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Fire Dynamics I

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Title: Fire Dynamics I


1
Fire Dynamics I
  • Lecture 1
  • Introduction / Polymeric Fuels
  • Jim Mehaffey
  • 82.575 or CVG7300

2
  • Introduction / Polymeric Fuels
  • Outline
  • Introduction
  • Gaseous, Liquid and Solid Fuels
  • Nature of Polymeric (Solid) Fuels
  • Thermal Decomposition of Polymers

3
  • Definitions
  • Fire dynamics study of how to describe and
    estimate the growth and intensity of fires
  • Fire safety engineering application of
    engineering principles based on a fundamental
    understanding of fire dynamics in order to save
    lives and protect property

4
  • Fire Dynamics
  • Fire involves exothermic chemical reactions
    between combustibles and oxygen
  • Physical conditions of fuel environment
    important
  • Fire dynamics depend on
  • Chemistry
  • Heat transfer
  • Fluid mechanics

5
  • The Nature of Fuels (Fire)
  • Gas / Liquid /Solid
  • Carbon-based Fuels
  • Simple gaseous hydrocarbons (CH4)
  • Solids of high molecular weight and great
    chemical complexity (polymers)

6
  • Gaseous Liquid Fuels Alkanes (CnH2n2)

7
  • Gaseous Liquid Fuels Others

8
  • Chemical Formula
  • Methane CH4 (actually a tetrahedron)
  • n - octane normal octane (C8H8)

9
  • Molecular Weight
  • Mole amount of a substance containing as many
    atoms or molecules as 12 g of Carbon-12
  • Mole 6.02 x 1023 atoms or molecules (Avagadro)
  • Molecular weight mass of 1 mole of of substance
    (g mol-1)
  • Molecular weight sum of atomic weights of
    constituents
  • Molecular weight (CH4) 1 x atomic weight of C
    4 x atomic weight of H
  • 1 x 12 4 x 1
  • 16

10
  • Solid Fuels

11
  • Flaming Combustion
  • Flaming combustion occurs in the gaseous phase
  • Gaseous hydrocarbons (e.g. CH4) can be ignited in
    air to produce flame
  • Flaming combustion of liquids solids requires
    conversion to volatiles (vapours)
  • For most liquids (e.g. C8H8) volatiles produced
    by evaporation
  • Liquids with high boiling points (gt250C) undergo
    chemical decomposition (e.g. cooking oil)

12
  • Flaming Combustion
  • For most solids, chemical decomposition
    (pyrolysis) yields products of low molecular
    weight which volatilize from surface
  • Surface temperature of burning solids 400ºC
  • Composition of volatiles is complex and depends
    on chemical nature of the solid

13
  • Polymers
  • Combustible solids are polymers of high molecular
    weight
  • A polymer consists of long chains of repeated
    units called monomers
  • Polymers are classified as
  • Natural or synthetic
  • Thermoplastic or thermosetting
  • Addition or condensation

14
  • Addition Polymers
  • Formed by direct addition of monomer units to a
    growing polymer chain
  • Simplest example Generation (polmerization) of
    polyethylene from ethylene
  • Ethylene C2H4 is a gas H H

  • C C
  • H H
  • Polymerization commences when double bond is
    broken replaced with a single bond

15
  • Production of Polyethylene
  • Use hydrogen peroxide (H2O2) as initiator
  • H H
    H H


  • 1st step H O O H C C
    ? H O H O C C

  • H H
    H H
  • H H
    H H H H H H


  • 2nd step H O C C C C
    ? H O C C C C

  • H H H H
    H H H H

16
  • Production of Polyethylene
  • Chain reaction proceeds spontaneously
    (exothermic)
  • Termination can occur if
  • OH group attaches to end, or
  • two chains combine
  • Length of chain can be controlled by controlling
    amount of initiator

17
  • Structure of Polyethylene
  • n Degree of polymerization
  • Also written as
  • R - C2H4n - R

