共查询到20条相似文献,搜索用时 15 毫秒
1.
The building industry uses great quantities of raw materials that also involve high energy consumption. Choosing materials with high content in embodied energy entails an initial high level of energy consumption in the building production stage but also determines future energy consumption in order to fulfil heating, ventilation and air conditioning demands. 相似文献
2.
Environmental quality has become increasingly affected by the built environment—as ultimately, buildings are responsible for the bulk of energy consumption and resultant atmospheric emissions in many countries. In recognizing this trend, research into building energy-efficiency has focused mainly on the energy required for a building's ongoing use, while the energy “embodied” in its production is often overlooked. Such an approach has led in recent years to strategies which improve a building's thermal performance, but which rely on high embodied-energy (EE) materials and products. Although assessment methods and databases have developed in recent years, the actual EE intensity for a given material may be highly dependent on local technologies and transportation distances. The objective of this study is to identify building materials which may optimize a building's energy requirements over its entire life cycle, by analyzing both embodied and operational energy consumption in a climatically responsive building in the Negev desert region of southern Israel—comparing its actual material composition with a number of possible alternatives. It was found that the embodied energy of the building accounts for some 60% of the overall life-cycle energy consumption, which could be reduced significantly by using “alternative” wall infill materials. The cumulative energy saved over a 50-year life cycle by this material substitution is on the order of 20%. While the studied wall systems (mass, insulation and finish materials) represent a significant portion of the initial EE of the building, the concrete structure (columns, beams, floor and ceiling slabs) on average constitutes about 50% of the building's pre-use phase energy. 相似文献
3.
Life cycle assessment in buildings: State-of-the-art and simplified LCA methodology as a complement for building certification 总被引:3,自引:0,他引:3
Ignacio Zabalza Bribin Alfonso Aranda Usn Sabina Scarpellini 《Building and Environment》2009,44(12):2510-2520
The paper presents the state-of-the-art regarding the application of life cycle assessment (LCA) in the building sector, providing a list of existing tools, drivers and barriers, potential users and purposes of LCA studies in this sector. It also proposes a simplified LCA methodology and applies this to a case study focused on Spain. The thermal simulation tools considered in the Spanish building energy certification standards are analysed and complemented with a simplified LCA methodology for evaluating the impact of certain improvements to the building design. The simplified approach proposed allows global comparisons between the embodied energy and emissions of the building materials and the energy consumption and associated emissions at the use stage.The results reveal that embodied energy can represent more than 30% of the primary energy requirement during the life span of a single house of 222 m2 with a garage for one car. The contribution of the building materials decreases if the house does not include a parking area, since this increases the heated surface percentage. Usually the top cause of energy consumption in residential building is heating, but the second is the building materials, which can represent more than 60% of the heating consumption. 相似文献
4.
Oyeshola F. Kofoworola 《Energy and Buildings》2009,41(10):1076-1083
A typical office building in Thailand was analyzed using the life cycle energy analysis (LCEA) method to illustrate the argument. Results indicate that although life cycle energy (LCE) distribution is concentrated at the operating phase, the embodied energy of buildings is a non-negligible fraction of the LCE balance. Energy (electricity) used for lighting and HVAC systems in the operation phase and; the manufacture of concrete and steel were the most significant elements in the buildings life cycle. Application of a combination of energy saving measures, showed that 40-50% of energy (electricity) used in a typical office building in Thailand can be saved. Preliminary analysis indicated that recycling building materials can also contribute additional energy savings (about 8.9%) to a buildings LCE profile. Therefore reducing energy consumption should be a priority for not only the operation but also other life cycle phases. It is suggested that both embodied and operating energy should be accounted for within the context of energy efficiency through the incorporation of LCEA into the existing Thai building energy code. 相似文献
5.
6.
This paper presents a building environmental performance analysis system—BEPAS, which was developed based on the life cycle assessment (LCA) framework. In BEPAS, environmental impacts were investigated in three main aspects of a building that were closely related to environmental performance—building facilities, building materials and location. In addition, a set of environmental databases were developed, covering the environmental performance profiles of these environmental aspects. The BEPAS can be used to assess the environmental performance of a new or existing building. This paper also discusses a case project in order to illustrate the assessment procedures and test the effectiveness of the system in application. 相似文献
7.
Presently in India, about 960 million tonnes of solid waste is being generated annually as by-products during industrial, mining, municipal, agricultural and other processes. Of this ∼350 million tonnes are organic wastes from agricultural sources; ∼290 million tonnes are inorganic waste of industrial and mining sectors and ∼4.5 million tonnes are hazardous in nature. Advances in solid waste management resulted in alternative construction materials as a substitute to traditional materials like bricks, blocks, tiles, aggregates, ceramics, cement, lime, soil, timber and paint. To safeguard the environment, efforts are being made for recycling different wastes and utilise them in value added applications. In this paper, present status on generation and utilization of both non-hazardous and hazardous solid wastes in India, their recycling potentials and environmental implication are reported and discussed in details. 相似文献
8.
