Predicted performance of in-duct UVGI systems under variable operating conditions

Research output: Contribution to journalConference article

Abstract

Ultraviolet germicidal irradiation (UVGI), typically utilizing 254 nm radiation from low pressure mercury vapor lamps, is being applied in HVAC systems to inactivate infectious airborne microorganisms in health care, security, and general air quality applications. Simulation can play a useful role in the design of application-appropriate systems. A key requirement for accurate modeling is consideration for the impact on lamp UV output of the temperature and velocity of the air stream to which it is exposed. Lamp output varies greatly with the vapor pressure of the plasma it contains, which is highly dependent upon lamp surface cold spot temperature. A model of a single zone HVAC system serving an office space was constructed and was used to simulate the effects of UVGI device location, weather conditions, filter efficiency, and operating cycle on control of generic vegetative bacteria-like and fungal spore-like air contaminants. UVGI device modeling included a model of variable lamp output based on predicted average lamp surface temperature. It was found that lamp output could vary by more than 50% across the range of conditions considered with variations in average contaminant concentration during occupied hours as large as 13%. Operation of UVGI only during occupied hours produced similar occupied hour concentration to continuous operation, but much larger unoccupied hour concentrations. Filtration was found to complement UVGI well by removing the larger spore-like contaminant for which UVGI was less effective than for bacteria.

Original languageEnglish (US)
JournalIAQ Conference
StatePublished - Dec 1 2008
EventHealthy and Sustainable Buildings Conference, IAQ 2007 - Baltimore, MD, United States
Duration: Oct 15 2007Oct 17 2007

Fingerprint

Ducts
Vapor Pressure
Electric lamps
Air
Irradiation
Bacteria
Equipment and Supplies
Temperature
Fungal Spores
Weather
Impurities
Spores
Mercury
Radiation
Ultraviolet lamps
Delivery of Health Care
Mercury vapor lamps
Vapor pressure
Health care
Air quality

All Science Journal Classification (ASJC) codes

  • Building and Construction
  • Environmental Engineering
  • Public Health, Environmental and Occupational Health

Cite this

@article{16fa8136b2b84b97a07250313101f0df,
title = "Predicted performance of in-duct UVGI systems under variable operating conditions",
abstract = "Ultraviolet germicidal irradiation (UVGI), typically utilizing 254 nm radiation from low pressure mercury vapor lamps, is being applied in HVAC systems to inactivate infectious airborne microorganisms in health care, security, and general air quality applications. Simulation can play a useful role in the design of application-appropriate systems. A key requirement for accurate modeling is consideration for the impact on lamp UV output of the temperature and velocity of the air stream to which it is exposed. Lamp output varies greatly with the vapor pressure of the plasma it contains, which is highly dependent upon lamp surface cold spot temperature. A model of a single zone HVAC system serving an office space was constructed and was used to simulate the effects of UVGI device location, weather conditions, filter efficiency, and operating cycle on control of generic vegetative bacteria-like and fungal spore-like air contaminants. UVGI device modeling included a model of variable lamp output based on predicted average lamp surface temperature. It was found that lamp output could vary by more than 50{\%} across the range of conditions considered with variations in average contaminant concentration during occupied hours as large as 13{\%}. Operation of UVGI only during occupied hours produced similar occupied hour concentration to continuous operation, but much larger unoccupied hour concentrations. Filtration was found to complement UVGI well by removing the larger spore-like contaminant for which UVGI was less effective than for bacteria.",
author = "Josephine Lau and Bahnfleth, {William P.} and Freihaut, {James D.}",
year = "2008",
month = "12",
day = "1",
language = "English (US)",
journal = "IAQ Conference",
issn = "2166-4870",

}

Predicted performance of in-duct UVGI systems under variable operating conditions. / Lau, Josephine; Bahnfleth, William P.; Freihaut, James D.

In: IAQ Conference, 01.12.2008.

Research output: Contribution to journalConference article

TY - JOUR

T1 - Predicted performance of in-duct UVGI systems under variable operating conditions

AU - Lau, Josephine

AU - Bahnfleth, William P.

AU - Freihaut, James D.

PY - 2008/12/1

Y1 - 2008/12/1

N2 - Ultraviolet germicidal irradiation (UVGI), typically utilizing 254 nm radiation from low pressure mercury vapor lamps, is being applied in HVAC systems to inactivate infectious airborne microorganisms in health care, security, and general air quality applications. Simulation can play a useful role in the design of application-appropriate systems. A key requirement for accurate modeling is consideration for the impact on lamp UV output of the temperature and velocity of the air stream to which it is exposed. Lamp output varies greatly with the vapor pressure of the plasma it contains, which is highly dependent upon lamp surface cold spot temperature. A model of a single zone HVAC system serving an office space was constructed and was used to simulate the effects of UVGI device location, weather conditions, filter efficiency, and operating cycle on control of generic vegetative bacteria-like and fungal spore-like air contaminants. UVGI device modeling included a model of variable lamp output based on predicted average lamp surface temperature. It was found that lamp output could vary by more than 50% across the range of conditions considered with variations in average contaminant concentration during occupied hours as large as 13%. Operation of UVGI only during occupied hours produced similar occupied hour concentration to continuous operation, but much larger unoccupied hour concentrations. Filtration was found to complement UVGI well by removing the larger spore-like contaminant for which UVGI was less effective than for bacteria.

AB - Ultraviolet germicidal irradiation (UVGI), typically utilizing 254 nm radiation from low pressure mercury vapor lamps, is being applied in HVAC systems to inactivate infectious airborne microorganisms in health care, security, and general air quality applications. Simulation can play a useful role in the design of application-appropriate systems. A key requirement for accurate modeling is consideration for the impact on lamp UV output of the temperature and velocity of the air stream to which it is exposed. Lamp output varies greatly with the vapor pressure of the plasma it contains, which is highly dependent upon lamp surface cold spot temperature. A model of a single zone HVAC system serving an office space was constructed and was used to simulate the effects of UVGI device location, weather conditions, filter efficiency, and operating cycle on control of generic vegetative bacteria-like and fungal spore-like air contaminants. UVGI device modeling included a model of variable lamp output based on predicted average lamp surface temperature. It was found that lamp output could vary by more than 50% across the range of conditions considered with variations in average contaminant concentration during occupied hours as large as 13%. Operation of UVGI only during occupied hours produced similar occupied hour concentration to continuous operation, but much larger unoccupied hour concentrations. Filtration was found to complement UVGI well by removing the larger spore-like contaminant for which UVGI was less effective than for bacteria.

UR - http://www.scopus.com/inward/record.url?scp=84874164768&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84874164768&partnerID=8YFLogxK

M3 - Conference article

AN - SCOPUS:84874164768

JO - IAQ Conference

JF - IAQ Conference

SN - 2166-4870

ER -