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Further to the European Waste Electrical and Electronic Equipment (WEEE) Directive, setting up efficient collection schemes is necessary to ensure the recovery targets set. Following the subsidiary principle, the WEEE Directive defines only the general requirements for mandatory collection and recycling objectives. The modalities of the logistics and the organisation of the take-back schemes are left to the choice of Member States. In this paper, the implementation of the WEEE Directive and the development of the WEEE recovery infrastructure in Finland are described and the challenges to the effective management of the WEEE recovery system in Finland are expressed. It can be said that the implementation of the WEEE Directive has succeeded in Finland and, at the same time, the legislative basis has been enacted. In addition, a functional WEEE recovery infrastructure has been built and, the collection requirements of the WEEE Directive have been exceeded in a relatively short time. However, the paper outlines that some inefficient practices still exist, particularly in the registration and WEEE collection stages. It is concluded that raising awareness would lead to a more environmentally sound behaviour and would, ultimately, improve WEEE recovery efficiency. 相似文献
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We use a combination of the marginal value theorem (MVT) of Charnov (1976), and a group foraging model featuring information
sharing to address patch residence in an environment where food occurs in discrete patches. We shall show that among equal
competitors the optimal patch time for the individual that finds the food patch is shorter than that for the non-finder among
equal competitors, T
E < T
N. This is the case if the patch-finder commences food harvesting in the patch earlier and manages to monopolise a fraction
of the prey items (finder's advantage) before the other individuals come to take their benefit. When individuals differ in
their food-searching abilities so that some of them (producers) contribute proportionally more to food-searching than others
(scroungers), and differ in ability to compete for the food found, a difference emerges between producer and scrounger individuals
in the optimal patch time. Within a patch we always have the finder's advantage (T
E < T
N) regardless of phenotype. Between patches a suite of optimal patch times for encountering individuals emerges depending on
the performance of producers and scroungers when changing from solitary feeding to feeding in a group. The optimal patch time
for individuals that are affected more severely by competition is shorter than that for individuals of the phenotype with
better competitive ability. When both phenotypes are affected similarly no difference in optimal patch times emerges.
Received: 13 February 1996 / Accepted after revision: 28 September 1996 相似文献
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