Your search keyword '"William J. Fisk"' showing total 84 results

1. Does dampness and mold in schools affect health? Results of a meta‐analysis

Author

William J. Fisk, Alexandra L Johnson, and Wanyu R. Chan

Subjects

Adult, Male, Environmental Engineering, Adolescent, 010504 meteorology & atmospheric sciences, 010501 environmental sciences, Affect (psychology), 01 natural sciences, Wheeze, Environmental health, medicine, Humans, Health risk, Child, Respiratory health, Respiratory Sounds, 0105 earth and related environmental sciences, Schools, business.industry, Fungi, Public Health, Environmental and Occupational Health, Humidity, Building and Construction, Odds ratio, Random effects model, Confidence interval, Cross-Sectional Studies, Cough, Air Pollution, Indoor, Meta-analysis, Female, medicine.symptom, business

Abstract

This paper provides meta-analyses of the published findings relating the respiratory health of occupants of schools with visible dampness, water damage, visible mold, and/or mold odor. Random effects models were used to develop central estimates and confidence limits for the associations of respiratory health effects with school dampness and mold. Eleven studies, all with cross-sectional designs, were included in the meta-analyses; however, analyses for some health outcomes were based on as few as four studies. Analyses were performed using data from adults and children combined, using only data from children, and using data from adults and children after excluding two studies. The central estimates of odds ratios from the meta-analyses were consistently above unity. The evidence of adverse health effects was strongest for cough and wheeze, which had confidence limits excluding unity in some or all analyses. The odds ratios of 1.32 for cough and 1.68 for wheeze suggest moderate increases in health risk. Studies not included in the meta-analyses provide additional evidence that dampness and mold in schools are associated with adverse health outcomes. These meta-analyses and the published literature not included in the meta-analyses suggest that dampness and mold in schools are associated with adverse respiratory health effects.

Published

2019

2. Health benefits and costs of filtration interventions that reduce indoor exposure to <scp>PM</scp> 2.5 during wildfires

Author

Wanyu R. Chan and William J. Fisk

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Cost effectiveness, Smoke Inhalation Injury, Cost-Benefit Analysis, Population, Psychological intervention, 010501 environmental sciences, Health benefits, 01 natural sciences, California, Wildfires, Patient Admission, Smoke, Environmental health, Humans, Medicine, education, 0105 earth and related environmental sciences, Inhalation Exposure, education.field_of_study, Cost–benefit analysis, business.industry, Public Health, Environmental and Occupational Health, Building and Construction, Intervention (law), Air Pollution, Indoor, Particulate Matter, business, Filtration

Abstract

Increases in hospital admissions and deaths are associated with increases in outdoor air particles during wildfires. This analysis estimates the health benefits expected if interventions had improved particle filtration in homes in Southern California during a 10-day period of wildfire smoke exposure. Economic benefits and intervention costs are also estimated. The six interventions implemented in all affected houses are projected to prevent 11% to 63% of the hospital admissions and 7% to 39% of the deaths attributable to wildfire particles. The fraction of the population with an admission attributable to wildfire smoke is small, thus, the costs of interventions in all homes far exceeds the economic benefits of reduced hospital admissions. However, the estimated economic value of the prevented deaths exceed or far exceed intervention costs for interventions that do not use portable air cleaners. For the interventions with portable air cleaner use, mortality-related economic benefits exceed intervention costs as long as the cost of the air cleaners, which have a multi-year life, are not attributed to the short wildfire period. Cost effectiveness is improved by intervening only in the homes of the elderly who experience most of the health effects of particles from wildfires.

Published

2016

3. How home ventilation rates affect health: A literature review

Author

William J. Fisk

Subjects

medicine.medical_specialty, Environmental Engineering, Health Status, Respiratory Tract Diseases, 0211 other engineering and technologies, review, Bioengineering, 02 engineering and technology, 010501 environmental sciences, Health benefits, Placebo, Affect (psychology), 01 natural sciences, Medical and Health Sciences, Home ventilation, homes, Engineering, Clinical Research, Wheeze, Air Pollution, 021105 building & construction, Behavioral and Social Science, Medicine, Humans, Indoor, Lung, Respiratory health, 0105 earth and related environmental sciences, Building & Construction, business.industry, Confounding, Public Health, Environmental and Occupational Health, carbon dioxide, health, Building and Construction, respiratory, Ventilation, Air Pollution, Indoor, Emergency medicine, Breathing, Housing, Earth Sciences, ventilation rates, Generic health relevance, medicine.symptom, business

Abstract

© 2018 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd This paper reviews studies of the relationships between ventilation rates (VRs) in homes and occupant health, primarily respiratory health. Five cross-sectional studies, seven case-control studies, and eight intervention studies met inclusion criteria. Nearly all studies controlled for a range of potential confounders and most intervention studies included placebo conditions. Just over half of studies reported one or more statistically significant (SS) health benefits of increased VRs. Wheeze was most clearly associated with VR. No health outcomes had SS associations with VRs in the majority of statistical tests. Most studies that reported SS health benefits from increased VRs also had additional health outcomes that did not improve with increased VRs. Overall, the number of SS improvements in health with increased VRs exceeded the anticipated chance improvements by approximately a factor of seven. The magnitude of the improvements in health outcomes with increased VRs ranged from 20% to several-fold improvements. In summary, the available research indicates a tendency for improvements in respiratory health with increased home VRs; however, health benefits do not occur consistently and other exposure control measures should be used together with ventilation. The research did not enable identification of a threshold VR below which adverse health effects occur.

Published

2018

4. Estimated effect of ventilation and filtration on chronic health risks in U.S. offices, schools, and retail stores

Author

Wanyu R. Chan, S. Parthasarathy, Thomas E. McKone, and William J. Fisk

Subjects

Chronic bronchitis, Environmental Engineering, 010504 meteorology & atmospheric sciences, 010501 environmental sciences, complex mixtures, 01 natural sciences, law.invention, law, Formaldehyde, Environmental health, Humans, Medicine, Workplace, Filtration, 0105 earth and related environmental sciences, Air filter, Pollutant, Inhalation exposure, Air Pollutants, Inhalation Exposure, Volatile Organic Compounds, Schools, business.industry, Public Health, Environmental and Occupational Health, Environmental Exposure, Building and Construction, Environmental exposure, Particulates, United States, Ventilation, Air Pollution, Indoor, Chronic Disease, Ventilation (architecture), Particulate Matter, business, Environmental Monitoring

Abstract

We assessed the chronic health risks from inhalation exposure to volatile organic compounds (VOCs) and particulate matter (PM2.5) in U.S. offices, schools, grocery, and other retail stores and evaluated how chronic health risks were affected by changes in ventilation rates and air filtration efficiency. Representative concentrations of VOCs and PM2.5 were obtained from available data. Using a mass balance model, changes in exposure to VOCs and PM2.5 were predicted if ventilation rate were to increase or decrease by a factor of two, and if higher efficiency air filters were used. Indoor concentrations were compared to health guidelines to estimate percentage exceedances. The estimated chronic health risks associated with VOC and PM2.5 exposures in these buildings were low relative to the risks from exposures in homes. Chronic health risks were driven primarily by exposures to PM2.5 that were evaluated using disease incidence of mortality, chronic bronchitis, and non-fatal stroke. The leading cancer risk factor was exposure to formaldehyde. Using disability-adjusted life years (DALYs) to account for both cancer and non-cancer effects, results suggest that increasing ventilation alone is ineffective at reducing chronic health burdens. Other strategies, such as pollutant source control and the use of particle filtration, should also be considered.

Published

2015

5. Energy and indoor air quality implications of alternative minimum ventilation rates in California offices

Author

William J. Fisk and Spencer Dutton

Subjects

Engineering, Environmental Engineering, Waste management, business.industry, Geography, Planning and Development, Environmental engineering, Building energy, Building and Construction, law.invention, Indoor air quality, Economizer, law, Air conditioning, HVAC, Ventilation (architecture), Electricity, business, Energy (signal processing), Civil and Structural Engineering

Abstract

The energy and IAQ implications of varying prescribed minimum outdoor air ventilation rates (VRs) in California office buildings were estimated using the EnergyPlus building simulation software tool. Weighting factors were used to scale these model predictions to state wide estimates. Energy use predictions were then verified using surveyed California building energy end use data. Models predicted state wide office electricity use that was within 15% of reported electricity consumption from power utilities. The HVAC energy penalty of providing the current Title-24 VRs was approximately 6%, of the total HVAC energy use. Having economizers installed reduced average indoor formaldehyde exposure by 38% and lowered HVAC EUI by 20%. For California offices with economizers, 50% and 100% increases in Title-24 prescribed minimum VRs increased heating, ventilating, and air conditioning (HVAC) modeled energy use by 7.6% and 21.6%, respectively, while decreasing the annual average workplace formaldehyde exposure by 8.6% and 14.4%, respectively. Economizers increased VRs above the minimum 79% of the time lowering annual average concentrations of formaldehyde. Decreasing minimum VRs below the Title-24 rate would have smaller predicted effects on energy use and comparatively larger effects on formaldehyde concentrations. In buildings without economizers in many climate zones, increasing VRs up to 150% of the current Title-24 minimum would save HVAC energy and significantly reduce formaldehyde. A key conclusion is that raising future minimum VRs in California offices is unlikely to significantly improve time-averaged IAQ in buildings with economizers. Lowering future minimum VRs would be unlikely to deliver substantive energy savings.

Published

2014

6. The ventilation problem in schools: literature review

Author

William J. Fisk

Subjects

Pediatrics, medicine.medical_specialty, Environmental Engineering, Secondary education, 010504 meteorology & atmospheric sciences, Health Status, education, costs, 010501 environmental sciences, 01 natural sciences, Medical and Health Sciences, law.invention, Public spending, Engineering, law, Air Pollution, Academic Performance, Medicine, Capital cost, Humans, Indoor, Lung, Respiratory health, health care economics and organizations, 0105 earth and related environmental sciences, Building & Construction, Schools, business.industry, Air, ventilation, Public Health, Environmental and Occupational Health, carbon dioxide, health, Building and Construction, Carbon Dioxide, Intervention studies, Ventilation, Air Pollution, Indoor, Ventilation (architecture), Earth Sciences, Demographic economics, business, performance

Abstract

© 2017 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd Based on a review of literature published in refereed archival journals, ventilation rates in classrooms often fall far short of the minimum ventilation rates specified in standards. There is compelling evidence, from both cross-sectional and intervention studies, of an association of increased student performance with increased ventilation rates. There is evidence that reduced respiratory health effects and reduced student absence are associated with increased ventilation rates. Increasing ventilation rates in schools imposes energy costs and can increase heating, ventilating, and air-conditioning system capital costs. The net annual costs, ranging from a few dollars to about 10 dollars per person, are less than 0.1% of typical public spending on elementary and secondary education in the United States. Such expenditures seem like a small price to pay given the evidence of health and performance benefits.

