Wind power in Ireland

the island of Ireland has 5,585 megawatt and the Republic of Ireland has 4,309 MW of installed wind power nameplate capacity, the third highest per capita in the world. In 2020, wind turbines generated 36.3% of Ireland's electrical demand, one of the highest wind power penetrations in the world.

Ireland has over 300 wind farms (nearly 400 all-island); mostly onshore, with only the 25 MW Arklow Bank Wind Park situated offshore as of 2020. This is unlike Germany and Great Britain two other European countries with high wind power penetration whose territorial waters (particularly the German Bight and waters off the coast of Scotland) are in extensive and growing use for offshore wind power.

Ireland's instantaneous wind power generation fluctuates between near zero and almost 4,500 MW due to weather, with an average capacity factor of 32.3% in 2015. Irish wind power generation is higher during winter and lower in the summer. The overall capacity factor of Irish wind farms is high compared to the global average of onshore wind farms which usually ranges around 20% but significantly lower than that of offshore wind farms which often achieve capacity factors around 50%.

Ireland uses an EU industry subsidy known as the Public Service Obligation to support development of wind and other domestic power generation, currently levied at €72 per year per household. In the 2016/17 period, €308 million raised through this levy was planned to be granted to supporting domestic renewable energy schemes. For comparison €120.90 million was planned to be granted to (non renewable) peat generation.

Concerns over energy security (Ireland lacks significant onshore fossil fuel resources other than peat, and has extensive wind resources), climate change mitigation policies, and compliance with EU Directives for market liberalisation, have all shaped wind power development in Ireland

Capacity Growth
Eddie O'Connor, then CEO of the semi-state owned peat harvesting company, Bord na Móna, commissioned the country's first "commercial wind farm" in a cutaway peat bog in County Mayo in 1992. Following the first commercial wind farm, wind power deployment in the Republic of Ireland started slowly in the 1990s, but increased more rapidly from the 2000s onwards. Whilst annual wind capacity growth has been variable, it has shown an increasing trend (Figure 1). Wind power has provided a steadily increasing share of electricity, from 4% (1,874 GWh) in 2005, to 28% in 2018 (10,195 GWh) (Figure 2). In the first two months of 2020, wind provided 49% of electricity demand, and a peak recorded output from wind power of 4,471 MW was delivered on 12 February 2021. Wind is now the second largest source of electricity generation after natural gas, which accounted for 52% of electricity generated in 2018.



Drivers of wind power expansion
Concerns over energy security (Ireland has an estimated 15.4m tonnes of coal reserves, peat bogs, offshore oil and gas fields, and has extensive wind resources), climate change mitigation policies, and compliance with EU Directives for market liberalisation, have all shaped wind power development in Ireland.

In the Directive 2001/77/EC, otherwise known as the RES-E Directive, the European Union stated a goal to have 22% of the total energy consumed by member states to be produced from renewable energy resources by 2010. As a result, Ireland, in a report titled "Policy Consideration for Renewable Electricity to 2010", made the commitment to have 4% of its total energy consumption come from renewable energy resources by 2002 and 13.2% by 2010. The Department of Communications Marine and Natural Resources (DCMNR) founded the Renewable Energy Group (REG) which established the short term analysis group (STAG) to investigate a means of accomplishing this goal. To meet the 2010 target of 13.2%, 1,432 MW of electricity will need to be generated from renewable resources with 1,100 MW being generated from wind resources both onshore and offshore.

State financial support
State financial support for the national electricity sector, and particular technologies, has been influenced by a slow move towards liberalisation, and concerns for energy security and climate change mitigation. Ireland uses an industry subsidy known as the Public Service Obligation (PSO) to support the generation of electricity from sustainable, renewable and indigenous sources, including wind. The PSO levy is charged to all electricity customers. As of April 2020, for residential consumers, the current PSO levy is €38.68 per year inclusive of VAT, and is displayed on the typical two-monthly electricity bill as €5.68 (€2.84 × 2) + 13.5% VAT.

