Economic, Environmental and Health Implications of Enhanced Ventilation in Office Buildings

Introduction: Current building ventilation standards are based on acceptable minimums. Three decades of research demonstrates the human health benefits of increased ventilation above these minimums. Recent research also shows the benefits on human decision-making performance in office workers, which translates to increased productivity. However, adoption of enhanced ventilation strategies is lagging. We sought to evaluate two of the perceived potential barriers to more widespread adoption—Economic and environmental costs. Methods: We estimated the energy consumption and associated per building occupant costs for office buildings in seven U.S. cities, representing different climate zones for three ventilation scenarios (standard practice (20 cfm/person), 30% enhanced ventilation, and 40 cfm/person) and four different heating, ventilation and air conditioning (HVAC) system strategies (Variable Air Volume (VAV) with reheat and a Fan Coil Unit (FCU), both with and without an energy recovery ventilator). We also estimated emissions of greenhouse OPEN ACCESS Int. J. Environ. Res. Public Health 2015, 12 14710 gases associated with this increased energy usage, and, for comparison, converted this to the equivalent number of vehicles using greenhouse gas equivalencies. Lastly, we paired results from our previous research on cognitive function and ventilation with labor statistics to estimate the economic benefit of increased productivity associated with increasing ventilation rates. Results: Doubling the ventilation rate from the American Society of Heating, Refrigeration and Air-Conditioning Engineers minimum cost less than $40 per person per year in all climate zones investigated. Using an energy recovery ventilation system significantly reduced energy costs, and in some scenarios led to a net savings. At the highest ventilation rate, adding an ERV essentially neutralized the environmental impact of enhanced ventilation (0.03 additional cars on the road per building across all cities). The same change in ventilation improved the performance of workers by 8%, equivalent to a $6500 increase in employee productivity each year. Reduced absenteeism and improved health are also seen with enhanced ventilation. Conclusions: The health benefits associated with enhanced ventilation rates far exceed the per-person energy costs relative to salary costs. Environmental impacts can be mitigated at regional, building, and individual-level scales through the transition to renewable energy sources, adoption of energy efficient systems and ventilation strategies, and promotion of other sustainable policies.

[1]  M Hamilton,et al.  Perceptions in the U.S. building industry of the benefits and costs of improving indoor air quality. , 2016, Indoor air.

[2]  A K Melikov,et al.  Advanced air distribution: improving health and comfort while reducing energy use. , 2016, Indoor air.

[3]  Joseph G. Allen,et al.  Associations of Cognitive Function Scores with Carbon Dioxide, Ventilation, and Volatile Organic Compound Exposures in Office Workers: A Controlled Exposure Study of Green and Conventional Office Environments , 2015, Environmental health perspectives.

[4]  A. Persily Challenges in Developing Ventilation and Indoor Air Quality Standards: The Story of ASHRAE Standard 62. , 2015, Building and environment.

[5]  Christoph F. Reinhart,et al.  Assessing future climate change and energy price scenarios: institutional building investment , 2013 .

[6]  C. Cooney Managing the Risks of Extreme Weather: IPCC Special Report , 2012, Environmental health perspectives.

[7]  L. Morawska,et al.  Room ventilation and the risk of airborne infection transmission in 3 health care settings within a large teaching hospital , 2011, American Journal of Infection Control.

[8]  G. Brooke Anderson,et al.  Heat Waves in the United States: Mortality Risk during Heat Waves and Effect Modification by Heat Wave Characteristics in 43 U.S. Communities , 2010, Environmental health perspectives.

[9]  Martijn Gough Climate change , 2009, Canadian Medical Association Journal.

[10]  Joel Schwartz,et al.  Uncertainty and Variability in Health‐Related Damages from Coal‐Fired Power Plants in the United States , 2009, Risk analysis : an official publication of the Society for Risk Analysis.

[11]  S. Joshi,et al.  The sick building syndrome , 2008, Indian journal of occupational and environmental medicine.

[12]  William J. Fisk,et al.  Economizer system cost effectiveness: Accounting for the influence of ventilation rate on sick leave , 2003 .

[13]  J. Church How Fast Are Sea Levels Rising? , 2001, Science.

[14]  P. Fanger,et al.  The effects of outdoor air supply rate in an office on perceived air quality, sick building syndrome (SBS) symptoms and productivity. , 2000, Indoor air.

[15]  D K Milton,et al.  Risk of sick leave associated with outdoor air supply rate, humidification, and occupant complaints. , 2000, Indoor air.

[16]  A. Rosenfeld,et al.  Estimates of Improved Productivity and Health from Better Indoor Environments , 1997 .

[17]  Stefan Gravenstein,et al.  Report of an Outbreak: Nursing Home Architecture and Influenza‐A Attack Rates , 1996, Journal of the American Geriatrics Society.

[18]  J Sundell,et al.  The Sick Building Syndrome (SBS) in office workers. A case-referent study of personal, psychosocial and building-related risk indicators. , 1994, International journal of epidemiology.

[19]  D. Musher,et al.  An epidemic of pneumococcal disease in an overcrowded, inadequately ventilated jail. , 1994, The New England journal of medicine.

[20]  Siegfried Streufert,et al.  Simulation-Based Assessment of Managerial Competence: Reliability and Validity. , 1988 .

[21]  David W. Smith,et al.  Building-associated risk of febrile acute respiratory diseases in Army trainees. , 1988, JAMA.

[22]  P. Abelson Effects of SO2 and NOx Emissions. , 1984, Science.

[23]  K. Sexton,et al.  Indoor air pollution: a public health perspective. , 1983, Science.