Applying Dynamic U-Value Measurements for State Forecasting in Buildings

IF 0.5 Q4 PHYSICS, APPLIED
J. Telicko, A. Jakovics
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引用次数: 0

Abstract

Abstract In the present day, monitoring and automated control stand as pivotal factors for the energy-efficient and comfortable operation of buildings. As the demand for indoor climate control grows, building management systems have become more intricate, making their control challenging due to the increasing number of controllable elements. Replacing manual human analysis of complex systems can be achieved through the utilization of algorithms like model-based control. It is important to note that performance of this method usually relies on the accuracy of neural network-based building state forecasts. Studying the internal dynamics of climate as influenced by temperature changes necessitates a brief record of measurements, whereas evaluating structural modifications through moisture transfer demands data covering a more extended period. Neural networks such as Long Short-Term Memory have the potential to lose information within lengthy time-series data, and the intricate nature of moisture transfer further adds complexity to the task of approximating functions, ultimately leading to a reduction in energy efficiency. In order to improve the precision of indoor climate predictions, our suggestion involves not only assessing changes in temperature but also considering alterations in U-values triggered by temperature variations and moisture transfer. Our preliminary assessment of the influence of U-value, conducted through numerical simulations using WUFI6, exposes variations of up to 10 % of U-value in certain scenarios. Dealing with these computations in real time using physical models proves to be demanding due to computational requirements and limited data availability. To tackle this issue, we present an innovative preprocessing approach for on-the-fly evaluation of U-values. Empirical trials involving three years of monitoring data indicate that the suggested technique led to an approximate 8 % reduction in the average mean squared error of climate predictions based on neural network models, in specific instances.
应用动态 U 值测量进行建筑状态预测
摘要在当今社会,监控和自动化控制是建筑节能和舒适运行的关键因素。随着室内气候控制需求的增长,建筑管理系统变得更加复杂,由于可控元素数量的增加,使其控制变得具有挑战性。通过使用基于模型的控制等算法,可以取代人工对复杂系统的分析。值得注意的是,这种方法的性能通常依赖于基于神经网络的建筑状态预测的准确性。研究受温度变化影响的气候内部动力学需要一个简短的测量记录,而通过水分转移评估结构变化则需要覆盖更长的时期的数据。像长短期记忆这样的神经网络有可能在长时间序列数据中丢失信息,而水分转移的复杂性进一步增加了近似函数的复杂性,最终导致能源效率的降低。为了提高室内气候预测的精度,我们建议不仅要评估温度变化,还要考虑温度变化和水分转移引起的u值变化。我们通过使用WUFI6的数值模拟对u值的影响进行了初步评估,揭示了在某些情况下u值的变化高达10%。由于计算需求和有限的数据可用性,使用物理模型实时处理这些计算被证明是非常苛刻的。为了解决这个问题,我们提出了一种创新的u值动态评估预处理方法。涉及三年监测数据的经验试验表明,在特定情况下,所建议的技术使基于神经网络模型的气候预测的平均均方误差减少了大约8%。
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来源期刊
CiteScore
1.50
自引率
16.70%
发文量
41
审稿时长
5 weeks
期刊介绍: Latvian Journal of Physics and Technical Sciences (Latvijas Fizikas un Tehnisko Zinātņu Žurnāls) publishes experimental and theoretical papers containing results not published previously and review articles. Its scope includes Energy and Power, Energy Engineering, Energy Policy and Economics, Physical Sciences, Physics and Applied Physics in Engineering, Astronomy and Spectroscopy.
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