The PSO levy funds the government's main mechanisms to support the generation of electricity from sustainable, renewable and indigenous sources. These mechanisms have shifted from the initial use of competitive auctions in the late 1990s, to a renewable energy feed-in tariff (REFiT) from 2006 to 2015, and back to a new renewable energy auction scheme as of 2020. Ireland's initial use of competitive auction from 1996 failed to support the intended growth in wind development. Between 2006 and 2015, the government supported a REFiT, secured for 15 years. The 2020 REFiT reference price for large wind (>5MW) is €70.98 /MWh and for small wind (<5MW) is €73.47/MWh. In June, 2020, Ireland will run its first competitive renewable energy auction under the government's new Renewable Energy Support Scheme (RESS-1). RESS-1 support is structured as a two-way floating feed-in premium (FIP), roughly the difference between the 'strike price' set in the successful auction bid and the 'market reference price'. When costs of electricity suppliers exceed market revenues a Support Payment will be due to the supplier, and when market revenues exceed costs a Difference Payment will be due from the supplier. An economic analysis of the financial cost of different RESS options, estimated that a least cost auction with floating FIP mechanism would cost a domestic consumer €0.79 per month by 2030 (at 2017 prices). This is significantly less than the current PSO levy rate to fund REFiT costs.

Offshore wind power
The Arklow Bank Wind Park, located 10 km off the coast of Arklow on the Arklow Bank in the Irish Sea, is Ireland's only offshore wind farm. The wind farm is owned and built by GE Energy and was co-developed by Airtricity and GE Energy. The site has 7 GE Energy 3.6 MW turbines that generate a total of 25 MW. The development of the site was originally divided into two phases with the first phase being the current installation of 7 turbines. The second phase was a partnership between Airtricity and Acciona Energy. Acciona Energy had an option to buy the project after the facility is completed. The wind farm was planned to expand to 520 MW of power. However, in 2007, Phase 2 was cancelled.

Although the waters off the Atlantic coastline of Ireland have higher winds, sites along the eastern coastline such as Arklow were chosen because of the shallower waters, which are 20 m deep or less.

In Belfast, the harbour industry is being redeveloped as a hub for offshore windfarm construction, at a cost of about £50m. The work will create 150 jobs in construction, as well as requiring about 1m tonnes of stone from local quarries, which will create hundreds more jobs. "It is the first dedicated harbour upgrade for offshore wind".

In 2023, an offshore wind auction approved four projects totaling 3 GW. The Codling project won first approval for a power price around €90/MWh by 2027.

Current trends
Grid connection is currently awarded on a 'first come, first connect' basis through Gate 3 procedures. On examination of the Gate 3 queue, there are a number of large onshore and offshore wind projects that are down the list and will, therefore, be offered grid connection towards the end of the anticipated 18-month processing period commencing in December 2009.

While planning permission normally expires after 5 years, the Planning and Development Act 2000 section 41 allows for a longer period. At present it is common to apply and obtain a 10-year permission for a wind energy development. Section 42 of the above Act originally permitted a 5-year extension of the "appropriate period" provided that substantial works were carried out. This caused major problems as the term "substantial works" was not clearly defined which resulted in a large variety in interpretation of what constituted substantial works among the various planning authorities. This issue was rectified by the Planning and Development (Amendment) Act 2010 section 28 which inserted an additional paragraph allowing a once off extension not exceeding 5 years if "there were considerations of a commercial, economic or technical nature beyond the control of the applicant which substantially militated against either the commencement of development or the carrying out of substantial works pursuant to the planning permission"

The fourth issue regarding the generation of wind power is the Renewable Energy Feed-in Tariff, or REFIT. The purpose of REFIT is to encourage development of renewable energy resources. For wind power production, the current limit to the tariff is 1,450 MW. However, applications currently being processed for grid connections exceed the limit by almost 1,500 MW for a total for nearly 3,000 MW. Since the limit is 1,450 MW, many of the applications for grid connections may not eligible for the tariff.

Economy
In 2011, the 120-member Irish Academy of Engineering described wind as "an extremely expensive way of reducing greenhouse gas emissions when compared to other alternatives" like conservation, nuclear energy or the Corrib gas project and Liquified Gas tanker imports at Shannon, concluding that the suggestion of 40% grid penetration by wind, is "unrealistic". In 2020, grid penetration had hit 36.3% and was still increasing but far slowly. By contrast, the Sustainable Energy Authority of Ireland said in 2014 that wind power cost the same as gas power. In 2020 the Irish Times reported that the cost of onshore wind energy had dropped over the last 20 years but that regulation on noise and height of turbines made Irish wind energy more expensive than elsewhere.

Peatlands and bog landslides
Building wind turbines and access roads on top of peatland results in the drainage and then eventual oxidation of some of the peat. The turbines represent a minor impact, provided that the entire wind farm area is not drained, potentially emitting more carbon dioxide (CO2) than the turbines would save. Biochemist Mike Hall said in 2009; "wind farms (built on peat bogs) may eventually emit more carbon than an equivalent coal-fired power station" if drained.

