Electronic devices and mobile applications have become a part of everyday life. Fast technological progress and rapid product obsolescence have led to the rapid growth of waste electrical and electronic equipment (WEEE). Due to hazardous substances and also substantial amounts of valuable materials contained in electrical and electronic equipment, the European Union has implemented Directives related to WEEE, in order to reduce negative environmental and health impacts and to improve material recovery of valuable substances from WEEE. This paper provides an overview of the WEEE Directive and its implementation to national legislations in Finland, Sweden, and Norway and, further, describes how the nationwide WEEE recovery infrastructures in the Nordic countries have been built. The Nordic WEEE management systems are evaluated from the point of resource efficiency and best practices. Evidently, the WEEE management systems as established in the Nordic countries have advantages because the WEEE collection rates in 2012 were 12?kg/inhab./year, in Finland, 16?kg/inhab./year, in Sweden, and 27?kg/ inhab./year, in Norway, despite their sparsely populated nature. The Swedish and Norwegian experiences, especially, with long history of WEEE recovery indicate that increasing consumer awareness leads to more environmentally sound behaviour and improves recovery efficiency. 1. Introduction Production and use of electronic and electrical equipment have significantly increased during the last three decades; electronic devices and new applications have become a part of everyday life due to technological innovations. Fast technological progress, market expansion to developing countries, and product obsolescence have also led to the rapid growth of waste electrical and electronic equipment (WEEE). Due to burgeoning amounts and the complex mixture of materials and hazardous substances contained in electrical and electronic equipment (EEE), environmental and health impacts of WEEE have become increased concerns. While hazardous substances present in electronic equipment are not likely to be released during their regular use, they may pose hazards during waste treatment and disposal. In the mid-1990s, more than 90% of WEEE was landfilled, incinerated, or recovered without pretreatment and, therefore, a large proportion of hazardous substances found in the municipal waste stream came from WEEE. Already at that time, the amount of WEEE arising as waste was estimated to be around 6 million tonnes in the European Union (EU) and the growth rate of WEEE was expected to be 3–5% per
References
[1]
European Commission, “Proposal for WEEE and RoHS Directives,” COM 347 final, 2000.
[2]
European Commission, “Report on critical raw materials for the EU,” Report of the Ad hoc Working Group on Defining Critical Raw Material, European Commission, Brussel, Belgium, 2014, http://ec.europa.eu/enterprise/policies/raw-materials/files/docs/crm-report-on-critical-raw-materials_en.pdf.
[3]
European Commission, “Directive 2002/96/EC of the European Parliament and of the Council of 27 January 2003 on Waste Electrical and Electronic Equipment,” Official Journal L 37, 2003.
[4]
European Parliament, “The principle of subsidiarity,” 2012, http://circa.europa.eu/irc/opoce/fact_sheets/info/data/how/characteristics/article_7148_en.htm.
[5]
European Commission, “Staff working paper,” Tech. Rep. SEC/2008/2933, 2008.
[6]
M. Banti, “The new WEEE Directive and the main challenges under this new regime,” in Proceedings of the ISWA Beacon Conference: Optimising Collection and Recycling of WEEE, Düsseldorf, Germany, November 2013.
[7]
European Commission, “Directive 2012/19/EU of the European Parliament and of the Council of 4 July 2012 on Waste Electrical and Electronic Equipment (WEEE) Text with EEA relevance,” Official Journal L197, 2012.
[8]
Association of Finnish Local and Regional Authorities, “Population statistics,” 2014 (Finnish), http://www.kunnat.net/fi/tietopankit/tilastot/vaestotietoja/Sivut/default.aspx.
Nordic Centre for Spatial Development (Nordregio), “Population density 2012,” 2014, http://www.nordregio.se/en/Maps–Graphs/.
[13]
J. Yl?-Mella, K. Poikela, U. Lehtinen, R. L. Keiski, and E. Pongrácz, “Implementation of waste electrical and electronic equipment directive in Finland: evaluation of the collection network and challenges of the effective WEEE management,” Resources, Conservation and Recycling, vol. 86, pp. 38–46, 2014.
