Tag: — Europe

Niestetal, Germany

Kirche Niestetal Heiligenrode, Germany

  • Target: Carbon neutral by 2034, and 100% renewable by 2050.
  • Status: In progress
  • RES: Solar, biomass, wind, geothermal and hydropower energy.
  • Implementation: The municipality of Niestetal is located in the district of Kassel in the state of Hesse, Germany. In 2012, a decision was made by the state to transition to 100% renewable energy by 2050. Four years earlier in 2008, motivated by the climate crisis, the people of Niestetal decided to commit to replacing all of their energy use with renewable resources. They would primarily source solar energy, and additionally biomass, wind, geothermal, and a small amount of hydropower. The target became the focus of the municipality's Integrated Climate Protection Plan launched in 2009. The plan contained around 20 measures that various community stakeholders can implement in order to reach the municipality's declared goal to become carbon neutral by 2034.
    Key to Niestetal's 100% renewable plan is to adopt high efficiency construction standards. With the support of public incentives that help bring down up front costs, five percent of the community's homes underwent energy efficiency retrofits from 2011-2013. Homeowners reportedly reduced their home energy requirement by 20-30% and their investment in the energy upgrades paid back within 5-6 years. Niestetal is utilizing the renewable energy expertise of several local companies and institutions,which include the University of Kassel, the energy research network deENet, and the international solar photovoltaic inverter and monitoring company SMA. SMA provides about 3000 local jobs, which helps add to the local value chain created by the renewable energy transition. Niestetal is one of four municipalities making up the German section of the Energy Region program, an EU funded cooperation between several European countries to further sustainable development of renewable energy.
  • Population: 11,030 (2017)
  • Area: 22.15 km2 (8.55 sq mi)
  • Link: (In German) https://www.niestetal.de/gv_niestetal/Bauen%20&%20Klimaschutz/Klimaschutz/Klimaschutzkonzept/integriertes%20klimaschutzkonzept%20fr%20die%20gemeinde%20niestetal.pdf
Kirche Niestetal Heiligenrode, Germany

Oslo, Norway

Oslo, Norway

  • Target: 100% renewable energy target in public transport and heating by 2020, reduce CO2 emissions by 50% below 1991 level by 2030, and become carbon neutral in 2050.
  • Status: In progress -  In 2014, 60% of the energy used by the city to power the public transport system was sourced from hydroelectric power.
  • RES: Hydropower, biogas, Passive House buildings, and hydrogen and electric vehicles.
  • Implementation: Oslo is Norway’s capital and is the most populous city. It aims to achieve 100% RE through its Energy Action Plan, built on previous initiatives by the city such as the municipal Energy and Climate Fund, which was implemented in 1982. Thanks to a compact urban fabric and a high share of public transport use (62% in 2010), Oslo per capita COemissions is already one of the lowest in Scandinavia (around 2,3 tonnes in 2007). Heating and transportation account for the highest share of COemissions. The city aims to increase the share of fossil-free hydrogen powered vehicles in the city’s operators fleet by 2020 to reach its 100% target. Although the city does not own any vehicles itself, Oslo municipality and Akershus County Council does own the transport management company, Ruter AS. This enables the two public bodies to  influence the decisions of operators. In 2014, the City of Oslo in cooperation with the surrounding regional government of Akershus County approved a Regional Hydrogen Strategy to reinforce the target set, and are working together to develop an infrastructure with biogas, hydrogen and electric vehicles. Reducing emissions in the heating of city buildings is another priority. By 2013 all municipal buildings were using 100% renewable energy, and from 2014 all new municipal buildings had to be of Passive House construction. Today, the city’s heating system is powered by 80% renewable energy, mainly from sourced from residual waste biomass. In 2010, FutureBuilt, a ten-year program, was launched by Oslo and 3 municipalities part Oslo’s Region to stimulate climate friendly urban development. 37 pilot projects, including  private and public buildings as well as urban areas, were developed in 2015.
  • Population: 673,469 (2018)
  • Area: 480.76 km(185.62 sq mi)
Oslo, Norway

