Wind Power breaks records across Europe

Wind Power smashes records across Europe

Britain’s fleet of onshore and offshore wind turbines met 22% of electricity demand on Sunday, setting a new record and outperforming coal, which met just 13% of demand.

Wind Turbines UK Image courtesy of ReNews
Wind Turbines UK Image courtesy of ReNews

Across the Channel, Spain has reported high levels of summer clean energy output with over 55% of electricity generation coming from zero emission sources during July. And Germany has announced that it generated more than a third of its energy from renewable sources in the first half of this year, while energy from fossil fuel plants – gas and coal – declined.

“Wind has become an absolutely fundamental component in this country’s energy mix,” RenewableUK Director of External Affairs Jennifer Webber said today in an e-mailed statement. “Wind is a dependable and reliable source of power in every month of year including high summer.” — Bloomberg

These figures are the latest clear signals that renewables are increasingly stealing the limelight from outdated fossil fuels. Earlier this year, onshore wind was revealed as the cheapest form of new electricity generation in Denmark and wind met over half of the country’s power demand last December. Renewable energy is also becoming cost competitive elsewhere with solar power reaching grid parity in Italy, Spain and Germany. This trend clearly indicates to European getting ready to agree a climate and energy framework to 2030 that the transition from fossil fuels to renewables is happening and here to stay. For more on this story click here.

Wind to power 50% of Denmark’s demand by 2020

While other countries debate whether to install wind turbines offshore or in remote areas, Denmark is building them right in its capital. Three windmills were recently inaugurated in a Copenhagen neighbourhood, and the city plans to add another 97.

“We’ve made a very ambitious commitment to make Copenhagen CO2-neutral by 2025,” Frank Jensen, the mayor, says. “But going green isn’t only a good thing. It’s a must.”

The city’s carbon-neutral plan, passed two years ago, will make Copenhagen the world’s first zero-carbon capital. With wind power making up 33% of ­Denmark’s energy supply, the country already features plenty of wind turbines.

Indeed, among the first sights greeting airborne visitors during the descent to Copenhagen’s Kastrup airport is a string of sea-based wind towers. By 2020, the windswept country plans to get 50% of its energy from wind power. — For more on this story visit Newsweek

Siemens receives Norwegian order for 67 wind turbines

Siemens has announced that it has received an order from Norwegian energy utilities Statoil and Statkraft for 67 wind turbines for the Dudgeon Offshore Wind Farm in the UK. The news comes just days after the UK installed their first 6 MW wind turbine at the burgeoning Westermost Rough offshore wind farm in the North Sea. Siemens will manufacture, deliver, install, and commission 67 of its direct-drive 6 MW wind turbines, each of which has a mammoth 154 meter rotor.

“We are proud to convince more and more customers about the advantages of our 6-megawatts-offshore machine”, said Dr. Markus Tacke, CEO of the Wind Power Division of Siemens Energy. “With Dudgeon we extend our project pipeline for this new turbine. This gives us the opportunity to further ramp up production capacity, which is a precondition to bring down the costs for offshore wind.”

The Dudgeon Offshore Wind Farm will begin construction in early 2017, and upon completion is expected to provide electricity to more than 410,000 UK households. For more on this story, head over to CleanTechnica

Vestas reports healthy profits and order for 32 – 8MW Wind Turbines

One of the world’s largest wind energy manufacturers, Vestas Wind, reported healthy second quarter earnings for 2014, and is now waiting on DONG Energy’s final investment in a UK offshore wind project which would require the Vestas 8 MW turbines. Vestas reported a strong turnaround from their second quarter earnings a year previously with a 13% increase to €1.34 billion. The company reported a net profit in the second quarter of €94 million ($125 million), compared to a €62 loss a year earlier

The news came just a day before Vestas confirmed that they had entered into a conditional agreement with DONG Energy for the upcoming Burbo Bank Extension in Liverpool Bay off northwest England. Vestas would provide 32 8 MW V164 turbines for the extension project, and are awaiting DONG Energy’s commitment to the project before the deal is sealed.

“Larger and more cost-efficient wind turbines are key elements in the realization of Dong Energy’s strategy towards reducing the cost of electricity from offshore wind,” said Samuel Leupold, an executive vice president at Dong. “Competition among the offshore wind turbine manufacturers will increase.”

