Abstract
The objective of this study was to explore the potential of a machine learning algorithm, the Support Vector Machine Regression (SVR), to forecast long-term hygrothermal responses and the moisture performance of light wood frame and massive timber walls. Hygrothermal simulations were performed using a 31-year long series of climate data in three cities across Canada. Then, the first 5 years of the series were used in each case to train the model, which was then used to forecast the hygrothermal responses (temperature and relative humidity) and moisture performance indicator (mold growth index) for the remaining years of the series. The location of interest was the exterior layer of the OSB and cross-laminated timber in the case of the wood frame wall and massive timber wall, respectively. A sliding window approach was used to incorporate the dependence of the hygrothermal response on the past climatic conditions, which allowed SVR to capture time, implicitly. The variable selection was performed using the Least Absolute Shrinkage and Selection Operator, which revealed wind-driven rain, relative humidity, temperature, and direct radiation as the most contributing climate variables. The results show that SVR can be effectively used to forecast hygrothermal responses and moisture performance on a long climate data series for most of the cases studied. In some cases, discrepancies were observed due to the lack of capturing the full range of variability of climate variables during the first 5 years.
Highlights
There is enough evidence that the climate has been warming globally [1], causing more frequent and extreme climate events that can significantly impact building infrastructure, the durability of building envelope components [2]
Given the evidence that global warming is in effect, there is a need to assess its impact on the long-term durability of building envelopes and its components and to find mitigation solutions
Considering the time constraints associated with the traditional hygrothermal simulations and the success of the modern machine learning algorithms, this study presents an approach to predict the long-term hygrothermal performance of the wall assembly using the Support Vector Regression
Summary
There is enough evidence that the climate has been warming globally [1], causing more frequent and extreme climate events that can significantly impact building infrastructure, the durability of building envelope components [2]. Given the evidence that global warming is in effect, there is a need to assess its impact on the long-term durability of building envelopes and its components and to find mitigation solutions. Even if it saves cost and time compared to laboratory tests, it is still time-consuming, especially when simulations are performed in 2D or 3D for multiple consecutive years It requires some knowledge of the heat and mass transfer mechanisms and numerical modeling to set up the model properly. The uncertainties associated with the projected climate data, i.e., uncertainties due to global warming scenarios and due to internal variability of the climate model [3], result in many sets of climate data that need to be considered in hygrothermal simulations
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