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Transcript 
Generation of Vapor-Phase
Hydrogen Peroxide Test
Atmospheres for the Evaluation of
Respirator Cartridges
and Air Samplers
C.R. (Gus) Manning, PhD, CIH
Hydrogen Peroxide
Common substance with unusual properties
–I have a bottle in the bathroom.
–How bad can it be?
Hydrogen Peroxide
(VHP = Vapor Phase Hydrogen Peroxide)
H2O2 = HO-OH
Traditional Uses:
Consumer Pharmaceutical
– Antimicrobial
Industrial
– Oxidizing Agent
Aerospace
– Propellant (rocket fuel)
H2O2 Regulatory Concerns
(formerly)
Traditional Uses of H2O2
– Used Low concentrations (3%)
– Or, were well-contained
Small number of exposed
employees
H2O2 Regulatory Concerns
(new)
New Application !
Medical Sterilizing Agent
Sterilizing Agent with lower risk profile than
Ethylene Oxide
Glutaraldehyde
Formaldehyde
H2O2 Regulatory Concerns
(new)
Medical Sterilization performed in 1000’s
of hospitals, surgical centers, and
medical mfg facilities
Sterilization generates high vapor levels
(100’s of ppm)
> 25,000 employees exposed
REL = TLV = PEL = 1.0 ppm
Project Needs
Evaluate Respirator Cartridges
– Challenge with levels of VHP near IDLH
Evaluate Personal Monitoring Methods
– Expose to VHP Levels near PEL
Goals of Study
Generate VHP (vapor phase H2O2)
– from PEL to IDLH or higher
PEL = 1 ppm
IDLH = 75 ppm
Detect and Measure H2O2
– Direct Reading & Personal Sampling
0.1 - 75 ppm
Generating H2O2 Vapor for Testing
(issues)
Not available in gaseous form
Available as a 3-50% solution in water
– Strongly attracted to water
Hydrogen Peroxide
Interactions
H2O2
decomposition
H2O
+ ½ O2
condenses
at 100oC
condenses
at 150oC
50% H2O2
Solution in water
boils at 114oC
Heating
Vaporization Methods for Liquids
(3 attempted in this study)
Equilibration with Heated Liquid
– Air or N2 stream passes over heated liquid
Liquid Injection through Heated Needle
– directly into test air stream
Liquid Injection into Heated Chamber
– chamber located in test air stream
Test Air Passes Over
Heated Liquid
Test Air from
Miler-Nelson
Generator
Test Air with
Contaminant
Concentration
Liquid to be Vaporized
(heated)
Temp
Sensor
Heating
Block
Feedback
-
+
Applied Voltage
 Highest Concentration Attainment (> 1,000 ppm)
 Liquid components separate by volatility (boiling point)
Heated Needle Vaporization
Liquid to be Vaporized
(metered from syringe pump)
Injection
Needle
Feedback
Applied Voltage
Resistance
Wire (NiCr)
Temp
Sensor
Septum
Test Air with
Contaminant
Concentration
Test Air from
Miler-Nelson
Generator
Vaporization
Chamber
 Vaporizes 100% of liquid (does not separates components)
 Lowest Concentration Attainment (1-50 ppm)
Heated Chamber Vaporization
Liquid to be Vaporized
(metered from syringe pump)
Injection
Needle
Septum
Test Air from
Miler-Nelson
Generator
Test Air with
Contaminant
Concentration
Heating
Mantle
Temp
Sensor
-
Vaporization
Chamber
(3-neck flask)
+
Applied Voltage
 Higher Concentration Attainment than Heated Syringe (to 500 ppm)
 Does not separate liquid components (if careful)
Evaluating Respirator Cartridges
(Schematic)
VHP Sampling Methods
Hydrogen Peroxide
Challenge Sampling Method
OSHA Method ID 006
– Impinger Containing TiOSO4 Solution
TiOSO4 Forms Yellow Complex with H2O2
– Analysis by UV Spectrometer
– 0.1 – 150 ppm
by varying sampling time
Analysis of H2O2
using OSHA ID 006
H2O2 Calibration Curve
0.45
y = 0.0089x
0.40
R 2 = 0.9964
Optical Absorbance
0.35
0.30
0.25
0.20
0.15
0.10
0.05
0.00
0
10
20
30
40
