Live Demonstrations at Combustible Dust Testing Lab in
conjunction with Two-Day combustible dust workshop July 25-26 North
Cinnaminson, New Jersey.
Course objectives- the
combustible dust hazard workshop will provide the basic knowledge in
identifying, evaluating, and controlling combustible dust hazards.
Topics include recognizing fire and explosion hazards, ignition sources
in operations, isolation engineering controls, laboratory testing for
ignition and explosive severity, best industry practices and
administrative controls for prevention, and conducting a facility hazard
assessment. Who should attend: management, health and safety, and
maintenance personnel in industries with combustible dust hazards
including food, grain, wood, pulp, paper, plastics, pharmaceutical,
rubber, metals and fossil fuel power generation.
Information
Two -Day Workshop July 25 & 26, 2013
One-Day Workshop July 25 includes tour and live demonstrations in combustible dust testing laboratory
EMSL Analytical Combustible Dust Testing Options:
Initial Dust CharacterizationThe most important information determined in this stage are Percent Combustible Dust. This is the percentage of the sample that has the potential to be combustible when it is dry and fine enough to pass through a 40 mesh sieve (less than 420 μm in size). The testing includes:
- Percent through 40 Mesh Screen
- Percent Moisture Content
- Percent Combustible Material (calculated)
- Percent Combustible Dust (calculated)
Go – No Go Testing (Explosive Screening) – ASTM E1226This is an economical and practical way to determine if the dust in the sample has the potential to be explosive. Testing consists of exposing the fine dust in the sample to low energy igniters inside the 20-Liter Siwek explosion chamber and determine the explosion over pressure. If the dust is not found to be an explosive threat, the analysis can be aborted to avoid unnecessary fees. If the sample turns out to be explosive on the screen testing, the more comprehensive analyses listed below should be conducted.
Explosion Severity (Kst, Pmax, [dP/dt]max) – ASTM E1226This testing provides an indication of the severity of the dust explosion by determining the deflagration parameters. The larger the value of Kst, the more severe the explosion is. For this test, the dust is suspended and ignited in the Siwek chamber and the maximum pressureand the rate of pressure rise are measured.
Minimum Explosion Concentration (MEC) – ASTME1515MEC is the minimum concentration for explosivity of a combustible dust cloud. It is determined by suspending the dust in the Siwek Chamber.
Minimum Ignition Energy (MIE) – ASTM E2019MIE is the electrical energy discharged from a capacitor, just sufficient to produce the ignition of the most ignitable mixture of air and dust. It is determined by suspending the dust in a Hartmann Lucite explosion chamber.
Minimum Ignition Temperature Test (MIT) – ASTM E1491 (dust cloud)ASTM E2021 (dust layer)This test method covers the minimum temperature at which a dust cloud will autoignite when exposed to air and heated in a furnace at atmospheric pressure. It is determined by introducing the dust into a BAM oven. As an alternative, the minimum temperature of self-ignition of dust layer can be measured using a hot plate set-up.
Class II TestingThis level of testing involves a number of parameters that determine if the sampled dust is considered a Class II hazardous material. Class II locations are defined as locations with combustible dust having Ignition Sensitivity (I.S.) greater than or equal to 0.2 or Explosion Severity (E.S.) greater than or equal to 0.5. I.S. is calculated from MIT, MIE, and MEC for the sample normalized to Pittsburg coal dust, whereas E.S. is calculated from Pmax and[dP/dt]max for the sample, also normalized to Pittsburg coal dust.
Resistivity Testing (for metal dust in particular)The resistivity testing is particularly important for metal dust. The electrical nature of the dust is one criteria to determine if it is necessary to take special precaution with regard to electrical insulation of the equipment operating in a location with Class II dust.
View Other Fire Investigation Testing - Fire, Smoke, Char, Ash, Soot, Accelerants
FREE Combustible Dust Poster for Environmental Professionals
Download 8.5 X 11 PDF
One-Day Workshop July 25 includes tour and live demonstrations in combustible dust testing laboratory
EMSL Analytical Combustible Dust Testing Options:
Initial Dust CharacterizationThe most important information determined in this stage are Percent Combustible Dust. This is the percentage of the sample that has the potential to be combustible when it is dry and fine enough to pass through a 40 mesh sieve (less than 420 μm in size). The testing includes:
- Percent through 40 Mesh Screen
- Percent Moisture Content
- Percent Combustible Material (calculated)
- Percent Combustible Dust (calculated)
Go – No Go Testing (Explosive Screening) – ASTM E1226This is an economical and practical way to determine if the dust in the sample has the potential to be explosive. Testing consists of exposing the fine dust in the sample to low energy igniters inside the 20-Liter Siwek explosion chamber and determine the explosion over pressure. If the dust is not found to be an explosive threat, the analysis can be aborted to avoid unnecessary fees. If the sample turns out to be explosive on the screen testing, the more comprehensive analyses listed below should be conducted.
Explosion Severity (Kst, Pmax, [dP/dt]max) – ASTM E1226This testing provides an indication of the severity of the dust explosion by determining the deflagration parameters. The larger the value of Kst, the more severe the explosion is. For this test, the dust is suspended and ignited in the Siwek chamber and the maximum pressureand the rate of pressure rise are measured.
Minimum Explosion Concentration (MEC) – ASTME1515MEC is the minimum concentration for explosivity of a combustible dust cloud. It is determined by suspending the dust in the Siwek Chamber.
Minimum Ignition Energy (MIE) – ASTM E2019MIE is the electrical energy discharged from a capacitor, just sufficient to produce the ignition of the most ignitable mixture of air and dust. It is determined by suspending the dust in a Hartmann Lucite explosion chamber.
Minimum Ignition Temperature Test (MIT) – ASTM E1491 (dust cloud)ASTM E2021 (dust layer)This test method covers the minimum temperature at which a dust cloud will autoignite when exposed to air and heated in a furnace at atmospheric pressure. It is determined by introducing the dust into a BAM oven. As an alternative, the minimum temperature of self-ignition of dust layer can be measured using a hot plate set-up.
Class II TestingThis level of testing involves a number of parameters that determine if the sampled dust is considered a Class II hazardous material. Class II locations are defined as locations with combustible dust having Ignition Sensitivity (I.S.) greater than or equal to 0.2 or Explosion Severity (E.S.) greater than or equal to 0.5. I.S. is calculated from MIT, MIE, and MEC for the sample normalized to Pittsburg coal dust, whereas E.S. is calculated from Pmax and[dP/dt]max for the sample, also normalized to Pittsburg coal dust.
Resistivity Testing (for metal dust in particular)The resistivity testing is particularly important for metal dust. The electrical nature of the dust is one criteria to determine if it is necessary to take special precaution with regard to electrical insulation of the equipment operating in a location with Class II dust.
View Other Fire Investigation Testing - Fire, Smoke, Char, Ash, Soot, Accelerants
FREE Combustible Dust Poster for Environmental Professionals
Download 8.5 X 11 PDF
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