Offshore construction of the Extension is expected to begin in 2016, and upon completion it is expected the project will be able to provide electricity for more than 230,000 UK homes. — Bloomberg

Renewable energy replaces lost European nuclear capacity

by John Brian Shannon John Brian Shannon

Nuclear reactors are starting to shut down in Europe

It began in earnest in the wake of the Fukushima disaster when Germany inspected its problem-plagued nuclear power plants and decided to take 9 of its nuclear power plants offline in 2011 and the rest offline by 2022.

There is plenty of public support in the country for Germany’s planned nuclear closures, even with the additional fee added to each German electricity bill to pay for nuclear power plant decommissioning, which completes in 2045.

Switzerland likewise has decided to get out of the nuclear power business beginning in 2015 and decommission their nuclear power plants by 2045.

Other European nations are also looking at retiring their nuclear power plants. But the news today is about the UK, Belgium, Germany and Spain.

Heysham_Nuclear_Power_Station UK operated by EDF
Heysham Nuclear Power Station in the UK which is operated by EDF of France. Image courtesy: CleanTechnica.com

In the UK, four (French-operated) EDF reactors built in 1983 have been shut down after one of them was found to have a crack in its centre spine. (EDF stands for Electricity de France which is a French utility responsible for managing many nuclear reactors)

At first only the affected unit was taken offline (in June) but upon further inspection it was determined that the other three were at risk to fail in the coming months. Whether or not these four reactors can be repaired economically — all were scheduled to be decommissioned before 2020.

The sudden shortfall in electrical generation due to these unscheduled nuclear power plant shutdowns has been met by 5 GW of new wind power generation, which has seamlessly stepped in to fill demand.

Additional to that, another 5 GW of solar power has been added to the UK grid within the past 5 years. And that’s in cloudy olde England, mates!

In Belgium, 3 out of 5 of their nuclear power plants are offline until December 31, 2014 due to maintenance, sabotage, or terror attacks — depending upon whom you talk to.

Belgium’s Doel 4 reactor experienced a deliberate malfunction last week and workers in the country’s n-plants are henceforth directed to move around inside the plants in pairs.

Also, their Tihange 2 reactor won’t be ready to resume power production until late March, 2021. See this continuously-updated (and long) list of nuclear power plant shutdowns in Belgium.

Further, the utility has advised citizens that hour-long blackouts will commence in October due to a combination of unexpected n-plant shutdowns and higher demand at that time of year.

Belgian energy company Electrabel said its Doel 4 nuclear reactor would stay offline at least until the end of this year after major damage to its turbine, with the cause confirmed as sabotage.

Doel 4 is the youngest of four reactors at the Doel nuclear plant, 20 km north of Antwerp, Belgium’s second-biggest city. The country has three more reactors in Tihange, 25 km southwest of the city of Liege.

Doel 1 and 2, which came on line in 1975, are set to close in 2015. Tihange 1, which also started operation in 1975 and was designed to last 30 years, got a 10-year extension till 2015.

The two closed reactors Doel 3 and Tihange 2 were connected to the grid in 1982 and 1983. Doel 4 and Tihange 3, which came on line in 1985, were operating normally until the closure of Doel 4 last week.

The shutdown of Doel 4’s nearly 1 gigawatt (GW) of electricity generating capacity as well as closures of two other reactors (Doel 3 and Tihange 2) for months because of cracks in steel reactor casings adds up to just over 3 GW of Belgian nuclear capacity that is offline, more than half of the total.

In Britain, EDF Energy, owned by France’s EDF, took three of its nuclear reactors offline for inspection on Monday after finding a defect in a reactor of a similar design. – Reuters

In Germany, the nuclear power generation capacity missing since 2011 has been met by a combination of solar, wind, bio, natural gas, and unfortunately some coal. But that sounds worse than it is.

According to the Fraunhofer Institute, renewable energy produced about 81 TWh, or 31% of the nation’s electricity during the first half of 2014. Solar production is up 28%, wind 19% and biomass 7% over last year.

Meanwhile, with the exception of nuclear energy, all conventional sources are producing less. The output from gas powered plants was half of what it had been in 2010 and brown coal powered plants are producing at a similar level to 2010-2012. – CleanTechnica.com

Let’s see what our friends at the Fraunhofer Institute have to say in their comparison of the first half of 2013 vs. the first half of 2014.

German electricity production H1 2013 - H1 2014
Fraunhofer Institute compares the different energy production between the first half of 2013 and the first half of 2014.

