Vattenfall Heat Uppsala
Transcription
Vattenfall Heat Uppsala
on ve rs i h l is En g Vattenfall Heat Uppsala Safety, Health and Environment 2014 Contents Foreword 3 Our products 4 Air emissions 5 Operations in Uppsala 6 Fuel mix in Uppsala 7 Facilities in Uppsala 8 Knivsta – almost exclusively carbon neutral heating 9 Operations in Storvreta 10 Fuel and ash 11 District heating in Sweden 12 We are working towards improved safety and health 13 We are working to reduce our impact on the environment 14 Vattenfall Heat Uppsala heats the city of Uppsala with district heating. We also produce and distribute district cooling and steam. Combined heat and power (CHP) produces electricity and heat at the same time, which is an efficient use of resources and therefore leads to a reduced impact on the environment. Emissions and environmental conditions 16 Our objectives within safety, health and the environment 17 Environmental glossary 19 Read more about district heating at www.vattenfall.se Management system for safety, health and the environment, plus energy and quality The management systems give structure to the work, and several areas border on each other. It can therefore be advantageous to have an integrated management system for safety, health and the environment, plus energy and quality. The diagram shows our management system with the elements of our everyday activities that are planned, managed and followed up. The management system is constantly being developed in order to better achieve our goal of reducing our environmental impact including energy use and improving safety and the work environment, as well as the quality for our customers using our waste incineration services. Our integrated management system is certified in accordance with environmental management standard ISO 14001 and registered in accordance with EMAS. This means that the environmental report is audited by an independent environmental auditor. The system is also health & safety certified according to OHSAS 18001, which is the international standard for work environment. We were the first power company in Sweden with an energy management system certified according to ISO 50001. The quality system for waste incineration is ISO 9001 certified. Situation analysis Policy Management review Legislation and other requirements Aspects/risks/ energy surveys SHM reporting Internal audit Action plan Objectives and objective programme Noncompliance Monitoring and measurement Organisation Training and skills Documentation Safety and protection Communications Operations Operation and maintenance Purchasing Contractors Chemicals Environmental auditor Intertek is one of SWEDAC’s accredited environmental auditors under EMAS (No. 1639). Vattenfall Heat Uppsala’s environmental management system complies with ISO 14001. Intertek has audited the environmental sections of the report and found them to be accurate and sufficiently detailed to meet the requirements in EMAS. EMAS registration number SE-000224. The registration includes the plants in Uppsala: the combined heat and power (CHP) plant, waste incineration, Bolandsverket, the gas turbine, Husbyborgsverket, Stallängsverket, the refrigerating plants in Ultuna and Ångström, and the distribution network, plus the Knivsta and Storvreta plants and distribution networks. 2 Vattenfall Heat Uppsala Safety, Health and Environment 2014 2014 – a warm year with low emissions As everybody knows, the year was a warm one and there was low demand for heat. During warm years, electricity generation is lower since electricity and heat are produced simultaneously in our CHP process. However, due to the warm year and many new connections, our cooling deliveries increased 20 per cent. We are pleased that emissions of climate-affecting carbon dioxide and acidifying substances such as nitrogen oxides and sulphur were low for the year. The decisions made by our customers are also making a difference, and sales of our Carbon Neutral Heating and Cooling decreased emissions by 11,000 tonnes of carbon dioxide. New architecturally significant buildings as customers It is always a joy when a collaboration leads to great solutions, for example at the Skandion Clinic in Uppsala, which officially opened in December 2014. It is the first clinic in the Nordic region for proton therapy, which treats cancer more effectively and with fewer side effects than conventional radiation therapy. It is a national project that is run jointly by the seven Swedish county councils with university hospitals. In collaboration with Akademiska Hus we have built a heat recovery facility to recycle the energy released during the proton treatment. Another architecturally significant building that will be supplied with district heating and cooling is Segerstedthuset at Uppsala University. Ground was broken in October 2014 for this new building, which will house the university’s management and administration. Safe workplace and constant improvements We had no accidents in 2014 that resulted in sick leave for either our own staff or our contractors. Safety is an important issue, and work on safety must be constantly improved. During the year we continued to work on a project for the safe shutdown of machinery, which is a key issue in this type of operations. We made a number of investments to continuously improve our plants in terms of safety, efficiency, environmental performance and availability. Some examples of larger measures taken during the year include new electrostatic precipitators for waste incineration and a new control system for flue gas condensation. We also invested in new, efficient compressors for compressed air, which together with reduced pressure in the system, and by repairing leakages, have cut the consumption of electricity for compressed air in half. Safety, Health and Environment 2014 In order to improve the security of supply and reduce our heat losses, we also took significant steps to reinvest in the existing network. Due to increased demand for district cooling, we have worked intensively on a project that has involved different groups within the company. We will find the best cooling solutions for the future while also taking care of existing customers. For example, we reviewed all substations in order to identify improvements. For both district cooling and district heating, improvements made anywhere in the system benefit the entire system. Now we go forward In order to meet Uppsala City’s needs for new capacity and move toward more sustainable energy solutions, Vattenfall is planning two major, crucial local investments: • The 40-year-old peat-fired plant will be phased out in favour of a new biomass-fired CHP plant that can deliver both electricity and heat. • A hot water boiler is being rebuilt to be able to burn biomass instead of peat. Vattenfall’s efforts to move away from peat will significantly reduce its