nicholas licht design engineer dust explosion fundamentals
TRANSCRIPT
Nicholas LichtDesign Engineer
Dust Explosion Fundamentals
Objectives
• Brief Overview of CV Technology• History of Dust Explosions• Recent Events• Dust Explosion Basics• Codes and Standards• Methods of Protection
Headquarters & Manufacturing in Jupiter, Florida
History of Dust Explosions• First recorded dust
explosion occurred in Turin, Italy back in 1785
• 281 combustible dust incidents in the US from 1980-2005
• Resulted in 119 deaths and 718 injuries
Consequences of Dust ExplosionsFebruary 2008:
Imperial Sugar-Savannah, GA
• Caused by a overheated bearing
• 14 people killed
• Over 40 injured
• Resulting OSHA fines totaled $8.7 million
• Rebuild cost of $200 million
Combustible Dusts Examples
Combustible Dust Events in US: 1980-2005
Food Products24%
Lumber & Wood15%
Chemical Manufacturing12%Primary Metal Industries
8%
Rubber & Plastic
Products8%
Electric Services
8%
Other7%
Fabricated Metal
Products7%
Equipment Manufactur-
ing7%
Furniture & Fixtures4%
Distribution of Dust Events by Industry
Food23%
Wood24%Metal
20%
Plastic14%
Coal8%
Inorganic4%
Other7%
Distribution of Dust Events by Material Type
Note: Coal mines & grain handling facilities excluded from study(Ref. U.S. Chemical Safety Board Report No. 2006-H-1)
Dust Explosion Concept
Log Kindling Dust
-Burns slowly-Difficult to ignite
-Burns quickly-Easier to ignite
-Burns very fast-Easily ignited
Dust Explosion PentagonIgnition Source
Suspended Cloud
Oxygen Explosive
Dust
Confined Area Dust
Explosion Pentagon
Dust Explosion by Equipment Type
Equipment Type % of Incidents
Dust Collector 52
Impact Equipment 17
Silos & Bins 13
Dryers & Ovens 9
Processing Equipment 6
Conveyor 3
Source: FM Global Property Loss Prevention Data Sheet 7-76, “Prevention andMitigation of Combustible Dust Explosion and Fire”, May 2008
Dust Explosion Terminology• Maximum Pressure (Pmax) –
The maximum pressure developed in a contained deflagration of an optimum mixture
• Deflagration Index (Kst) -The deflagration index of a dust cloud– Index value related to the
rate of pressure rise over time
Dust Explosion Terminology
Secondary Explosions:• Occur when deflagrations propagate from one vessel to another
through connecting piping/equipment
• Secondary explosion are often what causes the greatest amount of damage
• Pressure piling will occur increasing deflagrations into detonations
• Explosion isolation equipment used to prevent this from occurring
NFPA Dust Standards
• Keyway Documents
Standard Industry Edition
NFPA 652 All New
NFPA 654 All – General Industry Document 2013
NFPA 61 Food/Agricultural 2013
NFPA 664 Wood 2012
NFPA 484 Metal 2012
NFPA 655 Sulfur 2012
NFPA Dust Standards
• How-to Documents
Standard Purpose Edition
NFPA 68 Explosion Venting 2013
NFPA 69 Suppression/Isolation/Containment/Inerting 2014
NFPA 77 Static Hazards 2014
NFPA 70 National Electric Code 2014
NFPA 499 Practical Electric Classification 2013
Protection Techniques Prevention or Mitigation
• Prevention: eliminate the potential for an explosion
• Mitigation: accept that an explosion may occur and institute engineered measures that eliminate the potential for injury and/or damage– Mitigation is a damage limiting technique
How Does Mitigation Work?
