November 10, 2021

by AEA in News, Publication, Renewable

Development of Wind Power Projects in Albania -Wind Siting Study

This study analysis of Albanian territory aimed to find potentially suitable areas to develop new Wind Projects. A Geographic Information System (GIS) was implemented to collect and manage relevant data describing physical, biological and social features that characterize the Country.
The methodology consisted in a Multi-Criteria Decision Analysis (MCDA), based on GIS data, used to develop spatial criteria to support the decision-making process for the identification of the most suitable areas for new Wind Projects.
This study will be subject to periodic review and update. The criteria chosen for determining the suitability of areas for wind projects reflect policy choices at the date of publication.
The criteria identified as either constraints or no-go areas (to identify exclusions) or indicators (to characterize a higher or lower suitability) were implemented in response to a series of sustainability goals. The criteria were grouped into three sustainability dimensions, Environmental, Social and Technical, and weighted based on their relative importance, according to a consultation process with stakeholders.
The application of the proprietary GoldSET Spatial tool allowed to combine criteria and weights to produce a Suitability map. The final step was to analyse the suitability map and to identify large areas, presenting the higher values of suitability.

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August 20, 2019

by AEA in Energy, Events, News, Partners, Renewable

HYDROPOWER EUROPE seeks input from hydropower stakeholders

HYDROPOWER EUROPE is an EU-funded project that aims to create a Forum gathering all the hydropower stakeholders throughout Europe.

The project is currently undertaking a consultation process directed at collecting input from such stakeholders, with the ultimate goal of achieving a Research and Innovation Agenda (RIA) and a Strategic Industry Roadmap (SIR) for the sector. A vital part of the consultation process will take place at three one-and-a half day regional workshops, organized to discuss regional issues and hydropower challenges in three different climatic regions, with the intervention of expert industry and high-level official speakers. During the events, groups of participants will also lay out analyses for hydropower-related statements and exchange their views on the two main documents (RIA, SIR).

Register now on the Consultation Platform and sign up for the regional workshops (see below for details). Participation is free of charge:

Nordic workshop: 28-29 August 2019 in Lulea, Sweden.
Alpine workshop: 11-12 September 2019 in Lausanne, Switzerland.
Mediterranean workshop: 30 September – 1 October 2019 in Chania, Greece.

For more details on the HYDROPOWER EUROPE project, visit: www.hydropower-europe.eu

February 15, 2013

by AEA in News, Publication, Renewable

Albania Biomass

Biomass CO2 cycle

The term biomass covers a wide variety of both fuel and conversion technologies. Usually, the term biomass refers to woody or agricultural products being converted into useful energy through different conversion technologies (Ecofys BV 2006). Biomass often refers to solid materials such as wood, branches, industrial wood waste, urban solid waste and agricultural residues (agriculture plants, animal feeding); whereas bio-fuel refers to the (final) products that are liquids. Important conversion technologies are: Burning, incineration, Gasification, Digestion

Background

For ages, Albanians rely on fuel wood for cooking their food and heating their homes. Therefore, there is nothing new about biomass resources. However, it is the conversion technology and the size of these different new technologies that make things new. Biomass can be used as fuel for power plants (electricity), heat boilers (heat) and cogeneration (both heat and electricity). New plants can be constructed, but biomass can also replace coal (lignite, anthracite) in existing power stations, up to a certain percentage. Especially older power stations, which can deal with a variety of fuel qualities, might well be able to deal with biomass, next to fossil fuels such as lignite and anthracite. The term is then ‘co-firing’.

Potential

Biomass resources, woods, are plentiful available in Albania, especially in the mountainous regions. This does not mean automatically, though, that the potential for biomass is high. The woods are protected and/or part of nature reserves, or there are claims from logging/building/furniture industries. This means, woods have other economical and nature reserves, more important than those as biomass. On the European market, we see therefore that secondary woody materials are more and more being utilized as biomass, for example by compacting (pelletising or briquetting) sawdust or wood chips into a uniform product that can be traded in Europe and possibly worldwide (Ecofys BV 2006). Obviously, concerns about selling out the woods should be dealt with; the sustainability of woods and the contribution to biodiversity could be at stake. Woods and forests should be treated as natural reserve. An example to combat the abuse of woods is the introduction of the FSC label (‘Forestry Stewardship Council’), with which woods can be exploited for the different purposes, and still have enough time to be regenerated once the trees are felled.

According to some approximate estimation, the energy potential from agricultural residues were calculated at approximately around 800 toe/year in 1980; while in 2001 were around 130 toe/year. The potential of urban wastes from the main Albanian cities was calculated as approximately 405615 ton oil equivalent (Toe), predicted for the year 2010 (EBRD 2004).

The wood sources in Albania are concentrated in the forestry zones that cover around 38.2% of the total surface. The data on forest resources are based on inventories done every 10 years from the Forestry Directorate subordinated to the Ministry of Agriculture. Total forecasted resources reach some 125 million m³ (14.3 toe). Forests are classified in these major categories: high forests which represent 47-50% of the total wood resources; copses which are 29-30% of the total resources; and bushes, which are 24-25% of the total wood resources. From the three aforementioned categories, 10% of high forests, 50% of copses and 100% of bushes are used as fuel wood. From this data, proven resources of fuel wood are respectively 5.87, 18.25 and 30 million m³. The total proven reserves of fuel wood are considered about 6 Mtoe (Hizmo 2006).

