Combustibility and flammability

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DIN4102 Flammability Class B1 Vertical Shaft Furnace at Technische Universität Braunschweig, Germany
Sample Holder for DIN4102 Flammability Class B1 Vertical Shaft Furnace
The international pictogram for inflammable chemicals
German test apparatus for determining combustibility at Technische Universität Braunschweig

A combustible material is a material that can burn (i.e., sustain a flame) in air under certain conditions. A material is flammable if it ignites easily at ambient temperatures. In other words, a combustible material ignites with some effort and a flammable material catches fire immediately on exposure to flame.

The degree of flammability in air depends largely upon the volatility of the material - this is related to its composition-specific vapour pressure, which is temperature dependent. The quantity of vapour produced can be enhanced by increasing the surface area of the material forming a mist or dust. Take wood as an example. Finely divided wood dust can undergo explosive flames and produce a blast wave. A piece of paper (made from wood) catches on fire quite easily. A heavy oak desk is much harder to ignite, even though the wood fibre is the same in all three materials.

Common sense (and indeed scientific consensus until the mid-1700s) would seem to suggest that material "disappears" when burned, as only the ash is left. In fact, there is an increase in weight because the flammable material reacts (or combines) chemically with oxygen, which also has mass. The original mass of flammable material and the mass of the oxygen required for flames equals the mass of the flame products (ash, water, carbon dioxide, and other gases). Antoine Lavoisier, one of the pioneers in these early insights, stated that Nothing is lost, nothing is created, everything is transformed, which would later be known as the law of conservation of mass. Lavoisier used the experimental fact that some metals gained mass when they burned to support his ideas.

Definitions[edit]

Historically, flammable, inflammable and combustible meant capable of burning.[1] The word "inflammable" came through French from the Latin inflammāre = "to set fire to", where the Latin preposition "in-"[2] means "in" as in "indoctrinate", rather than "not" as in "invisible" and "ineligible".

The word "inflammable" may be erroneously thought to mean "non-flammable".[3] The erroneous usage of the word "inflammable" is a significant safety hazard. Therefore, since the 1950s, efforts to put forward the use of "flammable" in place of "inflammable" were accepted by linguists, and it is now the accepted standard in American English and British English.[4][5] Antonyms of "flammable" or "inflammable" include: non-flammable, non-inflammable, incombustible, non-combustible, not flammable, and fireproof.

Flammable applies to combustible materials that ignite easily and thus are more dangerous and more highly regulated. Less easily ignited less-vigorously burning materials are combustible. For example, in the United States flammable liquids, by definition, have a flash point below 100 °F (38 °C)—where combustible liquids have a flash point above 100 °F (38 °C). Flammable solids are solids that are readily combustible, or may cause or contribute to fire through friction. Readily combustible solids are powdered, granular, or pasty substances that easily ignite by brief contact with an ignition source, such as a burning match, and spread flame rapidly.[6] The technical definitions vary between countries so the United Nations created the Globally Harmonized System of Classification and Labeling of Chemicals, which defines the flash point temperature of flammable liquids as between 0 and 140 °F (60 °C) and combustible liquids between 140 °F (60 °C) and 200 °F (93 °C).[6]

Flammability[edit]

Flammability is the ease with which a combustible substance can be ignited, causing fire or combustion or even an explosion. The degree of difficulty required to cause the combustion of a substance is quantified through fire testing. Internationally, a variety of test protocols exist to quantify flammability. The ratings achieved are used in building codes, insurance requirements, fire codes and other regulations governing the use of building materials as well as the storage and handling of highly flammable substances inside and outside of structures and in surface and air transportation. For instance, changing an occupancy by altering the flammability of the contents requires the owner of a building to apply for a building permit to make sure that the overall fire protection design basis of the facility can take the change into account.

Classification of flammability[edit]

The US Government uses the Hazardous Materials Identification System (HMIS) standard for flammability ratings, as do many US regulatory agencies, and also the US National Fire Protection Association (NFPA).

The ratings are as follows:

Rating Degree of flammability Examples
0 Materials that do not burn water
1 Materials that must be preheated before they ignite lubricating oils, cooking oils
2 Materials that must be moderately heated or exposed to relatively high ambient temperatures before they ignite diesel fuel
3 Liquids and solids that can ignite under almost all temperature conditions gasoline, acetone
4 Materials that rapidly vaporize at atmospheric pressure and normal temperatures, or readily disperse in air and burn readily natural gas, propane, butane

Examples of flammable substances[edit]

Flammable substances include, but are not limited to:

Examples of nonflammable liquids[edit]

Furniture flammability[edit]