Published

2017

7. Effects of ventilation rate per person and per floor area on perceived air quality, sick building syndrome symptoms, and decision-making

Author

William J. Fisk, Wanyu R. Chan, Randy L. Maddalena, Marion L. Russell, D. P. Sullivan, K. Eliseeva, Mark J. Mendell, and Usha Satish

Subjects

Adult, Male, medicine.medical_specialty, Sick Building Syndrome, Environmental Engineering, Decision Making, law.invention, Young Adult, Sick building syndrome, law, Surveys and Questionnaires, Humans, Medicine, Effects of sleep deprivation on cognitive performance, Young adult, Air quality index, Simulation, business.industry, Public Health, Environmental and Occupational Health, Building and Construction, Ventilation, Air Pollution, Indoor, Ventilation (architecture), Physical therapy, Female, business

Abstract

Ventilation rates (VRs) in buildings must adequately control indoor levels of pollutants; however, VRs are constrained by the energy costs. Experiments in a simulated office assessed the effects of VR per occupant on perceived air quality (PAQ), Sick Building Syndrome (SBS) symptoms, and decision-making performance. A parallel set of experiments assessed the effects of VR per unit floor area on the same outcomes. Sixteen blinded healthy young adult subjects participated in each study. Each exposure lasted four hours and each subject experienced two conditions in a within-subject study design. The order of presentation of test conditions, day of testing, and gender were balanced. Temperature, relative humidity, VRs, and concentrations of pollutants were monitored. Online surveys assessed PAQ and SBS symptoms and a validated computer-based tool measured decision-making performance. Neither changing the VR per person nor changing the VR per floor area, had consistent statistically significant effects on PAQ or SBS symptoms. However, reductions in either occupant-based VR or floor-area-based VR had a significant and independent negative impact on most decision-making measures. These results indicate that the changes in VR employed in the study influence performance of healthy young adults even when PAQ and SBS symptoms are unaffected.The study results indicate the importance of avoiding low VRs per person and low VRs per floor area to minimize decrements in cognitive performance.

Published

2014

8. Evaluation of the indoor air quality minimum ventilation rate procedure for use in California retail buildings

Author

Wanyu R. Chan, Mark J. Mendell, William J. Fisk, M. Barrios, S. M. Dutton, D. P. Sullivan, Ekaterina A. Eliseeva, and Meera Sidheswaran

Subjects

Male, Engineering, Environmental Engineering, Adolescent, Air changes per hour, Air cleaning, California, law.invention, Transport engineering, Young Adult, Indoor air quality, law, Humans, Air quality index, Air Pollutants, Aldehydes, Volatile Organic Compounds, Waste management, business.industry, Commerce, Public Health, Environmental and Occupational Health, Building and Construction, Health Surveys, Intervention studies, Ventilation, Source reduction, Air conditioning, Air Pollution, Indoor, Ventilation (architecture), Female, Perception, business, Environmental Monitoring

Abstract

This research assesses benefits of adding to California Title-24 ventilation rate (VR) standards a performance-based option, similar to the American Society of Heating, Refrigerating, and Air Conditioning Engineers 'Indoor Air Quality Procedure' (IAQP) for retail spaces. Ventilation rates and concentrations of contaminants of concern (CoC) were measured in 13 stores. Mass balance models were used to estimate 'IAQP-based' VRs that would maintain concentrations of all CoCs below health- or odor-based reference concentration limits. An intervention study in a 'big box' store assessed how the current VR, the Title 24-prescribed VR, and the IAQP-based VR (0.24, 0.69, and 1.51 air changes per hour) influenced measured IAQ and perceived of IAQ. Neither current VRs nor Title 24-prescribed VRs would maintain all CoCs below reference limits in 12 of 13 stores. In the big box store, the IAQP-based VR kept all CoCs below limits. More than 80% of subjects reported acceptable air quality at all three VRs. In 11 of 13 buildings, saving energy through lower VRs while maintaining acceptable IAQ would require source reduction or gas-phase air cleaning for CoCs. In only one of the 13 retail stores surveyed, application of the IAQP would have allowed reduced VRs without additional contaminant-reduction strategies.

Published

2014

9. Effectiveness and cost of reducing particle-related mortality with particle filtration

Author

Wanyu R. Chan and William J. Fisk

Subjects

Engineering, Environmental Engineering, 010504 meteorology & atmospheric sciences, Cost-Benefit Analysis, Population, Particle (ecology), 010501 environmental sciences, 01 natural sciences, Air cleaner, law.invention, law, HEPA, Humans, Air Conditioning, Mortality, education, Filtration, 0105 earth and related environmental sciences, education.field_of_study, Inhalation Exposure, business.industry, Public Health, Environmental and Occupational Health, Environmental engineering, Building and Construction, Models, Theoretical, Economic benefits, Ventilation, Air conditioning, Air Pollution, Indoor, business

Abstract

This study evaluates the mortality-related benefits and costs of improvements in particle filtration in U.S. homes and commercial buildings based on models with empirical inputs. The models account for time spent in various environments as well as activity levels and associated breathing rates. The scenarios evaluated include improvements in filter efficiencies in both forced-air heating and cooling systems of homes and heating, ventilating, and air conditioning systems of workplaces as well as use of portable air cleaners in homes. The predicted reductions in mortality range from approximately 0.25 to 2.4 per 10 000 population. The largest reductions in mortality were from interventions with continuously operating portable air cleaners in homes because, given our scenarios, these portable air cleaners with HEPA filters most reduced particle exposures. For some interventions, predicted annual mortality-related economic benefits exceed $1000 per person. Economic benefits always exceed costs with benefit-to-cost ratios ranging from approximately 3.9 to 133. Restricting interventions to homes of the elderly further increases the mortality reductions per unit population and the benefit-to-cost ratios.

Published

2016

10. Indoor environmental quality benefits of apartment energy retrofits

Author

Gary Adamkiewicz, Federico Noris, William J. Fisk, Marion L. Russell, Michael Spears, Toshifumi Hotchi, William W. Delp, Brett C. Singer, and Kimberly Vermeer

Subjects

Pollutant, Engineering, Environmental Engineering, Apartment, Waste management, business.industry, Geography, Planning and Development, Environmental engineering, Humidity, Building and Construction, Attic, Energy consumption, chemistry.chemical_compound, chemistry, Carbon dioxide, Nitrogen dioxide, business, Environmental quality, Civil and Structural Engineering

Abstract

Sixteen apartments serving low-income populations in three buildings were retrofit with the goal of simultaneously reducing energy consumption and improving indoor environmental quality (IEQ). Retrofit measures varied among apartments and included, among others, envelope sealing, installation of continuous mechanical ventilation systems, upgrading bathroom fans and range hoods, attic insulation, replacement of heating and cooling systems, and adding wall-mounted particle air cleaners. IEQ parameters were measured, generally for two one-week periods before and after the retrofits. The measurements indicate an overall improvement in IEQ conditions after the retrofits. Comfort conditions, bathroom humidity, and concentrations of carbon dioxide, acetaldehyde, volatile organic compounds, and particles generally improved. Formaldehyde and nitrogen dioxide levels decreased in the building with the highest concentrations, were unchanged in a second building, and increased in a third building. IEQ parameters other than particles improved more in apartments with continuous mechanical ventilation systems installed. In general, but not consistently, larger percent increases in air exchange rates were associated with larger percent decreases in indoor levels of the pollutants that primarily come from indoor sources.

Published

2013

11. Protocol for maximizing energy savings and indoor environmental quality improvements when retrofitting apartments

Author

Brett C. Singer, Federico Noris, Gary Adamkiewicz, William J. Fisk, William W. Delp, and Kimberly Vermeer

Subjects

Protocol (science), Engineering, Architectural engineering, Waste management, Apartment, business.industry, Mechanical Engineering, Building energy, Building and Construction, Retrofitting, Electrical and Electronic Engineering, business, Energy (signal processing), Environmental quality, Civil and Structural Engineering

Abstract

The current focus on building energy retrofit provides an opportunity to simultaneously improve indoor environmental quality (IEQ). Toward this end, we developed a protocol for selecting packages of retrofits that both save energy and improve IEQ in apartments. The protocol specifies the methodology for selecting retrofits from a candidate list while addressing expected energy savings, IEQ impacts, and costs in an integrated manner. Interviews, inspections and measurements are specified to collect the needed input information. The protocol was applied to 17 apartments in three buildings in two different climates within California. Diagnostic measurements and surveys conducted before and after retrofit implementation indicate enhanced apartment performance.

Published

2013

12. Formaldehyde Emissions from Ventilation Filters Under Different Relative Humidity Conditions

Author

Wenhao Chen, William J. Fisk, Robert Miller, Agatha Chang, Hugo Destaillats, Kazukiyo Kumagai, Sebastian Cohn, Meera Sidheswaran, and Douglas P. Sullivan

Subjects

Waste management, business.industry, Formaldehyde, Humidity, General Chemistry, Ventilation, law.invention, chemistry.chemical_compound, chemistry, Air conditioning, law, Ventilation (architecture), HVAC, Environmental Chemistry, Environmental science, Relative humidity, business, Filtration

Abstract

Formaldehyde emissions from fiberglass and polyester filters used in building heating, ventilation, and air conditioning (HVAC) systems were measured in bench-scale tests using 10 and 17 cm(2) coupons over 24 to 720 h periods. Experiments were performed at room temperature and four different relative humidity settings (20, 50, 65, and 80% RH). Two different air flow velocities across the filters were explored: 0.013 and 0.5 m/s. Fiberglass filters emitted between 20 and 1000 times more formaldehyde than polyester filters under similar RH and airflow conditions. Emissions increased markedly with increasing humidity, up to 10 mg/h-m(2) at 80% RH. Formaldehyde emissions from fiberglass filters coated with tackifiers (impaction oils) were lower than those from uncoated fiberglass media, suggesting that hydrolysis of other polymeric constituents of the filter matrix, such as adhesives or binders was likely the main formaldehyde source. These laboratory results were further validated by performing a small field study in an unoccupied office. At 80% RH, indoor formaldehyde concentrations increased by 48-64%, from 9-12 μg/m(3) to 12-20 μg/m(3), when synthetic filters were replaced with fiberglass filtration media in the HVAC units. Better understanding of the reaction mechanisms and assessing their overall contributions to indoor formaldehyde levels will allow for efficient control of this pollution source.

