Fault Isolability Analysis and Optimal Sensor Placement for Fault Diagnosis in Smart Buildings
Abstract
:1. Introduction
2. Methodology
3. Modeling Approach
3.1. Case Study Building
3.2. Dynamic Model
3.2.1. Scenario 1
3.2.2. Scenario 2
4. Results and Discussions
4.1. Dulmage-Mendelnsohn Decomposition
4.2. Isolability Analysis
4.3. Discussion
5. Conclusions
- It was well demonstrated that the methods could successfully be used for building applications. It was possible to do the fault diagnosis of the faults introduced to the model. Here, the method was capable of handling five faults (in scenario 2).
- Systems that contain underdetermined parts cannot be used in a sensor placement analysis. As the sensor placement algorithm looks for all sensor sets ensuring full isolability, the set of sensors becomes too big to handle. Therefore, scenarios, where different variables (e.g., valve positions) were assumed to be constant, were designed to avoid underdetermined parts of the system.
- Full detectability and isolability was obtained by adding additional sensors to the system by using the sensor placement algorithm. It was found that as the system gets more complex through introducing more faults, additional sensors should be added to gain full isolability.
Author Contributions
Funding
Conflicts of Interest
Nomenclature
Symbol | Description | Units |
External thermal mass capacitance. | J/K | |
Internal thermal mass capacitance. | J/K | |
Thermal capacitance for the room. | J/K | |
Ventilation damper position. | % | |
FDD | Fault detection and diagnosis. | |
FDT | MatLab-driven Fault Diagnosis Toolbox | |
Percentage fault in . | % | |
Sensor fault in | ||
Sensor fault in | ||
Sensor fault in | ||
Solar coefficient. | ||
Percentage fault in | % | |
Faulty new added sensor in | ||
Horizontal global radiation. | W | |
Occupancy heat gain. | W | |
Maximum radiator power. | W | |
Ventilation heat gain. | W | |
External wall resistance. | K/W | |
External wall resistance | K/W | |
Internal wall resistance | K/W | |
Time derivative of . | °C | |
External thermal mass temperature. | °C | |
Time derivative of . | °C | |
Internal thermal mass temperature. | °C | |
Outdoor temperature. | °C | |
Time derivative of . | °C | |
Room temperature. | °C | |
Ventilation air temperature. | °C | |
Maximum airflow rate into the room when damper is fully open. | ||
Radiator valve position. | % | |
Sensor measurement of . | °C | |
Sensor measurement of . | °C | |
Sensor measurement of . | °C | |
Sensor measurement of . | °C |
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Trothe, M.E.S.; Shaker, H.R.; Jradi, M.; Arendt, K. Fault Isolability Analysis and Optimal Sensor Placement for Fault Diagnosis in Smart Buildings. Energies 2019, 12, 1601. https://doi.org/10.3390/en12091601
Trothe MES, Shaker HR, Jradi M, Arendt K. Fault Isolability Analysis and Optimal Sensor Placement for Fault Diagnosis in Smart Buildings. Energies. 2019; 12(9):1601. https://doi.org/10.3390/en12091601
Chicago/Turabian StyleTrothe, Max Emil S., Hamid Reza Shaker, Muhyiddine Jradi, and Krzysztof Arendt. 2019. "Fault Isolability Analysis and Optimal Sensor Placement for Fault Diagnosis in Smart Buildings" Energies 12, no. 9: 1601. https://doi.org/10.3390/en12091601
APA StyleTrothe, M. E. S., Shaker, H. R., Jradi, M., & Arendt, K. (2019). Fault Isolability Analysis and Optimal Sensor Placement for Fault Diagnosis in Smart Buildings. Energies, 12(9), 1601. https://doi.org/10.3390/en12091601