Abstract
Background, aim and scope
The evaluation of packaging’s environmental performance usually concentrates on a comparison of different packaging materials or designs. Another important aspect in life cycle assessment (LCA) studies on packaging is the recycling or treatment of packaging wastes. LCA studies of packed food include the packaging with specific focus on the contribution of the packaging to the total results. The consumption behaviour is often assessed only roughly. Packaging is facilitating the distribution of goods to the society. Broader approaches, which focus on the life cycle of packed goods, including the entire supply system and the consumption of goods, are necessary to get an environmental footprint of the system with respect to sustainable production and consumption.
Materials and methods
A full LCA study has been conducted for two food products: coffee and butter packed in flexible packaging systems. The aim was to investigate the environmental performance of packaging with respect to its function within the life cycle of goods. The study looks at the environmental relevance of stages and interdependencies within the life cycle of goods whilst taking consumers’ behaviour and portion sizes into consideration. The impact assessment is based on the following impact categories: non-renewable cumulative energy demand (CED), climate change, ozone layer depletion (ODP), acidification, and eutrophication.
Results
The study shows that the most relevant environmental aspects for a cup of coffee are brewing (i.e. the heating of water) and coffee production. Transport and retail packaging are of minor importance. Brewing and coffee production have an impact share between 40% (ODP, white instant coffee) and 99% (eutrophication, black coffee). Milk added for white coffee is relevant for this type of preparation. The instant coffee in the one-portion stick-pack needs more packaging material per cup of coffee and is prepared by a kettle with lower energy demand, such as a coffee machine, thus leading to higher shares of the retail packaging in all indicators. A one-portion stick-pack can prevent wastage and resources related to coffee production can be saved. The most relevant aspect regarding the life cycle of butter is butter production, dominated by the provision of milk. Over 80% of the burdens in butter production stem from the provision of milk for all indicators discussed. Regarding climate change, methane and dinitrogen monoxide, emissions of milk cows and fodder production are most relevant. Fertilisation during livestock husbandry is responsible for most burdens regarding acidification and eutrophication. The distribution and selling stage influences the indicators CED and ODP distinctly. The reasons are, on the one hand, the relatively energy-intensive storage in supermarkets and, on the other hand, the use of refrigerants for chilled storage and transportation. The storage of butter in a refrigerator for 30 days is responsible for about 10% of the CED.
Discussion
Several aspects have been modelled in a sensitivity analysis. The influence of coffee packaging disposal is very small due to the general low influence of packaging. In contrast, the brewing behaviour is highly relevant for the environmental impact of a cup of coffee. That applies similarly to the type of heating device—i.e. using a kettle or an automatic coffee machine. Wastage leads to a significant increase of all indicators. Under the wastage scenario, the coffee from one-portion stick-packs has a considerable better environmental performance concerning all indicators because, in case of instant coffee wastage of hot water and in case of ground coffee wastage of prepared coffee, has been predicted. Regardless of urban or countryside distances, grocery shopping has a low impact. The storage time of butter is relevant for the results in the indicator non-renewable CED. This is mainly the case when butter is stored as stock in the freezer. The end of life treatment of the packaging system has practically no influence on the results. Grocery shopping is of limited importance no matter which means of transport are used or which distances are regarded. Spoilage or wastage is of great importance: a spoilage/wastage of one third results in about 49% increased impacts compared to the standard case for all indicators calculated.
Conclusions
The most important factors concerning the environmental impact from the whole supply chain of a cup of coffee are the brewing of coffee, its cultivation and production and the milk production in case of white coffee. The study highlights consumer behaviour- and packaging-related measures to reduce the environmental impact of a cup of coffee. The most relevant measures reducing the environmental impacts of butter consumption are the optimisation of the milk and butter production. Another important factor is the consumers’ behaviour, i.e. the reduction of leftovers. The consumer can influence impacts of domestic storage using efficient and size-adequate appliances. The impacts of packaging in the life cycle of butter are not of primary importance.
Recommendations and perspectives
This study shows that, in the case of packaging industry, a reduction of relevant environmental impacts can only be achieved if aspects indirectly influenced by the packaging are also taken into account. Thus, the packaging industry should not only aim to improve the production process of their packages, but also provide packages whose functionality helps to reduce other more relevant environmental impacts in the life cycle such as, for example, losses. Depending on the product, tailor-made packaging may also help to increase overall resource efficiency.