Published

2013

13. Health benefits of particle filtration

Author

William J. Fisk

Subjects

Breathing zone, Environmental Engineering, business.industry, Public Health, Environmental and Occupational Health, Environmental engineering, air cleaning, allergy, asthma, filtration, particle, health, Building and Construction, Health benefits, Air cleaning, Health outcomes, medicine.disease, Intervention studies, Asthma, law.invention, law, Air Pollution, Indoor, Environmental health, Earth Sciences, medicine, Humans, Particulate Matter, business, Filtration

Abstract

The evidence of health benefits of particle filtration in homes and commercial buildings is reviewed. Prior reviews of papers published before 2000 are summarized. The results of 16 more recent intervention studies are compiled and analyzed. Also reviewed are four studies that modeled health benefits of using filtration to reduce indoor exposures to particles from outdoors. Prior reviews generally concluded that particle filtration is, at best, a source of small improvements in allergy and asthma health effects; however, many early studies had weak designs. A majority of recent intervention studies employed strong designs and more of these studies report statistically significant improvements in health symptoms or objective health outcomes, particularly for subjects with allergies or asthma. The percentage improvement in health outcomes is typically modest, e.g., 7percent to 25percent. Delivery of filtered air to the breathing zone of sleeping allergic or asthmatic persons may be more consistently effective in improving health than room air filtration. Notable are two studies that report statistically significant improvements, with filtration, in markers that predict future adverse coronary events. From modeling, the largest potential benefits of indoor particle filtration may be reductions in morbidity and mortality from reducing indoor exposures to particles from outdoor air.

Published

2013

14. Is CO 2 an Indoor Pollutant? Direct Effects of Low-to-Moderate CO 2 Concentrations on Human Decision-Making Performance

Author

Douglas P. Sullivan, Mark J. Mendell, Usha Satish, William J. Fisk, Siegfried Streufert, Toshifumi Hotchi, and Krishnamurthy Shekhar

Subjects

cognition, Pollutant, human performance, indoor environmental quality, business.industry, Research, ventilation, Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, Air pollution, carbon dioxide, Environmental exposure, medicine.disease_cause, decision making, law.invention, law, Environmental health, Ventilation (architecture), Respiration, medicine, Raw score, Analysis of variance, business, Air quality index

Abstract

Background: Associations of higher indoor carbon dioxide (CO2) concentrations with impaired work performance, increased health symptoms, and poorer perceived air quality have been attributed to correlation of indoor CO2 with concentrations of other indoor air pollutants that are also influenced by rates of outdoor-air ventilation. Objectives: We assessed direct effects of increased CO2, within the range of indoor concentrations, on decision making. Methods: Twenty-two participants were exposed to CO2 at 600, 1,000, and 2,500 ppm in an office-like chamber, in six groups. Each group was exposed to these conditions in three 2.5-hr sessions, all on 1 day, with exposure order balanced across groups. At 600 ppm, CO2 came from outdoor air and participants’ respiration. Higher concentrations were achieved by injecting ultrapure CO2. Ventilation rate and temperature were constant. Under each condition, participants completed a computer-based test of decision-making performance as well as questionnaires on health symptoms and perceived air quality. Participants and the person administering the decision-making test were blinded to CO2 level. Data were analyzed with analysis of variance models. Results: Relative to 600 ppm, at 1,000 ppm CO2, moderate and statistically significant decrements occurred in six of nine scales of decision-making performance. At 2,500 ppm, large and statistically significant reductions occurred in seven scales of decision-making performance (raw score ratios, 0.06–0.56), but performance on the focused activity scale increased. Conclusions: Direct adverse effects of CO2 on human performance may be economically important and may limit energy-saving reductions in outdoor air ventilation per person in buildings. Confirmation of these findings is needed.

Published

2012

15. Significance of the School Physical Environment - A Commentary

Author

Lloyd J. Kolbe, Claire L. Barnett, Jerome A. Paulson, and William J. Fisk

Subjects

Injury control, Accident prevention, Poison control, Environment, 010501 environmental sciences, 01 natural sciences, Suicide prevention, Occupational safety and health, Education, 03 medical and health sciences, 0302 clinical medicine, Injury prevention, Humans, Medicine, 030212 general & internal medicine, 0105 earth and related environmental sciences, Schools, business.industry, Public Health, Environmental and Occupational Health, Human factors and ergonomics, medicine.disease, Philosophy, Public Health and Health Services, Public Health, Medical emergency, business, Curriculum and Pedagogy

Published

2016

16. Ventilation, temperature, and HVAC characteristics in small and medium commercial buildings in California

Author

David Faulkner, William J. Fisk, Amber Trout, Xiangmei Wu, Michael G. Apte, D. P. Sullivan, and Deborah H. Bennett

Subjects

Engineering, Architectural engineering, Environmental Engineering, business.industry, Public Health, Environmental and Occupational Health, Thermal comfort, Energy recovery ventilation, Building and Construction, Minimum efficiency reporting value, law.invention, Dental Offices, law, HVAC, Ventilation (architecture), ASHRAE 90.1, Doors, business

Abstract

This field study of 37 small and medium commercial buildings throughout California obtained information on ventilation rate, temperature, and heating, ventilating, and air-conditioning (HVAC) system characteristics. The study included seven retail establishments; five restaurants; eight offices; two each of gas stations, hair salons, healthcare facilities, grocery stores, dental offices, and fitness centers; and five other buildings. Fourteen (38%) of the buildings either could not or did not provide outdoor air through the HVAC system. The air exchange rate averaged 1.6 (s.d. = 1.7) exchanges per hour and was similar between buildings with and without outdoor air supplied through the HVAC system, indicating that some buildings have significant leakage or ventilation through open windows and doors. Not all buildings had sufficient air exchange to meet ASHRAE 62.1 Standards, including buildings used for fitness centers, hair salons, offices, and retail establishments. The majority of the time, buildings were within the ASHRAE temperature comfort range. Offices were frequently overcooled in the summer. All of the buildings had filters, but over half the buildings had a filter with a minimum efficiency reporting value rating of 4 or lower, which are not very effective for removing fine particles. Practical Implications Most U.S. commercial buildings (96%) are small- to medium-sized, using nearly 18% of the country’s energy, and sheltering a large population daily. Little is known about the ventilation systems in these buildings. This study found a wide variety of ventilation conditions, with many buildings failing to meet relevant ventilation standards. Regulators may want to consider implementing more complete building inspections at commissioning and point of sale.

Published

2012

17. Changing ventilation rates in U.S. offices: Implications for health, work performance, energy, and associated economics

Author

G. Brunner, William J. Fisk, and Douglas Black

Subjects

Consumption (economics), Engineering, Environmental Engineering, Cost–benefit analysis, business.industry, Geography, Planning and Development, Environmental engineering, Building and Construction, Energy consumption, Agricultural economics, Energy accounting, law.invention, Work performance, Sick building syndrome, law, Ventilation (architecture), business, Civil and Structural Engineering, Health work

Abstract

This paper provides quantitative estimates of benefits and costs of providing different amounts of outdoor air ventilation in U.S. offices. For four scenarios that modify ventilation rates, we estimated changes in sick building syndrome (SBS) symptoms, work performance, short-term absence, and building energy consumption. The estimated annual economic benefits were $13 billion from increasing minimum ventilation rates (VRs) from 8 to 10 L/s per person, $38 billion from increasing minimum VRs from 8 to 15 L/s per person, and $33 billion from increasing VRs by adding outdoor air economizers for the 50% of the office floor area that currently lacks economizers. The estimated $0.04 billion in annual energy-related benefits of decreasing minimum VRs from 8 to 6.5 L/s per person are very small compared to the projected annual costs of $12 billion. Benefits of increasing minimum VRs far exceeded energy costs while adding economizers yielded health, performance, and absence benefits with energy savings.

Published

2012

18. Energy efficient indoor VOC air cleaning with activated carbon fiber (ACF) filters

Author

Meera Sidheswaran, Douglas P. Sullivan, Hugo Destaillats, Sebastian Cohn, and William J. Fisk

Subjects

Pollutant, Environmental Engineering, business.industry, Geography, Planning and Development, Environmental engineering, Formaldehyde, Building and Construction, Pulp and paper industry, law.invention, chemistry.chemical_compound, Adsorption, chemistry, law, HVAC, Ventilation (architecture), medicine, Environmental science, Freundlich equation, Relative humidity, business, Civil and Structural Engineering, Activated carbon, medicine.drug

Abstract

This study explores the potential environmental and energy benefits of using activated carbon fiber (ACF) filters for air cleaning in HVAC systems. The parallel aims for the air cleaning system were to enable reduced indoor exposures to volatile organic compounds (VOCs) and to simultaneously allow reduced rates and energy consumption for outdoor air ventilation. We evaluated the use of ACF media to adsorb VOCs from indoor air during repeated simulated 12-h to 24-h periods of occupancy. In a cyclic regeneration process, VOCs were desorbed from the ACF media and vented outdoors to enable the next cycle of air cleaning. The VOC removal efficiency of the ACF media was measured using a 9.5-cm 2 ACF specimen exposed to a mixture of VOCs that included toluene, benzene, o-xylene, 1-butanol, limonene, undecane and formaldehyde at 29 °C and 30% relative humidity. The concentrations of these model pollutants upstream of the ACF media were in the range 20–30 ppb, to simulate realistic conditions. Velocities through the ACF media were typical of those in normal particle filter systems (∼0.5 m s −1 ). Initial tests were conducted to develop a modified multi-component Freundlich isotherm and estimate the maximum adsorption capacity of the media, which was determined to be 90 mg VOC per gram of ACF. Three different ACF regeneration methods were explored using relatively cleaner outdoor air under ambient conditions, with this air humidified, and with the filter heated. It was found that heating the ACF media to ∼150 °C by circulation of a DC current through the fibers for a short period (15 min) yielded the best VOC removal results, allowing for subsequent consistent removal efficiencies of 70–80% for most VOCs. Regeneration with unheated outdoor air was also effective and used less energy (subsequent removal efficiency was 50–60% for most VOCs). ACF did not perform as well in eliminating formaldehyde, for which a maximum removal of 25–30% was achieved with heated regeneration. A mass balance model indicated that the combination of ACF air cleaning and a 50% reduction in ventilation will decrease indoor concentrations of VOCs by 60%–80% and reduce formaldehyde concentrations by 12%–40%. Energy modeling indicated the potential to reduce the energy required for heating and cooling of ventilation air by 35% to almost 50%.