Flammability of furniture is of concern as cigarettes and candle accidents can trigger domestic fires. In 1975, California began implementing Technical Bulletin 117 (TB 117), which required that materials such as polyurethane foam used to fill furniture be able to withstand a small open flame, equivalent to a candle, for at least 12 seconds.[7] In polyurethane foam, furniture manufacturers typically meet TB 117 with additive halogenated organic flame retardants. No other U.S. states had similar standards, but because California has such a large market, manufacturers meet TB 117 in products that they distribute across the United States. The proliferation of flame retardants, and especially halogenated organic flame retardants, in furniture across the United States is strongly linked to TB 117. When it became apparent that the risk-benefit ratio of this approach was unfavorable and industry had used falsified documentation (i.e. see David Heimbach) for the use of flame retardants, California modified TB 117 to require that fabric covering upholstered furniture meet a smolder test replacing the open flame test.[8] Gov. Jerry Brown signed the modified TB117-2013, which became effective in 2014.[9]

Fabric flammability[edit]

Lightweight textiles with porous surfaces are the most flammable fabrics.[10] Wool is less flammable than cotton, linen, silk, or viscose (rayon).[10][11] Polyester and nylon resist ignition, and melt rather than catch fire.[10][11] Acrylic is the most flammable synthetic fiber.[10]

Testing[edit]

A fire test can be conducted to determine the degree of flammability. Test standards used to make this determination but are not limited to the following:

Combustibility[edit]

Combustibility is a measure of how easily a substance bursts into flame, through fire or combustion. This is an important property to consider when a substance is used for construction or is being stored. It is also important in processes that produce combustible substances as a by-product. Special precautions are usually required for substances that are easily combustible. These measures may include installation of fire sprinklers or storage remote from possible sources of ignition.

Substances with low combustibility may be selected for construction where the fire risk must be reduced, such as apartment buildings, houses, or offices. If combustible resources are used there is greater chance of fire accidents and deaths. Fire resistant substances are preferred for building materials and furnishings.

Non-combustible material[edit]

A non-combustible material[12] is a substance that does not ignite, burn, support combustion, or release flammable vapors when subject to fire or heat, in the form in which it is used and under conditions anticipated. Any solid substance complying with either of two sets of passing criteria listed in Section 8 of ASTM E 136 when the substance is tested in accordance with the procedure specified in ASTM E 136 is considered to be non-combustible.[13]

Combustible dust[edit]

A number of industrial processes produce combustible dust as a by-product. The most common being wood dust. Combustible dust has been defined as: a solid material composed of distinct particles or pieces, regardless of size, shape, or chemical composition, which presents a fire or deflagration hazard when suspended in air or some other oxidizing medium over a range of concentrations.[14] In addition to wood, combustible dusts include metals, especially magnesium, titanium and aluminum, as well as other carbon-based dusts.[14] There are at least 140 known substances that produce combustible dust.[15]: 38 [16] While the particles in a combustible dusts may be of any size, normally they have a diameter of less than 420 μm.[14][note 1] As of 2012, the United States Occupational Safety and Health Administration has yet to adopt a comprehensive set of rules on combustible dust.[17]

When suspended in air (or any oxidizing environment), the fine particles of combustible dust present a potential for explosions. Accumulated dust, even when not suspended in air, remains a fire hazard. The National Fire Protection Association (U.S.) specifically addresses the prevention of fires and dust explosions in agricultural and food products facilities in NFPA Code section 61,[18] and other industries in NFPA Code sections 651–664.[note 2] Collectors designed to reduce airborne dust account for more than 40 percent of all dust explosions.[19] Other important processes are grinding and pulverizing, transporting powders, filing silos and containers (which produces powder), and the mixing and blending of powders.[20]

Investigation of 200 dust explosions and fires, between 1980 and 2005, indicated approximately 100 fatalities and 600 injuries.[15]: 105–106  In January 2003, a polyethylene powder explosion and fire at the West Pharmaceutical Services plant in Kinston, North Carolina resulted in the deaths of six workers and injuries to 38 others.[15]: 104  In February 2008 an explosion of sugar dust rocked the Imperial Sugar Company's plant at Port Wentworth, Georgia,[21] resulting in thirteen deaths.[22]

Important characteristics[edit]

Flash point[edit]

A material's flash point is a metric of how easy it is to ignite the vapor of the material as it evaporates into the atmosphere. It is defined as the lowest material temperature required for fuel oils in the materials to begin to give off flammable vapors in the quantity high enough to support a flash of fire when ignited by an external source.[23] A lower flash point indicates higher flammability. Materials with flash points below 100 °F (38 °C) are regulated in the United States by OSHA as potential workplace hazards.

Flame point[edit]

The flame point of a material is a temperature value at which sustained flame can be supported on the material once ignited by an external source.[23] Once the flame point of a material is reached, it produces enough fuel vapors or oils to support continuous burning.