[14]
S. A. Lonn, J. A. Stuart, and A. Losada, “How collection methods and e-commerce impact product arrival rates to electronics return, reuse, and recycling centers,” in Proceeding of the IEEE International Symposium on Electronics and the Environment, pp. 228–233, San Francisco, Calif, USA, May 2002.
[15]
N. Truttmann and H. Rechberger, “Contribution to resource conservation by reuse of electrical and electronic household appliances,” Resources, Conservation and Recycling, vol. 48, no. 3, pp. 249–262, 2006.
[16]
M. Savage, S. Ogilvie, J. Slezak, and E. Artim, Implementation of Waste Electric and Electronic Equipment Directive in EU, European Commission, Directorate-General Joint Research Centre, Institute for Prospective Technological Studies, Luxemburg, Luxemburg, 2006, http://ftp.jrc.es/EURdoc/eur22231en.pdf.
[17]
United Nations Environmental Programme, “E-waste Volume III—WEEE/e-waste ‘Take back system’,” Division of Technology, Industry and Economics, International Environmental Technology Centre, P. 148, 2013, http://www.unep.org/ietc/InformationResources/Publications/E-wasteManual3/tabid/130121/Default.aspx.
[18]
P. Chancerel, Substance flow analysis of the recycling of small waste electrical and electronic equipment-an assessment of the recovery of gold and palladium [Ph.D. thesis], Technical University of Berlin, Berlin, Germany, 2010.
[19]
P. Tanskanen, “Management and recycling of electronic waste,” Acta Materialia, vol. 61, no. 3, pp. 1001–1011, 2013.
[20]
A. Toppila, Waste flows in Finnish producer responsibility system—case WEEE and portable batteries and accumulators [M.S. thesis], University of Jyv?skyl?, Jyv?skyl?, Finland, 2011, (Finnish).
[21]
H.-Y. Kang and J. M. Schoenung, “Electronic waste recycling: a review of U.S. infrastructure and technology options,” Resources, Conservation and Recycling, vol. 45, no. 4, pp. 368–400, 2005.
[22]
Ministry of the Environment in Finland, “Waste Act 646/2011”, 2014, http://finlex.fi/.
[23]
SERTY, “Data from EEE distributors' register,” 2014.
[24]
E. Oyj, “Waste treatment,” 2014, http://www.ekokem.fi/en/waste-services/waste-treatment.
[25]
J. Huisman, F. Magalini, R. Kuehr et al., 2008 Review of Directive 2002/96 on Waste Electrical and Electronic Equipment (WEEE), United Nations University, Bonn, Germany, 2007.
[26]
Y.-C. Jang and M. Kim, “Management of used & end-of-life mobile phones in Korea: a review,” Resources, Conservation and Recycling, vol. 55, no. 1, pp. 11–19, 2010.
[27]
F. W. Melissen, “Redesigning a collection system for “small” consumer electronics,” Waste Management, vol. 26, no. 11, pp. 1212–1221, 2006.
[28]
M. Polák and L. Drápalová, “Estimation of end of life mobile phones generation: the case study of the Czech Republic,” Waste Management, vol. 32, no. 8, pp. 1583–1591, 2012.
[29]
P. Tanskanen and E. Butler, “Mobile phone take back learning's from various initiatives,” in Proceedings of the IEEE International Symposium on Electronics & the Environment (ISEE '07), pp. 206–209, Orlando, Fla, USA, May 2007.
[30]
P. Tanskanen, “Electronics waste: recycling of mobile phones,” in Post-Consumer Waste Recycling and Optimal Production, E. Damanhuri, Ed., pp. 129–150, InTech, 2012, http://www.intechopen.com/books/post-consumer-waste-recycling-and-optimal-roduction/electronics-waste-recycling-of-mobile-phones.
[31]
El-Kretsen, 2014, http://www.el-kretsen.se.
[32]
H. M. Lee and E. Sundin, “The Swedish WEEE system—challenges and recommendations,” in Proceedings of the IEEE International Symposium on Sustainable Systems and Technology (ISSST '12), pp. 16–18, Boston, Mass, USA, May 2012.
