextEra Energy Resources agreed to a build 380 MW wind-solar-storage plant in Oregon.
The Wheatridge Renewable Energy Facility will be the largest ‘hybrid’ renewable plant in the U.S., incorporating 300 MW of wind capacity, 50 MW of PV solar and 30 MW of battery storage. GE Renewable Energy will supply 120 wind turbines to the project.
New technologies should help accelerate the learning process and widen the expertise of technicians.
Augmented reality combined with handheld devices can provide detailed real-time guidance for turbine repairs, accelerating complex tasks and increasing technicians’ learning curves, Bane told the conference.
“Instead of taking five to 10 years for a technician to gain the [necessary] experience, we could see technicians productive after one or two years using tools like these,” he said.
Source – New Energy Update
- Published in Renewable Energy Sector News
India’s top 9 states by installed wind power capacity!
India is at the cusp of a renewable energy revolution. The government has already set an ambitious target to achieve 175 gigawatt (GW) of renewable energy capacity by 2022.
Keeping the target in mind, states have already started ramping up their installed solar and wind powered capacity.
1.Tamil Nadu
Tamil Nadu tops the list of states with the largest installed wind power generation capacity in the country. The state’s total wind capacity at the end of 2018 stood at 8,631 Mw while its total installed electricity generation capacity stood at 30,447 Mw at the end of 2018, with wind sector’s share at 28.34 percent.
2.Gujarat
Gujarat houses the second-largest installed wind power generation capacity in the country. The state’s total wind capacity at the end of 2018 stood at 6,044 Mw while its total installed electricity generation capacity stood at 31,382 MW at the end of 2018, with the wind sector’s share at 19.25 per cent.
3.Maharashtra
Maharashtra houses the third-largest installed wind power generation capacity in the country. The state’s wind capacity at the end of 2018 stood at 4,789 Mw while its total installed power generation capacity stood at 43,779 Mw at the end of 2018, with the wind sector’s share at 11 per cent.
4.Karnataka
Karnataka houses the fourth-largest installed wind power generation capacity in the country. The state’s wind capacity at the end of 2018 stood at 4,584 Mw while its total installed power generation capacity stood at 27,199 Mw at the end of 2018, with the wind sector’s share at 17 per cent.
5.Rajasthan
Rajasthan houses the fifth-largest installed wind power generation capacity in the country. The state’s wind capacity at the end of 2018 stood at 4,300 Mw while its total installed electricity generation capacity stood at 21,833 Mw at the end of 2018, with the wind sector’s share at 20 per cent.
6.Andhra Pradesh
Andhra Pradesh houses the sixth-largest installed wind power generation capacity in the country. The state’s wind capacity at the end of 2018 stood at 4,007 Mw while its total installed electricity generation capacity stood at 23,726 Mw at the end of 2018, with the wind sector’s share at 17 per cent.
7.Madhya Pradesh
Madhya Pradesh houses the seventh largest installed wind power generation capacity in the country. The state’s wind capacity at the end of 2018 stood at 2,520 Mw while its total installed electricity generation capacity stood at 21,873 Mw at the end of 2018, with the wind sector’s share at 11.52 per cent.
8.Telangana
Telangana’s installed wind capacity at the end of 2018 stood at 128 Mw while its total installed power generation capacity stood at 15,944 Mw at the end of 2018, with the wind sector’s share at 0.80 per cent.
9.Kerala
Kerala’s installed wind capacity at the end of 2018 stood at 53 Mw while its total installed power generation capacity stood at 5,083 Mw at the end of 2018, with the wind sector’s share at 1.04 per cent.
[Source: Economics Times]
- Published in Uncategorized
EU countries call for 100% renewable energy by 2050
The European Union’s 28 energy ministers had their first public debate on the European Commission’s 2050 climate plan on Monday (4 March) but five member states derided the lack of a 100% renewable energy scenario among the EU executive’s proposed options.