UnventedVented
Time
Pres
sure
Pmax
Pred
Pstat 0.1 bar
Mitigation - VentingVenting:• Rupture panels to relieve
pressure preventing a vessel failure
• Amount of vent area needed is determined using NFPA 68 equations
• Explosion vent need to exhaust into a safe area or a quenching device
Mitigation - Venting
Factors that Impact Venting
• Material (Kst)• Vessel Volume • Vessel Strength
– Reduced Pressure (Pred)
• Vessel Geometry – (L/D Ratio)– Filter Bag/Cartridges
Factors that Impact Venting
• Initial Pressure (+/-)• Explosion Vent
– Mass Index (M)– Burst Pressure (Pstat)– Burst Design
• Hinged/Translating
Mitigation – Suppression
Suppression:• Detect a deflagration at early stage
and quench the event with chemical suppressant
• Cannon/bottle consist of pressurized gas and suppressant chemical
• System triggers by pressure or optical sensor
• Higher maintenance requirements
Mitigation – Suppression
Factors that Impact Suppression
• Vessel Volume • Vessel Strength
– Reduced Pressure (Pred)
• Vessel Geometry – (L/D Ratio)– Filter Bag/Cartridges
Factors that Impact Suppression
• Initial Pressure (+/-)• Material (Kst)
• Activation Pressure (Pstat)
Isolation
Isolation
Isolation:• Must be used to prevent
propagation of an event in one vessel to interconnected equipment
• Usually always needed in conjunction with venting or suppression
Hierarchy of Equipment Use
6.) Containment
7.) Inerting
1.) Free venting a vessel outdoors
2.) Free venting a vessel indoors next to an exterior wall using a duct
3.) Free venting a vessel indoors next to an exterior roof using a duct
4.) Flameless venting
5.) Active Suppression
Prevention
Dust Collectors
Dust Collectors
Hierarchy of Equipment Use
6.) Containment
7.) Inerting
1.) Free venting a vessel outdoors
2.) Free venting a vessel indoors next to an exterior wall using a duct
3.) Free venting a vessel indoors next to an exterior roof using a duct
4.) Flameless venting
5.) Active Suppression
Prevention
Dust Collectors
Dust Collectors
Hierarchy of Equipment Use
6.) Containment
7.) Inerting
1.) Free venting a vessel outdoors
2.) Free venting a vessel indoors next to an exterior wall using a duct
3.) Free venting a vessel indoors next to an exterior roof using a duct
4.) Flameless venting
5.) Active Suppression
Prevention
Dust Collectors
Dust Collectors
Hierarchy of Equipment Use
6.) Containment
7.) Inerting
1.) Free venting a vessel outdoors
2.) Free venting a vessel indoors next to an exterior wall using a duct
3.) Free venting a vessel indoors next to an exterior roof using a duct
4.) Flameless venting
5.) Active Suppression
Prevention
Dust Collectors
Dust Collectors
Hierarchy of Equipment Use
6.) Containment
7.) Inerting
1.) Free venting a vessel outdoors
2.) Free venting a vessel indoors next to an exterior wall using a duct
3.) Free venting a vessel indoors next to an exterior roof using a duct
4.) Flameless venting
5.) Active Suppression
Prevention
Concluding Remarks
• No two dust explosions are the same. – No uniform dust laws like there are for gases
• Standards are evolving
• The dust explosion hazard exists– Be aware of the “I’ve never had a dust explosion
before”
Questions?
References• NFPA-654, “Standard for the Prevention of Fire and Dust Explosions from the
Manufacturing, Processing, and Handling of Combustible Particulate Solids”
• NFPA-68, “Standard on Explosion Protection by Deflagration Venting”
• NFPA-69, “Standard on Explosion Prevention Systems”
• OSHA Website, http://www.osha.gov/
• U.S. Chemical Safety Board, http://www.chemsafety.gov/
• Dust Explosions in the Process Industries, 3rd edition, R.K. Eckhoff, Elsevier, 2003
• Factory Mutual Loss Prevention Data 7-76, “Prevention and Mitigation of Combustible Dust Explosions and Fires”