由于在塞尔维亚实施能源效率条例而增加二氧化碳的个案研究

Marina Nikolić Topalović, M. Stanković
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引用次数: 1

摘要

为了展示隔热材料和立面细木工的增加对环境的影响,并改善其热特性,根据对设施能源效率的新规定,对两种情况的碳足迹进行了分析,以满足研究需求。对于每一个分析的场景,一个项目和一个工程概述,在此基础上,建筑材料的数量,活动和过程参与分析场景的建设被计算(S1和S2)。参考对象(S1)设计为无保温层,能源等级为“G”,场景(S2)设计为能源等级为“C”,根据新规定,这是新建设施的一个条件。该研究使用了生命周期分析(LCA),这是碳生命周期分析(laco2)或计算设施碳足迹的基础方法。英国环境保护署的建筑碳计算器用于计算碳足迹,URSA建筑物理2程序用于计算运行能量。研究表明,情景(S1)的隐含碳为138,40吨CO2 e,对环境的影响较小。隐含碳值较高的情景(S2)为148,20吨CO2 e。建设阶段的碳印记或对环境的影响较小的情景(S1)。然而,在使用该设施十年之后,由于运营阶段的碳足迹较大,情景(S1)成为具有更高环境影响的情景,总碳足迹为186,16吨二氧化碳e。方案(S2)在设施使用十年后的总碳足迹为163,86吨CO2 e。方案(S1)和方案(S2)在设施使用3,05年后的总碳足迹值相同,从环境方面来看,方案(S2)已成为较好的选择。研究表明,在计算设施的环境影响时,隐含碳被忽略,当节能建筑措施的应用可以预期收益时,隐含碳也被忽略。该研究还指出,需要低碳隔热材料来弥合建筑物灭火需求与减少温室气体排放以减缓气候变化之间的差距。
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A CASE STUDY OF THE INCREASE OF CARBON DIOXIDE DUE TO THE APPLICATION OF ENERGY EFFICIENCY REGULATIONS IN SERBIA
In order to demonstrate the environmental impact of the increased flow of thermal insulation materials and facade joinery with improved thermal characteristics, the analysis of the carbon footprint for two scenarios for the needs of the research was done as a consequence of the new regulations on the energy efficiency of the facilities. For each of the analyzed scenarios, a project and an overview of works on the basis of which quantities of construction materials, activities and processes that participate in the construction of the analyzed scenarios were calculated (S1 and S2), were made. The reference object (S1) is designed without thermal insulation layers, the energy class „G“, and the scenario (S2) is designed in the energy class „C“, which according to the new regulations is a condition for the construction of new facilities. The study uses the Life Cycle Analysis (LCA), a methodology that is the basis for Carbon Lifecycle Analysis (LCACO2), or calculation of the carbon footprint of the facility. Construction carbon calculator, Environmental Protection Agency UK, is used to calculate the carbon footprint, and for the calculation of operational energy, the URSA Construction Physics 2 program. The study showed that the embodied carbon for the scenario (S1) is 138,40 tonnes CO2 e, with less impact on the environment. The higher values of the embodied carbon have a scenario (S2) of 148,20 tonnes CO2 e. The carbon imprint from the phase of construction, or less impact on the environment, has a scenario (S1). However, after ten years of using the facility, the scenario (S1) due to the larger carbon footprint from the operational phase becomes a scenario with a higher environmental impact, with a total carbon footprint of 186,16 tonnes CO2 e, and the scenario (S2) after ten years of use of the facility has a total carbon footprint of 163,86 tonnes CO2 e. The scenario (S1) and (S2) achieve the same values of the total carbon footprint after 3,05 years of use of the facility and (S2) has since then become a better choice from the aspect of the environment. The research has shown that the embodied carbon is neglected in the calculation of the environmental impact of the facility, as well as the average when the benefits can be expected from the application of measures for energy-efficient buildings. The research also points to the need for low-carbon thermal insulation materials to bridge the gap between the demand for the extinguishing of buildings on the one hand and the efforts to reduce greenhouse gas emissions to mitigate climate change.
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