Effects of ERV Filter Degradation on Indoor CO2 Levels of a Classroom

Energy recovery ventilators (ERVs) are widely used to reduce energy losses caused by ventilation and improve indoor air quality for recently-constructed buildings. It is important for spaces with high occupancy density and longer residence times, such as classrooms. In classrooms, the ERV size is ty...

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Bibliographic Details
Published in:Sustainability 2018-04, Vol.10 (4), p.1215
Main Authors: Choi, Jae-Sol, Lee, Jae-Hyuk, Kim, Eui-Jong
Format: Article
Language:English
Subjects:
Aerodynamics
Air flow
Air quality
Carbon dioxide
Classrooms
Computational fluid dynamics
Computer applications
Degradation
Diffusers
Dilution
Dust filters
Energy recovery
Field tests
Flow rates
Flow velocity
Fluid dynamics
Hydrodynamics
Indoor air pollution
Indoor air quality
Indoor environments
Inspection
Residential density
Sustainability
Ventilators
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Summary:Energy recovery ventilators (ERVs) are widely used to reduce energy losses caused by ventilation and improve indoor air quality for recently-constructed buildings. It is important for spaces with high occupancy density and longer residence times, such as classrooms. In classrooms, the ERV size is typically estimated by the target number of students in the design phase, but the design air volume flow rates (m3/h) of the ERV can decrease over time owing to filter degradation such as increased dust loading. In this study, field tests are conducted in a classroom to investigate filter degradation through a visual inspection and by measuring the air volume flow rates at the diffusers connected to the ERV. In addition, variations in carbon dioxide (CO2) concentrations are also measured to verify the effects of filter degradation on the indoor CO2 levels over the entire test period, which includes filter replacement, as well. As the tests are conducted during classes, several adjusting methodologies are proposed to match the different test conditions. The results show that the total air volume flow rate of the ERV increases after the filter replacement (546 to 766 m3/h), but it again decreases as time elapses (659 m3/h). Accordingly, the indoor CO2 concentration decreases after the filter replacement by more than 300 ppm (1404 to 1085 ppm), clearly showing the effect of filter degradation. However, this CO2 concentration remains similar for four months after the replacement, and the total air volume rate decreases again. An interpretation is made using computational fluid dynamics analysis that the measured CO2 concentrations are affected by airflow patterns. The airflow in the cooling system may dilute CO2 concentrations at the measuring location. Thus, periodic filter replacement and management are important to ensure the desired ERV air volume rates and consequently the desired indoor CO2 concentrations.
ISSN:2071-1050
2071-1050
DOI:10.3390/su10041215