Published

2012

19. Ventilation rates and health: multidisciplinary review of the scientific literature

Author

S. T. Taylor, William W. Nazaroff, William J. Fisk, Jan Sundell, Andrew K. Persily, John D. Spengler, Hal Levin, David T. Grimsrud, Finn Gyntelberg, Yuguo Li, A. Pickering, Charles J. Weschler, Jonathan M. Samet, and William S. Cain

Subjects

Environmental Engineering, Air changes per hour, business.industry, Public Health, Environmental and Occupational Health, MEDLINE, Building and Construction, law.invention, Sick building syndrome, Indoor air quality, Multidisciplinary approach, law, Environmental health, Sick leave, Ventilation (architecture), Medicine, Biological plausibility, business

Abstract

The scientific literature through 2005 on the effects of ventilation rates on health in indoor environments has been reviewed by a multidisciplinary group. The group judged 27 papers published in peer-reviewed scientific journals as providing sufficient information on both ventilation rates and health effects to inform the relationship. Consistency was found across multiple investigations and different epidemiologic designs for different populations. Multiple health endpoints show similar relationships with ventilation rate. There is biological plausibility for an association of health outcomes with ventilation rates, although the literature does not provide clear evidence on particular agent(s) for the effects. Higher ventilation rates in offices, up to about 25 l/s per person, are associated with reduced prevalence of sick building syndrome (SBS) symptoms. The limited available data suggest that inflammation, respiratory infections, asthma symptoms and short-term sick leave increase with lower ventilation rates. Home ventilation rates above 0.5 air changes per hour (h−1) have been associated with a reduced risk of allergic manifestations among children in a Nordic climate. The need remains for more studies of the relationship between ventilation rates and health, especially in diverse climates, in locations with polluted outdoor air and in buildings other than offices. Practical Implications Ventilation with outdoor air plays an important role influencing human exposures to indoor pollutants. This review and assessment indicates that increasing ventilation rates above currently adopted standards and guidelines should result in reduced prevalence of negative health outcomes. Building operators and designers should avoid low ventilation rates unless alternative effective measures, such as source control or air cleaning, are employed to limit indoor pollutant levels.

Published

2011

20. Assessment of energy savings potential from the use of demand controlled ventilation in general office spaces in California

Author

William J. Fisk and Tianzhen Hong

Subjects

Climate zones, Engineering, Occupancy, business.industry, Building energy, Building and Construction, Civil engineering, Energy accounting, law.invention, Life-cycle cost analysis, Demand controlled ventilation, law, Statistics, Ventilation (architecture), business, Energy (signal processing), Energy (miscellaneous)

Abstract

A prototypical office building meeting the prescriptive requirements of the 2008 California Building Energy Efficiency Standards (Title 24) was used in EnergyPlus simulations to calculate the energy savings potential of demand controlled ventilation (DCV) in five typical California climates per three design occupancy densities and two minimum ventilation rates. The assumed minimum ventilation rates in offices without DCV, based on two different measurement methods employed in a large survey, were 38 and 13 L/s per occupant. The results of the life cycle cost analysis show DCV is cost effective for office spaces if the typical minimum ventilation rate without DCV is 38 L/s per person, except at the low design occupancy of 10.8 people per 100 m2 in climate zones 3 (north coast) and 6 (south coast). DCV was not found to be cost effective if the typical minimum ventilation rate without DCV is 13 L/s per occupant, except at high design occupancy of 21.5 people per 100 m2 in climate zones 14 (desert) and 16 (mountains). Until the large uncertainties about the base case ventilation rates in offices without DCV are reduced, the case for requiring DCV in general office spaces will be a weak case. Under the Title 24 standard office occupant density of 10.8 people per 100 m2, DCV becomes cost effective when the base case minimum ventilation rate is greater than 42.5, 43.0, 24.0, 19.0, and 18.0 L/s per person for climate zones 3, 6, 12, 14, and 16, respectively.

Published

2010

21. Airflow Simulations around OA Intake Louver with Electronic Velocity Sensors

Author

Douglas P. Sullivan, Hwataik Han, and William J. Fisk

Subjects

Cultural Studies, Pressure drop, Engineering, business.industry, Acoustics, System of measurement, Airflow, Fluid mechanics, Building and Construction, Computational fluid dynamics, law.invention, Arts and Humanities (miscellaneous), law, Architecture, HVAC, Ventilation (architecture), Louver, business, Simulation, Civil and Structural Engineering

Abstract

It is important to control outdoor airflow rates into HVAC systems in terms of energy conservation and healthy indoor environment. Technologies are being developed to measure outdoor air (OA) flow rates through OA intake louvers on a real time basis. The purpose of this paper is to investigate the airflow characteristics through an OA intake louver numerically in order to provide suggestions for sensor installations. Airflow patterns are simulated with and without electronic air velocity sensors within cylindrical probes installed between louver blades or at the downstream face of the louver. Numerical results show quite good agreements with experimental data, and provide insights regarding measurement system design. The simulations indicate that velocity profiles are more spatially uniform at the louver outlet relative to between louver blades, that pressure drops imposed by the sensor bars are smaller with sensor bars at the louver outlet, and that placement of the sensor bars between louver blades substantially increases air velocities inside the louver. These findings suggest there is an advantage to placing the sensor bars at the louver outlet face.

Published

2010

22. Quantitative relationship of sick building syndrome symptoms with ventilation rates

Author

Anna G. Mirer, Mark J. Mendell, and William J. Fisk

Subjects

Pediatrics, medicine.medical_specialty, Sick Building Syndrome, Environmental Engineering, business.industry, Public Health, Environmental and Occupational Health, Air Pollutants, Occupational, Building and Construction, Models, Theoretical, Ventilation, Office workers, law.invention, Sick building syndrome, Air pollutants, law, Air Pollution, Indoor, Linear regression, Ventilation (architecture), Linear Models, Prevalence, medicine, Humans, business, Symptom prevalence, Demography

Abstract

Data from published studies were combined and analyzed to develop best-fit equations and curves quantifying the change in sick building syndrome (SBS) symptom prevalence in office workers with ventilation rate. For each study, slopes were calculated, representing the fractional change in SBS symptom prevalence per unit change in ventilation rate per person. Values of ventilation rate, associated with each value of slope, were also calculated. Linear regression equations were fitted to the resulting data points, after weighting by study size. Integration of the slope-ventilation rate equations yielded curves of relative SBS symptom prevalence vs. ventilation rate. Based on these analyses, as the ventilation rate drops from 10 to 5 l/s-person, relative SBS symptom prevalence increases approximately 23% (12% to 32%), and as ventilation rate increases from 10 to 25 l/s-person, relative prevalence decreases approximately 29% (15% to 42%). Variations in SBS symptom types, building features, and outdoor air quality may cause the relationship of SBS symptom prevalence with ventilation rate in specific situations to differ from the average relationship predicted in this paper.On average, providing more outdoor air ventilation will reduce prevalence rates of sick building syndrome (SBS) symptoms. However, given the costs of energy use, including increased risks of climate change, it is important to balance the benefits and risks of increased ventilation. This paper provides initial estimates of how the incremental health benefits per unit of increased ventilation diminish at higher levels of ventilation.

Published

2009

23. Public health and economic impact of dampness and mold

Author

David Mudarri and William J. Fisk

Subjects

medicine.medical_specialty, Environmental Engineering, Respiratory Tract Diseases, Individual risk, Risk Assessment, Environmental Energy Technologies, Environmental health, Humans, Medicine, Economic impact analysis, Workplace, Asthma, Air Pollutants, Schools, business.industry, Public health, Fungi, technology, industry, and agriculture, Public Health, Environmental and Occupational Health, Humidity, Environmental Exposure, Building and Construction, medicine.disease, United States, Air Pollution, Indoor, Attributable risk, Public Health, Risk assessment, business

Abstract

The public health risk and economic impact of dampness and mold exposures was assessed using current asthma as a health endpoint. Individual risk of current asthma from exposure to dampness and mold in homes from W.J. Fisk, Q. Lei-GomezM.J. Mendell [(2007) Indoor Air, [corrected] 17, 284-296], and [corrected] asthma risks calculated from additional studies that reported the prevalence of dampness and mold in homes were used to estimate the proportion of US current asthma cases that are attributable to dampness and mold exposure at 21% (95% confidence internal 12-29%). An examination of the literature covering dampness and mold in schools, offices, and institutional buildings, which is summarized in the Appendix, suggests that risks from exposure in these buildings are similar to risks from exposures in homes. Of the 21.8 million people reported to have asthma in the USA, approximately 4.6 (2.7-6.3) million cases are estimated to be attributable to dampness and mold exposure in the home. Estimates of the national cost of asthma from two prior studies were updated to 2004 and used to estimate the economic impact of dampness and mold exposures. By applying the attributable fraction to the updated national annual cost of asthma, the national annual cost of asthma that is attributable to dampness and mold exposure in the home is estimated to be $3.5 billion ($2.1-4.8 billion). Analysis indicates that exposure to dampness and mold in buildings poses significant public health and economic risks in the USA. These findings are compatible with public policies and programs that help control moisture and mold in buildings.There is a need to control moisture in both new and existing construction because of the significant health consequences that can result from dampness and mold. This paper demonstrates that dampness and mold in buildings is a significant public health problem with substantial economic impact.

Published

2007

24. A longitudinal study of ventilation rates in California office buildings and self-reported occupant outcomes including respiratory illness absence

Author

Mark J. Mendell, Douglas P. Sullivan, Ekaterina A. Eliseeva, William J. Fisk, Wanyu R. Chan, Michael Spears, and Sebastian Cohn

Subjects

Multivariate statistics, Longitudinal study, Environmental Engineering, Environmental Science and Management, Geography, Planning and Development, Health outcomes, law.invention, Illness absence, Indoor air quality, law, Clinical Research, parasitic diseases, Architecture, Forensic engineering, Medicine, Building, Limited evidence, Lung, Civil and Structural Engineering, Building & Construction, Respiratory illness, business.industry, Building and Construction, Ventilation rate, Sample size determination, Ventilation (architecture), business, Demography

Abstract

© 2015 Elsevier Ltd. Background: Limited evidence has associated lower ventilation rates (VRs) in offices with higher illness-related absence rates. Methods: We studied spaces in office buildings, selected without knowledge of their VRs, in three California climate zones. In each study space, real-time logging sensors measured carbon dioxide and thermal parameters for one year. Web-based surveys every three months collected data on occupants' health outcomes. Using multivariate models, relationships were assessed between CO2 concentrations, or VRs estimated from CO2, and adverse occupant outcomes including respiratory infections and illness absences. For all outcomes, positive associations were hypothesized with higher CO2 levels (and negative associations with higher VRs). Results: Low survey response limited sample size and study power. In the 16 study spaces, CO2 concentrations were uniformly low over the year, and most estimated VRs ranged from twice to nine times the California office minimum VR standard (7L/s or 15 cfm per person). Primary CO2 and VR metrics had no statistically significant relationships with occupant outcomes. Conclusions: Within the observed range of uniformly low CO2 and high VRs (mostly 16-42L/s per person), little variation in contaminant concentrations would be expected, which would explain lack of relationships with occupant outcomes. These high VRs resulted partly from frequently used energy-saving "economizer" cycles in moderate California climates, but VRs at other times also substantially exceeded required VRs. These findings suggest, consistent with theory, that within a higher VR range, increased VRs do not reduce respiratory illness. Further studies are needed to better characterize such relationships.