Although unspokenby power company executives operating in Germany, Spain, and some other European countries, the panic felt by traditional power generators is due to the massive changes in ‘their’ market since 2009.

Things move slowly in the utility industry — ten years is seen as a mere eyeblink in time, as the industry changes very little decade over decade. Recent changes must be mind-blowing for European power company executives.

European-union-renewables-chart
European-union-renewables by Eurostat — Renewable energy statistics. Licensed under Public domain via Wikimedia Commons Keep in mind that this map displays results from 2012. The 2014 map will show significantly more ‘green’ energy, once that map becomes available in 2015.

It occurs to me that the end of the conventional energy stranglehold on Europe parallels the ending of Star Wars VI.

Help me take this mask off

It’s a mask to hide behind when conventional power producers don’t want the facts aired.

Fossil fuel and nuclear power generation have had (and continue to have) huge subsidy regimes in place which they don’t want publicly advertised — and they don’t want renewable energy power producers to have any subsidies. And conventional power producers don’t want fossil fuel externalities and nuclear power externalities advertised either. That’s a lot of hiding, right there.

Externalities are simply another form of subsidy to fossil fuel and nuclear power plant operators and their fuel supply chains, which usually take the form of additional public healthcare spending or environmental spending that is required to mitigate toxic airborne emissions, oil spills, etc.

Spain has ended it’s Feed-in-Tariff scheme for renewable energy, while keeping conventional power producer subsidies in place.

Not only that, suddenly homeowners aren’t allowed to collect power from the Sun or harvest power from the wind unless it is for their own use. Electricity cannot be collected by Spanish residents and then sold to the grid for example, nor to anyone else.

Spain’s government has taken it one step further in a bid to keep the conventional energy companies from drowning in their tears. After a meteoric rise in wind and solar capacity, Spain has now taxed renewable energy power producers retroactively to 2012 and ruled that renewable energy will be capped to 7.5% profit. Renewable energy profits over and above the 7.5% threshold instantly becomes instant tax revenue for the government. (Quite unlike conventional energy producers in the country which can make any amount of profit they want and continue to keep their subsidies)

While all of this has been going on, Spain and Portugal have quietly lowered their combined CO2 output by 21.3% (equal to 61.4 million fewer tonnes of CO2 emitted) since 2012, thanks to renewable energy.

But you’ll die

Not only has European renewable energy now stepped up to fill the voids due to nuclear power plant maintenance and sabotage shutdowns, it has scooped incredible market share from conventional power producers.

In January 2014, 91% of the monthly needed Portuguese electricity consumption was generated by renewable sources, although the real figure stands at 78%, as 14% was exported. – Wikipedia

Unwittingly, the German and Spanish power companies have provided the highest possible compliment to the renewable energy industry, and if publicized, it would read something like this;

“We can’t compete with renewable energy that has equal amounts of subsidy. Therefore, remove the renewable energy subsidy while we keep ‘our’ traditional subsidies, until we can reorient our business model – otherwise, we perish!”

Nothing can stop that now

Ending the European renewable energy Feed-in-Tariff schemes will only temporarily slow solar and wind installations as both have reached price-parity in recent months — against still-subsidized conventional power generators.

Even bigger changes are coming to the European electricity grid over the next few years. Nothing can stop that now.

Tell your sister; You were right about me

Conventional power producers in Europe provided secure and reliable power for decades, it was what powered the European postwar success story, but having the electricity grid all to themselves for decades meant that Europe’s utilities became set in their ways and although powerful, were not able to adapt quickly enough to a new kind of energy with zero toxicity and lower per unit cost.

Renewable energy, at first unguided and inexperienced, quickly found a role for itself and is now able to stand on its own feet without subsidies — unlike conventional power generators.

Considering the sheer scale of the energy changes underway in Europe, conventional energy has been superceded by a superior kind of energy and with surprisingly little drama.

Sustainable Energy Policy to save EU €81 bn/year by 2030

by John Brian Shannon John Brian Shannon

Accenture says a sustainable pan-European energy policy could save consumers €27 to €81 billion per year by 2030 and result in a cleaner utility grid model.
Accenture says a sustainable energy policy could save European electricity consumers €27 to €81 billion per year by 2030.

A recent report authoured by Accenture for EURELECTRIC says that if European nations work together towards an integrated and pan-European energy policy it could generate savings for electricity consumers between €27 to €81 billion per year by 2030 and the result would be a cleaner utility grid model.

