C. Lucchetti, M. Castelluccio, M. Altamore, A. Briganti, G. Galli, M. Soligo, P. Tuccimei, M. Voltaggio
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引用次数: 6
摘要
摘要在欧盟委员会资助的LIFE 2016项目氡实时监测系统和室内主动补救(RESPIRE)的框架内,研究了火山成因建筑材料对室内氡浓度的贡献。首先,测量了Caprarola地区(意大利中部)地质材料的总伽马辐射和相关室外剂量率,以确定主要辐射源。其次,这些用作建筑材料的岩石的222Rn和220Rn呼气率是使用与RAD7氡监测仪闭环连接的积聚室测量的。其中,多孔的“Tufo di Gallese”熔结凝灰岩提供了最高的价值。然后用这种材料建造了一个62cm×50cm×35cm(内部长度×宽度×高度分别为)的比例模型室,以评估平衡状态下的实验氡和钍活性浓度,并研究气候条件和不同涂层对氡水平的影响。第一次测试是在环境温度下进行的,以确定模型室中的实验222Rn和220Rn平衡活性,该模型室没有覆盖石膏或其他涂层材料。在短短两天内记录了222Rn的实验平衡,证明房间“呼吸”,与室外环境交换空气。这决定了室内氡浓度的稀释度。其他实验表明,内覆盖物(如石膏板和不同种类的油漆)部分影响222Rn,但完全切断了寿命短的220Rn。最后,环境温度的降低降低了建筑材料中氡的析出,进而降低了室内活动的浓度。
Using a scale model room to assess the contribution of building material of volcanic origin to indoor radon
Abstract In the frame of Radon rEal time monitoring System and Proactive Indoor Remediation (RESPIRE), a LIFE 2016 project funded by the European Commission, the contribution of building materials of volcanic origin to indoor radon concentration was investigated. First, total gamma radiation and related outdoor dose rates of geological materials in the Caprarola area (Central Italy) were measured to define main sources of radiation. Second, 222Rn and 220Rn exhalation rates of these rocks used as building materials were measured using an accumulation chamber connected in a closed loop with a RAD7 radon monitor. Among others, the very porous “Tufo di Gallese” ignimbrite provided the highest values. This material was then used to construct a scale model room of 62 cm × 50 cm × 35 cm (inner length × width × height, respectively) to assess experimental radon and thoron activity concentration at equilibrium and study the effects of climatic conditions and different coatings on radon levels. A first test was carried out at ambient temperature to determine experimental 222Rn and 220Rn equilibrium activities in the model room, not covered with plaster or other coating materials. Experimental 222Rn equilibrium was recorded in just two days demonstrating that the room “breaths”, exchanging air with the outdoor environment. This determines a dilution of indoor radon concentration. Other experiments showed that inner covers (such as plasterboard and different kinds of paints) partially influence 222Rn but entirely cut the short-lived 220Rn. Finally, decreases in ambient temperature reduce radon exhalation from building material and, in turn, indoor activity concentration.
期刊介绍:
"Nukleonika" is an international peer-reviewed, scientific journal publishing original top quality papers on fundamental, experimental, applied and theoretical aspects of nuclear sciences.
The fields of research include:
radiochemistry, radiation measurements, application of radionuclides in various branches of science and technology, chemistry of f-block elements, radiation chemistry, radiation physics, activation analysis, nuclear medicine, radiobiology, radiation safety, nuclear industrial electronics, environmental protection, radioactive wastes, nuclear technologies in material and process engineering, radioisotope diagnostic methods of engineering objects, nuclear physics, nuclear reactors and nuclear power, reactor physics, nuclear safety, fuel cycle, reactor calculations, nuclear chemical engineering, nuclear fusion, plasma physics etc.