Published

2015

25. Review of Some Effects of Climate Change on Indoor Environmental Quality and Health and Associated No-Regrets Mitigation Measures

Author

William J. Fisk

Subjects

Environmental Engineering, Mitigation, business.industry, Indoor environmental quality, Geography, Planning and Development, Environmental engineering, Climate change, Overheating (economics), Building and Construction, Indoor air quality, Effects of global warming, Air conditioning, Health, Greenhouse gas, Environmental health, Environmental science, Building, business, Roof, Environmental quality, Civil and Structural Engineering

Abstract

This paper reviews the potential health consequences of changes in climate that affect indoor environments, with an emphasis on residential environments in the U.S. and Europe. These changes in climate, include increases in the frequency and severity of heat waves, severe storms coupled with sea level rise, and wildfires, plus increases in urban airborne ozone. The potential for adverse health effects is substantial. Examples of projected effects include a doubling of heat-related deaths, increased hospitalizations for asthma, pneumonia, and cardiovascular effects during wildfires, and increased mortality and hospitalizations associated with ozone. The associated adverse exposures occur, to a significant extent, indoors. The adverse health effects will be substantially mediated by features of buildings, particularly of homes where people, particularly those most susceptible, spend the largest amount of time. Changes to buildings, or to building operations, are identified that could reduce the projected adverse health effects of climate change. Examples include improved roof insulation, roof coatings that reflect more solar energy, and more air conditioning to reduce indoor overheating. Improved particle filtration systems could reduce the health effects of particles from wildfires. Some of these measures will also reduce building energy use and the associated emissions of greenhouse gases. Most of these measures would improve health irrespective of climate change. Improvements in building energy efficiency in order to mitigate climate change, has to potential to either improve or worsen indoor environmental quality and health.

Published

2015

26. Energy and IAQ Implications of Alternative Minimum Ventilation Rates in California Retail and School Buildings

Author

Spencer Dutton and William J. Fisk

Subjects

Consumption (economics), Engineering, business.industry, Environmental engineering, Building energy, law.invention, Energy conservation, Indoor air quality, law, Ventilation (architecture), HVAC, business, Building energy simulation, Energy (signal processing)

Abstract

For a stand-alone retail building, a primary school, and a secondary school in each of the 16 California climate zones, the EnergyPlus building energy simulation model was used to estimate how minimum mechanical ventilation rates (VRs) affect energy use and indoor air concentrations of an indoor-generated contaminant. The modeling indicates large changes in heating energy use, but only moderate changes in total building energy use, as minimum VRs in the retail building are changed. For example, predicted state-wide heating energy consumption in the retail building decreases by more than 50% and total building energy consumption decreases by approximately 10% as the minimum VR decreases from the Title 24 requirement to no mechanical ventilation. The primary and secondary schools have notably higher internal heat gains than in the retail building models, resulting in significantly reduced demand for heating. The school heating energy use was correspondingly less sensitive to changes in the minimum VR. The modeling indicates that minimum VRs influence HVAC energy and total energy use in schools by only a few percent. For both the retail building and the school buildings, minimum VRs substantially affected the predicted annual-average indoor concentrations of an indoor generated contaminant, with larger effects in schools.more » The shape of the curves relating contaminant concentrations with VRs illustrate the importance of avoiding particularly low VRs.« less

Published

2015

27. Prototype Systems for Measuring Outdoor Air Intake Rates in Rooftop Air Handlers

Author

Wanyu R. Chan, Toshifumi Hotchi, and William J. Fisk

Subjects

Engineering, business.industry, business, Simulation, Automotive engineering

Published

2015

28. Performance of Underfloor Air Distribution in a Field Setting

Author

Man Pun Wan, Christopher Y.H. Chao, Douglas P. Sullivan, William J. Fisk, L. Zagreus, Tom Webster, and David Faulkner

Subjects

Pollutant, Engineering, business.industry, Environmental engineering, Building and Construction, Thermal stratification, Satisfaction rating, Energy requirement, Indoor air quality, Control and Systems Engineering, Thermal, Electrical and Electronic Engineering, business, Air quality index, Underfloor air distribution, Civil and Structural Engineering

Abstract

Underfloor air distribution (UFAD) is a new method of supplying heated or cooled air throughout a building. Reported advantages of UFAD include energy savings and improved indoor air quality (IAQ). We measured several aspects of the performance of an UFAD system installed in a medium-size office building. The measured air change effectiveness was very close to unity, which is comparable to that measured in buildings with typical overhead air distribution. The pollutant removal efficiency for carbon dioxide was 13% higher than expected in a space with well-mixed air, suggesting a 13% reduction in exposures to occupant generated pollutants. The increase in indoor air temperatures with height above the floor was only 1 to 2 C. This amount of thermal stratification could reduce the sensible energy requirements for cooling of outdoor air by approximately 10%. The occupant's level of satisfaction with thermal conditions was well above average and this high satisfaction rating could possibly be due, in all or part, to the use of a UFAD system. The results of this study provide some evidence of moderate energy and IAQ-related benefits of UFAD. Before general conclusions are drawn, the benefits need to be confirmed in other studies.

Published

2006

29. Some Quantitative Relations between Indoor Environmental Quality and Work Performance or Health

Author

Olli Seppänen and William J. Fisk

Subjects

Environmental engineering, Building and Construction, Environmental economics, Building design, Work performance, law.invention, Sick building syndrome, law, Ventilation (architecture), Sick leave, Business, Space conditioning, Productivity, Environmental quality

Abstract

Poor indoor environmental quality (IEQ) has been related to increases in sick building syndrome (SBS) symptoms, respiratory illnesses, sick leave, and loss in productivity. Calculations indicate that the cost of poor IEQ can be higher than energy costs FOR space conditioning and ventilation and that many measures taken to improve indoor IEQ will be highly cost-effective when accounting for the monetary savings resulting from improved health or productivity. To enable building professionals to select of building designs and operating practices that account for effects on health and productivity, we need models for quantifying the health and productivity benefits of better indoor environments. Therefore, we have reviewed the literature on the effects of indoor environment on health and performance and used existing data, when possible, to develop some initial models. Based on the best available evidence, we present quantitative relationships between ventilation rates and short-term sick leave, ventilation r...

Published

2006

30. Associations between classroom CO2 concentrations and student attendance in Washington and Idaho

Author

R.J. Prill, Michael G. Apte, William J. Fisk, David Faulkner, David Blake, and Derek G. Shendell

Subjects

Male, Washington, Architectural engineering, Engineering, Environmental Engineering, Idaho, medicine.medical_treatment, education, Psychological intervention, Environmental Energy Technologies, law.invention, law, Environmental health, Absenteeism, HVAC, medicine, Humans, Child, Students, Socioeconomic status, Mechanical ventilation, Air Pollutants, Analysis of Variance, Schools, business.industry, Public Health, Environmental and Occupational Health, Attendance, Thermal comfort, Building and Construction, Carbon Dioxide, Ventilation, Air Pollution, Indoor, Child, Preschool, Ventilation (architecture), Female, business

Abstract

UNLABELLED Student attendance in American public schools is a critical factor in securing limited operational funding. Student and teacher attendance influence academic performance. Limited data exist on indoor air and environmental quality (IEQ) in schools, and how IEQ affects attendance, health, or performance. This study explored the association of student absence with measures of indoor minus outdoor carbon dioxide concentration (dCO(2)). Absence and dCO(2) data were collected from 409 traditional and 25 portable classrooms from 22 schools located in six school districts in the states of Washington and Idaho. Study classrooms had individual heating, ventilation, and air conditioning (HVAC) systems, except two classrooms without mechanical ventilation. Classroom attributes, student attendance and school-level ethnicity, gender, and socioeconomic status (SES) were included in multivariate modeling. Forty-five percent of classrooms studied had short-term indoor CO(2) concentrations above 1000 p.p.m. A 1000 p.p.m. increase in dCO(2) was associated (P < 0.05) with a 0.5-0.9% decrease in annual average daily attendance (ADA), corresponding to a relative 10-20% increase in student absence. Annual ADA was 2% higher (P < 0.0001) in traditional than in portable classrooms. PRACTICAL IMPLICATIONS This study provides motivation for larger school studies to investigate associations of student attendance, and occupant health and student performance, with longer term indoor minus outdoor CO(2) concentrations and more accurately measured ventilation rates. If our findings are confirmed, improving classroom ventilation should be considered a practical means of reducing student absence. Adequate or enhanced ventilation may be achieved, for example, with educational training programs for teachers and facilities staff on ventilation system operation and maintenance. Also, technological interventions such as improved automated control systems could provide continuous ventilation during occupied times, regardless of occupant thermal comfort demands.

Published

2004

31. Summary of human responses to ventilation

Author

Olli Seppänen and William J. Fisk

Subjects

Sick Building Syndrome, Environmental Engineering, Climate, Air pollution, Infections, medicine.disease_cause, law.invention, Indoor air quality, law, Task Performance and Analysis, medicine, Humans, Air Conditioning, Air quality index, Pollutant, Waste management, business.industry, Public Health, Environmental and Occupational Health, Environmental engineering, Hygiene, Building and Construction, Infiltration (HVAC), Ventilation, Air conditioning, Air Pollution, Indoor, Ventilation (architecture), Environmental science, Perception, Ergonomics, business, Environmental Health, Building envelope

Abstract

It is known that ventilation is necessary to remove indoor-generated pollutants from indoor air or dilute their concentration to acceptable levels. But as the limit values of all pollutants are not known the exact determination of required ventilation rates based on pollutant concentrations is seldom possible. The selection of ventilation rates has to be based also on epidemiological research, laboratory and field experiments and experience. The existing literature indicates that ventilation has a significant impact on several important human outcomes including: (1) communicable respiratory illnesses; (2) sick building syndrome symptoms; (3) task performance and productivity, and (4) perceived air quality (PAQ) among occupants or sensory panels (5) respiratory allergies and asthma. In many studies, prevalence of sick building syndrome symptoms has also been associated with characteristics of HVAC-systems. Often the prevalence of SBS symptoms is higher in air-conditioned buildings than in naturally ventilated buildings. The evidence suggests that better hygiene, commissioning, operation and maintenance of air handling systems may be particularly important for reducing the negative effects of HVAC systems. Ventilation may also have harmful effects on indoor air quality and climate if not properly designed, installed, maintained and operated. Ventilation may bring indoors harmful substances or deteriorate indoor environment. Ventilation interacts also with the building envelope and may deteriorate the structures of the building. Ventilation changes the pressure differences across the structures of building and may cause or prevent infiltration of pollutants from structures or adjacent spaces. Ventilation is also in many cases used to control the thermal environment or humidity in buildings. The paper summarises the current knowledge on positive and negative effects of ventilation on health and other human responses. The focus is on office-type working environment and residential buildings.The review shows that ventilation has various positive impacts on health and productivity of building occupants. Ventilation reduces the prevalence of airborne infectious diseases and thus the number of sick leave days. In office environment a ventilation rate up to 20-25 L/s per person seem to decrease the prevalence of SBS-symptoms. Air conditioning systems may increase the prevalence of SBS-symptoms relative to natural ventilation if not clean. In residential buildings the air change rate in cold climates should not be below app. 0.5 ach. Ventilation systems may cause pressure differences over the building envelope and bring harmful pollutants indoors.