The Commission’s Clean Planet for All strategy, which debuted in November 2018, offers EU countries eight different emission-cutting scenarios to make Europe’s economy compliant with the Paris Agreement on climate change by mid-century.
EU member states are expected to dissect the plan and decide what option they want to adopt this year.
Luxembourg’s energy minister, Claude Turmes, kicked off proceedings by telling his colleagues that “you can forget six out of eight of the scenariosâ€, dismissing them as inadequate to stick to the Paris deal.
Turmes also criticized the other two options, which aim for net-zero emission cuts by 2050, for lacking transparency and urged the Commission to reveal the figures and statistics behind its conclusions.
“The Juncker Commission is suggesting that we should build 50 or 60 new nuclear reactors by 2050. It’s not a good neighborly policy with which to threaten EU citizens,†said the former member of the European Parliament from Luxembourg.
He added that the lack of a 100% renewable energy option is also problematic and suggested that an honest debate about the EU’s future energy and climate policy cannot be held while the strategy is “incompleteâ€.
A few member states, including Spain, have already announced that they are aiming for a completely renewable electricity system, but Turmes was referring to a 100% renewable energy system, which includes heating, cooling, transport and other drains on power.
The Luxembourger was joined in his call by his Austrian, Irish, Lithuanian and Spanish counterparts, while Finnish minister Kimmo Tiilikainen said his country aims to use its stint in charge of the EU presidency later this year to adopt conclusions.
EU governments effectively have carte blanche to do as they wish with the Commission’s document, as it is not a legally binding text. EURACTIV understands that Luxembourg or any other member states could propose the renewables option themselves if they put the work in.
Next top model
Some energy experts have actually already done that work for the Commission and modeled their own examples of pan-European and even global energy systems that run exclusively on renewables.
Danish academic Dr. Brian Vad Mathiesen is one of those experts and he told EURACTIV that he was “genuinely surprised that the Commission did not include this option in the first placeâ€.
He also agreed with Claude Turmes’ assessment that it will be difficult to have a proper debate about 2050 without a 100% scenario, questioning why the EU executive “did not go the full Monty. A lot of technology is going to change by 2050.â€
Mathiesen also said that the Commission’s first six scenarios can be ignored and that its two most ambitious scenarios, which focus on the circular economy and negative emissions tech like carbon capture, are essentially not that different to one another.
“To have a debate on this you need to look at full renewables penetration of transport, heating, cooling. Everything. There need to be more options,†he concluded.
Researchers from Finland’s Lappeenranta University of Technology (LUT) recently unveiled their own model of a 100% system, which would involve 20 independent European regions or “islands†connected together through a “super gridâ€.
Study author Christian Breyer welcomed that EU ministers now have the idea on their radars and told EURACTIV that “100% renewable energy is the only option†because nuclear energy costs and developing carbon-capture-storage are too expensive.
He added that the LUT study is just one example of a whole raft of peer-reviewed studies that show how clean energy systems can be rolled out.
At the energy council’s Monday meeting, several ministers mentioned the concept of ‘energy prosumers’. Breyer’s study includes the effect of citizens that both produce and consume power in its model. The findings showed that it would lower costs across the continent.
Monday’s Energy Council meeting was the second chance for ministers to share their views on the Commission’s draft strategy after a competition council began the process earlier this year. The third open debate on the 2050 plan will be held on Tuesday (5 March) when environment ministers hash out the draft strategy.
EU leaders will meet in Romania on 9 May and are expected to put their cards on the table ahead of a landmark UN summit in September on climate change.
Article Sources -Â EURACTIV.com
- Published in Renewable Energy Sector News
New IT Enabled Asset Management System For Wind Farm Owners !
Learn how POWERCON’s IT enabled Asset Management System helps Wind Farm Owners in achieving greater business results?