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References
Arena U, Mastellone ML, Perugini F (2003) Life cycle assessment of a plastic packaging recycling system. Int J Life Cycle Assess 8(2):92–98
AZM (2001) Umwelterklärung 2001. Aargauer Zentralmolkerei, Suhr
Büsser S, Steiner R, Jungbluth N (2008) LCA of Packed Food Products: the function of flexible packaging: coffee, spinach and butter, ESU-services Ltd. im Auftrag von Flexible Packaging Europe, Düsseldorf, DE and Uster, CH. Available at http://www.flexpack-europe.org/front_content.php?idcat=170
Coltro L, Mourad AL, Oliviera PAPLV, Baddini JPOA, Kletecke RM (2006) Environmental profile of Brazilian green coffee. Int J Life Cycle Assess 11:16–21
De Monte M, Padoano E, Pozzetto D (2005) Alternative coffee packaging: an analysis from a life cycle point of view. J Food Eng 66:405–411
Diers A, Langowski H-C, Pannkoke K, Hop R (1999) Produkt-Ökobilanz vakuumverpackter Röstkaffee. Fraunhofer-Institut für Verfahrenstechnik und Verpackung, 214 pp
ecoinvent Centre (2007) ecoinvent data v2.01, ecoinvent reports No. 1–25, Swiss Centre for Life Cycle Inventories, Duebendorf, Switzerland. Available at http://www.ecoinvent.org
EPA (1995) Food and agricultural industries, compilation of air pollutant emission factors, volume I (AP42). U.S. Environmental Protection Agency
Faist M (2000) Ressourceneffizienz in der Aktivität Ernähren: Akteurbezogene Stoffflussanalyse. Dissertation No. 13884 Thesis, Eidgenössische Technische Hochschule Zürich, Zürich, 145 pp. Available at http://e-collection.ethbib.ethz.ch/show?type=diss&nr=13884
Foster C, Green K, Bleda M, Dewick P, Evans B, Flynn A, Mylan J (2006) Environmental impacts of food production and consumption: a report to the Department for Environment, Food and Rural Affairs. Manchester Business School, DEFRA, London
Guinée JB (final editor), Gorrée M, Heijungs R, Huppes G, Kleijn R, de Koning A, van Oers L, Wegener Sleeswijk A, Suh S, Udo de Haes HA, de Bruijn H, van Duin R, Huijbregts MAJ, Lindeijer E, Roorda AAH, Weidema BP (2001a) Life cycle assessment; an operational guide to the ISO standards; parts 1 and 2. Ministry of Housing, Spatial Planning and Environment (VROM) and Centre of Environmental Science (CML), Den Haag and Leiden, The Netherlands. Available at http://www.leidenuniv.nl/cml/ssp/projects/lca2/lca2.html
Guinée JB (final editor), Gorrée M, Heijungs R, Huppes G, Kleijn R, de Koning A, van Oers L, Wegener Sleeswijk A, Suh S, Udo de Haes HA, de Bruijn H, van Duin R, Huijbregts MAJ, Lindeijer E, Roorda AAH, Weidema BP (2001b) Life cycle assessment; an operational guide to the ISO standards; part 3: scientific background. Ministry of Housing, Spatial Planning and Environment (VROM) and Centre of Environmental Science (CML), Den Haag and Leiden, The Netherlands. Available at http://www.leidenuniv.nl/cml/ssp/projects/lca2/lca2.html
Habersatter K, Fecker I, Dall’Acqua S, Fawer M, Fallscheer F, Förster R, Maillefer C, Ménard M, Reusser L, Som C (1998) Ökoinventare für Verpackungen. 250, 2. korrigierte und aktualisierte Auflage, Bundesamt für Umwelt, Wald und Landschaft, Bern, Schweiz
Heap R (2003) 16th informatory note on refrigerating technologies, refrigerated transport: progress achieved and challenges to be met. Available at http://www.iifiir.org/en/doc/1014.pdf
Heyde M, Kremer M (1999) Recycling and recovery of plastics from packagings in domestic wastes. LCA Documents, 5. Eco-Informa Press, Bayreuth
Hischier R (2007) Life cycle inventories of packaging and graphical paper. ecoinvent report no. 11, v2.0, EMPA St. Gallen, Swiss Centre for Life Cycle Inventories, Dübendorf, CH. Available at http://www.ecoinvent.org
