Waste management

The goal of conventional waste management is to prevent the production of waste and to reduce the amount of landfill waste through effective sorting. Waste management at the Loviisa power plant is comprised of two separate areas: waste management for the non-controlled area and waste management for the controlled area. All waste generated in the controlled area is treated as radioactive. Waste generated outside the controlled area can be treated as waste from a conventional industrial plant.

Low and intermediate level waste repository at Loviisa npp.

In 2016, a total of 730 tonnes of waste was transported out from the power plant area. Of this, 10% was landfilled, 82% was recycled and the remaining 8% was treated as hazardous waste. The annual waste intake depends on the length of the annual outage and particularly the deconstruction works carried out during that time.

Waste generated in the controlled area is divided into three categories: low-level waste (maintenance waste), intermediate- level waste (liquid waste), and high-level waste (spent fuel). Maintenance waste is either cleared as non-active and treated as conventional waste, or disposed of in the final repository located in a depth of 110 metres in the power plant area.

Liquid waste is treated and conducted into the sea or stored and solidified in concrete. In February 2016, the solidification plant for liquid radioactive waste started its full operation - a significant step forward in the power plant’s waste management.

Spent fuel is stored to await final disposal at Posiva Oy’s facilities in Olkiluoto, Eurajoki. Posiva Oy is an expert organisation responsible for the final disposal of spent nuclear fuel of the owners, Fortum and Teollisuuden Voima.

Nuclear waste management

What happens to spent nuclear fuel?
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Nuclear power plants produce electricity using uranium as fuel. The energy in uranium is in a tightly compressed format, so the amount of spent fuel is small. Spent nuclear fuel is radioactive. Therefore, it must be kept isolated until its radioactivity has decreased to a harmless level. This isolation is called final disposal.

Posiva, founded and owned by Fortum and another Finnish nuclear operator, TVO, takes care of the final nuclear waste disposal of their nuclear power plants. The plan is to dispose of high-level nuclear waste in the final repository of Posiva in Olkiluoto, in the municipality of Eurajoki. The final repository and related encapsulation unit are expected to be ready for use in 2020.

The Finnish Government granted in November 2015 a licence to Posiva for the construction of a final disposal facility for spent nuclear fuel. After extensive and multidisciplinary research and development work, Posiva can now proceed with construction of the final disposal facility in Olkiluoto according to the concept it has developed. The final disposal of the spent fuel generated in the Olkiluoto and Loviisa nuclear power plants into the Finnish bedrock is planned to start in the early 2020s.

SKB (Svensk Kärnbränslehantering AB) is responsible for managing the waste created by Fortum's co-owned nuclear power production in Sweden. A final repository for spent nuclear fuel is being built in Forsmark, in the municipality of Östhammar. The plan is to complete the construction by the end of this decade. After construction and the pilot period, final disposal can begin at the end of the next decade.

Who is responsible for nuclear waste?
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In Finland, the law stipulates that each producer of nuclear power-generated electricity is responsible for its own nuclear waste management.​ Fortum Power and Heat Oy and Teollisuuden Voima Oyj have established Posiva Oy to manage the research and development work required for the disposal of the spent nuclear fuel produced at their power plants as well as the implementation of the selected disposal solution.

The Ministry of Employment and the Economy holds the highest power of control and supervision over nuclear waste management in Finland. The Ministry prepares the legislation concerning nuclear waste as well as any associated international agreements with regard to Finland. It also supervises adherence to the legislation and agreements.

The Radiation and Nuclear Safety Authority (STUK) supervises the safety of nuclear power generation. STUK prepares instructions and regulations on nuclear safety and inspects the safety of the power plants. The safety aspects of nuclear waste processing and storage also fall within the scope of STUK's supervision activities.