Osnabrück District, Germany

Schloss Fürstenau, Osnabrück, Germany

  • Target: 100% renewable and to save up to 88% of today’s emissions.
  • Status: In progress
  • RES: Wind energy
  • Implementation: Located in the North-West of Germany, the region of Osnabrück has played an important role in Germany's energy transition. In the region, renewable energy production, energy efficiency and a sustainable economy have become intrinsic aspects to day-to-day decision-making by its inhabitants. The commitment is reflected in the more than 8,000 renewable energy plants that have been installed right across the region. These have benefited from a rural landscape with abundant natural resources, boosted by a robust economy and modern agriculture. Indeed, renewable energy and energy efficiency represent long-term strategies for sustainable development, climate protection and regional value creation in the region. The 100% renewable energy target dates back to 2010 and has since been part of municipal policy-making. To date, there are more than 50 different projects, planning or research endeavours being conducted and coordinated at the local “Energy and Climate Protection Department“. There are many activities targeting private households and the building sector. By 2013, new developing areas had been outlined as part of updated renewable energy policies and the integration of climate targets.
  • Population: 356,140 (2017)
  • Area: 2,122 km2 (819 sq mi)
  • Link: Klimaschutzkonzepte und Statistiken
Schloss Fürstenau, Osnabrück, Germany

Pellworm, Germany

Pellworm, Germany

  • Target: 100% renewable electricity
  • Status: Achieved
  • RES: Wind power, solar farm.
  • Implementation: Pellworm is the third largest North Frisian island and relies on tourism and agriculture. About 50 farms engage in livestock. 70 percent of the land is used as grassland .  A 28 km long and eight meter-high dyke protects the island from the North Sea. For more than 30 years, the island of Pellworm has been a pioneer in the renewable energy field. At the end of the 70s, the first small wind-energy systems were tested here. After 1983, a 300 kW solar power station appeared, complemented by three 25 kW wind-energy units. The electricity produced was used to supply a health resort. Since then, the plant has been upgraded and enlarged several times and today it serves the E.ON group for the testing of ‘smart grids’ and modern storage technologies.  In the second half of the 90s, the Association of Ecological Economies, the Municipality and the electricity provider Schleswag set up an energy concept that enabled Pellworm to become energy self-sufficient. A public wind-park company was founded in order to use electricity production as a source of income. The municipality opened an energy office. A biogas assessment led to the installation of a public biogas unit, local heating from which supplies the health centre. A round-table meeting brought together all operators and parties interested and involved in the energy sector and initiated further development of the energy concept.
  • Population: 1,136 (2016)
  • Area: 37.44 km2 (14.46 sq mi)
  • Link: Smartregion Pellworm
Pellworm, Germany

Watch "Pellworm: Germany's green energy island" by AFP News Agency

Perpignan, France

Perpignan, France

  • Target: "Energy positive" city by 2015
  • Status: In progress
  • RES: Wind turbines, solar farm and rooftop solar PV
  • Implementation: Perpignan is a city and commune located in France near the Spanish border. In 2008, the City of Perpignan and the Perpignan Méditerranée Communauté d'Agglomération, a collection of 36 towns in the region, signed an agreement to make Perpignan an "energy positive" city by 2015 - that is, a city that generates more electricity with renewable sources than the citizens consume. Named the first Grenelle 2015 Agreement, it set out a vision to modify the city's approach to urban development by engaging in energy efficient housing, sustainable transportation, organic agriculture, local food production, air/water resource conservation, and environmental protection. The agreement also aims to ensure that each town maintains its identity, individuality, traditions and way of life, while the above measures are carried out. Part of the strategy is to make the people of the region "eco-citizens" by sharing information, developing school programs, and engaging the business community, etc. Specifically, the plan aims to generate 440,000 euros per year to cover residential needs with an investment of about 500 million euros, with a return on investment of between 10 and 15 years.

    In relation to the energy target, the plan includes a wind development zone for 41 wind turbines with a generating capacity of 294,000 MWh a year, which could cover 67% of the region's  electricity needs. The plan also aims to generate 48,000 MWh annually from rooftop solar photovoltaic installations on public buildings. Solar PV on private buildings covering around 120,000 square meters of roof space is envisioned, thereby providing 10% of the involved community's electricity demand.  To help support this goal, CEMOI, a leading producer and exporter of French chocolate, has invested in a solar production facility. Additionally, a solar park of approximately 100 hectares (over a third of a square mile) is to generate 42,000 MWh per year.