impact on the environment and carbon dioxide emissions from the plant as a whole will be cut by more than 50 per cent. Waste incineration will continue in its current form with constant improvements. The largest share of combustible waste comes from Uppland and Mälardalen, but we also are accepting an increasing share of sorted, combustible household waste from Great Britain, Finland, Ireland and Norway. It may seem strange to import waste from other countries, but the majority of this waste is renewable and everything is recycled for energy after the material has fulfilled its role for society. The waste replaces other fuels at our facilities, and also a major improvement for the environment in Europe since the waste is not placed in landfills. Europe is currently reducing the amount of waste that is put in landfills, but half of all household waste still ends up there. In Sweden we have been able to implement reductions faster, and currently less than one per cent of our household waste is put in landfills. This is largely due to a functional infrastructure that includes waste incineration and a district heating network, assets that are well worth protecting and developing. Adrian Berg von Linde Head of Marketing & Distribution Heat Nordic Johan Siilakka Facility Manager Uppsala Vattenfall Heat Uppsala 3 Our products The building’s heating system District heating is our major product Water is pumped round the property’s closed heating system. It is heated in the heat exchanger District heating is distributed to households and by the district heating water. premises by transporting hot water in well-insulated pipes under high pressure to a central district heating unit in each property. The central unit contains a heat exchanger that utilises the hot water to heat up the building’s radiators and the hot water in the taps. The cooled district heating water is fed back to the district heating plant to be reheated and pumped Radiator out into the district heating system again. Heated water from the district heating plant District heating is flexible 75–120°C. as a number of different Heat exchanger fuels can be used. By using waste incineration, Cooled district heating this utilises resources water 40–60°C goes back Hot water. that would otherwise to the plant to be reheated. be lost. District heating Cold water from the water company. provides a secure supply The building’s heat exchanger The district heating water heats In the heat exchanger, the district heating is transferred and frees up space in the the tap water and shower water. to the building’s heating system. home. Customers have The two water systems are entirely separate from each other. low maintenance costs and can obtain help rapidly if needed. District cooling District cooling is based on the same principle as district heating, but with cold water. It replaces a large number of local refrigerating plants. There are numerous environmental benefits. Above all, it entails reduced electricity consumption and leakage of coolants into the atmosphere. It also means that there is no noise from local machinery. In the summer, we have spare capacity at the waste incineration plant as Uppsala’s heat requirements decrease. We are then able to use the existing plant to produce district cooling. We can offer local solutions for customers that do not have access to our district cooling grid. For example, cooling can be produced using district heating in what is known as an absorption refrigerator. Steam In Uppsala we also have a separate grid for steam for industrial premises. The steam is used in processes such as producing chemical reactions and sterilising. 4 Vattenfall Heat Uppsala Electricity We produce both district heating and electricity simultaneously with a high level of efficiency, an example of good utilisation of resources. The electricity we generate is not sold directly to end customers, but is included as a part of Vattenfall’s total electricity generation. Incineration services Combustible waste that can no longer be reused or recycled for materials should not go to landfill, but rather should go to waste incineration. The waste is processed and the energy in it is converted to district heating, electricity, district cooling and steam. We can even accept special types of waste, e.g. confidential documents in the form of paper and DVDs, etc. as well as hazardous waste, e.g. hospital waste. Safety, Health and Environment 2014 Air emissions from facilities in Uppsala Emission of carbon dioxide pe at co a n w in g an to at o pl P Le s pe s N ew bi om as 300 s- In fu el cr ea le d se d 400 pl w an t oo d co nt en t Le s 500 s n an to pl P C H 600 C H L pl ess an o t il, 700 l co nv er te d 800 to w ar p m Le eat w ow of ss in te th pe in r g e at t C o H ow m P i o pl ng re an t w t or as ef te ur bi sh m en t C H P 1,000 tonnes 200 100 Fossil fuel + peat Fossil fuel (oil + plastic) Projected development 20 2030 30 20 25 20 20 15 20 10 20 05 20 00 20 19 95 90 19 19 19 85 80 0 Trend line Emission of nitrogen dioxide and sulphur dioxide tonnes 1,600 1,400 1,200 1,000 Carbon dioxide that affects the climate During 2014 our carbon dioxide emissions decreased compared with 2013, in part because it was a warm year that did not require very much peat to be used as fuel on cold days. Peat is mainly used during the winter. The dotted line in the diagram shows our longterm plan for achieving carbon-neutral production by 2030. The measures mainly consist of an increased admixture of wood until such time as a new plant is commissioned around 2020 to replace our peat-fired CHP plant boiler. The fuel for the new CHP plant is based on renewable fuel such as wood chips and forest residues (branches and tops from logging activities). We will also carry out a fuel replacement for our hot water boiler, from peat to wood. We are offering our customers the opportunity to contribute to reduced CO2 emissions, in addition to the budgeted decrease, by choosing our Carbon Neutral Heating product and/or our Carbon Neutral Cooling product. Sale of these products reduced carbon dioxide emissions by almost 11,000 tonnes in 2014, compared to projections if no customers had chosen this offer. You can read more about these products on page 6 and on our website. Acidifying substances Nitrogen oxides and sulphur dioxide account for the greatest part of our acidifying emissions, and we are proud to announce that during 2014 we reached an all-time low. 800 600 400 200 Nitrogen dioxides 14 20 12 20 10 20 08 06 20 20 04 20 02 00 20 20 98 19 96 19 94 19 92 19 19 90 0 Sulphur dioxide Emission of dust tonnes 80 70 60 50 40 30 Dust Dust emissions for 2014 were at the same low level as in recent years. Historically the reduction from 2005 onwards has been due to reduced peat-firing and increased waste incineration. The waste incineration plant has the most extensive flue gas cleaning of all our production plants. Waste is the fuel that contains the most heavy metals. It is therefore important to achieve good performance for this flue gas cleaning and the plant surpasses the current environmental demands by a good margin, see page 16. 