Using GaBi 3 to perform life cycle assessment and life cycle engineering

The growing availability of software tools has increased the speed of generating LCA studies. Databases and visual tools for constructing material balance modules greatly facilitate the process of analyzing the environmental aspects of product systems over their life cycle. A robust software tool, containing a large LCI dataset and functions for performing LCIA and sensitivity analysis will allow companies and LCA practitioners to conduct systems analyses efficiently and reliably. This paper discusses how the GaBi 3 software tool can be used to perform LCA and Life Cycle Engineering (LCE), a methodology that combines life cycle economic, environmental, and technology assessment. The paper highlights important attributes of LCA software tools, including high quality, well-documented data, transparency in modeling, and data analysis functionality. An example of a regional power grid mix model is used to illustrate the versatility of GaBi 3.     

From life cycle talking to taking action

Introduction  

The biannual Life Cycle Management conference series aims to create a platform for users and developers of Life Cycle Assessment (LCA) and related tools to share their experiences. A key concern of the LCM community has been to move beyond the production of LCA reports toward using the developed knowledge. This paper reports and evaluates some of the main outcomes of the 4th International Life Cycle Management Conference (LCM 2009).     

Application of life cycle assessment to footwear

Life Cycle Assessment (LCA) has been applied in the leather footwear industry. Due to the fact that the goal of the study is to point those steps in the footwear cycle which contribute most to the total environmental impact, only a simplified semi-quantitative methodology is used. Background-data of all the inputs and outputs from the system have been inventoried. Impact assessment has been restricted to classification and characterisation. From the results of this LCA it has been concluded that energy consumption is an important impact generator phase, due to the characteristics of the electricity production in the studied area (Catalonia and the rest of Spain). A remarkable impact is generated in the solid waste management phase, also due to its characteristics in the studied area. Another significant impact source is the cattle raising phase where great values of Global Warming, Acidification and Eurrophication Potentials are estimated. At the tannery, a great value of water eutrophication potential is observed and this phase is also important for its non-renewable resource consumption.     

Application of life cycle assessment to landfilling

A case study of a life-cycle assessment (LCA) is performed concerning the treatment of household solid wastes in a landfill. The stages considered in this LCA study are: goal and scope definition, inventory analysis and impact assessment. The data of the inventory include the consumption of raw materials and energy through the transport of wastes and the management of landfill, and the corresponding emissions to the environment. Abiotic resource depletion, global warming, acidification, eutrophication and human toxicological impacts have been considered as impact categories for the impact assessment phase of the LCA. A comparison of the environmental impact of the landfilling with and without energy recovery is carried out. Members of the Spanish Association for LCA Development (APRODACV)     

Orthonectida's life cycle

Analysis of original and literary data permits to conclude that the life cycle in Orthonectida may be characterized as a monohost--monoxenous one, including regular interchange of three generations: asexual and parthenogenetic ones, which are represented by parasitic plasmodiums, and sexual generation, represented by free living and non-feeding males and females or, rarely, hermaphrodites. The sexual individuals are bilaterial, while the parasitic ones are anaxonic. The life cycle of Orthonectida includes the agamic reproduction, apomictic parthenogenesis and sexual reproduction regularly following one another. The life cycle of Orthonectida can be considered as a combination of metagenesis and heterogony. So far, such combination has not been described in any group of metazoan parasites.     

Criteria for the evaluation of life cycle assessment software packages and life cycle inventory data with application to concrete

Purpose

Life cycle assessment (LCA) software packages have proliferated and evolved as LCA has developed and grown. There are now a multitude of LCA software packages that must be critically evaluated by users. Prior to conducting a comparative LCA study on different concrete materials, it is necessary to examine a variety of software packages for this specific purpose. The paper evaluates five LCA tools in the context of the LCA of seven concrete mix designs (conventional concrete, concrete with fly ash, slag, silica fume or limestone as cement replacement, recycled aggregate concrete, and photocatalytic concrete).

Methods

Three key evaluation criteria required to assess the quality of analysis are adequate flexibility, sophistication and complexity of analysis, and usefulness of outputs. The quality of life cycle inventory (LCI) data included in each software package is also assessed for its reliability, completeness, and correlation to the scope of LCA of concrete products in Canada. A questionnaire is developed for evaluating LCA software packages and is applied to five LCA tools.

Results and discussion

The result is the selection of a software package for the specific context of LCA of concrete materials in Canada, which will be used to complete a full LCA study. The software package with the highest score is software package C (SP-C), with 44 out of a possible 48 points. Its main advantage is that it allows for the user to have a high level of control over the system being modeled and the calculation methods used.

Conclusions

This comparative study highlights the importance of selecting a software package that is appropriate for a specific research project. The ability to accurately model the chosen functional unit and system boundary is an important selection criterion. This study demonstrates a method to enable a critical and rigorous comparison without excessive and redundant duplication of efforts.