Robert H. Crawford Isabella CzerniakowskiRobert J. Fuller 《Energy and Buildings》2011,43(7):1748-1756
Building designers are often limited in their ability to reduce the environmental impact of buildings, due to a lack of information on the environmental performance of building components as well as inconsistencies in the way in which this information is derived. Whilst numerous tools exist to help facilitate the low-energy building design process, these typically require large investments of time and money that are often beyond those available within any particular project. This paper describes an approach for streamlining the design process to reduce building life cycle energy consumption. Building assemblies are ranked based on an assessment of the life cycle energy requirements associated with their use within a building. This facilitates early stage assessment, negating the need for a resolved design before the relative energy requirements of alternate design solutions are known. Previous work assessed the initial and recurring embodied energy as well as the operational energy requirements for heating and cooling associated with the use of a range of building assemblies, using a simplified house model. This paper presents a sensitivity analysis of variations to the floor area, shape and orientation of this model, to test the reliability and applicability of the ranking approach across a broad range of circumstances. It was found that these variations did not influence the ranked order of the assemblies in terms of their life cycle energy requirements. Thus, the ranking of assemblies appears to provide an appropriate approach for streamlining the selection of construction elements during the building design process. 相似文献
9.
This paper compares the environmental, economic and social impacts of two types of doors and windows (elements), namely timber and aluminum taking into consideration the life cycle perspective. These elements are widely used for the buildings in Sri Lanka. Thus, it will help in the decision-making process when selecting materials for these elements. Major materials used for these elements are timber, brass, glass, paint, aluminum, rubber, steel and PVC boards. Environmental burdens associated with these materials are analyzed in terms of embodied energy, and environmental impacts that are relevant to Sri Lanka, such as global warming (GWP), acidification (ACP) and nutrient enrichment (NEP). Economic analysis is done using market prices of materials and affordability for those materials. Social concerns such as thermal comfort, good interior (aesthetics), ability to construct fast, and durability are analyzed based on the data collected through the questionnaires and also, interviews with the stakeholders of the buildings such as engineers, architects, building contractors and building users. It was found that timber elements are superior to aluminum elements in environmental scores (GWP, ACP and NEP). On economic score, also, timber elements are better. But on social score, aluminum elements are better than timber. It was also found that the higher the recycling percentage of aluminum, the higher the environmental favorability of the aluminum. 相似文献
10.
Emerging trends in building environmental assessment methods 总被引:1,自引:0,他引:1
Raymond J. Cole 《Building Research & Information》1998,26(1):3-16
11.
Catarina Thormark 《Building Research & Information》2013,41(3):176-183
Previous life-cycle studies of buildings tended to omit the phases after demolition. If recycling is not included, the potential benefits of recycling are not possible to assess. A parametric study of a one family house is presented which focuses on the potential energy savings by recycling the various building materials after demolition. The results indicate that it can be more important to design a building for recycling than to use materials which require little energy for production, that the creation of effective recycling depends upon its consideration and inclusion at the design stage, that the re-use and adaptation of existing foundations is an important component of recycling. Le concept d'analyse de l'énergie du cycle de vie (LCEA) est employé; pour formuler en valeurs d'énergie les flux des produits durant chaque phase du cycle de vie d'une activité. Dans le cas des constructions résidentielles, cela comprend d'habitude l'énergie consommée lors de la fabrication des matériaux de construction, l'é;nergie employée pour les opérations de la construction elle-même et celle dépensée pour la maintenance périodique. Pour positionner ces quantités d'énergie dans un contexte national, il faut également prendre en considération l'énergie nécessaire aux autres marchandises et services consommés par les propriétaires. Cet article utilise le concept LCEA pour démontrer la nécessité de prendre en compte non seulement l'énergie de cycle de vie de la construction mais aussi l'énergie de cycle de vie attributable aux autres activités entreprises par les utilisateurs réels du bâtiment. L'énergie du cycle de vie d'un bâtiment résidentiel australien ainsi que les activités ordinaires des ménages sont analysées et simulées au cours d'une période de 30 ans en employant un exemple basé sur une portion jumelée à deux chambres à coucher et à revêtement de brique. Les implications à long terme montrent bien l'importance de prendre en compte l'énergie nécessaire à la construction initiale d'un bâtiment résidentiel aussi bien que celle résultant de la consommation de marchandises et de services par les propriétaires. Afin d'encourager de façon durable ces pratiques, il est suggéré que les architectes prennent davantage en considération les activités des propriétaires lorsqu'ils conçoivent des bâtiments résidentiels, particulièrement en zone de climat tempéré. La conclusion de l'article fait le point des futurs secteurs de recherche du concept LCEA dans le domaine résidentiel. 相似文献
12.