18
  • Structure of Polyethylene
  • As n ? gas ? liquid ? wax ? solid (polymer)
  • When n 200 material is a solid (polymer)
  • For commercial polyethylene n gt 3,000
  • For most polymers
  • 10,000 lt molecular weight lt 1,000,000
  • Polymer chains are twisted intertwined
  • Chains are not all the same length

19
  • Condensation Polymers
  • Formed by reactions in which two monomers link
    dropping a small molecular species (H2O)
  • Examples Cellulose and nylon 66
  • Condensation polymers are often more complex than
    addition polymers

20
  • Idealized Structure of NYLON 66
  • 66 refers to
  • 6 carbon atoms in amine unit, and
  • 6 carbon atoms in carboxyl acid unit

21
  • Production of NYLON 66
  • ?

22
  • Production of NYLON 66
  • Polymerization can continue at both ends of the
    new molecule by the same reaction
  • An endothermic reaction, so heat must be added
    for reaction to continue
  • Reaction continues until almost all of one of
    reactants is used up

23
  • Basic Structure of Polymers (Plastics)
  • Monomer A with two reactive groups can form
    linear chains
  • A A A A A A A
  • Properties of polymer can be modified by
  • Changing chain length (control amount of
    initiator)
  • Changing the monomer A
  • Introducing branching (vary conditions of
    reaction)

24
  • Polyethylene
  • Branching in Polyethylene

25
  • Branching in Polyethylene
  • Low density polyethylene (LDPE)
  • 8 to 40 branch points per 1000 main chain C atoms
  • Density 940 kg m-3
  • High density polyethylene (HDPE)
  • 5 or less branch points per 1000 main chain C
    atoms
  • Density 970 kg m-3
  • Polymethylene (PM)
  • Polyethylene with no branch points
  • LDPE is less thermally stable than HDPE which is
    less thermally stable than PM

26
  • Branching in Polymers
  • Branching occurs in linear polymers
    (polyethylene)
  • Branching can also be achieved by adding a small
    amount of a monomer B with 3 reactive groups
  • A
  • A
  • A A A B A A A

27
  • Cross-Linking in Polymers
  • Branching can produce cross-linked structures
    with altered physical and chemical properties
  • A A A B A A A B A A A A
    A B A A A


  • A
    A
    A


  • A
    A
    A


  • B A A A
    B A A B A A B A B A


  • A
    A
    A


  • A B A A B A A A A A A
    B A A A A B A A
  • A

28
  • Cross-Linked Polymer
  • Example Polyurethane (PU)
  • A copolymer of tolylene di-isocyanate and a
    polymer diol
  • B trihydric alcohol
  • Flexible PU foam - low degree of cross-linking
  • Rigid PU foam - high degree of cross-linking

29
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30
  • Thermoplastics
  • Flexible linear chains held together by weak
    (van der Waals) forces
  • Produced by addition or condensation reactions
  • Fire Performance
  • Melting temperature lower than ignition
    temperature
  • Generally do not produce char
  • Fire spread may be enhanced by burning droplets
    or spread of a pool of molten polymer
  • Fire spread may reduced if plastic melts and
    falls away from fire (NBCC 1995 / 3.1.13.4. Light
    Diffusers and Lenses)

31
  • Thermosetting Plastics
  • Linear chains bonded together via cross-linking
    into a rigid 3-D network
  • Cross-linking produced by condensation reactions
  • Fire Performance
  • Do not melt. Decompose to give volatiles char.
  • Volatile yield decreases as cross-linking
    increases (e.g. phenolic resins heated to 500C
    yield 60 char)
  • Thermosets burn much like wood
  • Lightly cross-linked thermosets may behave like
    thermoplastics (e.g. flexible polyurethane foam)