  • Population: 118,238 (2013)
  • Area: 68.07 km2 (26.28 sq mi)
  • Link: Perpignan Positive Energy Territory
Perpignan, France

Prato allo Stelvio (Prad am Stilfser Joch), Italy

Prato allo Stelvio, Alto Adige, Italy

  • Target: 100% renewable energy
  • Status: Achieved
  • RES: Biomass heating plant, 4 small hydroelectric plants, rooftop solar and a wind farm.
  • Implementation: In 2010, Prato allo Stelvia, a small Italian town in the mountains, won the RES Champions League title for having the best policies to promote renewable energy. Today, it has achieved 100% renewable energy self-sufficiency. The town has installed several renewable energy technologies, including a 1.4 MW central biomass heating plant, 4 small hydroelectric plants totaling just over 2 MW,  5.4 MW of rooftop solar power spread throughout the town, and a 1.2 MW wind farm. This energy mix has brought many benefits to the citizens of Prato all Stelvia. The air is free of pollution from conventional power plants, and utility bills have been reduced by 30-40%. Moreover, in 2003, when nearly all of Italy suffered a massive black out, the town fared well even though it was still connected to the national grid,  thanks to its efficient locally operated grid powered by renewable power plants.
  • Population: 3 603 (2018)
  • Area: 51,49 km²
  • Link: https://www.e-werk-prad.it/it/
Prato allo Stelvio, Alto Adige, Italy

Rhein – Hunsrück, Germany

Schönburg Castle, Flaggenwiese, Rhein-Hunsrück, Germany

  • Target: 100% renewable energy by 2020 based on local sources
  • Status: Achieved
  • RES: Hydropower, wind power, solar photovoltaics, and biomass.
  • Implementation: The District of Rhein-Hunsrück is located in the state of Rhineland-Palatinate in southwestern Germany. When the District set the target to entirely switch its energy system to one based on efficiency and local, renewable sources by 2020, it was in part due to the need to cease energy imports which was costing the district millions each year.

    In 2010, only 65% of Rhein-Hunsrück’s electricity was sourced from renewable energy. But by 2012, the District had become a renewable electricity exporter. Some of the surplus is used for running electric heat pumps, for methane created from excess wind and solar electricity, and for charging electric battery and fuel cell powered vehicles.

    The energy transition in Rhein-Hunsrück took place between 1999 and 2009. It first began with building efficiency improvements, which soon resulted in cost savings of 1.13 million euros. To lower local building energy use, the District implemented passive solar principles and heat pumps connected to ground heat collectors. Technologies made use of abundant local renewable resources such as wood pellet heating, biomass-based district heating, and rooftop PV. By 2009, 269,000 tons of CO2 emissions had been avoided through use of renewable electricity, heat and biofuels, and 12.3 million euros had been saved by avoided import costs for coal, natural gas and mineral oil. In 2010, Rhein-Hunsrück created its first zero-emissions school. Connected to the local district heating grid, the school is fueled with wood chips and a combined heat and power (CHP) unit that utilizes oil from regional rapeseed. By 2010, a total of 93 kW of PV were installed creating 33% more power than the facility consumes.

    Rhein-Hunsrück has invested a total of 7.5 million euros in district heating networks. The systems feed around 10 million m³ of biogas into the natural gas grid each year and save the District the equivalent of 660,500 liters of fossil fuel oil a year. Between 2011-2031, the investment is expected to bring the added value of at least 10.5 million euros due to fuel delivery costs staying within the region. By 2050, the aim is to reach a cost savings of 250 million euros.

    Rhein-Hunsrück makes use of Germany’s Feed-In Tariff law (Renewable Sources Act), and has simple permitting processes in place to ensure that rooftop solar installation is a relatively sound and easy investment. To show its own commitment, the District has installed PV on all public administration buildings. From 2007-2011, total capacity on public buildings jumped ten-fold from 35 kW to 366 kW. To increase community buy-in to the energy transition, educational facilities have been created where young people can learn about renewable energy and ecological stewardship. A public relations campaign focuses on public information, with attention given to making citizens aware of the community and financial benefits in participating in the energy transition.
  • Population: 102,938 (2017)
  • Area: 990.70 km2(382.51 sq mi)
  • Link: (In German) https://www.kreis-sim.de/Klimaschutz/Ziele-Motto-und-Konzept
Schönburg Castle, Flaggenwiese, Rhein-Hunsrück, Germany

Rietberg, Germany

Rietberg, Germany

  • Target: Energy self – sufficiency within the electricity sector by 2030
  • Status: In progress
  • RES: Biogas plant, geothermal energy system and solar tracker.
  • Implementation: In 2011, the town of Rietberg in Germany compiled a communal climate protection concept together with the public to outline a wide range of renewable energy, energy efficiency and energy saving initiatives. The city council also decided to fix the goal of achieving energy self–sufficiency within the electricity sector by 2030. To reach the target, the town has implemented several RE projects. The flagship of Rietberg is the unique “Klimapark Rietberg”. The Information- and Technology-Park exhibits several renewable energy facilities, like a walk-in biogas plant, a geothermal energy system and a solar tracker. Klimapark Rietberg is located in an old horticultural area and has involved 18 project partners from various business, science and environmental organizations. In 2013, Klimapark was awarded  the 'Place of Progress' from Nordrhein-Westfalen and UN-Decade Project of Education for Sustainable Development.
  • Population: 29,444 (2016)
  • Area: 110.37 km2 (42.61 sq mi)
  • Link: (In German) https://www.rietberg.de/rathaus/klimaschutz-energie
Rietberg, Germany