Published

2004

32. Association of ventilation system type with SBS symptoms in office workers

Author

William J. Fisk and Olli Seppänen

Subjects

Mechanical ventilation, Architectural engineering, Environmental Engineering, business.industry, medicine.medical_treatment, Public Health, Environmental and Occupational Health, Natural ventilation, Building and Construction, Office workers, law.invention, Sick building syndrome, Air conditioning, law, Environmental health, Ventilation (architecture), HVAC, medicine, Environmental science, Association (psychology), business

Abstract

Submitted to Indoor Air. Association of Ventilation System Type with SBS symptoms in Office Workers Olli Seppanen 1 and William J. Fisk 2, Helsinki University of Technology Laboratory of Heating, Ventilating and Air Conditioning Helsinki, Finland Lawrence Berkeley National Laboratory Indoor Environment Department Berkeley, CA USA February 6, 2001 Communications should be addressed to Olli Seppanen Abstract This paper provides a review and synthesis of current knowledge about the associations of ventilation system types in office buildings with sick building syndrome symptoms and discusses potential explanations for the associations. Relative to natural ventilation, air conditioning, with or without humidification, was consistently associated with a statistically significant increase in the prevalence of one or more SBS symptoms. Prevalences were typically higher by approximately 30% to 200% in the air conditioned buildings. In two of three assessments from a single study, symptom prevalences were also significantly higher in air conditioned buildings than in buildings with simple mechanical ventilation and no humidification. In approximately half of assessments, SBS symptom prevalences were significantly higher in buildings with simple mechanical ventilation than in buildings with natural ventilation. Insufficient information was available for conclusions about the potential increased risk of SBS symptoms with humidification. The statistically significant associations of mechanical ventilation and air conditioning with SBS symptoms are much more frequent than expected from chance and also not likely to be a consequence of confounding by several potential personal, job, or building- related confounders. The reasons for the increases in symptom prevalences with mechanical ventilation and particularly with air conditioning remain unclear. Multiple deficiencies in HVAC system design, construction, operation, or maintenance, including some which cause pollutant emissions from HVAC systems, may contribute to the increases in symptom prevalences. Practical Implications Because the causes of increases in SBS symptom prevalences in mechanically ventilated buildings are uncertain, the implications for building professionals are also uncertain. The available evidence suggests, but does not prove, that multiple preventative and corrective measures are needed to substantially reduce the SBS symptoms associated with HVAC systems. Commissioning, operational checks, training of operators, and maintenance may be particularly important for reducing the risks of health effects associated with HVAC systems.

Published

2002

33. Performance of thermal distribution systems in large commercial buildings

Author

Tengfang T. Xu, Duo Wang, Jennifer A. McWilliams, Francois Remy Carrie, William J. Fisk, Mark P. Modera, and Darryl Dickerhoff

Subjects

Engineering, business.industry, Mechanical Engineering, Airflow, Electrical engineering, Variable air volume, Building and Construction, Mechanics, Thermal conduction, Thermal, ASHRAE 90.1, Duct (flow), Constant air volume, Electrical and Electronic Engineering, business, Civil and Structural Engineering, Leakage (electronics)

Abstract

This paper presents major findings of a field study on the performance of five thermal distribution systems in four large commercial buildings. The five systems studied are typical single-duct or dual-duct constant air volume (CAV) systems and variable air volume (VAV) systems, each of which serves an office building or a retail building with floor area over 2000 m 2 . The air leakage from ducts is reported in terms of effective leakage area (ELA) at 25 Pa reference pressure, the ASHRAE-defined duct leakage class C L , and air leakage ratios. The specific ELAs ranged from 0.7 to 12.9 cm 2 /m 2 of duct surface area, and from 0.1 to 7.7 cm 2 /m 2 of floor area served. The ASHRAE-defined duct leakage classes ranged from 34 to 606 for the five systems and systems sections tested. The air leakage ratios were estimated to be up to approximately one-third of the fan-supplied airflow in the constant air volume systems. The specific ELAs and leakage classes indicated that air leakage in large commercial duct systems varied significantly from system to system, and from system section to system section even within the same thermal distribution system. Overall, the duct systems measured were much leakier than the ductwork specified as “unsealed ducts” by ASHRAE. On the other hand, thermal losses from supply ducts induced by conduction (including convection and radiation) were significant, on the scale that was comparable to the losses induced by air leakage in the duct systems. The energy losses induced by leakage and conduction suggested that there exist significant energy savings potentials from duct sealing and duct insulation practice in large commercial buildings.

Published

2002

34. Developing evidence-based prescriptive ventilation rate standards for commercial buildings in California: a proposed framework

Author

Mark J. Mendell and William J. Fisk

Subjects

Sick building syndrome, Engineering, Evidence-based practice, Indoor air quality, Cost–benefit analysis, business.industry, Process (engineering), Operations management, business, Set (psychology), Outcome (game theory), Risk management

Abstract

Background - The goal of this project, with a focus on commercial buildings in California, was to develop a new framework for evidence-based minimum ventilation rate (MVR) standards that protect occupants in buildings while also considering energy use and cost. This was motivated by research findings suggesting that current prescriptive MVRs in commercial buildings do not provide occupants with fully safe and satisfactory indoor environments. Methods - The project began with a broad review in several areas ? the diverse strategies now used for standards or guidelines for MVRs or for environmental contaminant exposures, current knowledge about adverse human effects associated with VRs, and current knowledge about contaminants in commercial buildings, including their their presence, their adverse human effects, and their relationships with VRs. Based on a synthesis of the reviewed information, new principles and approaches are proposed for setting evidence-based VRsstandards for commercial buildings, considering a range of human effects including health, performance, and acceptability of air. Results ? A review and evaluation is first presented of current approaches to setting prescriptive building ventilation standards and setting acceptable limits for human contaminant exposures in outdoor air and occupational settings. Recent research on approaches to setting acceptable levels of environmental exposures in evidence-based MVR standards is also described. From a synthesis and critique of these materials, a set of principles for setting MVRs is presented, along with an example approach based on these principles. The approach combines two sequential strategies. In a first step, an acceptable threshold is set for each adverse outcome that has a demonstrated relationship to VRs, as an increase from a (low) outcome level at a high reference ventilation rate (RVR, the VR needed to attain the best achievable levels of the adverse outcome);MVRs required to meet each specific outcome threshold are estimated; and the highest of these MVRs, which would then meet all outcome thresholds, is selected as the target MVR. In a second step, implemented only if the target MVR from step 1 is judged impractically high, costs and benefits are estimated and this information is used in a risk management process. Four human outcomes with substantial quantitative evidence of relationships to VRs are identified for initial consideration in setting MVR standards. These are: building-related symptoms (sometimes called sick building syndrome symptoms), poor perceived indoor air quality, and diminished work performance, all with data relating them directly to VRs; and cancer and non-cancer chronic outcomes, related indirectly to VRs through specific VR-influenced indoor contaminants. In an application of step 1 for offices using a set of example outcome thresholds, a target MVR of 9 L/s (19 cfm) per person was needed. Because thistarget MVR was close to MVRs in current standards, use of a cost/benefit process seemed unnecessary. Selection of more stringent thresholds for one or more human outcomes, however, could raise the target MVR to 14 L/s (30 cfm) per person or higher, triggering the step 2 risk management process. Consideration of outdoor air pollutant effects would add further complexity to the framework. For balancing the objective and subjective factors involved in setting MVRs in a cost-benefit process, it is suggested that a diverse group of stakeholders make the determination after assembling as much quantitative data as possible.

Published

2014

35. Association of classroom ventilation with reduced illness absence: A prospective study in California elementary schools

Author

Michael Spears, Agnes B. Lobscheid, Molly M. Davies, Michael G. Apte, Mark J. Mendell, Ekaterina A. Eliseeva, and William J. Fisk

Subjects

Environmental Engineering, Cost-Benefit Analysis, education, California, law.invention, Illness absence, law, Environmental protection, Humans, Medicine, Prospective Studies, Limited evidence, Child, Prospective cohort study, Respiratory Tract Infections, Schools, Models, Statistical, business.industry, Indoor environmental quality, Public Health, Environmental and Occupational Health, Original Articles, Building and Construction, Economic benefits, Ventilation, Carbon dioxide, Ventilation (architecture), Original Article, business, Demography

Abstract

Author(s): Mendell, MJ; Eliseeva, EA; Davies, MM; Spears, M; Lobscheid, A; Fisk, WJ; Apte, MG | Abstract: Limited evidence associates inadequate classroom ventilation rates (VRs) with increased illness absence (IA). We investigated relationships between VRs and IA in California elementary schools over two school years in 162 3rd-5th-grade classrooms in 28 schools in three school districts: South Coast (SC), Bay Area (BA), and Central Valley (CV). We estimated relationships between daily IA and VR (estimated from two year daily real-time carbon dioxide in each classroom) in zero-inflated negative binomial models. We also compared IA benefits and energy costs of increased VRs. All school districts had median VRs below the 7.1 l/s-person California standard. For each additional 1 l/s-person of VR, IA was reduced significantly (pl0.05) in models for combined districts (-1.6%) and for SC (-1.2%), and nonsignificantly for districts providing less data: BA (-1.5%) and CV (-1.0%). Assuming associations were causal and generalizable, increasing classroom VRs from the California average (4 l/s-person) to the State standard would decrease IA by 3.4%, increase attendance-linked funding to schools by $33 million annually, and increase costs by only $4 million. Further increasing VRs would provide additional benefits. These findings, while requiring confirmation, suggest that increasing classroom VRs above the State standard would substantially decrease illness absence and produce economic benefits. Published 2013. This article is a US Government work and is in the public domain in the USA.