This paper demonstrates that by understanding how energy is consumed in the manufacturing of reinforced concrete, designers can significantly reduce the overall embodied energy of structures. Embodied energy of products can vary from country to country. Therefore, to accurately estimate the embodied energy of reinforced concrete structures, data specific to the country where they are being constructed must be used. This paper presents the assessment of embodied energy in typical RC building structures in Ireland.The most common methods used to calculate EE are evaluated in this paper and the most suitable method was applied to reinforced concrete. The EE of a typical 30 MPa concrete mix in Ireland is calculated to be 1.08 MJ/kg. Notably cement is credited with 68% of the total EE. The major contributors of energy consumption are identified, which should aid to minimise energy consumption and optimise efficiency.A case study is presented which compares the EE of a typical reinforced concrete structure in Ireland using two concrete mix designs. The first uses Ordinary Portland Cement, while the second uses GGBS replacing half of the cement content. As expected, the EE of the GGBS mix is significantly lower (30%) than that of its counterpart. 相似文献
13.
14.
G. Assefa M. Glaumann T. Malmqvist B. Kindembe M. Hult U. Myhr O. Eriksson 《Building and Environment》2007
The EcoEffect method of assessing external and internal impacts of building properties is briefly described. The external impacts of manufacturing and transport of the building materials, the generation of power and heat consumed during the operation phase are assessed using life-cycle methodology. Emissions and waste; natural resource depletion and toxic substances in building materials are accounted for. Here methodologies from natural sciences are employed. The internal impacts involve the assessment of the risk for discomfort and ill-being due to features and properties of both the indoor environment and outdoor environment within the boundary of the building properties. This risk is calculated based on data and information from questionnaires; measurements and inspection where methodologies mainly from social sciences are used. Life-cycle costs covering investment and utilities costs as well as maintenance costs summed up over the lifetime of the building are also calculated. 相似文献
15.
This research proposes a Spatial Decision Support System based on the Geographical Information System (GIS) to evaluate the environmental performance in construction. The system has been designed to add a spatial component to the current tools for the inspection and management of the sustainability of buildings and to assist the planners in their decision-making. The multi-criteria evaluation method developed in the Green Building Challenge and implemented in the software SbTool has been used as a reference. The evaluation method presents a hierarchical structure of criteria and variables which is applied to buildings spatially indexed in GIS and the environmental data of the buildings comes from an external data-base developed in Access. In order to validate the system, the environmental assessment of a group of residential, industrial and public service buildings during the phases of operation was simulated. The application of this tool in the inspection and environmental assessment of buildings allows the geographical scale of analysis to be extended to a group of buildings within the area of interest and consequently to extend the limits of its usefulness within the field of planning and environmental assessment. 相似文献
16.
17.
Gordon Lowry 《Automation in Construction》2002,11(6):1718-705
This study examines user acceptance of building management systems (BMS) using a questionnaire survey. These systems are crucial for optimising building performance and yet it has been widely reported that users are not making full use of their systems' facilities. Established models of technology acceptance have been employed in this research, and the positive influence of user perceptions of ease of use and compatibility has been demonstrated. Previous research has indicated differing levels of importance of perceived ease of use relative to other factors. Here, perceived ease of use is shown generally to be more important, though the balance between this and compatibility is moderated by the user perceptions of voluntariness. 相似文献
18.
19.
This paper presents a matrix to select sustainable materials for buildings in Sri Lanka, taking into consideration environmental, economic and social assessments of materials in a life cycle perspective. Five building elements, viz., foundations, roofs, ceilings, doors and windows, and floors are analyzed based on materials used for these elements. Environmental burdens associated with these elements are analyzed in terms of embodied energy and environmental impacts such as global warming, acidification and nutrient enrichment. Economic analysis is based on market prices and affordability of materials. Social factors that are taken into account are thermal comfort, interior (aesthetics), ability to construct quickly, strength and durability. By compiling the results of analyses, two building types with minimum and maximum impacts are identified. These two cases along with existing buildings are compared in a matrix of environmental, economic and social scores. Analysis of the results also indicates need for higher consideration of environmental parameters in decision-making over social and economic factors, as social and economic scores do not vary much between cases. Hence, this matrix helps decision-makers to select sustainable materials for buildings, meaningfully, and thus helps to move towards a more sustainable buildings and construction sector. 相似文献
20.
Life cycle energy analysis of buildings: An overview 总被引:1,自引:0,他引:1
Buildings demand energy in their life cycle right from its construction to demolition. Studies on the total energy use during the life cycle are desirable to identify phases of largest energy use and to develop strategies for its reduction. In the present paper, a critical review of the life cycle energy analyses of buildings resulting from 73 cases across 13 countries is presented. The study includes both residential and office buildings. Results show that operating (80-90%) and embodied (10-20%) phases of energy use are significant contributors to building's life cycle energy demand. Life cycle energy (primary) requirement of conventional residential buildings falls in the range of 150-400 kWh/m2 per year and that of office buildings in the range of 250-550 kWh/m2 per year. Building's life cycle energy demand can be reduced by reducing its operating energy significantly through use of passive and active technologies even if it leads to a slight increase in embodied energy. However, an excessive use of passive and active features in a building may be counterproductive. It is observed that low energy buildings perform better than self-sufficient (zero operating energy) buildings in the life cycle context. Since, most of the case studies available in open literature pertain to developed and/or cold countries; hence, energy indicative figures for developing and/or non-cold countries need to be evaluated and compared with the results presented in this paper. 相似文献