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Wyszukujesz frazę "accumulator battery" wg kryterium: Temat


Wyświetlanie 1-2 z 2
Tytuł:
Technical and organisational conditions in the management of recovery and recycling processes of waste batteries and accumulators
Autorzy:
Wengierek, Maria
Powiązania:
https://bibliotekanauki.pl/articles/2032992.pdf
Data publikacji:
2021
Wydawca:
Politechnika Śląska. Wydawnictwo Politechniki Śląskiej
Tematy:
hazardous waste
waste recovery
recycling
efficiency
recycling technology
waste battery
accumulator
plants
odpady niebezpieczne
odzyskiwanie odpadów
recykling
wydajność
technologia recyklingu
zużyta bateria
akumulator
zakłady
Opis:
Introduction/background: Waste batteries and accumulators are hazardous waste and should not be sent to landfill sites. Their presence in the waste mixture causes the release of dangerous heavy metals into the natural environment. Aim of the paper: The aim of the study is to review the processes currently used in the recycling of used batteries and accumulators, currently used in the world and in Poland, as well as installations and technologies, depending on the types, kinds and physicochemical properties of waste, and to draw attention to the ventures to prevent waste generation. Materials and methods: The paper discusses the nature of waste, storage and transport conditions, organisation of collection, processes and processing technology. The article presents examples of waste management facilities dealing with recovery and recycling of batteries in Poland and Silesia. The research was based on an analysis of legal acts, statistical data, professional literature and company experiences. The second part is a case study. Selected environmental systems presented on descriptive models are based on the results of an environment (region) system analysis. Results and conclusions: EU directives and national law force the reuse of raw materials used in their production. Therefore, one should strive to apply the most effective technologies of waste recovery and recycling. The most recommended and cost-effective is product salvage followed by material recovery, especially of scarce, rare and precious earth metals. Various processes and technologies (installations) for the recovery of raw materials from waste batteries and accumulators are used around the world. The best known are: Jogmec, Batrec, Recytec, Accurec, Everead, Inmetco, Sab-Nife, Snam-Savam, Citron, Batenus, TNO. Long battery life minimises the amount of waste, and thus reduces the burden on the environment. Therefore, in the process of producing batteries, it is important to improve the technology already at the production stage. An example is the Polish experience (Europower; Tuborg; Tuborg-Silver).
Źródło:
Organizacja i Zarządzanie : kwartalnik naukowy; 2021, 1; 137-157
1899-6116
Pojawia się w:
Organizacja i Zarządzanie : kwartalnik naukowy
Dostawca treści:
Biblioteka Nauki
Artykuł
Tytuł:
Life cycle assessment of lead acid battery. Case study for Thailand
Autorzy:
Premrudee, K.
Jantima, U.
Kittinan, A.
Naruetep, L.
Kittiwan, K.
Sudkla, B.
Powiązania:
https://bibliotekanauki.pl/articles/207959.pdf
Data publikacji:
2013
Wydawca:
Politechnika Wrocławska. Oficyna Wydawnicza Politechniki Wrocławskiej
Tematy:
environmental impact
automobile industry
lead-acid batteries
conventional batteries
environmental protection
automobile battery
lead-acid accumulator
wpływ na środowisko
produkcja samochodów
akumulatory kwasowo-ołowiowe
przemysł motoryzacyjny
akumulatory konwencjonalne
ochrona środowiska
akumulator samochodowy
akumulator ołowiowo-cynkowy
Opis:
Over the past ten years, the automobile manufacturing basis has shifted to Thailand, thus transforming the country into an automobile industrial hub in Asia. An integral part of this industry, lead acid battery manufacturing has exhibited tremendous growth with increasing trends toward new manufacturing technology. This research aimed to study life cycle assessments of lead-acid automobile battery manufactured in Thailand by comparing conventional batteries with calcium-maintenance free batteries. Global warming and acidification are the largest environmental impacts associated with both battery types. Changing from conventional batteries to calcium-maintenance free batteries is able to reduce environmental impact by approximately 28% due to longer usage life and reduced utilization of manufacturing resources and energy. The greenhouse gases and acidification caused by one conventional battery amounted to 102 kg CO 2 and 0.94 kg SO2, respectively. These amounts decrease to 72 kg CO2 and 0.56 kg S02, respectively, when calcium-maintenance free technology is used. Raw material procurement is found to have the greatest environmental impact, followed by product usage. In this study, the information on environmental impact is incorporated with MET matrix principles to propose guidelines for environmental improvement throughout the battery life cycle.
Źródło:
Environment Protection Engineering; 2013, 39, 1; 101-114
0324-8828
Pojawia się w:
Environment Protection Engineering
Dostawca treści:
Biblioteka Nauki
Artykuł
    Wyświetlanie 1-2 z 2

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