A 2014 report for the Northern Ireland Environment Agency, which has similar peatland, notes that building wind turbines on peatland could release considerable carbon dioxide from the peat, weaken flood control, and spoil water quality: "The potential knock-on effects of using the peatland resource for wind turbines are considerable and it is arguable that the impacts on this facet of biodiversity will have the most noticeable and greatest financial implications for Northern Ireland."

The Irish Peatland Conservation Council maintains a database on incidences where building wind turbines (and wind farms) on or near peatland caused devastating landslides, called "bog bursts"/"peat flows". These accelerate the release of carbon dioxide into the atmosphere.

In October 2003, the building of a wind farm in County Galway caused the Derrybrien landslide, an almost 2.5 km long, 450,000 m3 bog landslide, polluting a nearby lake and killing 50,000 fish. The lake was also the source of the town of Gort's drinking water. If all carbon in the slide is being released, it represents 7–15 months of production from the wind farm in avoided carbon dioxide from fossil power. In 2004, engineering companies were convicted of being responsible for the pollution, while the wind farm company was acquitted. The Irish government was convicted in 2008 of poor oversight.

Following the Corrie Mountain bog burst of 2008, Ireland was fined by a European Court over its mishandling of wind farms on peatland. By 2010, there had been at least three major bog landslides related to wind farms in Ireland.

In 2020, there was another large bog landslide at a wind farm construction site at Meenbog, County Donegal. This polluted rivers that are protected Atlantic salmon habitats, and was predicted to have caused a "complete fish kill". Drinking water supplies linked to the rivers had to be suspended.

The body representing industrial peat harvesting in Ireland, Bord na Móna, announced in 2015 the "biggest change of land use in modern Irish history": harvesting peat is being phased out by 2030, due to the long-expected depletion of profitable lowland peat, at which point the company would complete its transition to becoming a "sustainable biomass, wind and solar power" organization.

Local opposition
Some on-land wind farms in Ireland have been opposed by local residents, county councils, the Heritage Council and An Taisce (The National Trust) for their potential to blight the landscape, and having a harmful impact on protected scenic areas, archaeological landscapes, tourism and cultural heritage. In 2014, more than 100 protest groups united against government plans to build thousands of wind turbines in the Midlands to export energy to Britain. Among other things, they argued the wind farms would ruin the landscape and mainly benefit "multinational corporations who are sucking subsidies from the UK taxpayers". The Irish government shelved the plans.

In 2021 a proposed wind farm at Kilranelagh in the Wicklow Mountains was refused as it would have harmed the area's archaeological landscape, which includes the Baltinglass hillfort complex.

An application to build a wind farm overlooking the scenic valley of Gougane Barra was refused by Cork County Council, who voted unanimously against it. The company appealed to An Bord Pleanála, whose inspector also rejected it, stating it "would have significant adverse environmental and visual impacts and is not sustainable at this highly sensitive location". Despite this, An Bord Pleanála granted permission, on the grounds that the wind farm would contribute "to the implementation of Ireland's national strategic policy on renewable energy". The spokesman of the campaigners against the wind farm said the decision was undemocratic, as the local people and council opposed it.

Environmental Impact & Greenhouse gases


In a typical study of a wind farms Life cycle assessment (LCA), in isolation, it usually results in similar findings as the following 2006 analysis of 3 installations in the US Midwest, were the carbon dioxide (CO2) emissions of wind power ranged from 14 to 33 metric ton per GWh (14 - 33 g CO2/kWh) of energy produced, with most of the CO2 emissions coming from the production of concrete for wind-turbine foundations.

However, when approached from the effects on the grid as a whole, that assess wind turbines' ability to reduce a country's total electric grid emission intensity, a study by the Irish national grid, a grid that is predominately (~70%) powered by fossil gas, (and if it was 100% gas, would result in emissions of 410 - 650 g CO2/kWh. ) found that "Producing electricity from wind reduces the consumption of fossil fuels and therefore leads to [electric grid] emissions savings", with findings in reductions of the grid-wide CO2 emissions to 0.33-0.59 metric ton of CO2 per MWh (330 - 590 g CO2/kWh).