Published

2013

36. H<scp>EALTH AND</scp> P<scp>RODUCTIVITY</scp> G<scp>AINS FROM</scp> B<scp>ETTER</scp> I<scp>NDOOR</scp> E<scp>NVIRONMENTS AND THEIR</scp> R<scp>ELATIONSHIP WITH</scp> B<scp>UILDING</scp> E<scp>NERGY</scp> E<scp>FFICIENCY</scp>

Author

William J. Fisk

Subjects

Empirical data, medicine.medical_specialty, Environmental Engineering, Renewable Energy, Sustainability and the Environment, Natural resource economics, Public health, Energy Engineering and Power Technology, Building energy, complex mixtures, Energy conservation, Sick building syndrome, Environmental protection, medicine, Business, Air quality index, Productivity, health care economics and organizations, Efficient energy use

Abstract

▪ Abstract Theoretical considerations and empirical data suggest that existing technologies and procedures can improve indoor environments in a manner that significantly increases productivity and health. The existing literature contains moderate to strong evidence that characteristics of buildings and indoor environments significantly influence rates of communicable respiratory illness, allergy and asthma symptoms, sick building symptoms, and worker performance. Whereas there is considerable uncertainty in the estimates of the magnitudes of productivity gains that may be obtained by providing better indoor environments, the projected gains are very large. For the United States, the estimated potential annual savings and productivity gains are $6 to $14 billion from reduced respiratory disease, $1 to $4 billion from reduced allergies and asthma, $10 to $30 billion from reduced sick building syndrome symptoms, and $20 to $160 billion from direct improvements in worker performance that are unrelated to health. Productivity gains that are quantified and demonstrated could serve as a strong stimulus for energy efficiency measures that simultaneously improve the indoor environment.

Published

2000

37. Hygroscopic Fine Mode Particle Deposition on Electronic Circuits and Resulting Degradation of Circuit Performance: An Experimental Study

Author

William J. Fisk, Andres Litvak, and Ashok J. Gadgil

Subjects

Environmental Engineering, Chemistry, business.industry, Public Health, Environmental and Occupational Health, Electrical engineering, Building and Construction, Electrostatics, Electrical resistivity and conductivity, visual_art, Electronic component, visual_art.visual_art_medium, Deposition (phase transition), Particle size, Electronics, Composite material, business, Electronic circuit, Particle deposition

Abstract

A portion of electronic equipment failures is a consequence of particle deposition on electronic circuits in normal indoor environments. Deposited hygroscopic particles reduce the electrical isolation (EI) between conductors. In laboratory experiments, we investigated the mechanisms, locations, and effects of particle deposition on electronic circuits with surface mounted chips (SMCs) and also on small television sets. One set of electronics was exposed for 281 h to an unusually high concentration of artificially-generated ammonium sulfate particles while a second set (experimental controls) was exposed to normal indoor particles. The particle mass concentration in the high-exposure chamber was 500 times higher than normal. Television reliability was observed and the changes in EI between adjacent legs of SMCs were measured. The experiments demonstrate the strong influence of electrostatic forces on the locations and rates of particle deposition. Although televisions did not fail after exposure to concentrated aerosols, the EI between adjacent legs of the SMCs was, in many cases, greatly diminished. Relative humidity had a very strong influence on the magnitude of EI. A qualitative explanation of the mechanisms of particle deposition and circuit degradation is proposed, including the role of fibers. Finally, a potential method to reduce particle deposition on electronic components is discussed.

Published

2000

38. Estimates of Improved Productivity and Health from Better Indoor Environments

Author

Arthur H. Rosenfeld and William J. Fisk

Subjects

Sick building syndrome, Empirical data, Environmental Engineering, Indoor air quality, Environmental health, Public Health, Environmental and Occupational Health, Sample (statistics), Asthma symptoms, Building and Construction, Business, Productivity, health care economics and organizations, Additional research

Abstract

The existing literature contains strong evidence that characteristics of buildings and indoor environments significantly influence rates of respiratory disease, allergy and asthma symptoms, sick building symptoms, and worker performance. Theoretical considerations, and limited empirical data, suggest that existing technologies and procedures can improve indoor environments in a manner that significantly increases health and productivity. At present, we can develop only crude estimates of the magnitude of productivity gains that may be obtained by providing better indoor environments; however, the projected gains are very large. For the U.S., we estimate potential annual savings and productivity gains of $6 billion to $19 billion from reduced respiratory disease; $1 billion to $4 billion from reduced allergies and asthma, $10 billion to $20 billion from reduced sick building syndrome symptoms, and $12 billion to $125 billion from direct improvements in worker performance that are unrelated to health. Sample calculations indicate that the potential financial benefits of improving indoor environments exceed costs by a factor of 18 to 47. The policy implications of the findings are discussed and include a recommendation for additional research.

Published

1997

39. Energy Impacts of Energy and Indoor Environmental Quality Retrofits of Apartments in California

Author

William J. Fisk, Federico Norris, and Brett C. Singer

Subjects

Engineering, Architectural engineering, Occupancy, Apartment, business.industry, Electric potential energy, Conclusive evidence, Electricity, Environmental economics, business, Energy (signal processing), Environmental quality

Abstract

Monthly gas and electricity use data from a set of 13 study apartments and 20 control apartments from three apartment buildings (B1 B3) in California were analyzed. The study apartments were retrofit with simultaneous energy savings and indoor environmental quality (IEQ) improvements as the goal. The control apartments were not retrofit. Pre-retrofit modeling indicated annual energy savings of 21percent, 17percent, and 27percent for the study apartments in B1-B3, respectively. Based on a comparison of changes in energy use of study apartments to energy use changes of control apartments, total measured savings of gas energy plus site electrical energy were 28percent in B1, 5percent in B2, and 3percent in B3. Given the small number of study apartments and the substantial changes in energy use within control apartments, the project yielded no conclusive evidence of energy savings. Apartment energy use increased with number of occupants and with floor area; however, the association with occupancy was most evident. Climate differences did not appear to be the major driver for the variability in energy use among apartments. Changes in occupant behaviors affecting energy use may have overwhelmed and obscured the energy savings in this small number of buildings. Much larger prior studies employing similarmore » retrofits indicate that the retrofits usually do save energy.« less

Published

2013

40. Association of Lower Classroom Ventilation Rates with Increased Illness Absence in a Prospective Study of California Elementary Schools

Author

Ekaterina A. Eliseeva, Molly M. Davies, Mark J. Mendell, Agnes B. Lobscheid, Michael G. Apte, and William J. Fisk

Subjects

medicine.medical_specialty, business.industry, education, law.invention, law, Ventilation (architecture), Emergency medicine, medicine, General Earth and Planetary Sciences, Limited evidence, Association (psychology), Prospective cohort study, business, General Environmental Science, Cohort study

Abstract

Background: Limited evidence associates inadequate classroom ventilation rates (VRs) with increased illness-related absence (IRA) in students. Aims: The goal of this research was to characterize VR...

Published

2013

41. Evaluation of the Indoor Air Quality Procedure for Use in Retail Buildings

Author

Spencer M. Dutton, Wanyu R. Chan, Mark J. Mendell, Marcella Barrios, Srinandini Parthasarathy, Meera Sidheswaran, Douglas P. Sullivan, Katerina Eliseeva, and William J. Fisk

Subjects

Energy conservation, Engineering, Research program, Architectural engineering, Indoor air quality, business.industry, Commission, business, National laboratory, Civil engineering, Public interest, Renewable energy, Efficient energy use

Abstract

Evaluation of the Indoor Air Quality Procedure for Use in Retail Buildings Spencer M. Dutton, Wanyu R. Chan, Mark J. Mendell, Marcella Barrios, Srinandini Parthasarathy, Meera Sidheswaran, Douglas P. Sullivan, Katerina Eliseeva, William J. Fisk Environmental Energy Technologies Division Indoor Environment Group Lawrence Berkeley National Laboratory Berkeley, CA 94720 February 1, 2013 The research reported here was supported by the California Energy Commission Public Interest Energy Research Program, Energy-Related Environmental Research Program, award number 500-09-049.The study was additionally supported by the Assistant Secretary for Energy Efficiency and Renewable Energy, Building Technologies Program of the U.S. Department of Energy under contract DE-AC02-05CH11231.

Published

2013

42. Regional and national estimates of the potential energy use, energy cost and CO2 emissions associated with radon mitigation by sub-slab depressurization

Author

William J. Fisk, William J. Riley, and Ashok J. Gadgil

Subjects

Radon mitigation, Engineering, business.industry, Mechanical Engineering, Energy current, Environmental engineering, chemistry.chemical_element, Radon, Building and Construction, Energy accounting, law.invention, Cabin pressurization, chemistry, law, Ventilation (architecture), Electrical and Electronic Engineering, business, Operating expense, Civil and Structural Engineering, Efficient energy use

Abstract

Active sub-slab depressurization (SSD) systems are an effective means of reducing indoor radon concentrations in residential buildings. However, energy is required to operate the system fan and to heat or cool the resulting increased building ventilation. We present regional and national estimates of the energy requirements, operating expenses and CO 2 emissions associated with using SSD systems at saturation (i.e. in all US homes with radon concentrations above the EPA remediation guideline and either basement or slab-on-grade construction). The primary source of uncertainty in these estimates is the impact of the SSD system on house ventilation rate. Overall, individual SSD system operating expenses are highest in the Northeast and Midwest at about $99 y −1 , and lowest in the South and West at about $66 y −1 . The fan consumes, on average, about 40% of the end-use energy used to operate the SSD system and accounts for about 60% of the annual expense. At saturation, regional impacts are largest in the Midwest because this area has a large number of mitigable houses and a relatively high heating load. We estimate that operating SSD systems in US houses, where it is both appropriate and possible (about 2,6 million houses), will annually consume 1.7 × 10 4 (6.4 × 10 3 to 3.9 × 10 4 ) TJ of end-use energy, cost $230 (130 to 400) million (at current energy prices), and generate 2.0 × 10 9 (1.2 × 10 9 to 3.5 × 10 9 ) kg of CO 2 . Passive or energy efficient radon mitigation systems currently being developed offer opportunities to substantially reduce these impacts.