Flammability or explosive range[edit]

The lower flammability limit or lower explosive limit (LFL/LEL) represents the lowest air to fuel vapor concentration required for combustion to take place when ignited by an external source, for any particular chemical.[24] Any concentration lower than this could not produce a flame or result in combustion. The upper flammability limit or upper explosive limit (UFL/UEL) represents the highest air to fuel vapor concentration at which combustion can take place when ignited by an external source.[24] Any fuel-air mixture higher than this would be too concentrated to result in combustion. The values existing between these two limits represent the flammable or explosive range. Within this threshold, give an external ignition source, combustion of the particular fuel would likely happen.

Vapor pressure[edit]

The vapor pressure of a liquid, which varies with its temperature, is a measure of how much the vapor of the liquid tends to concentrate in the surrounding atmosphere as the liquid evaporates.[25] Vapor pressure is a major determinant of the flash point and flame point, with higher vapor pressures leading to lower flash points and higher flammability ratings.

Codes[edit]

The International Code Council (ICC) developed fire code requirements to provide adequate protection to the building and occupants.[26] These codes specify the combustibility rating for materials, the entrance and exit requirements, as well as active fire protection requirements, along with numerous other things. In the U.S. other agencies have also developed building codes that specify combustibility ratings such as state and/or county governing bodies. Following the requirements of these fire codes are crucial for higher occupancy buildings.

For existing buildings, fire codes focus on maintaining the occupancies as originally intended. In other words, if a portion of a building were designed as an apartment, one could not suddenly load it with flammable liquids and turn it into a gas storage facility, because the fire load and smoke development in that one apartment would be so immense as to overtax the active fire protection as well as the passive fire protection means for the building. The handling and use of flammable substances inside a building is subject to the local fire code, which is ordinarily enforced by the local fire prevention officer.

Code definitions[edit]

For an Authority Having Jurisdiction, combustibility is defined by the local code. In the National Building Code of Canada, it is defined as follows:

BS 476-4:1970 defines a test for combustibility in which a technician heats three specimens of a material in a furnace. Combustibile materials are those for which any of the three specimens either:

  • Makes the temperature reading from either of two thermocouples rise by 50 degrees Celsius or more above the initial furnace temperature
  • Flame continuously for 10 seconds or more inside the furnace

Otherwise, the material is classified as non-combustible.

Fire testing[edit]

Various countries have tests for determining non-combustibility of materials. Most involve the heating of a specified quantity of the test specimen for a set duration. Usually, the material must not support combustion and must not lose more than a certain amount of mass. As a general rule of thumb, concrete, steel, and ceramics - in other words inorganic substances - pass these tests, so building codes list them as suitable and sometimes even mandate their use in certain applications. In Canada, for instance, firewalls must be made of concrete.

Categorization of building materials[edit]

Materials can be tested for the degree of flammability and combustibility in accordance with the German DIN 4102. DIN 4102, as well as its British cousin BS 476 include for testing of passive fire protection systems, as well as some of its constituent materials.

The following are the categories in order of degree of combustibility and flammability:

Rating Degree of flammability Examples
A1 100% noncombustible (nicht brennbar)
A2 ≈98% noncombustible (nicht brennbar)
B1 Difficult to ignite (schwer entflammbar) intumescents and some high end silicones
B2 Normal combustibility wood
B3 Easily ignited (leicht entflammbar) polystyrene

A more recent industrial standard is the European EN 13501-1 - Fire classification of construction products and building elements—which roughly replaces A2 with A2/B, B1 with C, B2 with D/E and B3 with F.

B3 or F rated materials may not be used in building unless combined with another material that reduces the flammability of those materials.

See also[edit]

Notes[edit]

  1. ^ I.e. they can pass through a U.S. No. 40 standard sieve.
  2. ^ E.g. NFPA 651 (aluminium), NFPA 652 (magnesium), NFPA 655 (sulphur)

References[edit]