Ringkøbing-Skjern, Denmark

Gammelsogn, Ringkøbing Skjern, Denmark

  • Target: 100% renewable energy by 2020
  • Status: In progress
  • RES: Bio-energy, wind power, new plus-energy buildings, hydrogen vehicles and hydrogen service stations, and solar power.
  • Implementation: Ringkøbing-Skjern is the largest municipality in Denmark, established in 2007. At its conception, the municipality only met 20% of its energy from renewable sources. However, Ringkøbing-Skjern aims to produce within its boundaries enough renewable energy to cover all consumption by its citizens and businesses by 2020. It has set out an Energy 2020 plan, which aims to have local people, businesses, institutions and non-profits implement energy projects, from testing to development to implementation, in order to stimulate sustainable economic growth within the municipality.

    The Energy 2020 plan includes a top-down and bottom-up leadership structure. From the top, the 100% plan would be lead by the Energy Board, which is made up of local business and organisation representatives, along with municipal officials and staff. The Board would advise the local governing Council, which appoints a Secretariat to coordinate the effort and provide information, marketing and an energy action plan. From the community level, projects of all sizes would be implemented by local citizens, businesses and non-profit organizations. Impetus to engage would be motivated by expected energy savings, environmental benefits, and economic opportunities.

    In relation to the energy target, the plan envisages different types of renewable installations. Ringkøbing-Skjern will take advantage of its large land area and the energy that can be made from farm animal waste and plants. New wind turbines are expected to generate twice as much power as the whole municipality consumes. New buildings will be "plus energy," that is, able to generate more energy than the use. The Council will continue to operate hydrogen vehicles and hydrogen service stations, and public and individual transport are to run on biofuel and electricity. Other technologies currently being used include thermal heat, fjord heat, solar power, solar cells, and wave energy.

  • Population: 57,148 (2014)
  • Area: 1,494.56 km² (577.05 sq mi)
  • Link: https://www.energi2020.dk/english
Gammelsogn, Ringkøbing Skjern, Denmark

Saerbeck, Germany

Solar module, Bioenergiepark Saerbeck, Germany

  • Target: 100% renewable energy and climate-neutral by 2030
  • Status: In progress
  • RES: Solar power, wind power and biogas.
  • Implementation: Saerbeck is a municipality in the district of Steinfurt, in North Rhine-Westphalia, north-west Germany. In 2008, its council decided to switch its entire energy supply to renewable energies in order to become climate-neutral by 2030. Since then it has achieved a range of climate protection milestones: In 2009, it won the German Solarprize. It was awarded the “NRW-Climate Community of the Future” by the State, functioning as a role model in the realm of climate protection and climate adaptation.
    To reach its 100% target, Saerbeck has developed an “Integrated Climate Protection and Climate Adaption Concept". Part of the Concept are three central flagship projects that have already been widely implemented. The first flagship project “Saerbeck’s Sunny Sites” focuses on investigating the potentials of energy efficiency improvements and renewables application in private and industrial buildings. The second flagship project “Saerbeckian Insights – Renewables Made Transparent” developed a glass-heating system supplying a local heating network that conveys the concept of renewables in an educative manner. The third project “Steinfurtian Material Flows – The Circle is Closing” represents the conversion of a former ammunition depot to a bio-energypark based on PV, wind and biogas plants.
    All of these achievements  of the Climate Community-Project of Saerbeck could not have been realized without the strong support of the town's clubs and organizations, local churches, schools and educational facilities, and last but not least its citizens. Citizens and community both benefit from the security of renewable energy supply, financial participation and local added value.
  • Population: 7,149 (2016)
  • Area: 58.98 km2(22.77 sq mi)
  • Link: (In German)  https://www.klimakommune-saerbeck.de/
Solar module, Bioenergiepark Saerbeck, Germany
  • Installation of solar modules in Bioenergypark Saerbeck, Germany © Tameer Gunnar Eden/Eifeler Presse Agentur/epa CC BY 3.0