The energy potential from animal residue’s as well as for agricultural residue potations is calculated at approximately 70 [toe/year] 12 740 GJ in 1995 with a trend to be increased in the future. These numbers should be considered estimates; a more comprehensive study should be carried out for real validation.

Figure 6 Territorial distributions of forest according to main government regime

Installed capacity

It is expected that, apart from a wide variety of old wood stoves and furnaces working on wood, several modern wood boilers are in operation, possibly at wood industry locations, to heat production halls and facilities. The increase of the biomass contribution is primarily based on a more efficient use of the fire wood. The actual average yield of fire woods is 35-40%. It is foreseen that in 2025 Albania will have a penetration of family market heaters with an average yield of 75-85%.

Characteristic features for Albania

As a rugged country, with limited fossil fuel resources (lignite), and an economy that is still close to its agricultural roots, there are good opportunities to develop the biomass potential much further. Environmental concerns should be taken care of, in order not to have a continuous and clean supply of indigenous energy and to prevent a sell out of the natural resources of the country.

Actually, from the categories mentioned above, the wood waste from the wood industry and solid urban waste biomass can be of a considerable contribution. Biomass from the agriculture is connected with agricultural plants being used to feed the animals during winter time.

A biomass group, which can be very profitable, consist of the cores of olive, peaches, etc. These cores that are waste of alimentary industry can be burnt supplying warm water or steam for different technology processes in the alimentary industry. The biomass from the so-called energetic plants is not applied yet in Albania. It still needs to be stressed the importance of the incentive policies on the application of these kinds of plants.

Another important group that can be taken into consideration on the energy supply is the high richness of bushes. They can be considered without any doubt, as a very good source of renewable energy, as they will always be growing up. Whereas biomass produced from the animal breeding can not be taken into consideration due to a low number of the house animals and lack of division of farms (a farm consist of a very small number of cows and other animals) and a small amount of waste, which actually are being used as organic fertilizer.

February 15, 2013

by AEA in Energy, Publication, Renewable

Climate characteristics of Albania

Albania is one of the Mediterranean countries. The geographic position of Albania gives to this country a Mediterranean climate, which is characterized by a wet and soft winter and a hot and dry summer. The climate regime of Albania is influenced by the frequency of occasional atmospheric systems, which are mainly the depressions coming from North Atlantic and Mediterranean Sea including the anti-cyclones coming from Siberia and Azores, as well. One of the main other factors that influence the climate conditions of a certain region is the closeness to the sea (IHM 1978).

As far as the Albanian territory is concerned, it has been noticed that there is a considerable increase from the sea level and removal towards the inner part of the territory. The inner part of the country is basically mountainous. The influences of the before-mentioned factors have brought out a great number of indicators and climate parameters in different regions of Albania.

As mentioned, the territory of Albania is divided in four main climate areas. Whole its elements are basically stable. These areas are name as following: The Field Mediterranean Area, The Hilly Mediterranean Area, The Pre-mountainous Mediterranean Area and Mountainous Mediterranean Area.

Figure 2 Mean average air temperature in the main cities of Albania for the period 1961 – 2000.

Air Temperature

The distribution of the temperatures in Albania presents a considerable variability. The annual average temperature is 8-9 ⁰C in the mountainous area up to 17 ⁰C in the seaside south-west area. During the year, the curb of the temperatures in the whole country is quite regular with a maximum in the summer months and the minimum in the winter months, as presented in the Figure 2. The period of the average of these calculations is during the years 1961-2000 .

The Annex A shows some tables with average middle monthly temperatures in the main cities for a period of 40 years. Some graphics that indicate the annual progress of the air temperature for the last 10 years are presented, as well. It is very interesting to analyze the data given in Annex A. It results that the variability of the temperatures in July (the highest) and January (the lowest) is lower than the one in the stations within the country. Concretely, in Vlora this difference is approximately 15 ⁰C, in Kukes approximately 21.5 ⁰C. This fact confirms the influence of the seaside in the territories around it. This influence does not allow a decrease of the air temperature during winter and a high increase during summer.

Figure 3 Daily mean average solar radiation for the 3 meteorological stations in Albania

Solar radiation

Figure 3 presents the daily mean average solar radiation according to the months for 3 main meteorological stations in Albania. It shows, as well, the existence of huge differences between the different seasons and stations in the country. According to these data, Peshkopia station, located in North-East shows a difference from a minimum of 1,5 kWh/m² in December to a maximum of 6.25 kWh/m² in July. The same phenomenon happens in the other stations as well (EEC 2005).

The ratio between the month of the highest solar radiation and the one of the minimal solar radiation varies from the smallest values of 4 for the stations of Erseka and Saranda to the values of 5 kWh/m² for Fier and Peshkopi. Annex A includes a detailed table with data for each station.

Figure 4 Average quantity of the monthly falls in the main cities of Albania during period of
1961 – 2000

Rain falls

The rainfalls in Albania have a Mediterranean regime. They are mainly active during winter months (65-75 % of the annual quantity) and less during the summer ones. Albania is characterized from a huge variation as far as the territorial distribution is concerned. The annual amount varies from 650 mm in the South-East to 2800 mm in the Alps of Albania. The average amount of falls for the whole territory is approximately 1400 mm annually. This is an indicator for a huge slack of falls, which can be used for energy. Below there is a graphic of the average amount of falls for the period of 40 years: 1961 – 2000. Compared to the temperatures, the falls’ regime in the last 10 years can be easily distinguished from previous one. The detail amount on the falls in the last 10 years is enclosed in Annex A.