  1. ^ inflammable, a. (n.) 1. combustible a. and n. 1. Oxford English Dictionary. 2nd ed. 2009. CD-rom.
  2. ^ "flammable", The American Heritage Dictionary of the English Language, 5th ed. Houghton Mifflin Harcourt Publishing Company. 2014. accessed 3/11/2015
  3. ^ Sherk, Bill. "fireproof", 500 Years of New Words. Toronto: Dundurn, 2004. 96. Print.
  4. ^ Garner, Bryan A., Garner's Modern American Usage. 3rd ed. New York: Oxford UP, 2009. 357. Print.
  5. ^ "inflammable". Common Errors in English Usage, The Web Site of Professor Paul Brians. Washington State University. Retrieved 30 June 2012.
  6. ^ a b "A Guide toThe Globally Harmonized System of Classification and Labeling of Chemicals (GHS)". Occupational Safety & Health Administration. U.S. Department of Labor. 2006. Archived from the original on 2007-07-02. Retrieved 2015-03-12.
  7. ^ California Department of Consumer Affairs, Bureau of Home Furnishings (March 2000). "Technical Bulletin 117: Requirements, test procedure and apparatus for testing the flame retardance of resilient filling" (PDF) (Report). pp. 1–8. Archived from the original (PDF) on 2014-06-11. Retrieved 2014-11-04.
  8. ^ "Proposed Regulations - Notice of Proposed New Flammability Standards for Upholstered Furniture/Articles Exempt from Flammability Standards". Department of Consumer Affairs, Bureau of Electronic and Appliance Repair, Home Furnishings and Thermal Insulation. Archived from the original on 2013-05-24. Retrieved 2014-11-04.
  9. ^ "Calif. law change sparks debate over use of flame retardants in furniture". PBS Newshour. January 1, 2014. Archived from the original on Nov 2, 2014. Retrieved November 1, 2014.
  10. ^ a b c d "These clothes are the most flammable". Sikker hverdag. Retrieved 2023-06-20.
  11. ^ a b "Flammable Fabrics". City of Phoenix. Retrieved 2023-06-20.
  12. ^ "NCDOI OSFM Evaluation Services: Subject of White Paper: Classification of Building Materials According to Combustibility" (PDF). NC DOI. 8 September 2011. Archived from the original (PDF) on Dec 6, 2018. Retrieved 6 December 2018.
  13. ^ "Standard Test Method for Assessing Combustibility of Materials Using a Vertical Tube Furnace at 750°C". ASTM International. Oct 10, 2022. Retrieved 2023-04-10.
  14. ^ a b c "Hazard Communication Guidance for Combustible Dusts". Occupational Safety and Health Administration. Retrieved 2023-04-10.
  15. ^ a b c Investigation Report No. 2006-H-1, Combustible Dust Hazard Study (PDF), Washington, D.C.: U.S. Chemical Safety and Hazard Investigation Board, 17 November 2006, OCLC 246682805, archived from the original (PDF) on 21 December 2016, retrieved 21 August 2017
  16. ^ National Materials Advisory Board, Panel on Classification of Combustible Dusts of the Committee on Evaluation of Industrial Hazards (1980) Classification of combustible dusts in accordance with the national electrical code Publication NMAB 353-3, National Research Council (U.S.), Washington, D.C., OCLC 8391202
  17. ^ Smith, Sandy (7 February 2012) "Only OSHA Has Not Adopted Chemical Safety Board Recommendations Stemming from Imperial Sugar Explosion" EHS Today
  18. ^ "NFPA 61 Standard for the Prevention of Fires and Dust Explosions in Agricultural and Food Processing Facilities"
  19. ^ Zalosh, Robert et al. (April 2005) "Dust Explosion Scenarios and Case Histories in the CCPS Guidelines for Safe Handling of Powders and Bulk Solids" 39th AIChE Loss Prevention Symposium Session on Dust Explosions Atlanta, Georgia
  20. ^ O'Brien, Michael (2008) "Controlling Static Hazards is Key to Preventing Combustible Cloud Explosions" Newton Gale, Inc. Archived 2012-05-07 at the Wayback Machine
  21. ^ The chief executive, John C. Sheptor, said the probable cause of the explosion was sugar dust building up in storage areas, which could have been ignited by static electricity or a spark. Dewan, Shaila (9 February 2008). "Lives and a Georgia Community's Anchor Are Lost". The New York Times. Retrieved 7 May 2012.
  22. ^ Chapman, Dan (13 April 2008). "Sugar refinery near Savannah determined to rebuild". The Atlanta Journal-Constitution. Archived from the original on June 29, 2011. Retrieved 7 May 2012.
  23. ^ a b Thangarasu, Vinoth; Anand, R. (2019-01-01), Azad, Kalam (ed.), "11 - Physicochemical fuel properties and tribological behavior of aegle marmelos correa biodiesel", Advances in Eco-Fuels for a Sustainable Environment, Woodhead Publishing Series in Energy, Woodhead Publishing, pp. 309–336, ISBN 978-0-08-102728-8, retrieved 2023-04-10
  24. ^ a b Manha, William D. (2009-01-01), Musgrave, Gary Eugene; Larsen, Axel (Skip) M.; Sgobba, Tommaso (eds.), "Chapter 20 - Propellant Systems Safety", Safety Design for Space Systems, Burlington: Butterworth-Heinemann, pp. 661–694, ISBN 978-0-7506-8580-1, retrieved 2023-04-10
  25. ^ "Vapor Pressure". ch302.cm.utexas.edu. Retrieved 2023-04-10.
  26. ^ "Digital Codes". codes.iccsafe.org. Retrieved 2023-04-10.

External links[edit]