Hischier R, Althaus H-J, Werner F (2004) Developments in wood and packaging materials life cycle inventories. Int J Life Cycle Assess 10(1):50–58
Høgaas-Eide M (2002) Life cycle assessment (LCA) of industrial milk production. Ph.D. Thesis, Chalmers, Göteborg, Sweden
Hunt RG (1974) Resource and environmental profile analysis of nine beverage container alternatives. Midwest Research Institute for U.S. Environmental Protection Agency, Washington, DC
Jungbluth N (2000) Umweltfolgen des Nahrungsmittelkonsums: Beurteilung von Produktmerkmalen auf Grundlage einer modularen Ökobilanz. Dissertation No. 13499 Thesis, Eidgenössische Technische Hochschule Zürich, Umweltnatur- und Umweltsozialwissenschaften, dissertation.de, Berlin, D, 317 pp. Available at http://www.jungbluth.de.vu
Jungbluth N (2006) Vergleich der Umweltbelastungen von Hahnenwasser und Mineralwasser. Gas Wasser Abwasser 3:215–219 (Available at http://www.esu-services.ch)
Jungbluth N, Tietje O, Scholz R (2000) Food purchases: impacts from the consumers’ point of view investigated with a modular LCA. Int J Life Cycle Assess 5:134–142 (Available at http://www.esu-services.ch)
Jungbluth N, Büsser S, Steiner R (2008) Life cycle inventories of food products. EcoSpold LCI database, ESU-services Ltd., Uster, CH. Available at http://www.esu-services.ch/inventories.htm
Kjer I, Simon KH, Zehr M, Zerger U, Kaspar F, Bossel H, Meier-Ploeger A, Vogtmann H (1994) Landwirtschaft und Ernährung. In: Enquete-Kommission «Schutz der Erdatmosphäre» (ed), Landwirtschaft-Studienprogramm. Economica Verlag, Bonn
MarchConsultingGroup (1999) UK Emissions of HFCs, PFCs and SF6 and Potential Emission Reduction Options, DETR (Department of the Environment, Transport and the Regions)
Nielsen PH, Nielsen AM, Weidema BP, Dalgaard R, Halberg N (2003) LCA food data base. Available at http://www.lcafood.dk
Perugini F, Mastellone ML, Arena U (2005) A life cycle assessment of mechanical and feedstock recycling options for management of plastic packaging wastes. Environ Prog 24(2):137–154
Plinke E, Schonert M, Meckel H, Detzel A, Giegrich J, Fehrenbach H, Ostermayer A, Schorb A, Heinisch J, Luxenhofer K, Schmitz S (2000) Ökobilanz für Getränkeverpackungen II. 37/00, Umweltbundesamt, Berlin. Available at http://www.umweltbundesamt.de/uba-info-daten/daten/bil.htm
PRé Consultants (2007) SimaPro 7.1. Amersfoort, NL. Available at http://www.simapro.com
Schmitz S, Oels H-J, Tiedemann A (1995) Ökobilanz für Getränkeverpackungen. 52/95, Umweltbundesamt, Berlin
Schweizer Milchproduzenten S (2007) Butter. Available at http://www.swissmilk.ch/
Steiner R, Faist Emmenegger M, Frischknecht R (2005) Ökobilanz Kombi-Kühlschrank Electrolux ERB3105, Uster. Available at http://web484.login-27.hoststar.ch/files/Kuehlschrank_Graue_Energie_ESU_Bericht_1.0.pdf
Acknowledgements
We thank FPE for financing the study and the steering group with their members Jörg Schäfer (Gesamtverband der Aluminiumindustrie), Gerald Rebitzer (Alcan Packaging), Hans-Jürgen Schmidt (Hydro Aluminium), Jean-Paul Duquet (Novelis) and John Fairweather (Amcor Flexibles) for input, feedback and comments throughout the study.
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Responsible editors: Gerald Rebitzer, Jörg Schäfer
Special Issue “Life Cycle Performance of Aluminium Applications”
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Büsser, S., Jungbluth, N. The role of flexible packaging in the life cycle of coffee and butter. Int J Life Cycle Assess 14 (Suppl 1), 80–91 (2009). https://doi.org/10.1007/s11367-008-0056-2
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DOI: https://doi.org/10.1007/s11367-008-0056-2