H2O2 Found (microgram)
50
60
H2O2 Analysis (high levels)
OSHA ID 006 Impinger
Sampling Rate = 1 L/min; Sampling Time = 2 min
1.00
Optical Abs (410 nm)
0.80
0.60
0.40
0.20
0.00
0
50
100
VHP Concn (ppm)
150
200
Hydrogen Peroxide
Breakthrough Sampling Methods
Infra Red Spectrometry
– Interference by Water
– FTIR can avoid water interference
Cost = $65,000
Honeywell TLD-1 (Chem Key)
– Paper tape reading device
– Reagent forms color with H2O2
Measures 0.1-3ppm
Evaluating Respirator Cartridges
(Schematic)
H2O2 Generation
Humidity Effects
350
25%RH
85%RH
50% RH
100% Efficiency
300
250
H2O2 Concn
(ppm)
200
150
100
50
0
0
20
40
H2O2 Added
(mg/min)
60
80
VHP Vapor Pressure
is Limited at High Humidity
700
600
500
Saturated
VHP Concn
400
300
200
100
0
0
20
40
60
% Relative Humidity
80
100
Hydrogen Peroxide
Interactions
H2O2
decomposition
H2O
+ ½ O2
condenses
at 100oC
condenses
at 150oC
50% H2O2
Solution in water
boils at 114oC
Heating
Evaluating Respirator Cartridges
(Schematic)
Accuracy of VHP Challenge
Challenge Level vs Testing Time
VHP Challenge Level (ppm )
250
200
150
100
50
0
0
1
2
Elapsed Time (hr)
3
4
Conclusions
Vapor Phase Hydrogen Peroxide (VHP) can be generated by
injecting 50% aqueous H2O2 solution into a heated glass chamber
with challenge air passing over.
– Challenge Levels from 50 - 150 ppm
– Flow Rates from 50 - 175 L/min
Vaporization Efficiency decreases as %RH increases
– 75 ppm (IDLH) can be generated at 85% RH
– 150 ppm can only be generated with difficulty at higher RH
Challenge Levels of VHP can be monitored using OSHA ID 006
utilizing TiOSO4 reagent in a glass impinger.
– Operating range 0.1 – 150 ppm
Breakthrough Levels of VHP may be monitored using a Honeywell
TLD-1 Analyzer.
– Operating range 0.1 – 3ppm
Hydrogen Peroxide
Evaluation of Personal Samplers
Concept of Side-by-Side
Sampler Comparison
MNR
Atmosphere Generator
Air Intake
Chemical Vapor
Generator
ChemDisk
ChemDisk
Sampling
Tube
ChemDisk
Diffusive
Sampler
Sampling
Pump
Exhaust Fan
Sampling
Tubes
Comparison of Samplers
(Hydrogen Peroxide)
Evaluating Air Samplers
(schematic)
Hydrogen Peroxide
Personal Sampling Methods
OSHA Method ID 006
– Impinger Containing TiOSO4 Solution
TiOSO4 Forms Yellow Complex with H2O2
– Analysis by UV Spectrometer
Diffusive Sampler (from OSHA Method)
– Personal Monitoring Badge Containing TiOSO4
TiOSO4 Forms Yellow Complex with H2O2
– Analysis by UV Spectrometer
H2O2 Analysis (low levels)
OSHA ID 006 Impinger
Sampling Rate = 1 L/min; Sampling Time = 40 min
1.00
Optical Abs (410 nm)
0.80
0.60
0.40
0.20
0.00
0
2
4
6
VHP Concn (ppm)
8
10
H2O2 Analysis
Personal Monitoring Badge
Sampling Rate = 90 mL/min; Sampling Time = 4 hour
1.00
Optical Abs (410 nm)
0.80
0.60
0.40
0.20
0.00
0
1
2
VHP Concn (ppm)
3
Conclusions
Vapor Phase Hydrogen Peroxide (VHP) can be generated by
injecting 50% aqueous H2O2 solution into a heated glass
chamber with challenge air passing over.
– Challenge Levels from 0.2 - 10 ppm
– Flow Rates from 50 – 150 L/min
Low Levels of Vapor Phase Hydrogen Peroxide (for TWA
personal sampling) were monitored side-by-side using OSHA
ID 006 and a Personal Monitoring Badge designed using
similar chemistry.
– Operating range 0.1 – 10 ppm
Conclusion
Diffusive Samplers (Personal Monitoring
Badges) based on TiOSO4 chemistry perform
similarly to the OSHA ID 006 method, but with
increased convenience.
– Eliminate need for Glass Impingers
– Operating range 0.1 – 10 ppm
Finis
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