     

Using life cycle assessment to achieve a circular economy

The International Journal of Life Cycle Assessment - The current global interest in circular economy (CE) opens an opportunity to make society’s consumption and production patterns more...     

Comparative life cycle assessment and life cycle costing of lodging in the Himalaya

Purpose

The main aim of the study is to assess the environmental and economic impacts of the lodging sector located in the Himalayan region of Nepal, from a life cycle perspective. The assessment should support decision making in technology and material selection for minimal environmental and economic burden in future construction projects.

Methods

The study consists of the life cycle assessment and life cycle costing of lodging in three building types: traditional, semi-modern and modern. The life cycle stages under analysis include raw material acquisition, manufacturing, construction, use, maintenance and material replacement. The study includes a sensitivity analysis focusing on the lifespan of buildings, occupancy rate and discount and inflation rates. The functional unit was formulated as the ‘Lodging of one additional guest per night’, and the time horizon is 50 years of building lifespan. Both primary and secondary data were used in the life cycle inventory.

Results and discussion

The modern building has the highest global warming potential (kg CO_2-eq) as well as higher costs over 50 years of building lifespan. The results show that the use stage is responsible for the largest share of environmental impacts and costs, which are related to energy use for different household activities. The use of commercial materials in the modern building, which have to be transported mostly from the capital in the buildings, makes the higher GWP in the construction and replacement stages. Furthermore, a breakdown of the building components shows that the roof and wall of the building are the largest contributors to the production-related environmental impact.

Conclusions

The findings suggest that the main improvement opportunities in the lodging sector lie in the reduction of impacts on the use stage and in the choice of materials for wall and roof.

     

Integrating life cycle assessment and life cycle cost: a review of environmental-economic studies

The International Journal of Life Cycle Assessment - The purpose of this document is to carry out a critical review of the existing literature by specifically addressing the following: (i) the...     

The dendritic cell life cycle

Dendritic cells (DCs) are a special class of leukocytes actively involved in initiating innate and adaptive immune responses against invading pathogens. They play a fundamental role in determining both the type and efficiency of adaptive immune reactions. In particular, the efficiency of adaptive responses is strictly correlated with the survival of the DCs that have encountered the antigen. In physiological conditions, the rapid death of DCs by apoptosis after an encounter with a microbe is important, to prevent both aberrant activation and autoimmunity. The mechanism leading to DC apoptosis after exposure to lipopolysaccharide (LPS) was recently elucidated, with activation of the c2 and c3 isoforms of nuclear factor of activated T cells (NFAT) playing a particularly important role in this process. In particular, the exposure of DCs to LPS induces the activation of Src-family kinases and phospholipase C (PLC)γ2, the influx of extracellular Ca2+ and calcineurin-dependent nuclear NFAT translocation. The initiation of this pathway is independent of TLR4 engagement and depends exclusively on CD14. We also consider here the possible role of CD14 in initiating this pathway and the way in which the c2 and c3 isoforms of NFAT exert their pro-apoptotic effects.     

Ecometrics for life cycle management

Metrics are a prerequisite for the successful monitoring and management of progress toward goals. Within the context of sustainable development these “values” are stakeholder dependent with the interests of the individual, society, the environmental infrastructure and intergenerational liability differing significantly. These stakeholder priorities may also be mutually inconsistent or simultaneously unattainable. Therefore, a set of scale- and value-specific indicators will he required to represent the priorities of individuals, religious organizations, political and public interest groups, non-government organizations, firms and industry associations, as well as national and international institutions. Restricting the number of ecometrics, or creating aggregated sustainability indicators, risks disenfranchisement and ivalidation respectively. Over the past three decades a series ofmicroecometrics have been developed to account for the impact of human activity, technology or products over regional, national, and sub-continental scales. These include life cycle energy consumption, dematerialization, waste minimization, as well as design for environment and eco-efficiency indicators, the latter two combining technological or economic aspects respectively with environmental factors.Metrics which evaluate the impact of a service, or the utility provided by a product, are lacking. A series of global measures, or macroecometrics have also been defined and include the average annual temperature as well as atmospheric compositions and concentrations, sea level, and earth based resources such as topsoil quantities. The validity of microecometrics as measures of global phenomena can be established through life cycle impact assessments which evaluate the “system’s” response to effects of products or services throughout their life cycle. However, the link between microecometrics and macroecometrics, their validity as indicators of sustainability, the subjectivity of sustainable developmentper se as a value, and the relationship of metrics and sustainable development with family values has not extensively been addressed. This paper summarizes recently proposed ecometrics, calls for the recognition of the subjectivity of indicators, the distinction between ecometrics used for internal corporate reporting and external decision making, and the establishment of a representative multistakeholder debate.