Traditionally, wind assets are hooked to SCADA systems, which have a far greater potential than the extent to which they are presently being utilized. The wind power plant during its operation continually reveals massive knowledge in the form of data, which unfolds the story of its performance.
O&M professionals with hands-on experience in the field of Wind Technology are able to devise dashboards & formulate algorithms to steer plant operations remotely or on the go. Integration of multiple makes, models or capacities of assets, from different technologies like wind, solar, etc., are placed on a single software platform.
Utilising these inputs with a remote communication infrastructure & centrally located data center forms the basis of POWERCON’s IT enabled asset management system.
The possibilities & results from such set up are –
- Getting the wind power plants for ‘online real time monitoring’ on the desktops or handhelds enhances coordinated efforts among the field & central teams facilitating quick restoration, QA & vigilance. This results in reduced down time, increased availability & hence an opportunity to harness more.
- Use of turbine data for ‘analytics’ would focus attention on power performance issues and trigger actions for alignments, corrections or improvements as necessary to achieve full functionality commensurate with certified power curve. Result— the inexplicable contributors towards energy loss get eliminated, thereby increasing operational efficiency and hence increase in yield is obtained.
- The time stamped data correlation for ‘diagnostics’ could identify the failure elements & elementary or compounded causes of failure. Result – combat & reduce failures, build component reliability hence obtain increased technical availability
- Correlation diagnostics & trend analysis of historic data could enable ‘predictive analytics’ using a site-specific self-learning logic. This could provide reasonably good fortune-teller / predictor capability for the asset base. Result – proactive preparedness resulting in prevention of prospective losses. A step towards futuristic maintenance trends of developing neural networks for self-corrective actions.
- Bigger capacity wind power plants (multiples of 100 MW) could have ‘remote Command & Control’ enablement to ramp up/down production levels, manage grid bottleneck, reset faults or warnings, switch on/off or set power levels. Result – reduce losses due to load shedding commands, responsive management hence optimized yield.
The orientation or transformation to a well-equipped asset management system provides avenues to manage performance at ease and importantly makes O&M interesting…. Thus you have a dedicated clutch and control for optimization of the park performance.
Author: Â Praveen Kakulte, CEO
For more information about our O&M Services and Asset Optimization Services …click here
- Published in Renewable Energy Sector News, Wind Power Technology
PowerFul Annual Awards (PAA) Winners- 2018!
The most awaited event “PowerFul Annual Awards (PAA) – 2018â€, was held on 4th Nov 2018, at Ambrosia Resort, Pune during the POWER Group’s Annual Gathering “PowerFul Annual Bash -2018â€
The POWER Group of Companies honoured the contribution and exemplary teamwork of PowerTeam members countrywide, who have put in distinct work and efforts in making the Wind & Solar Asset Owners happy & proud with an exceptional performance of their assets!
15 Star Performers were conferred the coveted Awards during this function. Following is a list of the Awardees which also indicates their specific achievements for which they were felicitated:
1.Man with The Eagle Eye – 2018: Mr. Sachin Patil, was conferred the title in appreciation of his alertness & detective ability in ‘Arresting Incipient Failures of Wind Assets’.
2. Safety & Quality Combo – 2018: Mr. Stephanose John, was adjudged as the right fit for the award in appreciation for Quality Workmanship in Repairs & Maintenance of Generators.
.3. The Safety Icon – 2018: Mr. Jotiba Patil, who has been Meticulous in Enforcement of Safety Standards was adjudged as the Safety Icon at Khandke field Operations.
4. The Go-Getter – 2018: Mr. Shrikant Sharma was appreciated for an exemplary performance in ensuring Meticulous Management of Balance of Plant (BOP), at sites across Ahmednagar. Left no stone unturned to ensure the highest performance levels of his team.