20 10 14 20 12 20 10 20 08 20 06 20 04 20 02 00 Safety, Health and Environment 2014 20 20 98 19 96 19 94 19 92 19 19 90 0 Vattenfall Heat Uppsala 5 100 Operations in Uppsala 100 80 Fuel 57 % Waste (1,063 GWh) 60 Energy supplied 80 District heating (1,266 GWh) 60 40 40 22 % Peat (411 GWh) 20 20 Process steam (92 GWh) 7 % Wood (123 GWh) 2 % Oil (42 GWh) 5 % Waste heat (63 GWh) 0 Electricity (net, 62 GWh) District cooling (40 GWh) 7 % Electricity (142 GWh) 0 Efficiency: 93 % Production 87 % Distribution Total efficiency 81 % Deliveries of 15 GWh of cooling were also supplied using ”island solutions”, i.e. independent of the district cooling network. The proportion of renewables in the fuel mix for district heating is 69 % with peat counted as (slowly) renewable. If peat is not included it is 49 %. Waste is calculated here as 60 % renewable in terms of energy, and the remainder is then nonrenewable, i.e. plastic with fossil origins. Key figures for delivered district heating, kg/MWh = g/kWh 2014 2013 20122011 CO2 in accordance with ETS 197 226 206223 CO2 in accordance with VMK 181 235 216254 NO 0.09 0.10 0.120.15 SO2 0.17 0.21 0.140.22 The emissions reported do not include the district heating and district cooling volumes produced from waste that is covered by customer-specific agreements (Carbon Neutral Heating and Cooling, respectively). This year we are reporting our carbon dioxide emissions using two different systems, as previously in accordance with the ETS emissions trading system and also in acc ordance with the Värmemarknadskommittén (Swedish Heating Market Committee) (VMK). The latter report is presented in more detail on the Swedish District Heating Association website, www.svenskfjarrvarme.se. This data includes not only carbon dioxide emissions from the plant but also templates for the emissions of the greenhouse gases methane and nitrous oxide, converted into CO2 equivalents. An emissions factor has also been added for the electricity that is purchased for the plant. Emissions are distributed between district heating and electricity produced using what is known as the Alternative Production Method. In brief, this means that more emissions are credited to the electricity compared with the heat produced at the same time, as alternative methods to generate electricity would require more fuel. The Swedish District Heating Association uses higher templates for peat than what we use, which are checked in the system for emissions trading. We include emissions trading for carbon dioxide Our plants are covered by the EU’s emissions trading scheme for carbon dioxide. For Sweden, waste incineration plants are included in the trading period which began in 2013. We also offer Carbon Neutral Heating and Cooling We offer larger customers a solution consisting of district heating and cooling from our waste incineration plant in Uppsala that is compensated for carbon dioxide. District heating and cooling is carbon neutral as we compensate for the proportion of the waste that is not renewable, i.e. the fossil-based plastic in the waste. We do this by increasing the amount of biomass in our total fuel mix, over and above the amount that is already planned*. Our basic plan is to increase the proportion of biomass every year, and sales of Carbon Neutral Heating and Cooling mean that the proportion of biomass is further increased. If customers choose Carbon Neutral Heating and/or Cooling they can join us in reducing carbon dioxide emissions even quicker than planned for Uppsala. See page 5. * Compensation is limited to the carbon dioxide emissions directly associated with our district heating production. 6 Vattenfall Heat Uppsala Safety, Health and Environment 2014 Fuel mix in Uppsala Fuel supply and heat production and electricity generation in Uppsala GWh 2,500 2,000 2,500 1,500 2,000 Heat production Safety, Health and Environment 2014 2011 2014 2009 2010 2013 2008 2012 2006 2007 2011 2005 2010 2003 2004 2009 2001 2002 2008 2000 1999 2006 1998 1997 2005 1996 2004 1995 1994 Electricity Electricity generation 2003 1991 1989 1990 2000 1988 1999 1986 1987 1998 1985 1984 1983 1993 Waste 1996 1982 1980 1981 1994 1992 Woo d Waste heat Production in Uppsala GWh/month 300 250 200 150 100 50 Waste incineration Combined power and heating plant, peat/wood Hot water boiler, peat/wood Dec Nov Oct Sep Aug Jul Jun May Apr Mar Feb 0 Jan Uppsala’s heat requirements govern production There is a big difference between Uppsala’s heat requirements during summer and winter and we adapt our production accordingly. The bar chart shows the usage of different plants during a normal year. The waste incineration plant heats Uppsala throughout the year, but during the winter the CHP plant is also needed. 1991 1990 1989 1988 1987 1986 1985 1984 1983 1982 1981 1980 Fuel supply Our mixture of fuels has changed over the years. We were entirely dependent on oil in the early 1980s. Since then, oil has been actively replaced, mainly by waste and peat. In the future, peat will be replaced by wood around 2020. 1993 0 0 Peat Waste heat Waste 500 1995 500 Ele 1992 1,000 Wood 2002 Electricity Coal 2007 Oil 2001 1,500 1,000 1997 Coal Oil Heat production Peat Heat pumps Oil boilers Vattenfall Heat Uppsala 7 Facilities in Uppsala Distribution network Accumulators District heating and district cooling are distributed to the heating and cooling systems of properties in the form of hot and cold water circulating in closed pipe systems. Our district heating network is 460 km long, and the district cooling network is 14 km long. We also have a 7 km network for steam. In order to meet the fluctuations in demand for district heating, there is a hot water accumulator inside the production area in Boländerna which holds 30,000 m3, providing 1,200 MWh of energy (100 MW) to the district heating network. There is also an accumulator for the district cooling network, which is located at Stallängsverket and is clearly visible from Kungsängsleden. It is 3,000 m3, 30 MWh and can supply 10 MW. Waste incineration Products: District heating, electricity, steam and district cooling. Capacity and fuel: Total of 170 MW heat + 10 MW elec tricity + 11 MW cooling, with 55 tonnes of waste per hour. Flue-gas cleaning: Nitrogen oxides – urea and ammonia injection and catalytic converters. Dust – electro-filters and fabric filters. Sulphur and hydrochloric acid cleaning – flue gas scrubber/condensation with energy recovery and fabric filter with limestone additive. Organic substances – fabric filters with active charcoal. Cleaning of flue gas condensate through limestone additive and complexing agent for heavy metals, then precipitation stage plus sand and charcoal filters. Gas turbine Backup for electricity generation. Product: Electricity for starting the CHP plant in the case of electrical power cut. Capacity and fuel: 16 MW electricity, light oil. Flue-gas cleaning: Additive in the oil results in less particle formation through more complete combustion. 