32
  • Formation of Volatiles from a Solid

33
  • Formation of Volatiles from a Solid

34
  • Products of Thermal Decomposition
  • Volatiles range from simple molecules to
    relatively large molecules
  • Volatiles (and rate of production) effect
    ignitability, flammability and toxicity
  • In flaming combustion most of volatiles consumed
  • In pyrolysis without combustion liquids tars
    condense forming aerosol smoke
  • Char regulates heat transfer to deeper
    pyrolysing levels hence effects flammability
  • Char may undergo oxidation

35
  • Mechanisms of Thermal Decomposition
  • 1. Unzipping or end-chain scission
  • For some addition polymers, thermal decomposition
    occurs by successive removal of monomer units
    from end of polymer backbone

36
  • Mechanisms of Thermal Decomposition
  • 2. Random chain Scission
  • Main chain bonds are broken at random locations
    along polymer backbone
  • Process continues until sections small enough to
    volatilize are generated
  • Products of thermal decomposition include wide
    range of molecular species
  • Example polyethylene

37
  • Mechanisms of Thermal Decomposition
  • 2. Random chain scission
  • Main chain bonds are broken at random locations
    along polymer backbone
  • Process continues until sections small enough to
    volatilize are generated
  • Products of thermal decomposition include wide
    range of molecular species
  • Example polyethylene

38
  • Mechanisms of Thermal Decomposition
  • 3. Chain stripping
  • Backbone remains intact but molecular species
    which are not part of main chain break away
  • Example Polyvinyl chloride (PVC) loses HCl at
    about 250C leaving a char-like residue

39
  • Flammability of PVC
  • HCl is an effective combustion inhibitor
  • Like most plastics, PVC has additives
  • (plasticizer / filler / pigment / fire
    retardant)
  • Rigid PVC grades used for electrical insulation
    often have low flammability
  • Flexible PVC often contains plasticizer which
    makes it more flammable
  • Caution HCl is an acid gas that is both
    corrosive and toxic
  • Char residue burns at high temperatures

40
  • Mechanisms of Thermal Decomposition
  • 4. Cross-linking
  • Some polymers undergo cross-linking during
    pyrolysis generating a lot of char
  • This reduces volatiles and flammability
  • Cross-linking during pyrolysis usually occurs
    together with other mechanisms
  • Effect not usually significant for thermoplastics
  • For thermosets, like phenolic resin (slide 1-30),
    which are highly cross-linked, further
    cross-linking can occur during pyrolysis

41
  • Thermal Stability of Polymers
  • Th Temperature at which half-life of polymer is
    30 min

42
  • Factors Affecting Thermal Stability
  • Increasing molecular weight strengthens polymer
  • Increasing chain branching weakens polymer
  • Increasing cross-linking strengthens polymer
  • Introducing double bonds in polymer backbone
    weakens polymer
  • Introducing aromatic rings in polymer backbone
    strengthens polymer
  • Introducing oxygen in polymer backbone weakens
    polymer

43
  • Increasing mol wt strengthens polymer
  • Polymethylmethacrylate (PMMA)
  • PMMA A (MW 1.5 x 105) Th 283 ?C
  • PMMA B (MW 5.1 x 106) Th 327 ?C
  • Monomer - C5H8O2 -

44
  • Increasing branching weakens polymer
  • Polymethylene (PM) Th 415 ?C
  • Polyethylene (PE) Th 406 ?C
  • Polypropylene (PP) Th 387 ?C
  • Polyisobutylene Th 348 ?C

45
  • Increasing branching weakens polymer
  • Monomers

46
  • Impact of Products of Decomposition
  • on Polymer Flammability
  • Production of char reduces production of volatile
  • Char insulates unburned polymer from heat of
    flame
  • Volatiles affect flame chemistry
  • Volatiles affect soot production
  • Soot controls thermal radiation
  • Aromatic volatiles (benzene) yield flames of high
    emissivity (e.g. polystyrene)
  • Thermal radiation affects rate of burning