5. Mr. Dependable – 2018: This award was conferred upon 3 members, who were found to be highly dependable in performance of their duties :
a) Mr. Abdul Razak, was given this award is in appreciation for establishing an excellent Technical Support System, resulting in exemplary performance of Site that he leads.
b)Mr. Pravin Hiremath, was appreciated, specifically for Building Technical Resources for Centre for Engineering Excellence, which has led to certain outstanding contributions in an extremely short period of time.
c) Mr. Gaurav S, was awarded in appreciation for Meticulous Planning & Execution of Solar PV Projects
6. The Silent Contributor – 2018:
Akshay Savat, was given this award to appreciate his consistent efforts for Effective & Strong support in Managing Book of Accounts.
7. The Trouble-shooter – 2018: Three members were awarded this title for Perfection in Fault Diagnosis & its Resolution
8. Mr. Adaptable – 2018: Two members were conferred with this award in appreciation of their Long-proven & Guaranteed availability – Anytime, Anywhere, for Any Work!!!
9.The Balanced Personality – 2018: Two members of the PowerTeam were conferred with this award in appreciation for their meticulous & efficient Team Management, resulting in an exemplary performance of their respective sites:
Our sincere gratitude towards One & All for being an integral part of PowerTeam’s journey!
- Published in Company News
World Reaches 1,000GW of Wind and Solar, Keeps Going
Bloomberg NEF data indicate that the world has attained the landmark figure of 1TW of wind and solar generation capacity installed. We estimate that the second terawatt of wind and solar will arrive by mid-2023 and cost 46% less than the first.
New output from the BNEF database shows that there were 1,013GW of wind and solar PV generating capacity installed worldwide as of June 30, 2018. The 1TW milestone would have been passed sometime just before this date. The total is finely balanced between wind (54%) and solar (46%).
Looking back on the first terawatt of wind and solar reveals just how far these two sectors have come. Total installed capacity has grown 65-fold since the year 2000, and more than quadrupled since 2010.
Even more striking is the growth of solar PV alone. As recently as 2007, there was just 8GW of PV capacity installed, compared with 89GW of wind. Since then, PV has grown from just 8% of total installed wind and solar capacity, to 46%. In the process, PV installations grew 57-fold, with utility-scale PV overtaking small-scale PV in 2014. Wind still represents the majority of the installed base at 54%, but is likely to relinquish this lead soon.
Investment
We estimate that the first 1TW of wind and solar required approximately $2.3 trillion of capital expenditure to deploy. The second terawatt will cost significantly less than the first. Based on estimates from our New Energy Outlook 2018, capital expenditures on wind and solar generation will total about $1.23 trillion from 2018 to 2022 inclusive.
What about other renewables?
We have singled out wind and solar in this piece because they are the fastest-growing sources of power generation and have just recently achieved the 1TW mark. If we were to include all other renewables, including hydropower, the total would already exceed 2TW, with the 1TW mark attained about a decade ago. Most of the growth in the intervening period can be attributed to wind and solar.
Did we forecast it right?
Reaching back into the BNEF archives allows us to examine our own forecasting track record, and see whether we were too optimistic or conservative on the growth of solar and wind. In our 2013 Global Renewable Energy Market Outlook (web | Terminal) – also known as GREMO – we estimated that global wind and solar installations would hit 865GW by the end of 2017, and get very close to 1,000GW by the end of 2018. In actual fact, the world had hit 945GW by end-2017, thus outperforming our expectations by 9%, and hit 1,000GW about six months earlier than we forecast. In other words, we were very close, but not quite aggressive enough.
We now estimate that wind and solar will hit 1.1TW by the end of this year – 11% more than we forecast five years ago. Given that the market has more than doubled in that time, we are happy to claim this as a ‘win’. As the figure below shows, our 2013 forecasts for onshore wind and small-scale PV ended up being very accurate. We were a little too bullish on offshore wind, while utility-scale PV has exceeded our expectations.
Article source:Â https://about.bnef.com/blog/world-reaches-1000gw-wind-solar-keeps-going/
- Published in Renewable Energy Sector News