8 Vattenfall Heat Uppsala The CHP plant Products: District heating and electricity. Capacity and fuel: 235 MW heating and 120 MW electricity with 80 tonnes of peat/wood briquettes per hour. Oil and coal are used as back-up fuels. Flue-gas cleaning: Sulphur – limestone additive in furnace and wet stage, before fabric filter. Nitrogen oxides – urea and ammonia injection and catalytic converters. Dust – electro-filters and fabric filters. Bolandverket Products: District heating and electricity. Capacity and fuel: Peat-fuelled hot-water furnace (HVC) 100 MW, electric furnace 10 and 50 MW (steam back-up), oil furnaces 4 x 75 MW (back-up). Flue-gas cleaning HVC: Sulphur – limestone additive in furnace. Nitrogen oxides – urea injection. Dust – electro-filters and fabric filters. Husbyborg unit Peak load and production back-up. Product: District heating. Capacity and fuel: Oil-fuelled hot-water furnaces 3 x 50 MW. Stallängsverket Heat pump facility located at Uppsala’s sewage works. Products: District heating and district cooling. Capacity: 3 x 15 MW heating and 3 x 8 MW cooling from electricity and waste heat. Cooling plant Ultuna Located at Ultuna Campus. Product: District cooling. Capacity: District heat-driven absorption refrigeration 1.5 MW, cooling tower 1 MW, compression refrigerating machines 1.3 MW. Cooling plant Ångström Located at Ångström laboratory. Product: District cooling. Capacity: District heat-driven absorption refrigeration 2.5 MW, cooling tower 2.7 MW, compression refrigerating machines 8 MW. Safety, Health and Environment 2014 Knivsta – almost exclusively carbon neutral heating In Knivsta, south of Uppsala, we supply district heating produced from biomass using our heating plant and district heating distribution network. The heating plant has two biomass-fuelled furnaces of 8 and 15 MW respectively, and oil furnaces for back-up and peak load. The fuel that is used is wood chips, bark and forest residues (branches and tops) from the forestry industry as well as other suppliers. An impressive 96 % of the fuel for the plant is biomass, which means that district heating in Knivsta is largely carbon-neutral. Knivsta has had district heating since 1976, and we have about 700 customers here. Our customers include both large buildings – such as schools and blocks of flats – and small buildings, such as single-family homes. 100 Fuel Energy supplied 100 96 % Biomass (64.3 GWh) 80 80 District heating (44.1 GWh) 100 60 60 40 80 20 3 % Electricity for pumps and fans, etc. (2.0 GWh) 0 1% Oil (0.8 GWh) 0 2014 2013 2012 2011 CO2 in accordance with ETS 5 15 7 12 CO2 in accordance with VMK 18 – – – NO 0.34 0.37 0.42 0.41 SO2 0.26 0.26 0.26 0.10 This year we are reporting our carbon dioxide emissions using two different systems, as previously in accordance with the ETS emissions trading system and also in accordance with the Värmemarknadskommittén (Swedish Heating Market Committee) (VMK). The latter report is presented in more detail on the Swedish District Heating Association website, www.svenskfjarrvarme.se. This data includes not only carbon dioxide emissions from the plant but also templates for the emissions of the greenhouse gases, methane and nitrous oxide, converted into CO2 equivalents. An emissions factor has also been added for the electricity that is purchased for the plant. The plant in Knivsta 40 20 Key figures for delivered district heating, kg/MWh = g/kWh Efficiency: 81.1% Production 60 80.5% Distribution Heat loss arises during both production and distribution. Smaller district heating networks and networks with many single family home customers have lower efficiency than larger distribution networks. Safety, Health and Environment 2014 40 Solid fuel furnaces Product: District heating Capacity and fuel: 8+15 MW wood chips, forest residues and bark Flue-gas cleaning: Dust – electro-filters Oil boilers Peak load and production back-up Product: District heating Capacity and fuel: 14 MW light oil Vattenfall Heat Uppsala 9 Operations in Storvreta – no oil in 2014 In Storvreta north of Uppsala, we supplied heating generated from wood as fuel in 2014. No oil was needed. Key figures for delivered district heating, kg/MWh = g/kWh 2014 CO2 in accordance with ETS The heating plant has two 2 MW furnaces fuelled with biomass fuel and an oil furnace in Ärentuna school for back-up and peak load. Wood pellets are used as fuel, with light oil for backup and peak loads. A large waterfilled underground rock cavity is used for heat storage and can deliver 8 MW. Fuel 100 99% Biomass (21 GWh) Energy supplied 100 District heating (13.6 GWh) 0% Oil 80 2013 2012 2011 0 12 13 16 CO2 in accordance with VMK 9 – – – NO 0.7 0.7 0.7 0.7 SO2 <0.003 <0.003 0.004 0.005 This year we are reporting our carbon dioxide emissions using two different systems, as previously in accordance with the ETS emissions trading system and also in accordance with the Värmemarknadskommittén (Swedish Heating Market Committee) (VMK). The latter report is presented in more detail on the Swedish District Heating Association website, www.svenskfjarrvarme.se. This data includes not only carbon dioxide emissions from the plant but also templates for the emissions of the greenhouse gases, methane and nitrous oxide, converted into CO2 equivalents. An emissions factor has also been added for the electricity that is purchased for the plant. Facilities in Storvreta 80 Solid fuel furnaces 60 60 40 40 20 20 0 0 1% Electricity for pumps and fans, etc., (0.2 GWh) 10 Vattenfall Heat Uppsala Efficiency: 85% Production including rock cavity storage 75 % Distribution Product: District heating Capacity and fuel: 2 x 2 MW wood pellets Flue-gas cleaning: Dust – cyclones Rock cavity Large rock cavity for storage of hot water Capacity: 2 x 4 MW storage volume 100,000 m3 (can store 5 GWh heat) Ärentuna school Peak load and production back-up Product: District heating Capacity and fuel: 4 MW light oil Safety, Health and Environment 2014 Fuel and ash Fuel in Uppsala The waste is composed of 50 per cent household waste and 50 per cent industrial waste. The majority of the waste comes from Uppland, Södermanland and Västmanland, but around 17 per cent is imported from Great Britain, Ireland, Norway and Åland. The peat comes in the form of briquettes from Härjedalen and Belarus. The peat fuel is mixed with wood pellets and wood briquettes. Coal and oil act as back-up fuels in case of delivery problems with the normal fuel or unavailability in the ordinary installations. Oil may also be needed for peak load during the