Measuring Air Changes per Hour with Carbon Dioxide Dr Rod Escombe MRCP DTM&H PhD Honorary Research Fellow, Wellcome Centre for Clinical Tropical Medicine & Department of Infectious Diseases & Immunity, Imperial College London, UK. Senior Investigator, Asociación Benéfica PRISMA, Lima, Perú. GP Registrar, St Mary s Hospital, London, UK. HOSPITAL NACIONAL DOS DE MAYO Measuring room air exchange Measure air supply & extract Negative pressure: extract > supply by ~1% Calculating ACH Q = room ventilation (cfm) V = velocity (feet/min) A = duct area (square feet) ACH = Q/room volume 1
Measuring room air exchange in low resource settings Q=V x A ACH = Q/volume Principles: Measuring room air exchange using a tracer gas Use gas that is not usually present in the room air: SF 6 Deliver gas and mix with room air Measure concentration decay to calculate air exchange Also a continuous release methodology US$ 3, Concentration decay 8 Standard tracer gas technique: 7 6 American Standards and Test Material Committee. 1988. Standard test method for determining air leakage rate by tracer dilution. In Annual Book ASTM Standards & Test Materials. Wash DC. 568-575 Standard test methods for determining air change in a single zone by means of a tracer gas dilution. Standard E741-. Philadelphia, Pennsylvania: American Society for Testing Materials. Decker J. Evaluation of isolation rooms in health care settings using tracer gas analysis. Appl Occup Envir Hyg 1995;1:887-91. 5 4 3 2 1..5.1.15.2.25.3.35 Time Other methods: theatrical fog Gershey EL, Reiman J, Wood W, Party E. Evaluation of a room for tuberculosis patient isolation using theatrical fog. Infect Control Hosp Epidemiol. 1998 Oct;19(1):76-6. 2
Measuring natural ventilation Measuring room air exchange using carbon dioxide as a tracer gas Infra-red gas analyser to measure CO 2 concentrations Advatanges: Cheap CO 2 easily available (dry ice, fizzy drinks) Can use occupied rooms Disadvantages: Not perfect CO 2 present in air CO 2 produced by occupants Menzies R, Schwartzman K, Loo V, Pasztor J. Measuring ventilation of patient care areas in hospitals. Description of a new protocol. Am J Respir Crit Care Med 1995;152:1992-9. 3
CO 2 release 6 CO 2 concentration (ppm) 5 4 3 2 1 Slow CO 2 concentration decay with windows closed Rapid decay with windows open.5 ACH 12 ACH 5 1 15 2 25 3 35 Closing apertures 4
CO 2 release Small rooms, little ventilation: Gas cylinder Large rooms, lots of ventilation: Fire extinguisher CO 2 release Very big rooms lots of fire extinguishers 5
Mixing: Aiming for complete mixing Mixing no electricity 6
CO 2 release 6 5 CO 2 concentration (ppm) 4 3 2 1 Slow CO 2 concentration decay with windows closed Rapid decay with windows open.5 ACH 12 ACH 5 1 15 2 25 3 35 Calculation of ACH CO 2 release Calculation of ACH 6 ACH = Absolute ventilation / Room Volume = Q / V CO 2 concentration (ppm) 5 4 3 2 1 Slow CO 2 concentration Rapid decay decay with windows closed with windows open.5 air-changes/hour 12 air-changes/hour 5 1 15 2 25 3 35 Plot natural log of CO 2 concentration against time Units: concentration (eg ppm) vs. time in hours ACH = slope of line of best fit Ln ppm Natural log of all data 1. 9. 8. 7. 6. 5. 4. 3. 2. 1....2.4.6.8 hours from start of experiment 7
CO 2 release Calculation of ACH CO 2 concentration (ppm) 6 5 4 3 2 1 Slow CO 2 concentration Rapid decay decay with windows closed with windows open.5 air-changes/hour 12 air-changes/hour Natural logarithm CO 2 concentration (ppm) 8.7 8.6 Windows and doors CLOSED.5 ACH y = -.5x + 8.7 R 2 =.89 5 1 15 2 25 3 35 8.5..5.1.15.2.25.3.35 Time (hours) CO 2 release Calculation of ACH CO 2 concentration (ppm) 6 5 4 3 2 1 Slow CO 2 concentration Rapid decay decay with windows closed with windows open.5 air-changes/hour 12 air-changes/hour 5 1 15 2 25 3 35 Natural logarithm CO 2 concentration (ppm) 9 8 7 6 5 4 3 2 1 y = -12.25x + 12.1 R 2 =.88.3.35.4.45.5 Time (hours) Windows and doors OPEN 12 ACH 8
Where to stop? Depends on room occupants Within 2 ppm of baseline CO 2 release 6 CO 2 concentration (ppm) 5 4 3 2 1 Slow CO 2 concentration Rapid decay decay with windows closed with windows open.5 air-changes/hour 12 air-changes/hour 5 1 15 2 25 3 35 ACH vs. Absolute ventilation 1 Concentration (cfu/m 3 ) 8 6 4 2 1 ACH ACH = Q / V Q = ACH x V 1 2 8 3 4 Time (hours) 4 2 4m 2m Area 25 m 3 V= 4x25 = 1 m 3 12 ACH = 1,2 m 3 /h V = 2x25 = 5 m 3 12 ACH = 6 m 3 /h In models of airborne infection, it is absolute ventilation that is a major determinant of disease transmission Wells-Riley equation: C=S(1-e Iqpt/Q ) 9
Effect of room volume if ACH is constant Wells-Riley equation: C=S(1-e Iqpt/Q ) ACH=12 Q=1,2 C=1x(1-e -1x13x.6x8 )/1,2 =.5 Risk = 5% C= new cases S=susceptibles I =number of infectors q=infectious quanta produced per hour p=pulmonary minute ventilation t=duration of exposure Q=absolute ventilation ACH=12 Q=6 C=1x(1-e-1x13x.6x8)/1,2 =.1 Risk = 1% Mechanical ventilation can t deliver high ACH in large rooms due to cost, drafts, fan noise etc More complex: room crowding / bed spacing / near-far effect Measuring room air exchange using carbon dioxide as a tracer gas Conclusions Simple Easy to do Equipment relatively easily available Cheap A bit rough, but with inherent variability of natural ventilation (wind speed etc) and such high air exchange rates, high precision is less important It s fun! 1
Thank you 11