Published

1996

43. Healthy Zero Energy Buildings (HZEB) Program Interim Report on Cross Sectional Study of Contaminant Levels, Source Strengths, and Ventilation Rates in Retail Stores

Author

Meera Sidheswaran, Douglas P. Sullivan, Sebastian Cohn, William J. Fisk, and Wanyu R. Chan

Subjects

Research program, Engineering, Zero-energy building, business.industry, Civil engineering, Agricultural economics, law.invention, Renewable energy, Energy conservation, law, Ventilation (architecture), National laboratory, business, Interim report, Efficient energy use

Abstract

Healthy Zero Energy Buildings (HZEB) Program– Interim Report on Cross‐Sectional Study of Contaminant Levels, Source Strengths, and Ventilation Rates in Retail Stores Wanyu R. Chan, Meera Sidheswaran, Douglas Sullivan, Sebastian Cohn, William J. Fisk Environmental Energy Technologies Division Indoor Environment Group Lawrence Berkeley National Laboratory Berkeley, CA 94720 November 5, 2012 The research reported here was supported by the California Energy Commission Public Interest Energy Research Program, Energy‐Related Environmental Research Program, award number 500‐09‐049. The project was also supported by the U.S. Dept. of Energy Building Technologies Program, Office of Energy Efficiency and Renewable Energy under DOE Contract No. DE‐AC02‐05CH11231.

Published

2012

44. New Air Cleaning Strategies for Reduced Commercial Building Ventilation Energy ? FY11 Final Report

Author

Sebastian Cohn, Meera Sidheswaran, William J. Fisk, Douglas P. Sullivan, and Hugo Destaillats

Subjects

Engineering, Zero-energy building, Waste management, business.industry, Air cleaning, Air cleaner, Civil engineering, law.invention, Energy conservation, law, Ventilation (architecture), HVAC, business, Efficient energy use

Abstract

The research carried out in this project focuses on developing novel volatile organic compounds (VOCs) air cleaning technologies needed to enable energy-saving reductions in ventilation rates. we targeted a VOC air cleaning system that could enable a 50% reduction in ventilation rates. In a typical commercial HVAC system that provides a mixture of recirculated and outdoor air, a VOC air cleaner in the supply airstream must have a 15% to 20% VOC removal efficiency to counteract a 50% reduction in outdoor air supply.

Published

2011

45. Defining a Standard Metric for Electricity Savings

Author

Jonathan Koomey, Hashem Akbari, Carl Blumstein, Marilyn Brown, Richard Brown, Robert Budnitz, Chris Calwell, Sheryl Carter, Ralph Cavanagh, Audrey Chang, David Claridge, Paul Craig, Rick Diamond, Joseph H. Eto, William J. Fisk, William Fulkerson, Ashok Gadgil, Howard Geller, José Goldemberg, Chuck Goldman, David B. Goldstein, Steve Greenberg, David Hafemeister, Jeff Harris, Hal Harvey, Eric Heitz, Eric Hirst, Holmes Hummel, Dan Kammen, Henry Kelly, Skip Laitner, Mark Levine, Amory Lovins, Gil Masters, Pat McAuliffe, James E. McMahon, Alan Meier, Michael Messenger, John Millhone, Evan Mills, Steve Nadel, Bruce Nordman, Lynn Price, Joe Romm, Marc Ross, Michael Rufo, Jayant Sathaye, Lee Schipper, Stephen H. Schneider, Robert H. Socolow, James L. Sweeney, Malcolm Verdict, Alexandra von Meier, Diana Vorsatz, Devra Wang, Carl Weinberg, Richard Wilk, John Wilson, Jane Woodward, Ernst Worrell, Daniel Kammen, Barbara Goss Levi, and Peter Schwartz

Subjects

Energy conservation, Engineering, Resource (project management), Standardization, Power station, business.industry, Operations management, Metric (unit), Electricity, Environmental economics, business, Investment (macroeconomics), Efficient energy use

Abstract

The growing investment by governments and electric utilities in energy efficiency programs highlights the need for simple tools to help assess and explain the size of the potential resource. One technique that is commonly used in that effort is to characterize electricity savings in terms of avoided power plants, because it is easier for people to visualize a power plant than it is to understand an abstraction like billions of kilowatt‐hours. Unfortunately, there is no standardization around the characteristics of such power plants.In this article we define parameters for a standard avoided power plant that have physical meaning and intuitive plausibility, for use in back‐of‐the‐envelope calculations. For the prototypical plant this article settles on a 500‐megawatt existing coal plant operating at a 70% capacity factor with 7% T&D losses. Displacing such a plant for one year would save 3 billion kWh/year at the meter and reduce emissions by 3 million metric tons of CO2 per year.The proposed name for this...

Published

2011

46. Phase 1 of the California Healthy Building Study: A Summary

Author

Alfred T. Hodgson, Matty Nematollahi, David Faulkner, Joan M. Daisey, Mark J. Mendell, Janet M. Macher, and William J. Fisk

Subjects

Engineering, Environmental Engineering, Demographics, Cross-sectional study, business.industry, Public Health, Environmental and Occupational Health, Public office, Building and Construction, Logistic regression, Sick building syndrome, Indoor air quality, Environmental health, business, Space sharing

Abstract

Twelve public office buildings were selected for a study of relationships between worker's health symptoms and a number of building, workspace, job, and personal factors. Three buildings were naturally ventilated, three were mechanically ventilated, and six were air conditioned. Information on the prevalences of work-related symptoms, demographics, and job and personal factors were determined via a questionnaire completed by 880 occupants. Several indoor environmental parameters were measured. Logistic regression models were used to evaluate associations between symptom prevalences and features of the buildings, indoor environments, jobs, and personal factors. A substantial fraction of the occupants in these typical office buildings reported frequent work-related symptoms. The occupants of the mechanically ventilated and air conditioned buildings had sipifcantly more symptoms than occupants of the naturally ventilated buildings after adjustment for confounding factors. Increased prevalences of some symptoms were associated with several job and workspace factors including: presence of carpet, increased use of carbonless copy paper and photocopiers, space sharing, and distance from a window

Published

1993

47. New Air Cleaning Strategies for Reduced Commercial Building Ventilation Energy

Author

Meera Sidheswaran, Hugo Destaillats, Douglas P. Sullivan, and William J. Fisk

Subjects

Pollutant, Waste management, business.industry, Energy recovery ventilation, Air cleaning, Counter measures, law.invention, law, HVAC, Ventilation (architecture), Environmental science, business, Energy (signal processing), Filtration

Abstract

Approximately ten percent of the energy consumed in U.S. commercial buildings is used by HVAC systems to condition outdoor ventilation air. Reducing ventilation rates would be a simple and broadly-applicable energy retrofit option, if practical counter measures were available that maintained acceptable concentrations of indoor-generated air pollutants. The two general categories of countermeasures are: 1) indoor pollutant source control, and 2) air cleaning. Although pollutant source control should be used to the degree possible, source control is complicated by the large number and changing nature of indoor pollutant sources. Particle air cleaning is already routinely applied in commercial buildings. Previous calculations indicate that particle filtration consumes only 10percent to 25percent of the energy that would otherwise be required to achieve an equivalent amount of particle removal with ventilation. If cost-effective air cleaning technologies for volatile organic compounds (VOCs) were also available, outdoor air ventilation rates could be reduced substantially and broadly in the commercial building stock to save energy. The research carried out in this project focuses on developing novel VOC air cleaning technologies needed to enable energy-saving reductions in ventilation rates. The minimum required VOC removal efficiency to counteract a 50percent reduction in ventilation rate for air cleaning systems installed in the HVAC supply airstream is modest (generally 20percent or less).

Published

2010

48. Recommended Changes to Specifications for Demand Controlled Ventilation in California's Title 24 Building Energy Efficiency Standards

Author

William J. Fisk, Douglas P. Sullivan, and David Faulkner

Subjects

Transport engineering, Engineering, Research program, Demand controlled ventilation, business.industry, Building energy, Commission, Environmental energy, business, Efficient energy use, Public interest, Renewable energy

Abstract

Recommended Changes to Specifications for Demand Controlled Ventilation in California’s Title 24 Building Energy Efficiency Standards W.J. Fisk, D.P. Sullivan, D. Faulkner Environmental Energy Techologies Division Indoor Environment Department Lawrence Berkeley National Laboratory Berkeley, CA 94720 April 8, 2010 The research reported here was supported by the California Energy Commission Public Interest Energy Research program award number 600303000 and by the Assistant Secretary for Energy Efficiency and Renewable Energy, Office of the Building Technologies Program, U.S. Department of Energy under Contract No. DE-AC02-05CH11231.

Published

2010

49. CO2 MONITORING FOR DEMAND CONTROLLED VENTILATION IN COMMERCIAL BUILDINGS

Author

William J. Fisk, Douglas P. Sullivan, David Faulkner, and Ekaterina Eliseeva

Subjects

Research program, Engineering, Architectural engineering, Zero-energy building, business.industry, Renewable energy, law.invention, Public interest, Co2 monitoring, Demand controlled ventilation, law, Ventilation (architecture), business, Efficient energy use

Abstract

CO 2 MONITORING FOR DEMAND CONTROLLED VENTILATION IN COMMERCIAL BUILDINGS W.J. Fisk, D.P. Sullivan, D. Faulkner, E.Eliseeva Environmental Energy Technologies Division Indoor Environment Department Lawrence Berkeley National Laboratory Berkeley, CA 94720 March 17, 2010 The research reported here was supported by the California Energy Commission Public Interest Energy Research program award number 600303000 and by the Assistant Secretary for Energy Efficiency and Renewable Energy, Office of the Building Technologies Program, U.S. Department of Energy under Contract No. DE-AC02-05CH11231.

Published

2010

50. Quantification of the association of ventilation rates with sick building syndrome symptoms

Author

Mark J. Mendell, William J. Fisk, and Anna G. Mirer

Subjects

medicine.medical_specialty, Sick building syndrome, business.industry, law, Internal medicine, Linear regression, Ventilation (architecture), Cardiology, Medicine, business, Symptom prevalence, law.invention

Abstract

Data from published studies were combined and analyzed to develop best-fit equations and curves quantifying the change in sick building syndrome (SBS) symptom prevalence with ventilation rate. For each study, slopes were calculated, representing the fractional change in SBS symptom prevalence per unit change in ventilation rate per person. Values of ventilation rate, associated with each value of slope, were also calculated. Linear regression equations were fit to the resulting data points, after weighting by study size. Integration of the slope-ventilation rate equations yielded curves of relative SBS symptom prevalence versus ventilation rate. Based on these analyses, relative SBS symptom prevalence increases approximately 23percent (12percent to 32percent) as the ventilation rate drops from 10 to 5 L/s-person and relative prevalence decreases approximately 29percent (15percent to 42percent) as ventilation rate increases from 10 to 25 L/s-person.

Published

2009