- Author
-
Persily, A. K.
|
Dols, W. S.
- Title
- Relation of CO₂ Concentration to Office Building Ventilation.
- Coporate
- National Institute of Standards and Technology, Gaithersburg, MD
- Report
-
ASTM STP 1067,
- Book or Conf
- American Society for Testing and Materials (ASTM). Air Change Rate and Airtightness in Buildings. ASTM STP 1067. 1990,
ASTM, Philadelphia, PA,
Sherman, M. H., Editors,
77-92 p.,
1990
- Keywords
-
building performance
|
indoor air quality
|
infiltration
|
measurement
|
mechanical ventilation
|
office buildings
|
tracer gas
|
ventilation
|
occupants
- Abstract
- Tracer gas techniques have been used to study air exchange in mechanically ventilated office buildings for many years. The analysis of the concentration of carbon dioxide (CO2) generated by building occupants has been suggested as an alternate means of evaluating building air exchange and ventilation system performance. Various techniques for CO2 analysis have been proposed. These include measuring the decay rate of CO2, concentration after the occupants leave the building, analyzing real-time CO2 concentration data in conjunction with a CO2 mass balance equation, and using instantaneous CO2 concentration readings to directly determine air exchange rates. Local CO2 concentrations have also been suggested as a means of evaluating ventilation effectiveness. These techniques require specific assumptions and unique conditions in order to yield reliable information on building air exchange characteristics, and these requirements may not always be met in office buildings. This paper examines the relationship between CO2 concentration and building air exchange. A dataset of simultaneously measured air exchange rates, based on sulfur hexafluoride (SF6) decay, and CO2 concentration obtained in there office buildings is employed to examine this relationship. The results indicate that CO2 decay rates can provide reliable estimates of building air exchange rates, but that there may be significant error associated with the use of instaneous concentrations to determine air exchange rates.