Abstract
Faults in Heating, Ventilation and Air Conditioning (HVAC) systems affect the energy efficiency of buildings. To date, there rarely exist methods to detect and diagnose faults during the operation of buildings that are both cost-effective and sufficient accurate. This study presents a method that uses artificial intelligence to automate the detection of faults in HVAC systems. The automated fault detection is based on a residual analysis of the predicted total heating power and the actual total heating power using an algorithm that aims to find an optimal decision rule for the determination of faults. The data for this study was provided by a detailed simulation of a residential case study house. A machine learning model and an ARX model predict the building operation. The model for fault detection is trained on a fault-free data set and then tested with a faulty operation. The algorithm for an optimal decision rule uses various statistical tests of residual properties such as the Sign Test, the Turning Point Test, the Box-Pierce Test and the Bartels-Rank Test. The results show that it is possible to predict faults for both known faults and unknown faults. The challenge is to find the optimal algorithm to determine the best decision rules. In the outlook of this study, further methods are presented that aim to solve this challenge.
Highlights
In the effort to fight global warming, one of the German government’s goals is to achieve a climate-neutral building stock by 2050
The automated fault detection is based on a residual analysis of the predicted total heating power and the actual total heating power using an algorithm that aims to find an optimal decision rule for the determination of faults
The data for this study was provided by a detailed simulation of a residential case study house
Summary
In the effort to fight global warming, one of the German government’s goals is to achieve a climate-neutral building stock by 2050. The policies focus on two strategies, the use of renewable energies and the increase in energy efficiency. Long-term climate neutrality in the building sector can be achieved by reducing energy consumption and expanding renewable energy [1]. The thermal properties of the building envelope, the efficiency of building technology, and the user behaviour significantly influence energy efficiency of a building. In order to take measures to improve existing buildings, it is essential to detect the actual energy efficiency of a building. With on-site measurement data, the actual energy consumption can be detected, and flaws in energy efficiency identified
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