These findings were of relatively "low [emission] savings", as presented in the Journal of Energy Policy, and were largely due to an over-reliance on the results from the analysis of wind farms LCAs in isolation. As high electric grid penetration by intermittent power sources e.g. wind power, sources which have low capacity factors due to the weather, either requires the construction of transmission to neighbouring areas, energy storage projects like the 292 MW Turlough Hill Power Station, that have their own additional emission intensity which must be accounted for, or the more common practice of requiring a higher reliance on fossil fuels than the spinning reserve requirements necessary to back-up the more dependable/baseload power sources, such as hydropower and nuclear energy.

This higher dependence on back-up/Load following power plants to ensure a steady power grid output has the knock-on-effect of more frequent inefficient (in e g/kW·h) throttling up and down of these other power sources in the grid to accommodate the intermittent power source's variable output. When one includes the intermittent sources total effect it has on other power sources in the grid system, that is, including these inefficient start up emissions of backup power sources to cater for wind energy, into wind energy's total system wide life cycle, this results in a higher real-world emission intensity related to wind energy than the in-isolation g/kW·h value, a statistic that is determined by looking at the power source in isolation and thus ignores all down-stream detrimental/inefficiency effects it has on the grid. In a 2012 paper that appeared in the Journal of Industrial Ecology it states.

"The thermal efficiency of fossil-based power plants is reduced when operated at fluctuating and suboptimal loads to supplement wind power, which may degrade, to a certain extent, the GHG (Greenhouse gas) benefits resulting from the addition of wind to the grid. A study conducted by Pehnt and colleagues (2008) reports that a moderate level of [grid] wind penetration (12%) would result in efficiency penalties of 3% to 8%, depending on the type of conventional power plant considered. Gross and colleagues (2006) report similar results, with efficiency penalties ranging from nearly 0% to 7% for up to 20% [of grid] wind penetration. Pehnt and colleagues (2008) conclude that the results of adding offshore wind power in Germany on the background power systems maintaining a level supply to the grid and providing enough reserve capacity amount to adding between 20 and 80 g CO2-eq/kWh to the life cycle GHG emissions profile of wind power." According to the IPCC, wind turbines when assessed in isolation, have a median life cycle emission value of between 12 and 11 (geq/kWh). While the more dependable alpine Hydropower and nuclear stations have median total life cycle emission values of 24 and 12 g CO2-eq/kWh respectively.

Regarding interconnections, Ireland is connected to adjacent UK National Grid at an electricity interconnection level (transmission capacity relative to production capacity) of 9%. The two grids have a high wind correlation of 0.61, whereas the wind correlation between the Irish grid and the Danish grid is low at 0.09.

Tourism
One major aspect of wind farms in Ireland is tourist attraction and also local attraction. The Bord na Mona wind farm in Mount Lucas, Daingean, Co.Offaly has provided a local walk way through the newly established wind farm that attracts people of all ages. The walk way provides a safe environment off-road for walking, running and cycling. The walk way is approximately nine kilometres in distance with numerous stop off points for breaks. Maps can also be located in a variety of locations on the walk for guidance around the wind farm and back to allocated car parks. The walk way also provides aesthetic scenery on a relatively flat landscape. Such a walk attracts many people year round and circulates money back into the local community as tourists stop off in local shops.

Grid study in Ireland
A 2008 Irish study of the grid indicates that it would be feasible to accommodate 42% (of demand) renewables in the electricity mix. This acceptable level of renewable penetration was found in what the study called Scenario 5, provided 47% of electrical capacity (different from demand) with the following mix of renewable energies:
 * 6,000 MW wind
 * 360 MW base load renewables
 * 285 MW additional variable renewables (other intermittent sources)

The study cautions that various assumptions were made that "may have understated dispatch restrictions, resulting in an underestimation of operational costs, required wind curtailment, and CO2 emissions" and that "The limitations of the study may overstate the technical feasibility of the portfolios analyzed..."

Scenario 6, which proposed renewables providing 59% of electrical capacity and 54% of demand had problems. Scenario 6 proposed the following mix of renewable energies:
 * 8,000 MW wind
 * 392 MW base load renewables
 * 1,685 MW additional variable renewables (other intermittent sources)

The study found that for Scenario 6, "a significant number of hours characterized by extreme system situations occurred where load and reserve requirements could not be met. The results of the network study indicated that for such extreme renewable penetration scenarios, a system re-design is required, rather than a reinforcement exercise." The study declined to analyze the cost effectiveness of the required changes because "determination of costs and benefits had become extremely dependent on the assumptions made" and this uncertainty would have impacted the robustness of the results.