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环境科学期刊投稿评价

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环境科学期刊投稿

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doi:1016/004 Copyright © 2008 Elsevier Ltd All rights Experimental evaluation of the growth rate of mould on finishes for indoor housing environments: Effects of the 2002/91/EC directive Marco D'Orazioa, , , Marco Palladinia, Lucia Aquilantib and Francesca Clementib aDepartment of Architecture Construction and Structures - DACS, Università Politecnica delle Marche, Via Brecce Bianche, 60131 Ancona, Italy bDepartment of Food Science, Agricultural-Engineering, Physics, Agricultural Economics and Landscape Science - SAIFET, Università Politecnica delle Marche, Via Brecce Bianche, 60131 Ancona, Italy Received 15 May 2008; revised 3 November 2008; accepted 5 November Available online 21 November Abstract We report the results of a study to evaluate the growth rate of three species of mould on plasters, finishes and paints typically used in structures with heavy weight building The aim was to determine the influence of the chemical composition (in terms of organic fraction of the materials) on the growth rate of The study was carried out in the following steps: – characterization of materials; – inoculation of mould spores (3 species) on 7 types of material (2 plasters, 3 finishes, 2 paints); – growth in a climatic chamber (23 °C and 90% RH); – analysis of the mould growth rate using various experimental techniques (fluorescence microscopy analysis, thermogravimetric analysis, ) Results show a clear correlation between the organic substances contained in paints, plasters and finishes and the growth rate of the This study is part of a more general research program which addresses the effects on indoor environment air quality based on the European directive 2002/91/EC This directive specifically indicates that energy consumption in buildings should be limited and sets threshold values for the thermal resistance of the building walls and As a consequence window manufacturers are improving the thermal property of windows by reducing the air permeability, which may increase the indoor and surface relative humidity percentage (RH%) and lead to the development of mould in the indoor Keywords: Mould; Plaster; Paint; Biocontamination Article Outline Introduction Steps, materials, methods Steps Materials Methods Results Preliminary characterization Growth rate of the mould Correlation between the mould growth area and the content of organic substances Conclusions References Introduction The tendency in industrialized countries to reduce energy consumption has been accelerated in the EC member states by the introduction of the 2002/91/EC directive [1] In fact, this directive fixed the minimum requirements which must be respected when building new structures and when renovating existing buildings so as to have a more effective reduction in energy consumption for the air-conditioning of indoor This strategy has, however, led to some undesired Windows manufacturers are currently producing systems with low permeability (class A4 UNI EN 12207, 2000) in order to obtain better thermal A reduction in permeability, in buildings which are already characterized by a limited amount of air exchange, can increase the indoor and surface RH% in winter [16] Consequently there may be an increased growth of mould species on some parts of the Numerous studies have been conducted in recent years to address the environmental aspects that favour the growth and the subsequent sporulation of fungi Rousseau [2] and Hud [3], indicate the following factors: oxygen availability; a suitable temperature range; a substrate of deposit that acts as nourishment; and a certain degree of humidity [4], [34] and [36] Krus et [5] have studied these conditions, together with a series of other specific factors that can influence the growth of fungi: pH value and the roughness of the substrate on which the mould grows, the light, the biotic interaction and the exposure Baughman and Arens [6] have underlined that, although moulds can grow at temperatures between 0 °C and 40 °C, a range going from 22 °C to 35 °C can be considered optimal for the species that are most frequently found inside On the contrary, the level of airborne spores in the indoor environment, which is one of the conditions able to influence the development of moulds, is dependent on seasonal changes in the external environment [7] Adan [7] has verified that there are a considerable number of buildings that offer favourable temperature conditions for the germination and the growth of mould on construction material and indoor environment Sedlbauer [8], [9], [10] and [11] has recently completed an important research and development study of models which are able to estimate mould growth inside buildings, classifying the various These different authors appear to be in agreement, however, in indicating that different kinds of fungi require minimum levels of humidity in the support surface material in order to proliferate and these values vary for different species [6], [12] and [35] Ayerst [12] has conducted experiments in order to characterize the ideal conditions and the minimum values of humidity required in the substrate for mildew These experiments indicate a range between 71% and 94%, according to the fungi Moulds (typically present on construction materials) can be separated into three groups on the basis of their water activity (aw) [13]: primer colonizer or storage moulds, capable of growing at aw < 8; secondary colonizer or phyllophane fungi, requiring a minimum aw between 8 and 9; and tertiary colonizer or water-damage moulds, needing aw > The last class includes the most toxic mould species for human Although each species has a preferential humidity for growth, the International Energy Agency [33] indicates an average RH% of 80% as the critical threshold for mould A reduction in moisture content in building materials to below 80% RH% is, therefore, the way to reduce mould Only a limited amount of information is available about the influence of the composition of the finish materials on the germination and development, in terms of percentage, of 可以的话留下你的联系e-MAIL 这种文章太多了 就随便搞了一篇的一部分让你看看·· 明天帮你找找!至于翻译的话比较困难··看情况,找到的话给你翻译个abstract吧·

环境影响评价杂志于2013年9月创刊,由环境保护部环境工程评估中心、中国环境出版社、重庆市环境科学研究院联合主办。该杂志是我国环境影响评价工作指导刊,也是当前我国唯一以环境影响评价为主题的国家级专业期刊,由环境保护部吴晓青副部长担任编委会主任,环境保护部环境工程评估中心梁鹏总工程师担任总编辑。环境影响评价致力于深入研究环境影响评价法规、标准、环评专业技术及学术动态、典型环评案例等环评领域的重点工作内容,进行权威的政策解读和业务讲解,为环境影响评价专业人员搭建了解国家政策、研讨环评技术、交流工作经验的平台,成为环评成果的展示窗口、环评技术的交流平台、环评理论的创新摇篮和公众参与的沟通桥梁。

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