Accenture is calling on European governments to phase-out renewable energy targets and renewable energy programme spending — replacing both with a carbon trading scheme, one that essentially rewards low carbon energy producers and penalizes high carbon energy producers.

All of this is happening during a time of unprecedented change within the European energy industry.

In the fascinating German example, that country shut down much of its nuclear power generation rather than spend multi-billions to upgrade its aging and oft-troubled nuclear fleet. Consequently, Germany is now burning record amounts of coal and natural gas to replace that lost generation capacity — in addition to the installation of record amounts of wind, solar and biomass capacities to the German grid.

In the decades following WWII, German utility companies operated in a cozy, sheltered environment. But few knew how expensive it was to operate and maintain on account of massive government subsidies and preferential treatment of the utility industry. German consumers never had it so good and likewise for sleepy German energy giants, which have now awoken to find that the energy picture has changed dramatically in little over a decade.

Hence, even more subsidies were employed to counter for the loss of German nuclear power via Feed-in-Tariffs (FiT) for wind, solar and biomass capacity additions to the grid, partially financed by a hefty nuclear decommissioning fee added to every German electricity bill.

At least in Germany, it turns out that while nuclear has practically disappeared, and with no fuel costs to worry about, renewable energy combined to lower German electricity rates during the hours of the day that wind and solar are active, causing downward pressure on electricity rates. At the same time, German utilities burned record amounts of brown coal and expensive Russian natural gas to meet total demand which caused upward spikes in the electricity rate during the hours of the day that coal and natural gas were required to meet total demand.

In simple terms, the removal of nuclear from the German energy mix has resulted in higher electricity rates — not because some of that capacity was replaced by renewable energy — but because significant fossil fuel burning was required to meet demand, combined with nuclear decommissioning costs.

Were German politicians and their voters wrong to shut down the country’s nuclear power plants? Not a bit. Germany’s nuclear power plants were problem-plagued and the costs to bring all 19 reactors up to modern standards were prohibitive. Shutting down the German nuclear fleet was unfortunate perhaps, but necessary.

German consumers continue to yearn for clean energy and low energy costs. Unsurprisingly, the German public has reacted to energy that seems to be getting dirtier and more expensive by the day, and the massive nuclear decommissioning costs which will continue long past 2022, perhaps until 2045.

After the loss of nuclear, the German energy grid initially became cleaner with the addition of wind and solar, but then became dirtier than ever as record amounts of brown coal and natural gas were burned! Es ist zum weinen.

And that’s just the story in Germany. Every European partner country has its own story to tell in an electricity market that is undergoing unprecedented and rapid change — and each country’s electricity market is as different from each other as they are from the German example. Although each story is different, the net result is the same; The energy industry across Europe must adapt to the loss of (some) nuclear and the growing consumer disenchantment with fossil fuels, and to the huge consumer driven additions of renewable energy to the grid. And it must be done in a cost-effective way or utility companies and their respective governments will face consumer backlash.

Utility companies shocked by the unprecedented and rapid changes thrust upon them by nuclear shutdowns and the multiple demands of consumers are hoping that a harmonized set of rules across Europe will allow them to meet rising electricity demand.

If you look at what utilities really want, it is one harmonized set of rules across Europe. Europe is one market; it’s one playing field, and utilities really benefit from a harmonized set of rules.

It is like playing football; if you play football,you don’t want different rules for different parts of the field. — Sander van Ginkel, Managing Director, Accenture Utilities

“European electricity prices are rising fast. As a result, the overall increase in energy expenditure is putting mounting pressure on residential end-users and undermining the competitiveness of European industry. The implementation of the energy transition has so far lacked optimization on a pan-European scale. Without a concerted effort to more effectively manage the costs of the energy transition, expenditure on electricity and gas in 2030 could be 50 percent higher than it is today.

A step-change in the reshaping of the European energy system is needed — by reconfirming the European power sector’s support for Europe’s sustainability agenda through an optimized approach that avoids unnecessary costs. Doing so would put significant benefits within reach: our analysis shows that implementing an integrated set of levers could generate net savings of €27 to €81 billion per year by 2030. Such savings could be achieved by further integrating energy markets and the supporting regulatory framework at a European level and by leveraging flexibility throughout the electricity value chain — provided utilities, governments, regulators and consumers can forge a joint commitment to work together.” — Quoted from the Accenture/EURELECTRIC report

Accenture’s report says that Europe’s utilities must meet customer demands for more energy, but make it cheaper and cleaner and that the existing grid model will fail unless changes are made. Accenture has suggested four main ways to achieve these goals.