What are the responsibilities in final disposal?
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The processing of nuclear waste is governed by the Nuclear Energy Act, the Nuclear Energy Decree, and a Government Decree. Amended in 1994, the Nuclear Energy Act stipulates that all spent nuclear fuel produced in Finland must be disposed of in the Finnish bedrock. The same legislation also prohibits the import, and disposal of, foreign nuclear waste in Finland.

The Government Decree on the safety of the final disposal of nuclear waste stipulates the following concerning the long-term radiation effects of final disposal: “The annual dose of the persons with the greatest exposure shall remain below 0.1 mSv (millisieverts), and the average annual doses of other persons shall remain insignificant.”

With regard to the management of radioactive substances, Fortum always strives to keep any emissions well below both the emission limits set by the authorities and Fortum's own target limits, which are more stringent than the official limits.


How was the site for final disposal chosen?
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The disposal solution is the result of decades of research and development work aimed at developing a safe solution for the permanent isolation of nuclear waste.

The Olkiluoto island was chosen as the site of the repository from among many survey sites on the basis of location surveys and safety assessments carried out between 1987 and 2000. The underground research facility ONKALO, which Posiva started to construct in 2004, has enabled research at the actual disposal depth. The aim has been to preserve the good characteristics of the rock as far as possible in the construction phase of the underground research facility.

The research carried out during the construction has confirmed earlier assumptions about the rock properties. Based on the research, it is now known that there are few cracks in the bedrock at the disposal depth the bedrock is stable at a depth of hundreds of meters, the  roundwater is oxygen-free the groundwater flow is minimal.

The safety of final disposal is supported with information obtained through research. The bedrock, the materials used in the disposal process, and the functionality of the technical solutions are subjected to safety studies.

An extensive body of assessment documentation, known as the safety case, is prepared to prove the safety of final disposal. The most central part of the safety case is scenario analysis whereby the behavior of the final disposal system installed deep in bedrock is assessed on the basis of postulated event sequences. The temporal scopes of the analyses stretch far into the future, and they consider factors such as climate change and the formation of a thick glacier as well as associated rock movement.

Further proof of the safety of final disposal for the safety case may be gathered by observing so-called natural analogs—in other words, by making comparisons with nature.​

Natural analogs are examples, observed around the world, of how naturally occurring materials have behaved under different conditions over long periods of time. By studying nature, it is possible to establish how copper, clay, and radioactive substances behave under different conditions over long periods of time. This has led to a better understanding of the representativeness of the models used to describe the functionality of the disposal system.

It is now known, for example, that clay has effectively stopped the migration of uranium as well as other radioactive substances from a radioactive uranium deposit deep in the bedrock in Cigar Lake, northern Canada. No radiation levels differing from the normal natural background radiation levels can be observed above ground in the area.

Furthermore, natural copper formations found around the world have persisted for up to millions of years, which can be considered as proof of the long-term strength of copper canisters placed deep in the bedrock. In Hyrkkölä in southern Finland, for example, copper occurs in its original form in granite rocks despite having been exposed to groundwater containing sulfide under oxidizing conditions.

Who pays for the costs of disposal?
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Companies with a nuclear waste management obligation prepare for the costs by collecting funds in advance in the price of electricity and depositing them in a specific fund. This provides society with a financial guarantee for the handling of nuclear waste management under all circumstances.

The Finnish State Nuclear Waste Management Fund was established in 1988 in accordance with the Nuclear Energy Act. Separate from the state budget, the fund is controlled by the Ministry of Employment and the Economy. The purpose of the fund is to collect, preserve, and safely invest the funds required for the management of nuclear waste in the future.

The fund's capital consists of annual payments by the companies with a nuclear waste management obligation as well as the fund's revenue. The Ministry makes annual decisions on the amount of cost liability at the current price level on the basis of reports submitted by the companies with a nuclear waste management obligation. The total amount of collected funds must, at any given time, correspond to the costs of nuclear waste management activities not yet implemented.

Nuclear waste management payments collected in the fund also cover any research and development costs and the costs incurred from official supervision and administrative activities.