An eco-balance of a recycling plant for spent lead-acid batteries.

PubMed

Salomone, Roberta; Mondello, Fabio; Lanuzza, Francesco; Micali, Giuseppe

2005-02-01

This study applies Life Cycle Assessment (LCA) methodology to present an eco-balance of a recycling plant that treats spent lead-acid batteries. The recycling plant uses pyrometallurgical treatment to obtain lead from spent batteries. The application of LCA methodology (ISO 14040 series) enabled us to assess the potential environmental impacts arising from the recycling plant's operations. Thus, net emissions of greenhouse gases as well as other major environmental consequences were examined and hot spots inside the recycling plant were identified. A sensitivity analysis was also performed on certain variables to evaluate their effect on the LCA study. The LCA of a recycling plant for spent lead-acid batteries presented shows that this methodology allows all of the major environmental consequences associated with lead recycling using the pyrometallurgical process to be examined. The study highlights areas in which environmental improvements are easily achievable by a business, providing a basis for suggestions to minimize the environmental impact of its production phases, improving process and company performance in environmental terms.

Eco-Balance analysis of the disused lead-acid-batteries recycling technology

NASA Astrophysics Data System (ADS)

Kamińska, Ewa; Kamiński, Tomasz

2017-10-01

The article presents the results of the eco-balance analysis of the disused lead-acid batteries recycling process. Test-dedicated technology offers the possibility to recover other elements, for example, polypropylene of the battery case or to obtain crystalline sodium sulphate. The life cycle assessment was made using ReCiPe and IMPACT2002 + methods. The results are shown as environmental points [Pt]. The results are shown in the environmental categories, specific for each of the methods grouped in the impact categories. 1 Mg of the processed srap was a dopted as the functional unit. The results of the analyses indicate that recycling processes may provide the environmental impact of recycling technology less harmful. Repeated use of lead causes that its original sources are not explored. Similarly, the use of granule production-dedicated polypropylene extracted from battery casings that are used in the plastics industry, has environmental benefits. Due to the widespread use of lead-acid batteries, the attention should be paid to their proper utilization, especially in terms of heavy metals, especially lead. According to the calculations, the highest level of environmental benefits from the use of lead from secondary sources in the production of new products, was observed in the refining process.

Carbon footprint of forest and tree utilization technologies in life cycle approach

NASA Astrophysics Data System (ADS)

Polgár, András; Pécsinger, Judit

2017-04-01

In our research project a suitable method has been developed related the technological aspect of the environmental assessment of land use changes caused by climate change. We have prepared an eco-balance (environmental inventory) to the environmental effects classification in life-cycle approach in connection with the typical agricultural / forest and tree utilization technologies. The use of balances and environmental classification makes possible to compare land-use technologies and their environmental effects per common functional unit. In order to test our environmental analysis model, we carried out surveys in sample of forest stands. We set up an eco-balance of the working systems of intermediate cutting and final harvest in the stands of beech, oak, spruce, acacia, poplar and short rotation energy plantations (willow, poplar). We set up the life-cycle plan of the surveyed working systems by using the GaBi 6.0 Professional software and carried out midpoint and endpoint impact assessment. Out of the results, we applied the values of CML 2001 - Global Warming Potential (GWP 100 years) [kg CO2-Equiv.] and Eco-Indicator 99 - Human health, Climate Change [DALY]. On the basis of the values we set up a ranking of technology. By this, we received the environmental impact classification of the technologies based on carbon footprint. The working systems had the greatest impact on global warming (GWP 100 years) throughout their whole life cycle. This is explained by the amount of carbon dioxide releasing to the atmosphere resulting from the fuel of the technologies. Abiotic depletion (ADP foss) and marine aquatic ecotoxicity (MAETP) emerged also as significant impact categories. These impact categories can be explained by the share of input of fuel and lube. On the basis of the most significant environmental impact category (carbon footprint), we perform the relative life cycle contribution and ranking of each technologies. The technological life cycle stages examined in the stands are the followings: Stage 1. cleaning cutting Stage 2. selection thinning Stage 3. increment thinning Stage 4. final harvest In these priority impact categories, the life cycle contribution of technologies varied according to the life cycle stages. • The spruce stand showed the smallest contribution in the stages 1, 2, 3 alike. • After the large contribution of beech stand at the beginning (stage 1), it continues representing a moderate level in stage 2 and 3, and it shares the smallest rate in final harvest (stage 4). • The oak stand showed the largest contribution in the stages 2, 3, 4 alike. • In the case of acacia and poplar, we have got the same results as in the case of oak stands. • In the case of short rotation energy plantations (willow, poplar), we got the results typical on stage 4 of spruce stands. We can conclude, that in case of the stage of final harvest, which represents the most significant environmental impact, the ranking of working systems showes the increasing order of „energy plantations - beech - spruce - acacia - poplar - oak". The environmental assessment of technological aspects of land use and land use change represent an important added value to the climate research. Acknowledgement: This research has been supported by the Agroclimate.2 VKSZ_12-1- 2013-0034 project. Keywords: life-cycle assessment / forest utilization technology / carbon footprint / life-cycle thinking

Identification of chlorophyll ( with application of IRS-P4 OCM data and Geographical Information System - a case study of part of Bay of Bengal, India

NASA Astrophysics Data System (ADS)

Pavan Dayaker, T.

2002-05-01

As 60 - 70 % of the world's population live within 20 - 30 km of the coastline, coastal zone management and optimisation of ocean resources have grown in of importance. The study of the ocean encompasses its physical chemical, biological properties and its interaction with land and biological productivity. Mapping of coastal zone gives us insight about how to conserve its eco-balance and implement effective coastal zone management. Effective Coastal Zone Management will need accurate and comprehensive scientific data, on which decisions can be based. In the present study Ocean Color Monitor ( OCM ) data is used for identification of chlorophyll, which inturn indicates the presence of phytoplankton, which is the primary producer in the food chain, and also to fish . The study area is part of Bay of Bengal Sea near the coastal region of Andhra Pradesh, India. Remote sensing in optical region is found useful in understanding the spatial distribution of ocean water constituents, in which phytoplankton pigment which impart a green colour to the sea water, has a definite response in the visible region, which enables plant material to be distinguished from the other suspended matter. Normalised Differential Vegetative Index ( NDVI ), which is mainly used on land applications for the identification of vegetation based on chlorophyll absorption, is used on water surface in the present study. The positive value of NDVI is an indication of the presence of pigment concentration / chlorophyll / phytoplankton / fish. The successful launch of the IRS - P4 satellite which provides us a challenging opportunity to study ocean resources and its characteristics and see how best we can benefit, over a period of time, in several areas of human survival specifically related to food security on a sustained basis. This study is first of its kind in utilising the latest technology to explore the marine resources for mapping the fishing zones and the results, clearly indicate that NDVI can be utilised as an indicator for the presence of phytoplankton on water surface.