very coldest winter days. More than one kind of ash Ash from waste incineration Waste incineration produces two different types of ash, as well as sludge from water treatment. The first type of ash is bottom ash from the furnaces, also called slag. The metals in the slag are sorted out and sent for recycling. The remaining ash is sorted into two different sizes. The fine fraction is used as a sealant and the coarse fraction is used as a drainage layer when covering landfills. The other type of ash is fly ash from the flue-gas cleaning. This ash contains material separated from the flue gases and is not suitable for roads, etc. Instead, it is handled at a waste site for hazardous waste or treated at Langöya in Norway, where it is used to neutralise other Safety, Health and Environment 2014 hazardous waste, such as acids, which constitutes a kind of recycling. There are also wet cleaning stages for the flue gases. The water from these cleaning stages is treated in a process which includes the addition of an organic sulphide, which binds heavy metals. The impurities are precipitated as a sludge, which is sent to a hazardous waste deposit site. This means that the heavy metals that make their way into the installation via waste are removed from circulation in society. In order for the quantity of heavy metals in waste to be reduced, products must be manufactured without them, or those who use items such as batteries and low-energy bulbs must recycle them carefully, so that they are not disposed of with combustible waste. Ash from peat-burning Peat produces ash that is ideal for constructing roads and other surfaces. We have forest roads in Uppsala and a jogging circuit in Storvreta where peat ash is used as construction material. The approach ramp in Librobäck’s recycling station is made of peat ash. There are also projects where the peat ash replaces cement, which saves one kilo of carbon dioxide emissions per kilo of replaced cement. One of the reasons that ashes from peat can be used in this way is because lime is added in the combustion process in order to bind sulphur. The lime content in the ash makes it hard, but simultaneously light. Vattenfall Heat Uppsala 11 energy recovery Recycling of material Biological treatment Landfills ige.se Treated amount of household waste Household waste in Sweden 1975–2013* Total amounts (thousand tonnes) 3,000 2,500 2,000 1,500 1,000 Incineration with energy recovery Recycling of materials Biological treatment 2013 2012 2011 2010 2009 2008 2007 2006 2005 2004 2003 2002 2001 2000 1999 1998 1997 1996 1995 1990 1985 1980 0 1975 500 Landfills * www.avfallsverige.se District heating in Sweden Over half of all homes and properties are heated using district heating. District heating is supplied to 270 of Sweden’s 290 municipalities and accounts for half of all heating of dwellings and other buildings, about 50 TWh per year. District heating is the main reason why Sweden has succeeded in reducing its emissions of greenhouse gases. District heating has doubled in Sweden since 1982, and in the same period, oil in the district heating system has been replaced by wood, peat and waste. Uppsala’s modified fuel consumption is shown on page 7. For more information about district heating: www.svenskfjarrvarme.se Waste as fuel The graph above from the Swedish Waste Management and Recycling Association shows how the treatment of household waste has developed in recent years. The total volume of household waste is 4.4 million tonnes, or around 460 kg per person per year. Increased recycling, biological treatment and waste incineration with energy 12 Vattenfall Heat Uppsala recovery made it possible to reduce the proportion of waste sent to landfill to 0.7 per cent in 2013. More information about Swedish waste management: www.avfallsverige.se Peat as fuel A quarter of Sweden’s surface area consists of peat (bogs and marshes). Peat is used both for soil improvement and as a fuel. The annual harvest is less than 25 % of annual growth in Sweden. Between 0.1% and 0.2 % of the peatlands are used. The Intergovernmental Panel on Climate Change (IPCC) places peat in a category of its own: neither fossil, like oil or coal, nor biomass, like wood. Peat is part of the European system for carbon dioxide trade, but in Sweden it is approved for a green electricity certificate, and is not subject to carbon dioxide tax. Until a common position is adopted as to peat’s possible climate impact, we will report carbon dioxide emissions both with and without contributions from peat (see page 5). For more information about peat: www.torvproducenterna.se Safety, Health and Environment 2014 We are working towards improved health and safety 70 60 50 40 30 ”Our goal is that all of our internal and external employees work in a safe, healthy and motivating environment. Our long-term goal is for zero injuries and no work related ill-health.” Safety is one of our core values – read our entire work environment policy in Vattenfall’s Code of Conduct, available at www.vattenfall.se. Vattenfall also has a ’Code of Conduct for Suppliers’ available on our website. In 2014 we also continued to work on the ’Safe Stop’ project, the aim of which is to reinforce the culture of safety and prevent accidents during maintenance work. 20 10 0 2007 2008 2009 2010 2011 Number of reported accidents/injuries and incidents in Uppsala Number 70 accidents incidents 60 We are working persistently to reduce risks associated with working at heights, with mobile parts of machinery, electricity and steam, as well as to prevent fires and explosions. As some of our activities take place in environments where there is a lot of traffic, we are also working actively to reduce the risks through, for example, diversions and hi-visibility clothing. For several years we have been spared serious accidents (death or severe disability) and fortunately the trend continued during 2014 as well. No accidents resulted in sick leave. To identify risks and enable us to take preventive measures, we use for instance incident reporting containing information on ’near accidents’. There are considerably more incidents than accidents, which enables us to institute preventive measures, thereby preventing future accidents. Besides incident reports we have other important tools to identify risks, for example risk assessments, work environment inspections and internal audits. Safety, Health and Environment 2014 50 40 30 20 10 0 2007 2008 2009 2010 2011 2012 2013 2014 It is important that a high number of near-accident reports are submitted so we are able to prevent actual accidents. The statistics include accidents with and without sick leave for employees and contractors. Vattenfall Heat Uppsala 13 We are aiming at reducing our impact on the environment In order to reduce our environmental impact, we are working on what we have identified as our significant environmental aspects.* Core indicators for our environmental impact are given partly as total consumption and partly as consumption per kWh supplied. Climate impact See diagram on page 5 for emissions of carbon dioxide and page 6 for emissions per supplied district heating. Uppsala also has emissions of other greenhouse gases. Nitrous oxide emissions (N2O) amount to some 12 tonnes per year, which with a conversion factor of 290 contributes less than 1% compared with carbon dioxide emissions We also use the coolant R134a which normally contributes less than one per cent compared with carbon dioxide emissions despite the large conversion factor of 1,430. Acidifying emissions See diagram on page 5 for emissions of substances that produce acidification such as nitrogen oxides and sulphur dioxide, and page 6 for emissions per district heating supplied. Nitrogen dioxide emissions for the Uppsala plants are below the average for Sweden in the nitrogen oxide fee system. More information about the nitrogen oxide fee is available at the Swedish Environmental Protection Agency’s website, www.naturvardsverket.se Energy efficiency Total energy turnover Our total energy turnover can be seen on pages 6, 9 and 10. It shows the degree of efficiency from fuel to delivery to the customer. We are working systematically on increasing energy efficiency, for example through new insulation for the accumulator tank, which resulted in major heat savings. * Internal electricity consumption For Uppsala we use about 75.6 GWh of electricity (45 kWh/produced MWh) per year for pumps, fans and other equipment, which is lower than the previous year and continues the trend of reduced electricity consumption. Electricity consumption for compressed air has been cut in half thanks to new, efficient compressors, reduced pressure in the system and the elimination of leaks. Efforts are being made to reduce the internal consumption of electricity, see page 17. For Knivsta we use about 2.0 GWh of electricity (36 kWh/produced MWh), and for Storvreta we use 0.19 GWh (10 kWh/MWh), which is comparable to the previous year. Electricity consumption Heat Uppsala (kWh/produced MWh) 55 50 45 40 35 2006 2007 2008 2009 2010 2011 2012 2013 2014 Electricity consumption is lower than in previous years, with the exception of cold years like 2010 when electricity consumption was lower per produced MWh since idling consumption is shared across a large production volume. The customer’s energy use also affects the environment Our customers’ energy consumption affects society’s use of resources and the degree of emissions. Examples of how we contribute to our customers’ good energy housekeeping are outlined below: - By providing free energy statistics via www.vattenfall. se/mina-sidor for all of our customers, it is possible for them to track trends and changes. - Breaking the charge into an effect portion and an energy portion will encourage an effect reduction. The need for heat is then reduced even during the coldest winter days, and oil can be used for peak loads. - Flow charges benefit larger customers if their district heating units are more efficient than the norm. - We recommend different types of energy optimisation adapted to the customer’s situation. We have skills, expertise and experience to offer, such as service and heat exchanger replacement, to help customers achieve a high degree of efficiency in their heating system. Contact us for more information about our assessment. See the back page for contact details. 14 Vattenfall Heat Uppsala Safety, Health and Environment 2014 Resource efficiency Our fuel consumption in Uppsala has refuse as a basis, which is a waste resource and thereby resource-efficient to use instead of other fuels. All our fuel consumption is shown on Page 6. Use of finite resources – coal and oil Coal is now only used as a back-up fuel, and oil for very cold weather and in case of interruptions in production. The proportion of oil in our fuel mix is around 2 per cent in Uppsala, 1 per cent in Knivsta and 0 per cent in Storvreta. Water For the Uppsala plant we used 491,000 m3 of water in 2014 (290 litres per delivered MWh), which is less than for 2013. For Knivsta we used 3,800 m3 of water (70 litres/MWh), which was less than for 2013. For Storvreta we used 1,900 m3 (100 litres/MWh), which was also less than for 2013. Waste Scrap metal is sorted from the slag from incinerated waste and recycled. Peat ash is recycled for road construction. Fly ash and sludge from waste incineration Each year about 10,000 tonnes of fly ash and sludge are produced from waste incineration. This is about 5 kg per MWh delivered, and does not change from year to year. The content of metal in the waste determines the amount of metal in the ash from waste incineration. The mercury content in the waste dropped significantly during the 1990s. Cadmium and lead levels remain unchanged, with no reduction. An organic sulphide is added and it binds metals such as mercury and cadmium. The sludge is separated through the waste incineration’s water purification treatment. The sludge and fly ash are considered hazardous waste and treated according to current regulations, which means that leaching from landfills is minimal. Good incineration reduces the content of organic matter in fly ash and sludge. Safety, Health and Environment 2014 Biodiversity Fuel suppliers can affect the environment and the work environment in different countries. Oil extraction has an environmental impact and there is a risk of oil spills in connection with transporting oil. Both the environment and the work environment are important when cutting peat. We have visited both our Swedish and our Belarusian suppliers to ensure that the conditions are good enough. We are also following developments around sustainability criteria for biomass fuels. Risk of environmental accidents Instituting preventive measures against accidents such as oil spills and fires is an important part of our work. We do this through, for example, maintenance, inspections, risk analyses and deviation reports. No major accidents occurred during 2014. Risk of disturbances in the local environment We prevent disturbances in the local environment, such as dust from peat and ash, by handing fuels and ashes indoors as far as possible. Disturbances can also arise from the odour of waste that is used as a fuel. We prevent this by working proactively in planning deliveries, waste inspections and controlling air flows in connection with waste treatment. One complaint was submitted in 2014 regarding the smell from our operations in Boländerna. The cause was fire-damaged and damp peat which gave off an acidic smell during a period while it was being ground prior to combustion. ”An important part of Vattenfall’s vision is to be one of the companies that are leading developments towards environmentally sustainable energy production.” Read our environmental policy at corporate. vattenfall.se/hallbarhet/miljofragor-ochvattenfalls-verksamhet Vattenfall Heat Uppsala 15 Emissions and environmental permits A selection of substances and conditions that are of interest from an environmental point of view are presented below. Air emissions from waste incineration Emission permit Results 2014 Annual average Dust, mg/m3 as mean daily average, measured continuously 10 No days over 10 0.18 Mercury, μg/m3, measured twice per year 25 0.01–0.1 Dioxins, μg/m3, measured twice per year 0.1 <0.002 Some values under the detection limit Total organic coal, mg/m3, as daily average, measured continuously 10 No days over 10 0.62 Dust is interesting from an environmental perspective as it can contain both heavy metals and hydrocarbon (unburned). It is consequently important to keep dust emissions down. However, mercury is a heavy metal that is not usually carried in dust and is therefore reported separately. Explanation mg milligram µg microgram ng nanogram Water emissions from waste incineration Emission permit Results 2014 Mercury kg per year, limit value, continuous measurement 0.5 <0.03 Lead kg per year, limit value, continuous measurement 12.5 2.0 Cadmium kg per year, limit value, continuous measurement 0.75 0.27 Dioxins ng/l, measured twice per year, target value 0.1 < 0.005 During the year a limited number of operational interruptions occurred, and these were reported to the environmental authority. Measures were taken to reduce the risk of new operational interruptions, for example through the installation of back-up oil 16 Vattenfall Heat Uppsala thousandth of a gram millionth of a gram billionth of a gram Some values under the detection limit Some values under the detection limit burners and optimisation of the feeder function. A full report on emissions and environmental permits can be found in our environmental report to the authorities, which is available from Vattenfall Heat Uppsala. Safety, Health and Environment 2014 The green housing company Uppsalahem is Uppsala’s leading housing company and its goal is to make Uppsala a greener city in terms of energy and the environment. ”As Uppsala’s greenest housing company, we want to promote a good environment in many different ways. An important choice for us is district heating from Vattenfall. This is in part because Vattenfall has concrete plans to decrease its CO2 emissions, but also because it already offers a CO2 neutral district heating product, which we have opted to purchase for all of our newly constructed residences,” says Fredrik Holm. Head of Business Development ”Another important aspect for Uppsalahem is the high security of supply from district heating, enabling us to provide heat and hot water 24 hours a day, every day of the year, without interruption to our 30,000 customers throughout Uppsala.” Fredrik Holm, Head of Business Development at Uppsalahem Our objectives within safety, health and the environment Targets Outcome 2014 Current and future work The relationship between incident reports and accidents should be at least 8 for production and maintenance. The target was met, the relationship was 10. The goal for production and maintenance in 2015 is at least eight preventive reports per accident for inhouse staff and at least six for contractors. For distribution operations, incident reporting must increase compared to 2012. The goal was met, near-accident reporting increased in 2014 compared to 2012 and 2013. The goal for production and maintenance in 2015 is at least eight preventive reports per accident for inhouse staff and at least six for contractors. Reduced impact on the climate via at least 12 % wood admixture in the peat, in addition to the wood admixture used for the Carbon Neutral Heating and Cooling. The wood admixture was 17% plus an additional 6 % via Carbon Neutral Heating and Cooling. At least 13 % wood admixture in 2015 plus sale of Carbon Neutral Heating and Cooling. A project is underway for a new wood-fired CHP plant around 2020, as well as a change from peat to wood in the HVC boiler, which will together halve CO2 emissions. Work on the new CHP plant continued during 2014. During 2015 work continues on both the HVC boiler and the CHP plant. Reduced internal electricity consumption in 2014 compared to 2013. Electricity consumption fell to 44.9 kWh per produced MWh compared to 45.3 for 2013 (the 2013 values have been adjusted). Work continues in 2015 to achieve more efficient consumption of energy internally, including measures to reduce steam consumption. Increased resource efficiency through the investigation of opportunities to improve the quality of the waste slag. An application has been submitted to continue the previous full scale leaching tests. This work continues during 2015 and the Swedish Energy Agency has granted project funds. Work environment and health Reduced climate impact Safety, Health and Environment 2014 Vattenfall Heat Uppsala 17 In this way we comply with Swedish environmental objectives Reduced Climate Impact Uppsala City Council’s objective is to decrease emissions of greenhouse gases per inhabitant by 50 per cent by 2020 compared with the level in 1990. Vattenfall Heat Uppsala has reduced carbon dioxide emissions by 33 per cent compared with 1990. Carbon dioxide emissions will be further reduced through our project of replacing peat with wood primarily when the CHP plant is replaced with a new plant around 2020. We are participating in the Uppsala Climate Protocol, which is a collaborative project started by the Uppsala municipality for reduced climate impact. Fresh air The County Administrative Board has stated that the greatest source of particle and nitrogen oxide emissions in Uppsala county is from traffic. Our contribution to inner city air particles is at most 0.004 μg/m3 of the environmental quality standard 50 per day. For nitrogen oxides, our contribution to inner city air is at most 1.5 μg/m3 of the environmental quality standard 90, per hour. Only natural acidification Our emissions from acidifying substances have dropped considerably over the years; see the graphs concerning acidifying substances on page 5. calculated as nitrogen, which constitutes one per cent of the total nitrogen emissions into the Fyris River. Good urban environment District heating allows cities and urban areas to provide a good and healthy lifestyle environment and also contribute to a good regional and global environment. In order for the buildings at our new CHP plant to be optimally designed for their surroundings in Boländerna, an architectural competition was announced. Such a tall building cannot be hidden, but must instead be designed as a landmark, in the same way as was done with waste incineration Block 5. Air emissions – mercury kg/year 600 500 400 300 200 100 18 Vattenfall Heat Uppsala 2000 2005 2010 2014 2000 2005 2010 2014 1995 1990 1985 1980 Air emissions – dioxins 15 g/year 12 9 6 3 1995 1990 0 1985 No eutrophication The Fyris River has a modest ecological status as per the Swedish Water Framework Directive, which is due to the transportation of nitrogen and phosphorous, primarily from agriculture but also from large and small waste water treatment plants. Vattenfall Heat Uppsala’s total emissions of nitrogenous substances have been reduced over the years as mentioned above, and are primarily in the form of airborne nitrogen oxides; around 50 tonnes per year calculated as nitrogen, or 4 per cent of the county’s emissions. Water emissions are around five tonnes per year 0 1980 A Non-Toxic Environment Our air emissions of mercury and dioxins have been dramatically reduced since the 1980s, see the diagrams to the right. Our water emissions contribute only a limited amount to the transport of heavy metals in the Fyris River. Our water emissions from the waste incineration’s flue gas condensation are reported on page 16. Safety, Health and Environment 2014 Environmental terms Sulphur, nitrogen oxides, hydrogen chloride and ammonia These substances cause acidification. It leads to nutrients leaching out of the ground and metals being released that are normally bound. Sulphur emissions have decreased throughout the entire country, thanks to reduced use of coal and oil. Nitrogen oxides are formed in connection with all combustion and affect the environment in four different ways as they lead to acidification, eutrophication, intensification of the greenhouse effect and formation of ground level ozone. Hydrogen chloride is a corrosive gas and together with water it forms hydrochloric acid, which is acidifying. Ordinary salts can form hydrogen chloride in conjunction with waste incineration Hydrogen chloride is removed from flue gas through condensing. Ammonia also appears to be acidifying as it easily forms ammonium ions, which are weak acids. Dust Dust is particles of ash that are released into the air from industries and cars. The dust can contain heavy metals and hydrocarbon. We clean the flue gases of dust using electrofilters and fabric filters. The dust from waste incineration (fly ash) is hazardous waste. Fly ash from peat and wood contains only low levels of pollutants and can be used, for example, in road building and as a substitute for cement. Carbon dioxide Carbon dioxide is a gas that is found naturally in the air and is one of the most important substances in photosynthesis. However, a distinction is made between the amount of carbon dioxide that is part of the natural cycle, and the surplus that arises through use of fossil fuels. This surplus intensifies the greenhouse effect. The increase that disturbs the balance is caused chiefly by traffic and burning of fossil fuels such as oil and coal. On the other hand, the amount of carbon dioxide that arises when biomass fuels are used is absorbed again by plants. Opinion is divided on whether peat should be regarded as a biomass fuel (slowly renewable) or not. The annual growth of peat in Sweden is greater than its removal, but the peat used can be thousands of years old. Peat moss emits carbon dioxide if there is a supply of air in the peat layers (aerobic conditions). If there is no supply of air (anaerobic conditions), methane gas is produced, which is a stronger greenhouse gas than carbon dioxide. It is therefore a fairly difficult equation Safety, Health and Environment 2014 to balance between the climatic impact from peat usage and its combustion. Dioxin Dioxins are a group of over 200 different chlorinated hydrocarbons. Some of the variants are highly toxic. In principle, dioxin arises in connection with all combustion, where landfill fires are the worst. A single short-lived fire at a landfill site produces more emissions of dioxin into the air than Heat Uppsala’s waste incineration plant does in ten years, which is one of the reasons why there is a ban on dumping combustible waste in landfills. Heavy metals The heavy metals that have the most effect on the environment are mercury, lead and cadmium. They are naturally present in all animals and plants, but only in small quantities. If their content increases unnaturally, these heavy metals are highly powerful environmental toxins. In Sweden, emissions of many heavy metals have declined substantially in recent years, thanks to new processing techniques, better cleaning techniques, a ban on mercury, increased collection of batteries and a ban on lead in petrol. The major sources of emissions of mercury are crematoriums and chlor-alkali industries. For cadmium it is the metal industries. Waste incineration in Sweden accounts for less than one per cent of the total air emissions of heavy metals. More information • The industry association Swedish Waste Management has information about waste handling: www.avfallsverige.se • Swedish district heating: www.svenskfjarrvarme.se • Swedish peat production: www.torvproducenterna.se • The Swedish Energy Authority has statistics on energy use in Sweden and information about energy and energy efficiency: www.energimyndigheten.se • Energy advice and environmental programmes, Uppsala Municipality www.uppsala.se and Uppsala Municipality’s Climate Protocol. • Follow-up of Sweden’s environmental objectives is available at www.miljomal.nu For more information about Vattenfall, you can visit our website: www.vattenfall.se Vattenfall Heat Uppsala 19 Heat Uppsala is a business unit in Vattenfall AB. District heating is the largest part of our business and our customers are real estate companies, housing associations, home owners, industrial and public facilities, such as schools, swimming pools and libraries. The business covers the entire value chain: generation, distribution and sales. We also offer district cooling and steam, with the latter being used in industrial processes. Producing electricity and heat simultaneously delivers a high level of efficiency. Uppsala has Vattenfall’s largest plant for district heating in Sweden. Our major district heating plants in Sweden, including subsidiaries 1 Volume of heat: 4,000 GWh Volume of electricity: 380 GWh Turnover: MSEK 3,0002 Employees: 400 Vänersborg Haparanda Ludvika Fagersta Uppsala Southern Greater Stockholm Motala Nyköping Visby If you have questions please contact us: Vattenfall Heat Uppsala Visit: Vattenfall Heat Uppsala Bolandsgatan 13 varme@vattenfall.com 1. Västerbergslagens Energi AB (VB Energi), Gotlands Energi AB (Geab), and Haparanda Värmeverk. 2. This information includes revenues from energy sales (electricity, heating, cooling and steam), and certain other revenues, primarily waste and back-up power. September 2015. Blomquist & Co. Customer enquiries: Vattenfall Customer Service PO Box 13 SE-880 30 Näsåker, Sweden Telephone: +46 (0)20 82 00 00 Email: kundservice@vattenfall.com www.vattenfall.se/uppsala