47
  • Impact of Products of Decomposition
  • on Polymer Flammability
  • Volatiles (product of decomposition) affect
    toxicity HCl from PVC HCN from wool or
    polyurethane)
  • Principal toxicant is CO (carbon monoxide), a
    product of combustion (not decomposition). Rate
    of generation CO depends on conditions of burning
    and supply of air

48
  • Behaviour of Individual Polymers
  • The properties of a plastic depend sensitively on
    the degree of polymerization (molecular weight)
    of the main polymer, its degree of branching and
    the presence of additives. Values given below
    may not apply to all commercial plastics.
  • Additives can comprise 1/2 or more of the weight
    of commercially available plastics.
  • Additives fillers, plasticisers, lubricants,
    anti-aging agents, fire retardants, colorants,
    blowing agents, impurities

49
  • Definitions
  • Tm melting temperature
  • Td temperature at which molecular weight
    decreases (depolymerization commences)
  • Tv temperature at which volatilization
    commences
  • Th half-life temperature (30 minutes)
  • Tig ignition temperature
  • Mech primary mechanism of thermal decomposition
  • Prod principal products of thermal
    decomposition

50
  • Polyethylene (PE)
  • Applications waste baskets, bags, plastic chairs
  • Type thermoplastic
  • Tm 133C 406 K
  • Td 292C 565 K Note PE is recycable
  • Tv 372C 645 K
  • Th 406C 679 K
  • Tig 363C 636 K
  • Mech random chain scission
  • Prod alkanes alkenes with 2 or 3 carbons

51
  • Polypropylene (PP)
  • Applications carpet backing, TV computers
  • Type thermoplastic
  • Tm 186C 459 K
  • Td 237C 510 K
  • Tv 302C 575 K
  • Th 387C 660 K
  • Tig 334C 607 K
  • Mech random chain scission
  • Note PP is recycable

52
  • Polyvinyl Chloride (PVC)
  • Applications piping, siding, flooring,
    upholstery
  • Type thermoplastic, but does produce char
  • Td Tv 250C 523 K (generation of HCl)
  • Mech chain stripping
  • Note H2 is evolved from char 452C 725 K
  • Monomer -C2H3Cl-

53
  • Polystyrene (PS)
  • Applications insulation, foam cups
  • Type thermoplastic
  • Tm 240C 513 K
  • Tv 302C 575 K
  • Th 364C 637 K
  • Tig 366C 639 K
  • Mech random chain scission
  • Prod monomer, dimer, trimer tetramer
  • Note PE is recycable

54
  • Polystyrene (PS)
  • Monomer -C8H8-

55
  • Polymethyl Methacrylate (PMMA)
  • Applications plexiglass, glazing
  • Type thermoplastic, but does not flow well
  • Tm 160C 433 K
  • Tv Td 272C 545 K
  • Th 327C 600 K
  • Tig 310C 583 K
  • Mech end chain scission
  • Prod monomer
  • Note Th Tig are for high molecular weight PMMA
    B

56
  • Polyurethane (PU)
  • Applications flexible foam cushions, mattresses
    rigid foam insulation
  • Type thermosetting, but does melt
  • Td gt 202C 475 K
  • Mech very complex decomposition process many
    steps and many products (including HCN)

57
  • References
  • D. Drysdale, An Introduction to Fire
    Dynamics,Wiley, 1999, Chap 1
  • F.W. Billmeyer, Textbook of Polymer Science,
    Wiley, 1984, Chap 1
  • Donald R. Askeland, Science and Engineering of
    Materials, Chapman Hall, 1990, Chapter 15
  • C.F. Cullis and M.M. Hirschler, The Combustion of
    Organic Polymers, Oxford Science Publications,
    1981, Chapter 1
  • C.L. Beyler and M.M. Hirschler, "Thermal
    Decomposition of Polymers" Section 1 / Chapter 7,
    SFPE Handbook, 2nd Ed. (1995)
  • C.F. Cullis and M.M. Hirschler, The Combustion of
    Organic Polymers, Oxford Science Publications,
    1981, Chapter 1
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