[33]
U. Lehtinen, K. Poikela, J. Yl?-Mella, and E. Pongrácz, “Examining the WEEE recovery supply chain: empirical evidence from Sweden and Finland,” in Proceedings of the 21st Annual NOFOMA Conference, J?nk?ping, Sweden, June 2009.
[34]
A. Bernstad, J. la Cour Jansen, and H. Aspegren, “Property-close source separation of hazardous waste and waste electrical and electronic equipment—a Swedish case study,” Waste Management, vol. 31, no. 3, pp. 536–543, 2011.
[35]
A. Bernstad, J. La Cour Jansen, and H. Aspegren, “Local strategies for efficient management of solid household waste-the full-scale Augustenborg experiment,” Waste Management & Research, vol. 30, no. 2, pp. 200–212, 2012.
[36]
S. Miafodzyeva, N. Brandt, and M. Andersson, “Recycling behaviour of householders living in multicultural urban area: a case study of J?rva, Stockholm, Sweden,” Waste Management and Research, vol. 31, no. 5, pp. 447–457, 2013.
[37]
E. Román, “WEEE management in Europe: learning from best practice,” in Waste Electric and Electronic Equipment (WEEE) Handbook, V. Goodship and A. Stevels, Eds., pp. 493–525, Woodhead Publishing, 2012.
[38]
EE-registeret, 2014, http://www.eeregisteret.no.
[39]
E. Román, J. Yl?-Mella, E. Pongrácz, W. D. Solvang, and R. Keiski, “WEEE management system: cases in Norway and Finland,” in Proceedings of the Electronics Goes Green Conference, Berlin, Germany, September 2008.
[40]
State of the Environment Norway, “Waste electrical and electronic equipment,” 2014, http://www.environment.no/Topics/Waste/Waste-electrical-and-electronic-equipment/.
[41]
Ministry of Justice in Finland, Finlex Data Bank, 2014, http://finlex.fi/en/.
[42]
Government Offices of Sweden, “Environment, energy and planning,” Swedish Code of Statutes, 2014, http://www.government.se/sb/d/3288/a/19572.
[43]
Norwegian Environment Agency, “Regulations relating to the recycling of waste (waste regulations),” 2014, http://www.miljodirektoratet.no/no/Regelverk/Forskrifter/Regulations-relating-to-the-recycling-of-waste-Waste-Regulations.
[44]
Ministry of the Environment in Finland, “Economic influence and costs of Waste management in Finland,” Reports of Ministry of the Environment, 2014 (Finnish), http://www.ym.fi/fi-FI/Ajankohtaista/Julkaisut/Raportteja_RA.
Eurostat, “Environmental data centre on waste—Waste Electrical and Electronic Equipment (WEEE),” 2014, http://epp.eurostat.ec.europa.eu/portal/page/portal/waste/key_waste_streams/waste_electrical_electronic_equipment_weee.
[47]
Statistics Finland, “Official statistics in Finland 2011,” 2012, http://www.stat.fi/til/jate/2011/jate_2011_2012-11-20_fi.pdf.
[48]
Statistics Finland, “Official statistics in Finland 2012,” 2013, http://www.stat.fi/til/jate/2012/jate_2012_2013-11-26_fi.pdf.
[49]
E?F (Elektronik?tervinningsf?reningen i Sverige), “WEEE Statistics,” 2014, http://elektronikatervinning.com/en/information/weee-statistics/.
[50]
Eurostat, “Waste statistics—electrical and electronic equipment,” 2014, http://epp.eurostat.ec.europa.eu/statistics_explained/index.php/Waste_statistics_-_electrical_and_electronic_equipment.
[51]
J. Huisman, M. van der Maesen, R. J. J. Eijsbouts, F. Wang, C. P. Baldé, and C. A. Wielenga, The Dutch WEEE Flows, United Nations University, ISP-SCYCLE, Bonn, Germany, 2012.
[52]
R. Peagam, K. Mcintyre, L. Basson, and C. France, “Business-to-business information technology user practices at the end of life in the United Kingdom, Germany, and France,” Journal of Industrial Ecology, vol. 17, no. 2, pp. 224–237, 2013.