  1. Optimizing renewable energy systems
  2. Market integration
  3. Active system management
  4. Demand response and energy saving

“The restructuring of the European electricity system will have to be carried out cost-effectively if we are to gain the support and trust of energy consumers. This study shows that, with the right policies in place, the energy transition could cost each European citizen over € 100 less a year than if we continue with business as usual.” Hans ten BERGE Secretary General. Union of the Electricity Industry – EURELECTRIC

It seems reasonable that all of Europe’s utility companies acting together could arrive at a better solution. Complementary and overlapping energy capabilities may prove to be the model that works for Europe, as opposed to the direct competition model favoured in the U.S.

A carbon tax which reflects the true societal costs of fossil fuels could be a just solution to Europe’s present grid malaise. However, it is doubtful that a carbon tax will ever reflect the true cost to society of fossil fuels — which have been estimated to cost €30 per tonne of CO2 — but a carbon mechanism may well provide the impetus to foster a new and better European energy paradigm.

No matter the how the equation looks, it is sometimes only the answer that matters. A cleaner energy mix and reasonable electricity rates within a stable electricity grid is something that all sides can cheer for. How very European!

See the Accenture video (click here)

UK Launches Major Solar Strategy

International Digital Editor, Power Engineering International

April 04, 2014 | The UK government today announced its Solar Strategy, the first such strategic document dedicated to solar by any European Union government.

It will entail the creation of ‘solar hubs‘ whereby commercial and public sector buildings deploy solar arrays onsite, effectively shifting the focus of the market towards mid- to large-scale rooftop installations.

It also reasserts the government’s goal to deliver 20 GW of solar capacity by 2020 and sets out a new ambition to double the number of domestic rooftop solar arrays in the UK to one million homes by 2015.

UK Energy Minister Greg Barker
UK Energy Minister Greg Barker. Image courtesy: Power Engineering International

The announcement made by Energy Minister Greg Barker – at a Solar Strategy conference session at event SunSolar Energy in Birmingham – is a statement of intent by the UK government that it is seeking to play a more influential role in the global solar sector, estimated to be around 46 GW by analysts from Deutsche Bank.

That 46 GW represents a 50 per cent increase in existing installed capacity.

Barker said: “We have put ourselves among the world leaders on solar and this ambitious strategy will place us right at the cutting edge.

“There is massive potential to turn our large buildings into power stations and we must seize the opportunity this offers to boost our economy as part of our long term economic plan.

“Solar not only benefits the environment, it will see British job creation and deliver the clean and reliable energy supplies that the country needs at the lowest possible cost to consumers.”

Ministers have also set a target of delivering 1 GW of capacity on public buildings by 2020 and will set out plans for the first 500 MW of installations later this year.

The conference session was co-chaired by Solar Trade Association (STA) PV Specialist Ray Noble and chaired by STA Chief Executive Paul Barwell.

Barwell said: “It’s a clever move by the UK government to start strategising to maximise its stake in a global market estimated at $134bn by 2020. With The Royal Society, the IPCC and even Shell  anticipating solar could be the world’s biggest energy source, the UK needs to make the most of its R&D, product design and manufacturing skills to steal a march in the global clean energy race.”

Noble said: “The Solar Strategy gives a clear signal that solar in the UK makes total sense. We still have work to do in developing solutions to some of the barriers but, working with government, these will be sorted during 2014. The message to the solar industry is full speed ahead and the message to the Minister is that we will achieve your ambition of 20GW.”

CSP Solar power
CSP solar system. Image courtesy: Power Engineering International

Other highlights of the strategy include plans to work with BIS to increase economic opportunities for UK plc in solar, building on UK innovation leads; new industry collaboration on building integrated photovoltaics (BIPV) and the addressing removal of grid barriers that prevent the expansion of solar.

The strategy follows the ‘Roadmap to a Brighter Future‘ which was published last October. It looks to showcase how the UK is at the forefront of innovation in solar PV and its importance in driving further cost reduction, meeting the challenges of balancing the electricity system, securing carbon lifecycle benefits, and identifying new financial models to help households invest.

This article is republished here with the kind permission of Diarmaid Williams, International Editor of Power Engineering International

Additional gov.UK information is available: