用非固定方法测定建筑围护结构的热损失

Nodar KEVKHISHVILI, None Tengiz JISHKARIANI, Nikoloz JAVSHANASHVILI
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引用次数: 0

摘要

气候变化的主要原因之一是积累大量的二氧化碳(CO2)在大气中从燃烧的有机燃料(煤,石油产品和天然气),因此,减缓全球变暖的进程直接关系到二氧化碳的排放限制,这可以通过合理使用燃料和能源在每个部门(工业,家庭,运输和建筑部门)实现。引进节能措施,包括高效技术和创新方法。建筑部门约占节能潜力的40%,因此减少能源损失是降低建筑能耗的最佳途径。为了计算建筑围护结构的热损失,必须知道每个建筑单元的导热系数(λ)。目前发展的λ测定方法是完全基于实验室测试使用的平稳制度。为了得到更真实的结果,有必要考虑温度和非平稳导热过程的每日变化。求解非平稳导热系数问题由于应用了相对复杂的数学方程而具有很大的困难。通常,非平稳导热理论指的是分离变量的方法或所谓的拉普拉斯变换,这需要使用运算计数方法。本文提出了一种创新的方法,用于确定在非平稳温度状态下每个建筑元件的导热系数(λ),该方法可以使用热流速度的精确定义来确定真实环境中建筑围护结构的热损失。
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DETERMINING HEAT LOSSES FROM THE BUILDING ENVELOPE USING THE NON-STATIONARY METHOD
One of the main causes of the climate change is accumulation of huge amount of carbon dioxide (CO2) in the atmosphere emitted from the combusting of organic fuels (coal, oil products and natural gas), consequently, to slow down the progress of the global warming is directly related to the limitation of CO2 emission which could be achieved through the rational use of fuel and energy in every sector (industrial, household, transport and building sectors), introduction of energy-saving measures including highly efficient technologies and innovative methods. The building sector accounts for about 40% of the energy saving potential, therefore reduction of energy losses is the best way to reduce energy consumption of buildings. To calculate the heat loss from the building envelope, it is necessary to know the thermal conductivity coefficient (λ) of each construction element. Currently developed methods of λ determination are entirely based on the laboratory test using the stationary regime. For more realistic results, it is necessary to take into account the daily variability of temperature and non-stationary thermal conductivity processes. Solving the non-stationary thermal conductivity tasks are associated with the significant difficulties due to the application of the relatively complex mathematical equations. Usually, the theory of non-stationary thermal conductivity refers to the method of separation of variables or the so-called Laplace Transform, which requires the use of operational counting methods. The article presents an innovative method for determining the coefficient of thermal conductivity (λ) of each construction element in the non-stationary temperature regime, which enables determination of heat losses from the building envelope in real environment using the precise definition of thermal flow velocity.
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来源期刊
Pharmacy World & Science
Pharmacy World & Science 医学-药学
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>12 weeks
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